Are you a scientist, physician, or pharma professional stepping into the world of blockchain and DLT? In this guide, we’ll break down DLT basics and dive into its game-changing applications in pharma and life sciences—from decentralized clinical trials and tokenized research funding to biobanking. Whether you’re interested in decentralized funding models, data security, or how DLT could reshape clinical trials, this is your go-to resource.
What Is DLT and Why It Matters
DLT, or Distributed Ledger Technology, is a secure, decentralized digital record where each transaction (not limited to financial exchanges), is stored across a network of computers across the world. Unlike traditional centralized databases, DLT distributes data across multiple nodes, creating a transparent and nearly tamper-proof record. This decentralized architecture has made DLT a cornerstone in the decentralized science (DeSci) and blockchain for pharma movements.
In DLT, each participant has a copy of this ledger, and they constantly sync with each other. This system is tamper-resistant, as altering one copy requires altering all other copies—a near-impossible feat.
DLT’s Core Benefits in Pharma and Life Sciences:
- Security: High-level cryptographic security ensures data integrity.
- Transparency: Every transaction is visible to authorized participants, making it ideal for industries requiring compliance.
- Efficiency: Reduces middlemen, cuts costs, and increases processing speed, ideal for decentralized clinical research and decentralized science grants.
Watch this video to learn more about DLT: Chain Reaction: Distributed Ledger Technologies (DLT) explained.
Understanding Blocks and Chains
The foundation of blockchain technology lies in its block-and-chain architecture.
Breaking Down Blocks
Think of a block as a container for data, like a digital filing cabinet that stores information (e.g., patient records or trial data). Each block holds:
- Transaction data,
- A timestamp, and
- A cryptographic “hash” (a unique identifier).
Once a block is filled with data, it’s sealed and linked to the previous block, forming a chain of records.
Chains: The Backbone of DLT Security
Each block links to the previous one, forming a nearly unbreakable chain. This interconnected structure provides an additional layer of security. If someone tries to alter any data, every block following it would also need to be changed—a nearly impossible task.
Imagine adding pages to a notebook, each one glued to the last. Once you add a page, it can’t be removed without tearing apart the entire notebook. This is how blockchain ensures data remains intact and unaltered.
DLT’s structure is why it’s considered “unhackable,” bringing new levels of trust and transparency to decentralized science (DeSci) and clinical research.
In the DeSci ecosystem, innovation knows no bounds. Every day, new platforms are emerging to tackle key challenges, from NFT science funding to decentralized clinical trial platforms. Whether you’re a scientist, a physician, or a patient advocate, this network offers a world of tools and communities designed to democratize science and make research more impactful.
Here’s a glimpse into the vast DeSci network
Decentralized Clinical Trials: A Transparent Future
Clinical trials traditionally rely on centralized systems that can slow down recruitment and create data bottlenecks. DLT offers a transparent, decentralized approach, enabling more efficient, secure trials.
Key Features of DLT-Powered Clinical Trials
- Physician and Patient Profiles: Physicians maintain real-time profiles listing specialties, trial participation, and availability. Patients control their data and can join trials with full transparency.
- Patient Consent Tracking: Patients can manage their consent status, giving them the freedom to withdraw or update consent at any time.
- Transparent Data: Every trial stage is logged and verified on a DLT network, accessible to patients, doctors, and sponsors.
Unlike traditional trials that store data in closed systems, decentralized clinical trials allow all parties equal access to secure, transparent data.
Imagine a future where every clinical trial is open, secure, and accessible to all stakeholders—building trust at every step.
AminoChain: Secure Biobanking with DLT
Biobanking, or the storage of biological samples for research, is critical in life sciences. AminoChain uses DLT to transform biobanking, ensuring that samples are traceable, secure, and only accessible by authorized researchers.
In conventional biobanking, transparency is limited, and data access is restricted by centralized protocols. AminoChain’s DLT-powered biobanking disrupts this model by creating an immutable ledger that records every action associated with each sample, from collection to research use. This means that samples are not only stored but continuously verified, providing real-time traceability and ownership clarity.
In a DLT-powered ecosystem, every sample’s path is visible and protected, ensuring that both researchers and patients can trust the integrity of the biobanking process. With AminoChain, biobanking evolves from simple storage to a secure, accountable chain that supports advanced, ethical research.
Molecule: Decentralized Funding for Research
Traditional research funding requires substantial time for grant applications, distracting scientists from essential research. Molecule streamlines research funding, allowing scientists to post projects, seek funds, and retain intellectual property.
How Molecule is Reshaping Funding
- Tokenized Intellectual Property: Researchers can “tokenize” their projects, allowing individuals and companies to invest in research.
- Community-Driven Funding: Molecule and BioDAOs allow interested parties—from patients to biotech companies—to support specific research through DeSci tokens.
- Transparent Ownership: Researchers retain ownership while gaining resources, helping to bridge the funding “Valley of Death.”
Molecule lets scientists return to the lab, while supporters—patients, advocates, and firms—can invest in research that matters to them.
Research Hub: Redefining Scientific Publishing
Research Hub combines decentralized publishing with community feedback. Think of it as a Reddit-style platform for researchers to publish, discuss, and collaborate on scientific projects.
Features of Research Hub
- Crowdsourced Publishing: Researchers can publish preprints and receive real-time feedback from peers.
- Bounty System: Scientists place bounties on questions, offering funding for those who provide valuable answers.
- Transparent Reputation: Researchers build profiles that showcase contributions, allowing them to earn DeSci crypto rewards for meaningful work.
Traditional journals can take years to publish studies, while Research Hub offers an open, immediate forum that promotes collaboration.
With Research Hub, science doesn’t wait for publishing backlogs; it goes straight to the community.
Visit Research Hub – Decentralized platform for scientific publishing and peer collaboration.
DLT in Pharma Supply Chains: Ensuring Authenticity and Safety
DLT isn’t only useful for research; it’s revolutionizing the pharma supply chain. By tracking every step from production to delivery, DLT ensures drug authenticity, reduces counterfeiting, and streamlines recalls.
How DLT Enhances Pharma Supply Chains
- Secure Tracking: Every stage, from manufacturing to patient, is recorded on the blockchain.
- Counterfeit Prevention: With DLT, drugs can be verified as authentic, ensuring they aren’t replaced with counterfeits.
- Quick, Accurate Recalls: In the event of recalls, DLT allows fast, precise tracking, reducing risks and increasing patient safety.
Unlike traditional supply chains that rely on central records, DLT creates a transparent, tamper-proof ledger for every drug’s journey.
In a DLT-powered supply chain, every medication’s path from factory to pharmacy is recorded, ensuring patients receive safe, authentic drugs.
DLT is the Future of Transparent, Patient-Centered Pharma
Distributed Ledger Technology isn’t just hype—it’s transforming every level of decentralized science (DeSci) in pharma, from clinical trials and biobanking to funding and publishing. This transparent, patient-centered technology is redefining trust in scientific research and healthcare.
Are you ready to join the future of decentralized science?
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Paul Kohlhaas - DeSci: The Future of Decentralized Science - Zima Red Podcast
Paul Kohlhaas visited the Podcast of Andrew Steinwald, and spoke about his path into the pharmaceutical space and web3. He shares his experiences in biohacking, the pharma industry, the drug development process and how web3 could play a crucial role in making drug development more efficient, fair and transparent. This is achieved through BioDAOs an open source approach of pharmaceutical early stage research and leveraging the traits of NFTs through and a new standard, the IP-NFT.
Molecule is a company that is virtualizing and decentralizing how drug development works. They do this by attaching data and IP rights to non-fungible tokens (NFT's) and then bringing the core IP into web3. This makes the intellectual property liquid, which is very hard to achieve in biotech today, and also enables price discovery around IP. Molecule has created a curation market where people can trade and discover therapeutics for drugs.
Molecule has also started building biotech DAOs, which are research collectives that are comprised of patients, investors, and researchers in a specific therapeutic area. The mission is to democratize access to medicine by empowering researchers and patients to become co-owners of the IP and data associated with a new therapeutic.
Paul describes how the company's IP-NFTs work to store data associated with a new therapeutic and how they can be used to fractionalize ownership of the IP. He also walks through the company's roadmap and explains how they plan to decentralize ownership of the data and IP associated with a new therapeutic. Paul discusses the origins of VitaDAO and IP-NFT, the process of setting up a DAO, and the long-term vision for a DAO-based ecosystem for pharmaceutical research and development.The grand vision for the projects is to develop a drug that is enabled and discovered through the process and reaches patients in an eight to ten year timeframe. He also discusses the potential for IP-NFTs to be used to fractionalize the ownership of IP and allow patients to contribute funding to research."
Andrew Steinwold 0:00
Hey what's up everyone, I'm Andrew Steinwold, and this is ZIMA RED. On this show, we speak with the users, founders and creatives that are diving into the world of unique digital assets, also called non-fungible tokens.
Intro 0:23
Andrew Steinwold is the managing partner of Sfermion, an investment firm focused on the NFT ecosystem. All opinions expressed by Andrew and podcast guests present solely their own opinions and do not reflect the opinion of the Sfermion. This podcast is for informational purposes only and should not be relied upon as a basis for investment decisions. Sfermion or related entities may maintain positions and assets discussed in this podcast.
Andrew Steinwold 0:48
My guest today is Paul Kohlhaas, the founder of Molecule, as well as VitaDAO and PsyDAO. Molecule is a decentralized biotech protocol, that is democratizing pharma research and development. This one is going to blow your mind, we chat how drug development currently works the monopolistic nature of drug development, the open source pharma movement, longevity research, DAOs, psychedelic medicines, how the Molecule team is building the future of decentralized science and so much more. This episode offers a sneak peek in the future of medicine, please enjoy my conversation with Paul. Paul, thank you so much for joining me today. Super excited to chat with you. And to get started, I'd love to hear a little about your background.
Paul Kohlhaas 0:56
Hi, Andrew. Yeah, thank you so much for the invite on the show. And hi to everyone who's listening. My name is Paul Koolhaas, I am the founder of a new protocol and DAO called Molecule. And my background is pretty atypical to be working on something that straddles the biotech space, but I've been working in the crypto space for a really long time. So when I was a teenager around 16,17,18, I spent a lot of time in online biohacking forums. And these are some of the forums that splintered off harm reduction sites like Erowid. So Erowid, for example, was a large collection of trip reports on psychedelics run in the public domain, a lot was pioneered by Alexander Shulgin, who was the original inventor of MDMA, and then went on to work at a pharma company, as he was doing that, and the pharma company didn't think his work was valuable. I think organizations, such as MAPS are really proving that this thesis was completely wrong. But he went on to discover hundreds of different very strange novel psychedelic compounds, many of them are being actively researched in therapeutic use cases today. And so these communities I was a part of, we're exploring these compounds in a very open fashion. Back then, these were all like unscheduled substances, and research chemicals. And I found that really fascinating, this open source nature of drug discovery and drug development. And as I got deeper into those communities, I realized, hey, at the fringes here, there's diabetes communities, for example, that are developing their own open source insulin synthesis methods. And some of these communities then gave birth to the open insulin movement in the United States, which is now fighting to provide very cheap and affordable insulin made in clandestine labs across the US. Another cases were cancer patient communities, that said, “hey, guys, there's a drug here on the US market, I need to survive and treat my cancer, it costs 150k out of pocket. I make 30k a year, but I have an internet connection.”
And interestingly those communities source the base chemicals from the same Chinese manufacturers that the psychedelic research folks got their base chemicals from, so you have these big, Chinese and South Korean chemical manufacturers that back then didn't really care what you asked them to produce, as long as it wasn't patented. And as long as it was not a scheduled substance, I found that really fascinating. The same time, I was looking at the macroeconomics of the US pharmaceutical system. So these are like the early days of the US opioid crisis. And it started becoming apparent to me that there's something fundamentally wrong here that on the one side, there's people online that are being driven to engage in in some cases, dangerous behaviour, for example self testing compounds on themselves, and often out of sheer necessity. And on the other side, you have a large pharmaceutical system that's fundamentally failing to deliver what I would say is patient centric healthcare to providing medicine that is affordable by the public. I went on and studied , and I came looking at this whole thing because people in my family were prescribed early ADHD medication and antidepressant and I just felt like it wasn't really serving them. Yeah. And so I went on and studied economics at the University of St. Gallen in Switzerland, which is a fantastic, really rigorous Business School.
During my time there, I started trading biotech stocks. I had a couple of friends, we were exchanging stock tips and I found that fascinating. A biotech stock typically tends to trade just on the value of the asset. And it's the burn rate of the company as it's trying to develop this asset. And it's typically just a line downwards, pretty steady, that represents the burning of the company. And then you have positive data emerge, and it does a 5x or 10x in the day, where you have negative data emerge, and it does like minus 80, 90% in a day. And if you think about that, that's, a fundamental market inefficiency. As we're studying, I found that fascinating, looking at systemic inefficiencies and how capital markets behave. And then a friend of mine did an internship at a company called Bitcoin Suisse. Which at the time was the first Bitcoin brokerage in Europe. That was mid 2013. And then he started telling me about Bitcoin. I think, it happened many of us, we quickly fell down this rabbit hole. I taught myself how to code. Because I then got interested in open source software and the way that these various cryptocurrency Reddits, were sprawling, and you'd have someone fork the Bitcoin code and a new coin would appear. I still remember master coin and the white paper emerged. I'm also a big fan of Dogecoin, in the early days, just because I find it hilarious. And then I finished my studies in economics and moved to South Africa. Worked briefly in private equity there. And then during my time there, this is like, mid 2015, was already pretty neat, knee-deep in crypto.
Then I started my first company called Linium Labs at the age of 23. We started building out early applications on Ethereum. And providing training. And then did a couple of projects for larger companies that were at the time able to pay for development services, or that were trying to understand what's going on in this decentralized space, I became good friends with someone called Simon de la Rouviere, who I would say is like the grandfather of bonding curves.
So I've also done a lot of writing about bonding curves over the years because they're fascinating mechanisms for curating assets and discovering information. And then briefly worked at Consensys, did a project with UNICEF in digital identity in Cape Town, and then started working at Consensys, this is early 2017. And yeah, at the tail end of working at Consensys, I was doing a lot of work on data at the stations, and trying to figure out how we could attach data to stations to digital identities, and then also going into data marketplaces. So and then we were looking at NFT's among other things. And then I had this aha-moment where I thought, “hey, what if instead of attaching a picture of a cat to an NFT, we would attach a composition of matter patent”. So like the fundamental IP that describes a new drug or a new therapeutic. Yeah, and that gave the inputs to what I'm building today. That's like, going back almost, yeah, four years.
Andrew Steinwold 8:22
Wow. Okay. That is incredible. So we have biohacking psychedelics, open source, creation of medicine, you studied economics, you're trading biotech stocks, I can definitely see how all this is leading up to what you're working on today. It's really incredible. Going all the way back to when you're a teenager, how do you get interested in biohacking? And to clarify, is it like I am putting some sort of device in my arm or what exactly about biohacking were you so interested in?
Paul Kohlhaas 8:54
I was really interested in on the one side how nutraceuticals certain chemicals or psychedelics, for example, can just fundamentally alter your consciousness. So there's a huge supplement market on the one side, for example, it's very active in bodybuilding. So that's a form of biohacking. How do you hack your system to behave differently. Lots of bodybuilders use very various forms of biohacking to boost their metabolism. But then biohacking also obviously goes into using nutraceuticals that boosts brain function. Lots of people use Modafinil, which you could also consider biohacking. It's hacking your system to behave somewhat differently. There's also a lot of research around meditation, meditation could be considered a form of biohacking to gain more focus to gain more clarity. Another community that I found fascinating was HIV communities that were developing their own gene therapies to overcome the disease that they had. Gene therapies are another form of biohacking. So it's not the cyborg sense like implanting something in someone, but that could be that could be considered biohacking as well. It's how do you hack your own biology through the means of substances through the means of how you change your behaviour.
Andrew Steinwold 10:39
Incredible. You also mentioned that there's this movement of open source, medicine creation, I don't even know what you call that. But that's fascinating. Is that because the US healthcare system is just so fucked up?
Paul Kolhaas 10:59
I think in many cases there is a movement. This was really inspiring to me and to our team. In the early days when we built Molecule, called the open source pharma and the open source pharma foundation. And so there are many areas of medicine that are just not of interest to pharma companies. Often, these can be rare diseases, where the patient populations are just too small. And pharma companies are not interested in bringing a drug to market. And then, the FDA gives special special approval methods to those disease areas, you have the orphan drug designation, for example. But even despite that, it's an uphill battle to get a drug approved, you need enormous amounts of capital to bring a drug to market. And in other areas, for example, in tropical diseases like malaria, that affects millions, hundreds of millions of people across the world, even, I think COVID may have changed this. But before COVID, I think malaria was one of those diseases that killed most people around the planet. Yet, we still since the 80s, 90s, it was not possible to develop an effective vaccine, or really, effective long term treatments for malaria. So this open source pharma foundation, consists of researchers around the world that banded together around various universities, I think it's UCL, for example, brace Australian universities, where researchers committing new drug targets, to an open source repo which you can find on GitHub. They use GitHub to do this open source malaria. It's also open source mycetoma, another tropical disease. And what's fascinating there, this type of work has been funded by organizations like the Gates Foundation, or, other international organizations that feel its humanitarian work in a way. But those organizations often just lack the funding to then bring a drug to market in the end. And they often just get stuck in the best case. So as soon as , these researchers upload drug targets, new discoveries that they have of what could be a potential treatment to this GitHub repo. And then they discuss it in a open source way. And that's a completely different way of how biotech companies work or the pharmaceutical system works. Because as soon as they make one of these GitHub commits, that drug target, (which might could be used to treat to cure malaria) gets unpatentable. Because now you have prior art. As soon as you have prior art, you're not able to file a patent application. And, it is really powerful if you think about it, because now no one will be ever able to patent that. But because no one can claim a patent, you're unable to bring this Molecule in the long pharmaceutical development pipeline. Even organizations like the Gates Foundation will not fund your work any more. The only the potential for this drug is to become a generic, no one can patent it. The problem with having a drug immediately as a generic and this is the same for these psychedelic compounds. Many of the psychedelic compounds, that could be used for example to treat depression, become technically unpatentable for that indication, once they are uploaded to GitHub. The problem now is that nobody (maybe in the future this will change) now pays for the clinical trials to bring it to market, because there is no way to recoup the high costs. And the cost for a third stage clinical trial can be, depending on the indication, in the hundreds of millions. And if the drug can only be a generic, you're never going to find a partner like a pharmaceutical company, that will help you shoulder the costs, even if it's paid with public funding to bring it to market. This was a huge insight. These researchers, in open source malaria, are not able to get funding for any of the drugs that they develop. Another example, if you are a researcher at a university, and you publish a blog post about a new molecule that you believe could cure cancer, that you just discovered, will never make it to market, because you can't patent it any more. We could have amazing cures out there, that would work. But due to the way that innovation works, in terms of protecting patents, and then shouldering the high costs to get to an FDA approval, you'll never be able to recoup those costs.
Andrew Steinwold 16:21
Wow, okay, so you said that, that these people are uploading this research to GitHub, and I'm a complete noob here, but does this research look like code? Or is it like actual written papers that go into depth on more like theory? Or how does it look?
Paul Kohlhaas 16:37
It can be both. I mean, it could be in most cases, it would just be a data set that describes a new molecule.
Andrew Steinwold 16:49
Okay, why is pharma research so expensive?
Paul Kohlhaas 16:55
That's, that's a good question. So at Molecule we believe it could be way cheaper, if it was coordinated in a better way. The innovation processes, and the way that research is done in pharma, and specifically, the approval process, is extremely bureaucratic. And this has not really evolved in the past 30, 40, 50 years, the way that the FDA approves a drug today, and the hoops that companies need to jump through, haven't really evolved, despite so much new technology available. I think there's this cultural and bureaucratic problem. But because of that, I think many pharma companies have barely evolved. And I think can be compared to the banking industry. I think the banking industry is only started evolving in the past 10 years in the wake of FinTech, because Fintech is starting to really hurt their bottom line and take away customers and hurt their margins. I think we haven't seen any similar developments in the pharma space. If you think about it, it's beneficial for them, that it's really expensive to bring a drug to market, because it means that they're the only ones that can bring drugs to market. It's chronically hard, many biotech companies will never have an intention of bringing a drug to market themselves. Because they know, at the end of the day, they won't be able to shoulder those high-end stage costs. So what typically happens is that you, you have a biotech company, that spins out of a university, and then goes through several financing rounds, until the VCs that are financing that biotech company, their LPs or pharma companies themselves sell it to big pharma. The typical path is to become an acquisition target for a larger pharma company, that can gets the assets from that biotech company and brings them to market. Or what often also happens is that these companies IPO in order to be able to raise enough continuous capital, many of them that IPO typically don't make it to market , or they end up selling one of their lead assets. And, and many of them become zombie companies that keep existing despite not having a clear path of when one of their drugs could come to market.
Andrew Steinwold 19:16
Okay, so let's pretend that the regulatory agencies that are approving these medicines of the pharmaceuticals, let's pretend that that process is super simple and super cheap. Is that cost then brought down by like 90% or 95% , and what is the main cost of researching pharmaceutical stuff? Is that that just labour costs for people testing all that stuff out?
Paul Kohlhaas 19:44
Yeah, I mean, so you can differentiate between the preclinical stages and then clinical stage drug development. In the preclinical stages, costs have come down tremendously, because increasingly you can do a lot of outsourcing. And for example, if you have a certain compound today as you can choose from probably hundreds of providers today that can run standardized preclinical trials for you. These could be toxicology, reports, essays, fly studies, mouse studies, to determine whether it's even toxic and mammals in the first place, you tested in human cell cultures. And then you use all of that data to obtain an approval, like you do an IND application to obtain an approval to move into clinical trials. And in clinical trials, you're going to be testing the component in humans. And that gets much, much more expensive. But interestingly, if we compare this with these open source communities that I described earlier, you have an open source community that would try to obtain a certain compound. Now, typically, for example, these aren't cancer therapeutics. So it's a very different ballpark. But if you are testing a drug for chronically depression, and you hear about a new substance online, and you would obtain it, and it would help you, and that drug may have never gone through the typical preclinical costs and approval and application process. It is very expensive for a drug already to get into the first stages of clinical trials, where you test the drug then in the small patient population. But like, I think, for example, drug costs could be brought down exponentially if there was a more open source and anecdotal culture of how drugs are tested in certain indications. But okay, back to your question. So there's the preclinical cost, those have come down a lot, because we can increasingly do outsourcing. And outsourcing just means that and for example, we work with a company called Arcturus, they receive, robotics laboratory. So they have robots that run an automated lab that will test your compounds. So you can just tell them, hey, I want to test the following compounds, please run the following experiments, they will get it synthesized for you, they will then test it in their lab, and they will upload the data to the cloud, or in our case, they would upload the data to an IP-NFT. And because there's a lot of outsourcing happening, the costs around this have become increasingly competitive. So 10, 20 years ago, it didn't make sense to start a biotech company with, less five, that's less than five to $10 million in funding, just because you had to build your own lab, you had to get all of this stuff yourself. Increasingly, you can do a lot of outsourcing. It's still more difficult, though, in the clinical trials process, where you can't really cut costs that easily. I think what we can do, enable a lot more coordination. And the other thing is the enablement of decentralized clinical trials. So typically, when you do a clinical trial, it's very expensive to find patients to run the trial with, then coordinate the patients, monitor the effects and all of that, and just the regulation around that is very strange. But one solution to that could be, this is a huge hope and actively being worked on: having more decentralized clinical trials. And then a last component of the high cost is really each player in the current pharmaceutical system, you have to imagine these assets get passed on from company to company. And if a biotech company goes through an acquisition, and an asset could go through multiple acquisition cycles, leaves a seed stage startup and goes into a b series funded startup. And then that b series funded startup eventually sells it on to like a larger pharma company, each transaction in that value chain, the people that transact in it, and these typically tend to be like, just financial transactions add costs because everyone is trying to make money with it, right? If I bought it for this much, I want to sell it at least for like 5x to make a 3x return, we invested like 2x of the cost, and so on and so forth. And in the end, the pharma companies still need to make a lot of money with it. And maybe then the last thing to say: all of these financial transactions add a lot of costs. It's like the Wall Street for this entire value chain.
But the other component of why the costs are high is because so many drugs fail. For each drug that comes to market, Pharma has 20 drugs buried that didn't work. If you have to imagine if they buy 20 drugs for like $100 million each, often the costs are much, much higher. The system is quite inefficient and identifying targets that could work because it's very closed. And there's this principal agent problem in terms of how assets are transacted if I'm selling you a drug as a biotech company, I only have incentive to show you the good data. So we could run 50 studies on this new cancer drug, and like 48 of them show that it doesn't work. And two of them show that it works. One of them is inconclusive, we'll show you the two studies that work. And if you're desperate enough, you will buy it, and then it might work. But also based on if the data was more open source, it could have been identified much earlier that the drug doesn't work. So now let's see them this drug is bought by a large pharma company, they take it into stage one trials that may be working, but also inconclusive. Stage two is a massive failure. And at this point, they've spent an enormous amount of money to discover in stage two that the drug didn't work. This could have been discovered before, this drug was never supposed to go to market in the first place, because it doesn't work. So all the cost of those failed drugs are offset to patients and the end.
All of that taken together is what makes drug development so expensive today. So maybe it's a lost analogy, it's a little like if I used to make this analogy in the beginning, if IBM was developing a social media app, and it had a mandate to develop this app for the government, and no one else is allowed to develop a social media app, and it takes them eight years. And it's a really crappy app. And in the end, it cost you $1,000 per month as a subscription fee. And you have to pay 50 cents for every DM that you send on this app. Then they have a 15-year exclusivity on social media apps. And that's a little of how pharma works today. Nothing against IBM at all. By the way, I'm just more using them as an example of, like, software incumbents, and how and so open source software completely changed how we engage with apps. We can ask ourselves, why are apps free? Whereas 20 years ago, you still used to go to like a store and buy a physical CD that had a CD key on it. Pharma is still in that level of innovation, buying a CD at a store with a licence key.
Andrew Steinwold 27:12
Wow. Okay, so, um, from, you know, from everything, you're telling me just insane inefficiencies that are currently ingrained in the system? And you know, with your interests, which are open source, pharma, economics, Bitcoin, etc, open source, you've started this company called Molecule. So can you tell me what is Molecule, and why is it exciting?
Paul Kohlhaas 27:37
Yeah, of course. So at Molecule, we're really trying to virtualize and decentralize how drug development works. So at the core, like, if you look at this, like from a meta level, the core value drivers in drug development and in biotech and pharma are on the one side, its intellectual property through the form of patents or early stage IP. This is just data around a new molecule. And, on the other side, its data produced about these compounds. So we just talked about these expensive clinical trials and so on. But so, it's companies that claim innovation through a patent, for example, and then they waste funding to produce data. If we think about data, and the data has increasingly become a virtual asset, really since the 70s, and 80s. Before that, we still use that data and like these giant filing cabinets, but data has increasingly become virtual. On the other side, intellectual property has never really become virtual. It's a box of papers that you file from a lawyer, and then granted a patent by the US government. But so, if you think about intellectual property, it's the perfect asset class to virtualize. Because it doesn't exist, right? It exists in terms of being granted a unique right, but it's not like it's something physical. It's not like real estate. It's not like a car. It's intellectual property. What we do at Molecule, we attach both a data and these IP rights to non-fungible tokens (NFT's). And then we bring the core IP into web3. Then we've developed a new framework called an IP-NFT. At Molecule, we think pharma and biotech development as a marketplace. And as I described this pipeline earlier, pharma is one of the last big pipeline models, where IP is owned by a single company and then passes through the pipeline and then eventually brought to market by a single company, and most pipeline business models have been disrupted by marketplace models over the past 20 or 30 years. And we think that, it isn't necessarily about disrupting Pharma. It's about making pharma and biotech development much more efficient. And to bring down the costs both for incumbents, but especially for patients and for researchers. And so what we build is, and maybe to use some crypto terminology, in essence, a mixture between an Open Sea and ResearchGate that enables researchers, biotech companies, universities across the globe, to mint their research and their IP into an IP-NFT. As you can imagine, a drug discovery department at a university can create a portfolio of their research projects through our framework, and put their IP into web3. And what this now does is it makes the intellectual property liquid, which is very hard to achieve in biotech today, like biotech investments tend to be super illiquid, because it takes so long to bring drugs to market. And then you have tractability before but tractability on a patent basis is quite expensive. And NFT's make that really cheap, hyper liquid. And they also enable price discovery around IP, which is another thing that that's really valuable. So typically, you would only have price discovery for IP through, like public market listings. But that's also an inefficient price discovery mechanism, because then you have very stringent reporting around the data.
So what we had as an early vision for molecule was to create a curation market. So this is based on some of Simon de la Rouviere is already thinking of like, what if we had markets domains where people could just like, trade and discover and curate the most promising memes? And some of our early thinking was, in essence, hey, wait, “what if we had like a meme market, but for therapeutics for drugs, when our patients researchers could enable in price discovery for therapeutics together”. And now this therapeutics would live off data that people commit, or data that flows into the data repos attached to these drugs that have been researched, which would then garner more attention. And then positive data would increase the price of a therapeutic and negative data would decrease the public perception of price of a therapeutic. This is the baseline of thinking. And so we're working with universities across the globe that upload their IP. And then this could now be purchased by anyone. So we're trying to build the system in a very open way. But on the other side, we started realizing it's probably not going to it's not going to be industry and like industry incumbents that will be first to use new frameworks like this. But ideally, it would be folks that are already in web3 that are native to owning an NFT. But then, we thought it might not be efficient to have the typical, NFT speculator audience engage in this IP, and own it, because ideally, you want to make the IP productive. So the following data emerges, you would then need to define the next steps of the experiments to move this closer to market and move it closer to the patient. So what we started doing, at the same time to make this marketplace productive, is to build biotech DAOs, or we call them bio DAOs, which now function like new biotech research collectives that are comprised of patients, of investors of researchers in that specific therapeutic area. And develop those drugs. So I'm sure many of your listeners are familiar with a DAO called FlamingoDAO. FlamingoDAO is a huge inspiration to us. It's a DAO that curates and collect an amazing collection of NFT artworks. And so we launched, VitaDAO in June last year, June 2021. And VitaDAO builds, curates and collects IP-NFTs focused on longevity research. So this is one of the first fully functioning biotech DAOs that the world has seen. Only focused on longevity. And there's another one that we're building now in psychedelics research focused on psychedelics and mental health. This DAO will, in a similar vein, also be building a portfolio now of these IP assets and making them productive. And there's already a large amount of industry interest to collaborate with entities such as VitaDAO because the industry is really interested in the deal flow that has been created and the IP that has been researched and discovered.
Andrew Steinwold 34:59
Wow. Okay, so again, incredible, my mind is like just being blown non-stop. But okay, let's go back to Molecule. So I'm a little confused on , and it's my fault. But the efficiency gains you get from putting this data and IP rights onto the NFT. Why is that important? You said that it creates a more liquid market. But if that information is on this NFT, can anyone come claim and read it? And then it's open source? Why is there value attached to that NFT?
Paul Kolhaas 35:32
Yeah, of course. So the way that our IP-NFT works, the IP-NFT consists of two core components. So on one side, it's a one to one legal agreement. So Andrew, if you went onto our app, and you find an asset there from your favourite longevity researcher at MIT, and you said, and he's looking to raise some funding for a new set of molecules. This researcher says ”I am looking for $200,000 in funding to complete the experiments.” This will be one way to engage, and then you engage through something that's called a sponsored research agreement. So you, Andrew, it's typically not natural people that do this, but let's just use that as an example, you would then enter into a sublicencing agreement or something that's called a sponsored research agreement with MIT to sponsor the following work. And as a result, you would now own the IP and the data that results from it. And that IP agreement is encrypted.The owner of the IP-NFT, is able to see the licence agreement and everything around it. But the identity of the molecules or the resulting data is not of made available to the public, unless you do that. On the one side, it's a legal agreement for someone to license you a a certain amount of work, a certain amount of IP. And on the other side, it's a data storage layer that lives on top of Filecoin. Some metadata is on our wiki, some of it is on Areweave, it's an encrypted data access control system. To make that very simple, the NFT now is linked to decentralized Google Drive, where you as the NFT, holder, get to grant access rights to different parties. So the researcher now uploads his or her data into that data storage, and you get to see it, and you get to give other people access. So now you can say, “I want to give access to another research team that I also want to be working on this. And I'm going to pay them another 100k. And they are going to deliver the following data assets into this repo as well”. You could also show your friend at Harvard Medical School, he's been looking into this , and you tell him about this work, and use it very easily simply grant them access rights. And then a year later, like a biotech comes along, and they hear about the asset, and they're interested in looking at it. So you're like, cool, let me grant them access rights as well. They can DD some work through your granted access rights, and then they make you a bid on the chain to buy the IP-NFT from you. Yeah. So just to explain how the IP-NFT works. But the really cool thing about this now is this data is typically stored on company on servers, it's transacted like PDFs and emails, they're granting access control to the data stores that are described as follows the same NDA as patterns. So like, if you're the owner, you obviously don't want to invalidate your own IP, right? At the same time, if you wanted to, you could just open up access to that data repo. It's like having a private GitHub repo that you can add different collaborators to, or making it a public GitHub repo. And, at the point, if you decided now to patent this discovery, or these molecules, what the IP-NFT now grants you is everything that you need to go to the patent office with. It's saying, you're the legal owner, you out licensed this from MIT. And here's all the data that proves that this could work in the following indication, based on that you could be granted a patent. And this 9is what makes the whole research really valuable. The cool thing about this is now you can transact both the data and the IP, like the legal rights in the same way that I can send you a crypto kitty on my phone like a crypto fund, you could also now make the IP fractional. So VitaDAO is currently exploring fractionalizing, one of its first IP-NFTs. That doesn't mean again that the holders of those fractions get to access the IP, they get to access the data. But you can build all sorts of funky open source collaboration methods in there. For example, you could say, if someone contributes to the following dataset which I need to develop this from some university, for example, you say, hey, anyone who can do the mouse studies gets 2% of the asset. And then some university can say, hey, we're interested in this work. And we can do the mouse studies, we will take 2%. And we also want 20k from you, but it's not going to cost 150k that it normally costs. So you're starting to decentralize ownership of the asset, and make the whole development process much more modular.
Andrew Steinwold 40:22
Okay. Is it fair to say that Molecule if we had to give Molecule a one-liner, Molecule is a drug development research marketplace? Is that a simple one-liner?
Paul Kolhaas 40:36
Yeah, you could also I mean, we, you could say, for example, decentralized biotech protocol.
Andrew Steinwold 40:40
Okay. Okay, that sounds way better. And then would you say the mission of molecule is to broadly open up the market? So, you know, to more participants? So more research happens?
Paul Kohlhaas 40:53
Yes, absolutely. So it's a way to democratize access, in the same way that the internet democratize access to information. I think for us, this is really about democratizing access to medicine. And if we think about this whole development process, there are two user groups that are enormously user groups in the sense of like, this is a value creation process. There are two user groups that are fundamentally disenfranchised today. And those are researchers, the people that are doing the work, they don't typically see no upside, unless they go in like it really into the hardcore, like biotech, VC, biotech startup, like IPO route, which many of them don't want. They are really keen to provide value to patients. That's why they became researchers in the first place. But we want to empower researchers to become co-owners of the IP and of the upside. And on the other hand, patients are really the most disenfranchised people in this entire process. But they're the ones that stand to benefit the most, and that need access to new medicine. And you'd be surprised, for example, how much a cancer patient, how much a rare disease patient, are familiar with their disease, about the potential treatments about what might work for them and what couldn't. And the current system just completely removes them from that process. If you have a disease, you, you get what's on the market, you don't get to determine its price, you have no influence on that. I think this has enormous potential. And the same way that lets say NFT's empowered, in many cases, disenfranchised artists across the globe, to take power again, of, of their creations. I think this similar thing is happening in the music industry at the moment. We believe that NFT's in the medical space, and like these IP-NFTs can really fundamentally empower the creators and the benefactors of a therapeutic.
Andrew Steinwold 42:54
Okay, so I definitely see how everything that you've built so far is massively more efficient than the current system. And just better overall, but how did the regulatory agencies interact with that is, are they still a massive inefficiency and blocker?
Paul Kohlhaas 43:14
We are currently really focused on, early stage, preclinical development. Getting IP out of university and getting financing, for a researcher or a laboratory or a team that is looking for, 500k, at 200k 500k, maybe up to a million to complete the preclinical studies. To overcome something that's known as the valley of death. In this entire process, a lot of innovation never even makes it out of academia, and many, many precede and like seed stage, biotech companies just die, not because their innovation wasn't good, just because like there's a lack of funding, there is a lack of discoverability it's really difficult to discover this IP today and know what's in the market. Pfizer, for example, has for the entirety of North America has 12 drug scouts, business development managers, that are trying to source IP and work with universities to find IP. Coming back to your question, we tend to be quite focused at the moment on early stage development, where the regulatory overhead is quite small so that the regulatory overhead really increases. Once you move into the clinical stage once you file for an IND. I think as a crypto project that's really trying to bridge into the real world, it's super important to pick your niche. So we're really focused on the early stages of development at the moment. We're also the funding requirements alive and the regulatory overhead is quite low. So these IP-NFT's are fully forward compatible, they can be purchased by a biotech company or a pharma company that can then continue developing the drug. So for the time being, I think and also, while the web3 space is still quite small, we're really trying to accelerate innovation in their early stages to broaden the funnel. So enabling more great therapeutics to come into the clinical stage in the first place, but knowing very well that we won't have the capacity yet, I think even as a community, to skew it to a clinical trial. I think over time, though, like the DAOs that we're building could really start doing their own clinical trials, I think that would be an absolute dream, they can create their own spin off companies and then could orchestrate clinical trials. But I think for the time being there's just not enough liquidity and enough real world integrations for that to work efficiently.
Andrew Steinwold 45:55
So can you walk me through like the dream scenario from start to finish of research and drug development if people are utilizing Molecule and beat it down and all these other all this all these other products and things that you guys are building? Yeah, just walk me through from start to finish how that would work like on a mechanical level.
Paul Kohlhaas 46:16
Okay, that's a big question.
Andrew Steinwold 46:18
You can make it super simple like the person at MIT researching a drug then me as investor, I go buy the thing and so on so forth.
Paul Kohlhaas 46:28
Research at MIT developing a rare disease molecule that can be promising, gets financed by a rare disease DAO that also finds this approach really promising, kicks off initial studies, with the like, 300k in financing that she received. IP-NFT is now co owned by a researcher at 10%, University 20%. and rare disease DAO owns 70%. Rare Disease DAO initially now commission's an initial findings are promising, rare disease DAO commissions to CRO's, one in Singapore, one in India, to also begin working on this compound, all of those data flows and pays them both in in in shares in the IP-NFT. So like in sub tokens of the IP-NFT as well as in fiat, those additional data flows start flowing into the IP-NFT. Together with another rare disease patient foundation, IP-NFT is then spun into a small biotech company that is almost already at IND approval stage, all the data was procured in a fraction of the time as it normally would. Because of the rare disease, DAO is working with other researchers and a legal counsel that have helped shape and just expedite the value of the IP and what experiments to focus on very quickly. And then a biotech company is formed and is fully owned by patients and by this rare disease DAO which also mainly consists of patients, but also investors. And ultimately, a biotech company is able to get funding from that structure, you probably then need about 10 million, 20 million plus in funding to perform the first stages of clinical trials. First stages of clinical trials are quite promising, which prompts the interest now of a larger, pharmaceutical company. And now patient groups and pharma company agree that the DAO will continue financing the asset together with pharma company, but pharma company will start expediting all the clinical trials just because they have a much bigger machinery in the current system to do that. And the part of that agreement is that once the drug reaches the market, it will not be sold, that's an over maybe 4x, or like 3x, the cost of what it took what the entire development took, provided that both pharma company and like rare disease DAO, continue to share the cost of the development. Again, three years later, drug maybe gets FDA approval, that will be incredibly that would be incredibly fast. But think if you do more efficient coordination, around trials that could be possible. And an end result could be, you now have a drug that is still a majority patient owned. We're also a pharma company is making money off of it, but their input was much lower. So they're also happy to take a much lower cut on future revenue. And our pharma company uses their supply chain and their network of pharmacies very efficiently distribute this drug to doctors and to patients without needing to overcharge on it to make up for their losses in other areas.
Andrew Steinwold 50:03
No, amazing. Yeah, thank you for that overview, I think I'm beginning to understand the full process from start to finish here. So the DAOs are a super essential part of this whole structure here. And the first DAO that you help set up is called VitaDAO and you wanted to focus on longevity research. Was there a reason that you wanted to focus on longevity research first?
Paul Kohlhaas 50:29
Yeah, I personally think longevity research is a fascinating, interesting topic. It's like the holy grail of medicine. And longevity is fascinating also from an economic perspective, because, longevity is not about living for longevity research in my eyes is not about living forever. It's about living a much healthier, longer lifespan. So what if you could reach in like the age of 120, 130, 140? I think it gets critical after that. But without the typical onset of age related diseases such as Alzheimer's, such as cardiovascular diseases, cancer. So, the question is more, how could we live a longer, healthier end of life without the bad side effects that come with it, it's the reason people don't want to get old, because you have so many really shitty age related diseases that sit on, and those also cause massive costs to society. So, I think it's a really cool mission. And then I'm ageing research touches many areas of medicine, which for us, as a marketplace and as a protocol, is interesting because it allows us to quickly branch out into all sorts of disease areas. So that's the second reason. The third reason is, I think, ageing research should fundamentally be democratized. So the bulk of ageing, and longevity startups are currently funded by billionaires. And it's quite obvious if you've made a lot of money in your life, you want to live it out for as long as you can. But I think there's a risk there. Because if like the richest people in the world live longer and longer and get richer and richer, that will fundamentally, in the long run, create and an unjust society, because wealth isn't distributed as much any more. If I don't know if a bad leader of a country can now go on his fifth or sixth or seventh presidency term enabled by longevity therapeutics, that won't be good, but it's so at least let's ensure that access to longevity Therapeutics is democratic and not so centralized in the hands of the few. And then the last point is, as a community and as a marketplace, tend to be super conscious of product market fit with web3. And so for the time being, I think it would be quite difficult to launch, a DAO focused on breast cancer research. And it's not that breast cancer research isn't a like a really important topic. It's simply that the patient groups in that are affected by breast cancer wouldn't be as native to using discord and Twitter and Metamask as the people that are interested in longevity research. I think that comes over time. One thing that I'm, really excited about is , lots of patient communities are already quite digital. They tend to have like massive Facebook groups where they coordinate events online, but they're not like they're not in Discord yet. And so lots of web3 folks that I know got really interested in longevity research, lots of web3 people that are also interested in psychedelic research. So those are just areas and therapeutic areas that I think have a natural product market fit for us at the moment. As we are still in the early days of building out.
Andrew Steinwold 53:53
Awesome. Okay, so August of last year, VitaDAO, I think, you guys were able to transfer some sort of IP on chain as NFT. Can you describe what that was?
Paul Kohlhaas 54:04
Yeah, absolutely. So that was one of the first full end to end out licensing events with a university. This was with a professor and the leader of a laboratory called Dr. Morten Scheibye-Knudsen. He heads up the ageing, the Scheibye-Knudsen lab and the ageing Research Lab at the University of Copenhagen. So this is a study that's ongoing, that's analysing 10 molecules that could have life extenuating properties. And VitaDAO in this case now out licensed the full IP from the university, paid for the research. The research has joined VitaDAOitself and also now participates in the governance of VitaDAO through the Vita token. So they receive tokens in the organization, which is fascinating because now these researchers also actively bringing in other researchers , and they bring in other interesting work that they're doing you to receive funding. Yeah, so this, this research was attached fully to an IP-NFT. And then VitaDAO did purchase the IP-NFT. And the funds went to the University to kick off the work. And now, we've seen other research groups within VidaDAO that are building on this research, and they also want to collaborate with this first study that they're doing. Which is really exciting. So you see these other researchers that come in that hear about the work , and they're like, “Hey, I have a thesis here as well. And we should also investigate the following thing, and I can then make it a part of, of the work that you guys are already doing”. The work itself is about repurposing 10 molecules that have life extending properties statistically, from a huge data set of the Danish population's medical records that they analysed, so that the lab received access to from the Danish government and that they analysed. And based on this, now they're running through a series of studies. And these molecules can then be repurposed, most likely through an analogue strategy, to potentially bring entirely new longevity therapeutics to market.
Andrew Steinwold 56:15
Okay, so if I am a regular person, that's not as, some sort of research scientists or drug development scientists, what part can I play in VitaDAO?
Paul Kohlhaas 56:28
So, yeah, so if you do that, it's quite interesting. If you go into the Discord, you have a mix between lots of people that are just really interested in longevity research. But like you said, they're not researchers. They're not scientists, but they want to contribute to the field, they want to learn more about it, they want to connect with researchers. And then I'd say the core of the DAO is really what is called the longevity working group, which at this point, is over again, probably over 100 scientists from across the world, I'd say about 60 of them working very actively. In some cases, we have MD PhDs from Harvard, we have professors that were leading laboratories that have left their academic past almost full time to work on this. And they are now constantly bringing in research to be funded by VitaDAO. And as VitaDAO token holder, you can on the one side influence the direction of what work you would like to see funded. For example, you might have heard about a new, exciting supplement or a new exciting research policy, so you could actively begin engaging those researchers asked him about it, and also suggest specific things to receive funding. But ultimately, this longevity working group will then make proposals to the DAO and token holders to vote on what research should get funded. And also, then if like positive results are found over time, you as a token holder also then get to decide as a next step, what to do with the research, which I also find really exciting. So, like, VitaDAO could. And this goes back to something I said in the very beginning, about potentially open sourcing IP. So like, that's just a hypothetical scenario, if VitaDAO discovered a groundbreaking new molecule that could make, every human on Earth, at least 200 years old, and then read it, I thought this is far too big to ever be owned by a single company. It's too influential, terribly commercialized. Let's open source it. So VitaDAO token holders could decide to just open source IP that they develop. However, they could also decide to sell it to a biotech company. And then, any proceeds that come into VitaDAO through this process would be re reinvested into further research. So we hope that VitaDAO becomes this just growing and growing decentralized collective, that now democratically manages its IP, and engages in a much more open process and philosophical design thinking around how IP should be managed by humanity. Yeah, so this is how you could engage.
Andrew Steinwold 59:11
That's so freaking cool. It's insane. Alright, so your long term vision is that there are different DAOs that are focused on different pharmaceutical markets or focuses, like, for example, you said the next DAO that you're you want to launch will focus on psychedelics and mental health. And there'll be another one called rare disease DAO and so on so forth. So in your mind, there's going to be many DAOs, each focus on different sectors of this market?
Paul Kohlhaas 59:41
So we hope I mean, we, so what we're increasingly doing is we're building the DAO frameworks to enable that, because as a community, and as a network, we don't want to be in a position to launch all of these. They require an enormous amount of domain specific knowledge and specialization. And they're also best in the hands of researchers and patients or people that are really affected by these diseases. So where we're like, we're actively building some of them out. But over time, we hope that there will be a sprawling ecosystem that emerges that builds on our frameworks are built on other frameworks, and help brings biotech dollars to life. And then I think initially, these organizations will, as I, as I explained earlier, we feel this like preclinical funding gap, and we need just accelerate, help accelerate early stage research and innovation. Because that's where there's a huge need. But then over time, if they grow large enough, they can increasingly really move into the clinical trial stages.
Andrew Steinwold 1:00:49
Awesome, awesome. All right. So let's fast-forward now, 5 / 10 years from now, what is your grand vision for everything that you're currently working on?
Paul Kohlhaas 1:01:00
I think the really grand vision is that a first drug that that was enabled and discovered in this process reaches patients. I think that could really happen in a five to 10 year timeframe, I would be, I'd be really happy. And more so if that drug was developed at a fraction of the cost. Because I think this is what's really possible. And that's what's really possible we found so incredible about the emergence of VitaDAO was that VitaDAO turned into like a mid-sized biotech company within just comparatively in terms of staff and in terms of knowledge, in terms of expertise. But in the course of three to six months, and with much, much less funding, and often driven by people that are just really passionate about doing this, like drug development doesn't have to be like it sadly, today, it's really often about profits just about like revenue, because you have a giant VC funded ecosystem that is optimizing for that. But I think we should optimize, for patient centric, healthcare. And if you then have people that are working, that not on a voluntary basis, but you can coordinate people to produce the same outcomes at much lower costs. So this many ways, obviously, that this ecosystem can go, we're trying to build it in a very open source way. So also, if you want to create a DAO that is highly focused on like, just maximizing profits from IP entities, you can obviously do that as well. So we're not I think we're not trying to build, we're trying to build this system out as a very open and free marketplace. But I think what would be really cool to see in the next five to 10 years is one of these IP-NFT based drugs reaching patients, and doing so at a much lower cost than is possible in the current system.
Andrew Steinwold 1:03:03
Amazing. Awesome. All right. All right. Paul, are you ready for the closing questions? Yes, yeah. Awesome. All right. What is your single favourite NFT that you own?
Paul Kohlhaas 1:03:27
Do you know sad girls?
Andrew Steinwold
No, I don't.
Paul Kohlhaas 1:03:27
It's called sad girl's bar. It's like a project by a really cool female artist called Glam Beckett. And the principal is just it's like these sad girls. They like to have pizza slices in their hand. And it's like black and white and a golf look. I find it funny. I think it's great. And I somehow got into the position of owning sad girls number one, so if there's any sad girls fans out there, reach out to me.
Andrew Steinwold 1:03:54
I love it. I love it. Yeah, normally I hear like, punk sport, apes, etc. But I've never heard sad girls. So very, very cool. All right, what is your most controversial thought relating to the drug development industry?
Paul Kohlhaas 1:04:08
Probably that if our legal system changed, that we could treat drug development like software. Ultimately, like developing drugs, it's impossible to do open source drug development today because of our legal system. But ultimately, drugs once you get into producing them, they cost nothing, in example the cost of a pill is virtually zero, especially, once you get into chemical production, but these drugs are sold for hundreds of thousands of dollars. And it's really, really reminiscent in some sense of the software development industry in the late 90s and early 2000s. So I think, most controversial thought, I do believe drug development could be like software development.
Andrew Steinwold 1:04:57
That's awesome. Okay, so could we do it safely without the government?
Paul Kohlhaas 1:05:04
Definitely. Yeah. What we're seeing more and more emerge in the web3 space is very sound, self-regulating processes and principles. I think if you, if you have completely open systems, people will self regulate, and the government often regulates, I think, in very bad ways. And over time, that regulation often becomes self-serving through lobbyism. If you just we really have to ask ourselves, like, what job has half the FDA done, in some cases, in terms of like protecting US citizens from the opioid crisis? I think it's so painfully obvious that some of these regulatory processes have hurt patients and consumers more than they protected them. And I'm sure, I'm not based in the US, but I'm sure there's a long story that people can tell about the justice, the financial regulation in the web3 space, and the role of government there.
Andrew Steinwold 1:06:04
All right, you can snap your fingers and instantly solve one issue in the drug development research industry. What would it be?
Paul Kohlhaas
Patents!
Andrew Steinwold
Okay, so I explained that.
Paul Kohlhaas 1:06:16
I mean, yeah, I think it's based on what we had before. If we had IP protection, that was more like open source licensing frameworks, as opposed to patents. We could develop, engage in much more open drug development. So if I could snap my fingers, I would hope that licensing frameworks in the pharma industry could effectively replace patents as drivers and protectors of innovation.
Andrew Steinwold 1:06:49
Amazing, alright, who is someone that you look up to? And why?
Paul Kohlhaas 1:06:55
I hate myself was No, I don't hate myself for saying this. But like, I do look up to Elon Musk on the one side, I think he's such a funny troll. Sometimes, have the audacity to just go out and say that stuff. But on the other side, I think he's someone who's inspired a whole generation of builders, and likes to push for the limits of what is possible. “if you want to, like, you can't just decide to go to Mars” and “if you stick with it for long enough, then like you have a fighting chance of doing that”. And I think with that type of behaviour, anything is possible. It's something our younger generations used to get that from political leaders, and presidents. Unfortunately, that isn't the case any more. Today, I don't know anyone, or very few people, who look up to our political leaders. But I think Elon is someone who really inspires us to build and to push new boundaries. And to push for a better world. Oh, and Vitalik Buterin as well.
Andrew Steinwold 1:08:08
All right. Last question. Where do you see IP-NFTs in three years?
Paul Kohlhaas 1:08:15
In three years, I think we could see a similar highly liquid market around IP assets through IP-NFTs. I don't think fractionalization makes as much sense for normal NFTs, for example having fractions of a punk, I even think having fractions of the Mona Lisa. Okay, it's fun , but you can't actively engage with it. But for the IP-NFT, I think we could have a much, much more fractional market over time. So if you have this drug, and it has a specific patient population, or you have a bunch of researchers working on it, it would make a lot of sense for it to become factional. So now, you as a patient could say, “Hey, there's this new, rare disease”. And then there's a new drug and development that you hear about, and it has the form of an IP-NFT or several IP-NFTs. And now you can contribute funding that. You can take $2,000 of your money, and say, “I'm going to contribute funding to this research”. And now you don't just know, you get to govern the future of that asset. And you get to have a voice in terms of what the actual drug should be priced when it comes to market. I think that's really powerful. So yeah, I really hope that we can enable that market to exist. And for IP to become a public domain.
Andrew Steinwold 1:09:47
Amazing, awesome. Paul, this was just mind-boggling. I feel like I just did a college level no beyond college, course, and everything about drug development, drug discovery, etc. And it's really cool to see NFTs being used and in a way that truly matter, not that all the other use cases don't matter. But we're talking about like our health, which is obviously the most important thing. And so it's just super inspiring to hear everything that you're doing and building. If people want to find out more about yourself, find out more about molecule or VitaDAO, where should they go? What should they do?
Paul Kohlhaas 1:10:18
Absolutely, yeah. So you can find me on Twitter. My DMs are open, please feel free to connect. If you're excited about this use case. It's @paulkhls. On Twitter, we're @molecule_dao. Also, you'll easily find VitaDAO. Yeah, we're constantly looking for people that are just as excited about this use cases we are, so please feel free to reach out. And our website is molecule.to.
Andrew Steinwold 1:10:46
Amazing, Paul, thank you so much for coming on. I really, really appreciate it.
Paul Kohlhaas 1:10:49
Thank you so much for your time. And yeah, I had a lot of fun speaking to you, and yeah, hope to speak. Speak soon.
Andrew Steinwold 1:10:57
Awesome, man. Thank you. Hey, everyone. Stay tuned for more episodes of The ZIMA RED podcast, and subscribe to the ZIMA RED newsletter for more info on all things. NFTs thanks so much for listening.
Coming together for DeSci.Berlin
DeSci Berlin was not a regular conference. It was a combination of talks, interactive workshops, and discussions encouraging attendees to self-organize and explore collaborations. From the lessons and reflections of the early pioneers, to ways to navigate the DAO ecosystem, and the proof-of-concept for funding research and science - it was clear that this is one of the most exciting use cases for positive impact from crypto.
It was organized by our team Molecule. We are a decentralized protocol and marketplace to fund research through IP-NFTs, biotech DAOs and our marketplace.
DeSci Berlin took place over two days (May 24 and 25, 2022) at CODE Berlin, where we gathered scientists, developers, investors and enthusiasts to meet each other and explore how to grow this community.
The event kicked off with a welcome by Paul Kohlhaas, CEO and co-founder of Molecule to give a brief recap in the current Decentralized Science Ecosystem and the fresh official announcement of closing Molecule’s 13 million seed round. This set the stage to explore the potential and future of decentralized science and biotech.
Highlights
Doing highlights is difficult when there is a program with so many great speakers, sessions and conversations to learn from: Jack Scanell, Puja Ohlhaver, Rafa the Builder, Sebastian Brunemeier, Sarah Hamburg, Karola Kirsanow, Niklas Rindtorff, to name a few.
One crucial highlight was meeting the community. So many of these relationships were forged during the pandemic, via discord or video calls.
There is a magic to connect with like-minded online friends, colleagues, and people in person. To share and discuss ideas of how we want to make this space a success and serve its purpose. Which is why having these in-person gatherings is crucial to make our globally spanning, decentralized networks a success.
Sebastian Brunemeier - Another World is Possible: How DeSci Can Transform Biomedical Research & Venture Capital
Sebastian is a prolific figure in the field of longevity biotech. Co-founder of multiple startups, former principal at Apollo Health Ventures, his page of “what I have done” is the who is who of academia, research institutes, biotech, and investment. No surprise he is also working both with Molecule and VitaDAO. But his biggest unexplored talent might be as Meme Chief Officer for longevity. Who knew a presentation on Biomedical Research & Venture Capital. (Insert video link) could be so entertaining and funny.
With great analogies and some impersonations, this presentation might as well become a scientific standup hour.
There are an increasing number of articles that talk about why DeSci has the potential to change so many of the current paradigms in scientific research funding and publishing. (Some of which you can find in Molecule’s blog). However if you want to be thoroughly moved and clearly understand how and why we need IP-NFTS, watch this presentation.
Sönke Bartling - Lessons learned from earlier revolutions. How the DeSci community can do better this time.
Sönke Bartling is a well-known name at the intersection of blockchain and science, having birthed the Blockchain for Sciences conference in 2017. He is well known to the researchers and crypto enthusiasts who have been trying to figure out how to improve science and access with these new technologies. As the man who years ago was trying to get people together to explore how to make open science happen she was the ideal person to end the calendar of DeSci.Berlin. Part retrospect, part “what we got wrong”, it ended up being a great call to action on how to build on from past mistakes.
Puja Ohlhaver - Decentralized Society (DeSoc) x DeSci
It is a testament to being able to explore novel ideas with your community having Puja Ohlhaver lead a workshop on Decentralized Society ideas in the context of Decentralized Science! She recently co-authored a paper together with Glen Weyl and Vitalik Buterin called “Decentralized Society: Finding Web3’s Soul”.
DeSoc (Decentralized Society) points away from web’s current hyper-financialized state towards a “more transformative, pluralist future of increasing returns across social distance”.
Calling for a new enlightened way to navigate property rights and governance mechanisms for more plural networks. It was quite interesting seeing people discussing the importance of this new concept on Twitter while at DeSci Berlin the discussion was happening in real time.
A note about women in DeSci
Web3, crypto, scientific research; are still characterized as male dominated fields however the number of panels and speakers reflected the participants in this conference. Having Puja as a speaker felt like an important moment in highlighting her thought leadership. Good things come from curation that includes diverse participation.
Jesse Hudson, Jose Pinto, Savva Kerdemelidis - Navigating the Challenges in DeSci
DAOs, web3, DeSci, property rights, legal rights, it is all still early days in having all of these defined. It is not surprising that that workshop with lawyers working in this emerging field generated so many questions.
The running theme for this workshop was “This is not legal advice”, because reporting on some of the ways these new entities are navigating regulation and setting up ways to fall within regulation is a work-in-progress.
It is also important to highlight that all of this is being taken very seriously by everyone as there are venture funds and institutional investors that still need to have certain parameters in place to feel comfortable investing in this ecosystem.
A take away was to seek proper legal advice, and get in-house counsel as soon as you possibly can. No workshop can provide the complete picture to any one particular jurisdiction and scenario.
Legal will become an important part of the DeSci ecosystem, especially when the legal teams are as enthusiastic about this emerging field as the community. More importantly it will be crucial to report the different ways legal teams are navigating the field. Note that it helps when you have an eloquent team lead the panel. (Alas, we wish we could share the workshop, but our legal department says legally we should not.)
Paul Kohlhaas, Tyler Golato, Laurence Ion, Niklas Rindtorff, Vincent Weisser - DeFi x DeSci - Liquid Singularity: embracing the hyper-financializtion of science.
IP NFT - is owning equity in a research project.
Yes, that was a lot of names and a big title.
However this panel that turned into an interactive workshop was one of the most interesting in clarifying funding models, new grant funding systems, direct micro-grants, and mechanisms of decentralized science prizes.
VitaDAO, the collective funding longevity research, just turned one year old this June 18th and it served as the best clear proof-of-concept for the utilization of all these tools. The DAO has the metrics to show that a community powered by researchers, scientists, developers, and enthusiasts can accomplish a lot with different incentives in place.
There was also a great level of transparency on the challenges at hand such as “how can IP become more open, transactable and liquid” - the way IP works right now makes this difficult.
And working in clarifying the communication and jargon. Tyler Gelato pointed out that one of the biggest challenges in the field is explaining the tools.
For example:
An IP-NFT can be explained as “Owning equity on a research project”
Vincent Weisser also reminded us that there are multitudes of ways to fund Public Goods, and though this talk talk and workshop was one of the first ones of DeSci Berlin it should also be the one that most of us will keep in mind of why we are involved. A raison d’être.
Decentralized Science is one of the best use cases for web3 as it looks to power drug discovery, rare disease research, carbon capture, renewables, and new technologies. All of these can create a net positive impact.
DeSci is a game changer not just for how to create new collectives, use blockchain, access capital, and change incentives, but for a benefit to society in general.
Thank you to the DeSci community
A big thank you and massive appreciation for all the people that helped make this amazing conference possible!
Seeing everyone in person and getting to share ideas in person is going to be a way to move forward as we grow.
Also a massive thanks to the wide range of incredible, supporting partners and sponsors including:
Until next time!
Follow @molecule_dao on twitter, and @desciberlin to stay up to date on future events.
—
Follow the author @lauraminquini, longevity advocate and entrepreneur and DeSci Berlin’s MC.
Molecule’s first IP-NFT for drug discovery R&D in the United States
This is the first time that Molecule’s IP-NFT is being used to fund drug discovery research based in the US. Watch the transfer ceremony with Dr. An below or here:
Dr. An’s research interests lie at the intersection of Geroscience (aging biology) and Oral Biology. His primary research focuses on understanding the basic biological mechanisms of aging in the context of oral health and disease. Chronic, subclinical dental inflammation may be a driver of systemic inflammation and especially cardiovascular disease risk, due to the lymphatic connections between the heart and mouth. This field is largely neglected by the pharmaceutical industry.
As a practicing dentist, Dr. An experiences a lack of mechanistic understanding of why older people are more susceptible to oral disease and oral health decline on a daily basis. Dr. An’s laboratory targets specific hallmarks of aging in the oral cavity to translate these discoveries into the clinic. Dr. An is currently an Assistant Professor of Oral Health Sciences and Faculty in the Healthy Aging and Longevity Institute. He also serves as the Assistant Graduate Program Director of Oral Health Sciences. Dr. An currently directs courses in the departments of Oral Health Sciences and the Department of Lab Medicine and Pathology.
Periodontal disease (periodontitis) is a worldwide burden that affects over 70% of older adults. It reduces oral health-related quality of life, impacts systemic health, and an often-neglected age-related disease for which there is no cure. Consequently, the research of Jonathan An’s laboratory at the University of Washington focuses on the intersection between biological mechanisms of aging and the accompanied onset of common age-related oral health conditions, with a special emphasis on periodontitis.
A major neglect in all current standard therapy and research of periodontitis is the impact of a low-grade, chronic inflammation without overt infection known as “inflammaging”. By evaluating pathways that target “inflammaging”, Jonathan An’s team recently demonstrated that modulating the PI3K/NFkB/mTOR cellular signalling axis with an immunosuppressive and antiproliferative mTOR inhibitor rejuvenated oral health and reversed periodontal disease in an age-related periodontitis animal model. In the project funded here, An’s research group plans to ultimately translate an additional set of drug candidates with already well defined characteristics and a proven effect to interfere with the inflammatory response triggered by the PI3K/NFkB/mTOR into the first medical, non-surgical treatment for age-related periodontitis.
“Current therapies are limited to treating the symptoms and fail to address the underlying cellular and molecular causes of oral disease and decline in older adults, which we hypothesize are a direct consequence of biological aging. Targeting such processes may introduce novel strategies to prevent the onset, the progression, or even reverse age-related oral decline and disease ” - Jonathan An
You can learn more about the research proposal on Molecule’s project page or on the VitaDAO governance site.
To learn more, discuss or try this approach, connect with us at info@molecule.to or join our Discord to interact directly with our team. For more specific ways of engaging with us, please be guided by the following:
- If you are interested in funding biomedical research, get in touch with your therapeutic area of interest and explore projects listed on Molecule’s Discovery Marketplace
- If you are a researcher, get in touch to list your R&D project on Molecule Discovery.
- If you are interested in creating a biotech DAO, we’re launching bio.xyz soon, a biotech DAO and DeSci launchpad - apply here for funding.
- If you want to stay informed about our workings, visit our website, join the conversation on our Discord, follow us on Twitter, or subscribe to our Youtube channel.
- For any additional questions, reach out to us on info@molecule.to or, for any media requests, reach us at pr@molecule.to
Molecule is building the first Solana-native DeSci funding platform: Pump.Science
DeSci Breaks Ground on Solana
Just like pump.fun is the poster child of Solana’s memecoin bull run, pump.science will be the poster child of Solana’s DeSci movement.
Using bonding curves and a simple UX, pump.fun made launching meme coins (which used to be a somewhat mysterious process) simple, fast, fun, and transparent. Pump.fun showed that when the barriers to creation fall, more good ideas rise, and new users are drawn into crypto. It was proof that culture eats strategy for breakfast.
We are no strangers to bonding curves. Molecule’s founder was yapping about bonding curves funding science back in 2019. Molecule’s newest product, Catalyst, leverages a unique bonding curve for funding early-stage scientific research with IP tokens. But Catalyst is on Ethereum (Base). Solana is faster. And scientific progress must accelerate.
Pump.science: Betting on How to Live Forever
Molecule is developing pump.science, a platform for funding and streaming longevity experiments powered by Wormbot.
On pump.science, anyone can submit or fund experiments with drug regimens for C. elegans worms trying to extend their 20-day lifespan. Every experiment gets a token named after the drug regimen and seeks to answer the question, “Does this regimen extend the worm's lifespan?”
Anyone can buy the drug regimen’s tokens, watch the experiments unfold on Wormbot, and, if the regimen extends the worm’ lifespan, have a stake in the resulting drug development and distribution. The goal? Bet on the winning regimen, get it to humans, and live forever.
This isn’t just fun. It's science.
Learn more about pump.science by joining our Telegram and following us on Twitter.
About Molecule
Molecule is dedicated to advancing scientific research through democratized funding and the tokenization of intellectual property (IP). By transforming IP into liquid, onchain assets, Molecule aligns the incentives of researchers and funders, fostering a more collaborative and efficient research ecosystem.
Molecule Launches Catalyst, a New Platform for Funding Science Using Tokens
Early-stage biomedical research funding is plagued by a mismatch between funded and impactful research. This disconnect results in detrimental diseases being underfunded despite their impact on public health. For instance, conditions like longevity, hair loss, women’s health, cryonics, and brain aging often receive disproportionately less funding compared to their prevalence and burden on society.
Public funds play a substantial role in financing research. In Europe, approximately 0.74% of GDP is allocated to research and development (R&D), representing a significant public investment. In the United States, the investment is even higher, with R&D expenditures accounting for around 3.4% of GDP. Despite this forced, substantial investment by taxpayers, the public has almost no influence over how these funds are allocated.
Enter Catalyst. By utilizing blockchains, Catalyst democratizes research funding, allowing individuals to directly support projects that resonate with them. This decentralized model aims to rectify the inefficiencies of the current research funding apparatus, ensuring that funding better aligns with societal needs.
Catalyst empowers individuals to use their cryptocurrency to make impactful decisions, fostering a more transparent and impactful research funding protocol.
Introducing Catalyst: Aligning Incentives Through Onchain Intellectual Property
Molecule is thrilled to unveil Catalyst, the decentralized science (DeSci) funding machine. Catalyst aims to fuel scientific advancements by enabling democratized research funding through tokenizing intellectual property (IP).
Catalyst forms communities around the drug development process and empowers individuals to support meaningful scientific research. In exchange for funding the research, funders receive tokens with rights to the research IP. This creates aligned incentives for researchers and funders to collaborate to bring more breakthroughs to those in need.
Benefits of Catalyst
For Funders:
- Purchase Tokens to Fund Research: Funders can contribute directly to advancing scientific research ideas.
- Take Part in Research and Licensing Decisions: In exchange for funding contributions, funders receive IP tokens, which gives them the right to participate in certain research and IP licensing decisions.
- Trade Tokens to Match Evolving Interests: Funders can trade their IP tokens on decentralized exchanges, giving them the flexibility to match their evolving interests.
For Researchers:
- Access to a Network of Global Funders: Catalyst opens up new avenues for funding beyond traditional sources.
- Build Community Around Your Research: IP Tokens are tools for building engaged communities around research, so researchers can connect with passionate supporters and collaborators.
- Focus on Science: Researchers can concentrate on pursuing and advancing scientific work.
How Catalyst Works
Catalyst works by turning scientific ideas into digital tokens (IP Tokens). IP Tokens allow researchers to grant funders rights in exchange for backing their project. These rights create a shared incentive for researchers and funders to collaborate together to make the research valuable.
But what rights do these IP Token holders have? The right to govern and access IP is limited by the IP-NFT holder. The governance decisions could include:
- Voting on proposed IP licenses
- Deciding on the distribution of proceeds earned from the IP-NFT and its IP
- Signaling support for experimental and clinical trial designs
Using IP Tokens and shared governance rights, Catalyst aligns the interests of researchers and funders, making it easier for them to collaborate around budding research ideas.
The Foundational Pieces of Catalyst
Catalyst brings together key infrastructure to tackle the scalability and incentive challenges traditional research funding models face. These components include:
Democratized Funding: Catalyst creates access to funding opportunities without the need for traditional intermediaries, enabling anyone to participate in funding research projects.
IP Tokenization: Catalyst converts research funding into IP Tokens. IP Tokens grant the token holder rights to exclusive data, voting on project execution details, licensing the intellectual property to patients and pharmaceutical organizations, and determining how proceeds earned from licensing are distributed to token holders.
Bonding Curves: Bonding curves distribute IP tokens, rewarding early funders with a larger share of tokens. Funders can contribute or withdraw funds until a project meets its funding goal, making funding science unruggable.
Liquidity Provision: A portion of IPTs is used to set up a liquidity pool on a decentralized exchange, allowing funders to swap their tokens and enhancing flexibility.
A New Era of Incentive-Driven Research Funding
By leveraging blockchain technology and tokenized intellectual property, Catalyst creates a dynamic, democratized funding marketplace that brings together researchers and funders, accelerating scientific progress. For more information, check out our documentation.
Jumpstart the DeSci Machine; Get Insider Access
Molecule is gearing up for Catalyst’s beta launch. We invite you to be among the first to experience funding groundbreaking research projects and join the DeSci movement.
To celebrate the upcoming launch, we encourage you to sign up for Catalyst Insider Access. By joining now, you'll be the first to receive exciting updates and exclusive information on what's coming next. Trust us—you won't want to miss out on what's coming.
Be the first to know, and get ready to jumpstart the future of decentralized science funding.
About Molecule
Molecule is dedicated to advancing scientific research through democratized funding and the tokenization of intellectual property (IP). By transforming IP into liquid, onchain assets, Molecule aligns the incentives of researchers and funders, fostering a more collaborative and efficient research ecosystem.
BioDAOs are Community-Owned Research Translation Engines, Not Investment DAOs
Introduction
Moving research from concept to market is like conducting a symphony - there are numerous players and stakeholders, each bringing their unique expertise to work in harmony and advance a project. As research continues to speed up and span across disciplines, the challenge of bringing new ideas and innovations from the academic sphere to the commercial realm becomes increasingly crucial. For instance, many of the top-selling therapeutics available today were originally developed in academia and had to navigate the difficult path of translation.
The process of transforming a therapeutic or technology from the research and development stage into a market-ready product or service is intricate and laden with obstacles. Presently, it calls for the cooperation and coordination of a multitude of organizations, along with funding, expertise, collaboration, and various other resources and support. BioDAOs streamline the process by consolidating all pertinent stakeholders into a single, internet-based virtual organization. This vertical integration enables a seamless end-to-end approach, fostering increased efficiency, collaboration, and resource-sharing throughout the entire research and development journey.
In this brief piece, we delve into the challenges and opportunities associated with translating research from academic institutions and investigate how organizations like BioDAOs are contributing to the support and facilitation of this vital process.
The Primitives of Biomedical Discovery and Development
It's noteworthy that the majority of approved medicines, around 60%, have their roots in academia, with the remaining 40% stemming from pharmaceutical research and discovery. Early-stage therapeutic research generally involves target-based or phenotypic screening using cell lines (in vitro) and model organisms (in vivo), depending on the disease model being studied. This work is often grant-funded and carried out in academic labs until patents or other intellectual property (IP) are filed by the university's technology transfer office (TTO).
The university then licenses the IP to an existing pharmaceutical company or a biotech startup, which takes on Investigational New Drug (IND) enabling studies. These studies involve more in vivo testing in increasingly larger animals to evaluate safety and efficacy. This phase is typically executed by private biotech labs and/or contract research organizations, funded by venture capital and/or pharma balance sheets. Clinical development kicks off when the company files an IND with the FDA, progressing through Phase I for safety, Phase II for early signs of efficacy, and Phase III for determining full approval.
Once an experimental medicine has undergone all clinical development phases, the company files a new drug application (NDA - or MAA), which can be approved or denied by the FDA (or EMA). If approved, the company can then market and distribute the therapeutic. This process entails a blend of patient- and physician-targeted marketing to ensure the maximum number of eligible patients receive the treatment.
Throughout this progression, the therapeutic IP is often transferred among multiple organizations, including academia, biotech, and pharma. Funding typically comes from a mix of government agencies, venture capitalists (VCs), and pharmaceutical companies. The goal of a BioDAO is to consolidate all funding and development functions for a specific therapeutic area within a single organization, streamlining the entire process.
What is a BioDAO?
A BioDAO refers to a decentralized autonomous organization (DAO) that specializes in harnessing the collective efforts of a diverse group of stakeholders to expedite the development and distribution of biotechnology products and services, spanning from early concept to market. BioDAOs fund and incubate projects during the initial stages of translational research, often through IP-NFTs, even before a company is established. While venture studios and corporate venture arms share similarities, BioDAOs stand out as community-owned and operated entities.
Contrasting with venture studios and corporate venture arms, where investment is the primary activity and profits are distributed to shareholders or partners, investment in BioDAOs is a secondary endeavor within the community, akin to venture investments by a university endowment supporting the university's operations. Returns from BioDAO investments are channeled into funding further research and operations, mirroring how a university endowment's investments contribute to additional research, facility improvements, and the university's functioning. However, BioDAOs differ from universities in their ability to vertically integrate the scientific discovery and commercial development of biotechnology products and services for a specific indication or therapeutic area, unifying all relevant stakeholders within a single, internet-based virtual organization.
During a project's early stages, BioDAOs engage in activities such as inventing novel IP, funding and developing research from its members and consolidating biomedical datasets among their members. As projects advance and gain value within the community, BioDAOs allocate more resources toward company formation, business development, scaling, regulatory filing, and distribution of biotechnology products. By fostering a community of stakeholders with aligned incentives and diverse backgrounds, BioDAOs facilitate the translation of technologies. In this regard, BioDAOs can be viewed as collaborative research translation engines and a novel form of biotech organization that develops IP through an online-native approach.
How do BioDAOs differ from investment DAOs?
Investment DAOs, such as MetaCartel, FlamingoDAO, The LAO and BeakerDAO, primarily focus on pooling capital to generate profits that are distributed to their stakeholders. These organizations represent a collective of investors aiming to achieve the highest possible risk-adjusted financial returns. For instance, a member of The LAO may receive a distribution of profits resulting from the capital deployed by The LAO into a project.
On the other hand, BioDAOs concentrate on developing novel IP and funding research and development of its members. The capital they deploy aims to generate value for their members and returns that can be reinvested in further R&D, rather than yielding profits for stakeholders or distributing them. Similar to how a university member benefits from enhanced research facilities, program funding, and administrative support provided by the university endowment without receiving direct proceeds, a BioDAO member benefits from the organization's successful R&D efforts.
BioDAOs are designed to facilitate and support vertically integrated R&D by granting members access to necessary resources and expertise for the successful development and commercialization of new biotechnology products and services. The community isn't primarily composed of investors; instead, it consists of researchers, entrepreneurs, companies, patients, and other stakeholder groups, most of whom contribute their time and effort rather than capital. The activities of a BioDAO encompass funding R&D investments and other functions such as community education, company formation, project incubation, access to expertise and knowledge, networking opportunities, member data aggregation, and assistance with regulatory compliance and various challenges. By offering these resources and support, BioDAOs aid their members in overcoming the numerous obstacles involved in transitioning technology from the research and development stage to a commercially viable product or service.
The mission of BioDAOs is to incubate and translate research
The mission and vision of BioDAOs are patient- and-impact-centric compared to VC funding. While VC funding emphasizes maximizing return on investment for partners or shareholders, BioDAOs concentrate on supporting and facilitating the development of effective biotechnology products and services for humanity. Structured around a sustainability loop, BioDAOs create an endowment to fund research indefinitely. Below is an example of how VitaDAO has structured its sustainability loop.
BioDAOs generally offer resources and support to their members, helping them develop and commercialize new biotechnology products and services. This assistance can include funding for research and development, access to expertise and knowledge, and networking opportunities within the BioDAO community. In contrast to VC firms, which exclusively focus on investing in companies to generate financial returns for their investors, BioDAOs are solely dedicated to funding R&D that benefits their communities within their respective subject areas.
As a result, the mission and vision of BioDAOs align more closely with the needs and objectives of researchers and patients.
Examples of BioDAOs and Their Activities
VitaDAO, among the first BioDAOs, exemplifies how a BioDAO's function fundamentally differs from an investment DAO. VitaDAO comprises working groups of experts in various fields (refer to the figure above). Anyone can join VitaDAO by contributing either funding or time (work). In return, they receive governance tokens in the organization, granting them voting rights on proposals, such as which research projects to fund or how to support a project. The fact that many VitaDAO members join by contributing time and receive tokens, rather than providing funding, significantly differentiates it from an investment DAO. VitaDAO features many more operational roles than funding roles. Many of the largest token holders are those who actively participate in research project sourcing, evaluation, peer review, and operational activities for the DAO. Another major differentiator from an investment DAO lies in the allocation of proceeds from funding research that generates and monetizes IP. In VitaDAO, these proceeds return to the VitaDAO treasury to finance further projects. In an investment DAO, a portion of the proceeds directly goes to its members, but in VitaDAO, no portion is directly distributed to VITA holders. Instead, similar to a university researcher who may benefit from better facilities and increased research funding due to successful investments made by the university endowment, a VitaDAO member may gain advantages from the organization's funding activities.
VitaDAO community members with relevant experience collaborate with researchers on their projects, reviewing data and offering feedback on experimental direction. For instance, VitaDAO's deal flow and legal working groups negotiate deal terms with universities on behalf of the researcher and the DAO. The DAO efficiently leverages its extensive network of highly effective individuals using token incentivization. As research progresses, DAO community members assist with the creation of spin-outs to advance research to the next stage.
This interdisciplinary, cross working group approach to incubating and advancing research sets BioDAOs apart. In some cases, the DAO is so proficient in this task that negotiating research agreements and initiating projects takes weeks, compared to the industry standard of months. Some BioDAO activities, such as decentralized tech transfer (DTT), capitalize on the community and academic consultants as a collective intelligence to design experiments, create research projects, and generate IP within the DAO itself.
Decentralize or not? That is the question.
Biopharma R&D is gravitating toward increased decentralization, outsourcing much high-risk work to specialist contract organizations while keeping IP and data storage centralized internally. BioDAOs, however, offer an alternative by federating IP and data on Ethereum instead of keeping them siloed. This creates a more efficient superstructure and a new paradigm for biopharma R&D, boasting benefits like standardized data generation and decentralized analysis and interpretation.
Data structure and quality can vary significantly when performed by disparate entities, giving federated data acquisition an advantage over siloed, unconnected systems. Federated data is more likely to generate valuable insights through superior statistical power because it is compared against similar data in an open, connected system. For instance, RNA sequencing is highly sensitive to batch effects, and using a single high-quality RNAseq provider to federate data is more likely to result in the highest statistical power than multiple providers who don't share data and correct each dataset for data science purposes.
Data federation has compelling benefits, especially in areas like clinical trial recruitment. If clinical trial repositories or patient data are not connected via data federation, both the biopharma company and the patient or physician may miss eligible patients for clinical trials. Just as efficient financial markets require maximum liquidity on both supply and demand sides, data also needs to be highly liquid to create the most value for patients and biopharma companies.
However, centralization has its advantages in specific scenarios. For example, therapeutics manufacturing can benefit from centralization through economies of scale, resulting in the best drug prices for patients. Moreover, centralized data capture and/or storage can lead to dataset standardization. When federated, this standardized data—originally captured and stored centrally—can be even more advantageous to biopharma R&D, bringing top scientific and medical minds to the data for high-value decision-making. Existing biopharma companies often capture these centralization benefits, but there are numerous advantages of decentralization that are not fully exploited.
Although biopharma is moving toward more significant decentralization, it's only tapping into a fraction of the potential benefits. Most pharmaceutical companies have venture investment arms, but the quality and quantity of deal flow are constrained by the limited size of corporate venture teams. By expanding the team size and opening it up to a community, it's likely to increase connections, deal flow quality and quantity, and the expertise leveraged for decision-making. Decentralized entities also have competitive advantages, such as greater access to capital and patients. Decentralization offers a genuine means to regain public trust lost in recent years. This can be achieved by providing incentives and governance rights to patients participating in clinical research, shifting biopharma's focus from profits to patient value. Compensating patients with ownership and governance rights in the medicines they often risk their lives for can significantly increase their willingness to participate in research and expedite the clinical research process. For example, clinical trial recruitment often limits the progression of clinical-stage therapeutics, and the lack of a sense of ownership and governance among participating patients may be partially responsible. This shift from profit to patient value could boost biopharma's public trust and efficiency. In this respect, BioDAOs offer a solution that prioritizes patients over shareholders as the primary stakeholders.
Conclusion and future outlook for BioDAOs
BioDAOs represent a distinctive type of DAO that focuses on creating a comprehensive research translation ecosystem and novel IP creation engines. This approach enables BioDAOs to connect scientific innovation with real-world application, making them valuable players in the fast-paced biotechnology sector.
In the future, one might imagine that BioDAOs natively integrate AI and LLM capabilities, built and steered by their members to outright produce novel IP and therapeutics themselves and coordinate their development, thus decoupling from the current university and industry funding landscape. We believe that the pace and speed at which this may happen could surprise industry and provide an extremely valuable addition to the research landscape, given the agility, speed and open source nature that is required to make AI drug development capabilities and model development successful.
Unlike investment DAOs, BioDAOs generate returns to finance R&D rather than distribute profits to stakeholders. Nevertheless, similar to how university researchers and students benefit from improved research facilities and program funding provided by university endowments, BioDAO members may also reap the rewards of the BioDAOs' successes.
The existence of BioDAOs is grounded in the idea that patients and researchers are disenfranchised from the core stages of therapeutic development. Yet, they they have the strongest incentive and motivation for finding cures. Community-governed research translation organizations offer a solution. The motivations for prestige among academics and profits among venture capitalists are potent, but the desire for patients to alleviate their suffering is even more powerful. This underutilized driving force from patients could accelerate drug discovery, and BioDAOs aim to harness that potential.
In the future, BioDAOs are poised to play a vital role in advancing biotechnology, biotech-centric AI and bringing novel innovations to market. As DAO technology continues to evolve, BioDAOs are expected to gain wider adoption. The enormous potential of BioDAOs to drive progress and foster collaboration in biotechnology is disruptive and worth monitoring in the years to come.
To learn more about BioDAOs, check out bio.xyz and the BioDAO Bible.
Molecule Launches Intellectual Property Tokens (IPTs), Democratizing Biotech Intellectual Property and Empowering Innovators
Imagine having a magical key that not only allows you to peer into the treasure chest of scientific invention, but also lets you govern and own a piece of it. Today, Molecule unveils IP tokens (IPTs), a revolution in how we value and transact around scientific discoveries.
IPTs are already an experimental reality. VitaDAO recently introduced VITA-FAST, an IPT which confers governance over the IP-NFT which originally funded Viktor Korolchuk’s research into autophagy activators for longevity. Control of the IP-NFT has now been decentralized, giving VITA-FAST tokenholders direct voting power in guiding the research's future direction.
With IPTs, we've turned biotech intellectual property into composable digital assets. IPTs make it possible for everyone, not just large amorphous entities, to fund and benefit from scientific research. You no longer have to be a millionaire to own a piece of a pharmaceutical or have a say in the direction of an innovative experiment - you can do it using IPTs. Your ownership and governance is verified, secure, and transparent, thanks to the trust and reliability of blockchain technology.
We believe that biomedical scientists are the unsung heroes of our time. Behind every revolutionary breakthrough, is a team of biomedical scientists driven by the desire to decrypt the secrets of diseases, create innovative therapies, and provide cures to people in pain. They are the code-breakers of biological conundrums, and the inventors of medical marvels. However, despite their critical contributions, these remarkable individuals often aren’t able to reap the full rewards of their essential work.
As we look to the future, it's essential to develop mechanisms that ensure a more equitable recognition and remuneration for these pioneers. Inspired by their efforts to unlock the mysteries of our health, we should strive to unlock the full value of their contributions - both for their sake and for the advancement of biomedical science as a whole. When we truly value our scientists, we empower them to do what they do best: create a healthier, brighter future for us all.
Participating in the Molecule Ecosystem
To our scientists;
We want to bolster you as your innovative research transforms into a beacon of hope, not just for the patients waiting for a cure, but also for a community eager to support the promise of your work. IPTs are a platform designed to empower you, to help you raise funds for your research, and to bring your work into the spotlight. It's more than a tool - it's an invitation to join a revolution in how we value and fund scientific innovation.
The beauty of IPTs lies not solely in encapsulating your own pursuits, but in the power to unite a community of intellectual explorers and enthusiastic supporters. In distributing IPTs, you harness the collective intelligence and energy of a global network, propelling your work into frontiers you could not take them alone. As your research flourishes, the IPTs you've created grant you with the ability to guide the onward journey of your invention, safeguarding its integrity while amplifying its potential.
Today we invite you to begin your journey with IPTs, and in doing so, elevate the scope and impact of your invaluable research. It's time to let others support your research, and to see the fruits of your labor blossom.
To join us, please visit mint.molecule.to. Here, you can explore how to create a unique digital representation of your work, transform it into IPTs, and open it up to a world of potential patrons.
Alternatively, if you want to connect more directly, please join us on Discord. For further information, please see our documentation. Our vibrant community of scientists, innovators, and supporters are waiting to welcome you, answer your questions, and guide you through the process. Join us, and let's shape the future of medicine together!
Announcing bio.xyz
The first biotech DAO accelerator
Since 2018, Molecule has been at the forefront of decentralized science (DeSci). By helping to build the first biotech DAO - VitaDAO - and by creating core DeSci infrastructure like the IP-NFT framework we have laid the foundation for the next generation of builders in DeSci to emerge and reshape the life sciences. Through this process, Molecule and the DeSci community have learned a tremendous amount about building at the intersection of web3 and bio.
Opening the Biotech DAO Playbook
We want to open-source this knowledge and are excited to share and scale our learnings and frameworks with the broader ecosystem by offering hands-on builder support and funding to ambitious DAO-builders shaping the future of decentralized science.
Building a DAO in web3 is hard. Developing a value proposition and value accrual mechanism for DAOs is materially different from building a startup. Choosing the right technical infrastructure to build on can be daunting and confusing. Navigating the regulatory complexity of building a DAO is almost an art. Tokenomics and governance have evolved considerably over time and builders need to be constantly aware of the new DeFi trends and potential vulnerabilities.
Building a biotech organisation is equally hard. Builders in biotech require significant domain expertise, a strong network, an understanding of disease areas and patient needs, knowledge of intellectual property and licensing frameworks, and a fundamental understanding of successful execution and commercialisation patterns in biotech.
We realised that building a biotech DAO is ULTRA hard. Simultaneously, we saw the immense potential that these new organisational forms hold for humanity. For the first time showing a viable pathway for medicines to be openly and democratically developed and owned.
Announcing bio.xyz, a biotech DAO and DeSci launchpad that will fund and support future builders in decentralized science and biotech. bio.xyz will provide funding for DAOs working on a range of therapeutic areas and scientific domains, access to whitelabel frameworks and resources, mentorship, and networking opportunities. Our goal is to enable biotech DAOs to take full advantage of web3 and decentralized intellectual property frameworks like the IP-NFT, enabling them to fund, govern, and develop intellectual property emerging from universities, laboratories and biotech companies across the globe.
bio.xyz will be governed and owned by its members. It takes foundational stakes in program DAOs and manages those via its community multi-sig. By committing to shared governance with the DAOs we support, our goal is to create shared public infrastructure for network effects across the DeSci ecosystem. Thus, bio.xyz is more than an accelerator for biotech DAOs and DeSci projects - it is also a tokenized DeSci Meta-governance layer, shared infrastructure, a DAO of DAOs.
Program Structure: A Petri-dish for DeSci Innovation
For builders, bio.xyz is an 18 week hands-on experimental program organized into 3 foundational milestones, culminating in the public launch of a series of new biotech DAOs.
Quick Facts
- 18 weeks of dedicated support from the bio.xyz network and Molecule
- Suite of technical frameworks and resources to get your biotech DAO to launch
- Shared governance rights in bio.xyz
- $100,000 USDC WAGMI grant
Our community will provide you funding, regulatory support, technical support, community support - but more importantly: commitment to build.
We will strive to funnel the brightest and most committed biotech and web3 builders into our DAOs because we know that together we are going to make it.
Customizable modules on building a biotech DAO
Building a sustainable biotech DAO requires deep domain expertise in both biotech organizational processes and web3. This first module will explore how biotech DAOs can generate sustainable value accrual mechanisms through building IP portfolios and networks of researchers and how these mechanisms form a symbiosis with web3 tokenomics, governance, and organizational design.
DAO Legal Defense Protocol
We help demystify the most complex elements of starting a DAO, such as important regulatory questions and hurdles, implementing a DAO legal defense protocol and tooling that helps simplify everything from incorporation, structuring, contract signing, and IP-NFT integration.
Technical IP-NFT Integrations
Intellectual property is the core value driver in sustainable biotech DAOs. We provide everything you need to mint, transfer, and sell IP-NFTs using the Molecule tech stack.
Governance and Operations Support
We provide proven governance frameworks, battle-tested for success. We help simplify DAO operations and accounting through a network of frameworks and operators.
Community Building
We help you go from 0 to 1000 with the right tools and people, and a special focus on helping you build a strong network of academics relevant to your therapeutic or scientific area of interest.
Dealflow Process Implementation
We turn sourcing, evaluation, and dealmaking into a standardized and replicable process with custom tools and whitelabelled frameworks for deal flow management, standardized agreements, and licensing and negotiation support.
Custom Tokenomics, Incentive Programs, and Fundraising
We design and enable sustainable token economies for long-lasting scientific organizations, plus access to visionary and patient capital from our network.
Plugging into Web3 and DeFi
We provide liquidity avenues, partnerships and awareness to make sure your DAO is web3-compliant and cutting edge.
Branding and Design
Branding and identity are key to communicating a credible and reputable organization. Our network of designers and brand identity experts will help you create the best possible identity for your organization to cultivate a sense of trust and professionalism with researchers and your broader community.
WAGMI Grant and Milestones
We provide DeSci DAOs with a $100,000 USDC on-chain WAGMI grant into a multi-sig wallet on Ethereum controlled by members of your founding team and members of bio.xyz. Every 6 weeks, 1/3 of the grant is automatically released provided your DAO meets measurable (in some cases on-chain) milestones set upon grant issuance.
A portion of the grant converts into your DAO’s governance tokens issued to bio.xyz so that members of bio.xyz can vote in your DAO, helping to ensure your DAO’s ownership is decentralized from day zero.
First Cohort
The program will operate in cohorts of 4-5 biotech DAOs. We are extremely excited to announce four members of our first cohort:
ValleyDAO
ValleyDAO is an open community collectively financing and enabling access to synthetic biology technologies to protect the future of our planet.
PsyDAO
PsyDAO will revolutionize R&D and ownership of psychedelics IP using the permissionless, trustless, decentralized, and censorship-resistant web, web3.
HairDAO
HairDAO is a decentralized asset manager funding early stage research and companies focused on better understanding and treating hair loss.
AthenaDAO
AthenaDAO is a decentralized collective to fund women’s reproductive health research & drug discovery.
In our view, the first bio.xyz cohort represents some of the most credible and exciting projects in DeSci, complemented by extraordinary teams and strong academic communities. We are extremely excited to support them on their journey to change their respective therapeutic areas for the better!
Contributors and Mentors
A core goal with bio.xyz is to build a large community of contributors, mentors, scientists, and builders, working together to collaboratively create the future of DeSci. We are actively looking for mentors in dealflow, scientific diligence, governance, tokenomics, legal, Web3/DeFi, and community. Mentors in the program will be rewarded with governance stakes. Applications are open now for the program.
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The future of biotech DAOs is bright
We are excited to work closely with the next generation of biotech DAO builders! We’d be thrilled to hear from you.
- For more information on the program, please visit the FAQ here. Applications for the second cohort are opening December 2022.
- To apply to become a mentor, apply here.
- If you want to stay informed about our workings, visit our website, join the conversation on our Discord, follow us on Twitter.
For any additional questions, reach out to us on info@bio.xyz
The Emergence of Biotech DAOs
Breaking Eroom’s Law
We are all familiar with Moore’s Law - the observation that the number of transistors in a dense integrated circuit doubles about every two years, which broadly describes the exponential growth we see in computational power over time. Eroom's law (Moore’s Law, in reverse) is the observation that drug discovery is becoming slower and more expensive over time, despite improvements in technology. While technologies such as high-throughput screening, combinatorial chemistry, and computational drug design should have arguably improved the rate of innovation, progress has been bottlenecked by other systemic and institutional-level issues such as increasing regulatory burden, a lack of open-source sharing of technologies, and misallocation of capital in incumbents that have prevented new drugs from reaching the market, and therefore, patients.
One potential explanation for this trend is the failure of coordination of capital and resources, coupled with monopolistic intellectual property models that pervade pharma and biotech at scale. These models disincentivize information sharing and collaboration, muddling data production and generating ambivalence on experimental outcomes. While new laboratory technologies alone have failed to improve efficiency in drug development, we believe that new advances in network, coordination, and incentive technologies at a structural level could reverse this trend by enabling new methods of optimizing collaboration, talent, and capital allocation.
Biotechnology and pharma have been historically centralized in the form of large companies and organizations that lack incentive to work in open and collaborative ways. Put differently, pharma has a “closed source” culture. The decentralization trend is dethroning centralized entities with power monopolies and shifting towards networks of collaborators co-existing in flat hierarchies.
Decentralized communities are powered by sharing pre-competitive resources within a community to achieve a common goal. They promote an open-source culture to their members and incentivize them to collaborate using token-based mechanisms.
Decentralized networks provide a trustless environment where data reconciliation is improved, points of weakness are reduced, and resource distribution is optimized at scale. In the context of biotech, this means creating new organizational structures that have a low barrier to entry (logging onto Discord, for example), are intrinsically collaborative and incentive aligned (WAGMI), and can coordinate capital and work from any participant (even the general public and patients). These features are emerging in the form of decentralized autonomous organizations (DAOs).
DAOs are relatively new smart contract-based entities that enable the coordination of capital, talent, and crowd intelligence at an unprecedented scale. Recently, a new decentralized science (DeSci) movement has been rapidly changing the way that coordination in science and biotech occurs by leveraging DAOs (see VitaDAO, PsyDAO, labDAO), with Molecule increasingly positioned as a core infrastructure provider in the space.
The DeSci movement is currently forming as a talent pool for entrepreneurial researchers and leading thinkers in biotech innovation that are frustrated by the status quo, whether it relates to funding, coordination, collaboration or other systemic issues that affect young founders and academics in biotechnology. The NIH, for example, allocates just 2% of its funding to scientists under 36, and 98% to those 36 and older. This trend, amongst others, has led to enough frustration that several new organizational types, such as FROs and DAOs, have emerged with an intention to revolutionize the biotech landscape. But what exactly is a DAO? Why is it important, and how might it change biotech?
The Biotech DAO Design Space
Let’s begin to understand biotech DAOs by walking through the steps of creating a DAO and how they function. An appropriate starting point for a biotech DAO is a clear vision and mission — what do these new, open organizational frameworks enable? Biotech DAOs can coordinate talent, enable decentralized fundraising and governance, or help create standardized methods of data collection and production, among other things. They can be philanthropic or for-profit. While biotech DAOs have a limitless design space their key innovation is their lack of gate-keeping and the use of technology to mediate decisions by large communities.
One element that all biotech DAOs have in common: they address a problem that has so far been unsolvable given the lack of incentive mechanisms for widespread collaboration in biotech.
To better understand this, we can take an example — VitaDAO, the first biotech DAO birthed by Molecule. VitaDAO is focused on funding early-stage preclinical drug development in the context of longevity. When designing VitaDAO, Molecule’s goal was to 3-fold:
- Create a Schelling point and community building exercise at the intersection of longevity and Web3, enabling researchers and the public to gather and participate in research and funding.
- Fund cutting edge, high impact research out of academia, and help to translate this research into effective medicines
- Create a sustainable organization as a function of its commercial efforts, with proceeds from these efforts providing a continuous funding mechanism for longevity science.
The third point, “a sustainable organization as a function of its commercial efforts” requires that the DAO derives monetary value from its funding efforts. To do this, VitaDAO leverages Molecule’s IP-NFT framework, which allows the DAO to own, license, and transact in intellectual property generated from the projects it supports. VitaDAO works to fund and later commercialize early-stage research out of academia. The DAO owns the resulting IP from the projects it funds. For the first time, value is captured by large, decentralized communities of researchers and patients.
NFTs can enable us to capture all sorts of asset types, including IP rights and data, and manage them natively in web3. Web3 allows these assets to exist in cyberspace, which means you can interact with them in some way no matter which country you’re in, transcending borders, time zones and jurisdictions. This is a big step in democratizing access to these assets. NFTs can be transferred to another wallet, tokenized, collateralized and borrowed against, sold on NFT marketplaces and they can be programmed so that the original creator automatically receives royalties every time the NFT is resold.
At Molecule, pioneering novel frameworks for IP-NFTs that attach both IP and data to NFTs turns IP into a new highly liquid, transactable asset class that bridges web3 into the real-world. Designs here are early, and these new vehicles will need to stand the test of time and the courts. Early data shows they work and comply.
BioDAO Frameworks
VitaDAO is the first design of what a biotech DAO might look like. One of the core goals at Molecule is to create productized biotech DAO frameworks that enable anyone to build their own biotech DAO, operationalize it, and begin leveraging the effects of a large, open community to achieve their goals. To this end, Molecule is seeking to work with motivated researchers, patient groups, entrepreneurs, community builders and visionaries that are interested in building at the intersection of biotech x web3.
We imagine these structures becoming instrumental in shaping patient and researcher communities. Imagine patient- and researcher-centric Bio DAOs focused on Alzheimer’s research, specific types of cancers, or diabetes with tight feedback loops and collaboration between patients and researchers during the entire end-to-end drug development process, from funding to licensing and beyond.
At Molecule, we see our core responsibilities here to help builders in a number of ways:
- Enable biotech DAO builders to leverage our IP-NFT legal licensing frameworks and DAO organizational frameworks. We will support their efforts of collaborating with and supporting academics via Molecule’s marketplace.
- Funding from the right sources. We will provide liquidity and support to projects in the form of grants and token swaps. WAGMI.
- Provide a talent pool that can move between DAOs, helping build and bootstrap across all components of a DAO: treasury, governance, operations, strategy, marketing, education, and search/evaluation. We have a network of researchers, entrepreneurs, builders, biotech VCs, and enthusiasts to help build the best organizations possible.
- Help establish sound global legal frameworks tailored to specific biotech and patient-centric DAO communities such as for-profit LAO like frameworks pioneered by Tribute Labs or non-profit Swiss Associations.
PsyDAO will be the second biotech DAO that Molecule launches and its ultimate goal is to democratize access to psychedelics. We aim to achieve this core goal through several related means. The first is by bringing together a large community of researchers, KOLs, enthusiasts, and spiritual leaders to collaborate and determine the future of psychedelic research. Collectively, this group will work on funding psychedelic research in exchange for ownership in intellectual property, which will be open-sourced and made available to all or commercialized. A key goal is working to make psychedelic IP unmonopolizable by front-running industry or purchasing IP to be made public, before it is patented. This design principle differs slightly from VitaDAO’s, for example.
Others in the ecosystem are also beginning to build biotech DAOs with entirely different functions, going beyond funding. One leading example here is LabDAO. LabDAO is building a community-owned and operated platform to run scientific laboratory services, exchange protocols, and share data. These organizations have a high potential for interoperation and collaboration.
You can imagine a scenario where organizations like VitaDAO source assets from Molecule’s Discovery Marketplace in the form of IP-NFTs. VitaDAO funds early preclinical de-risking experiments. Once positive data emerges, and new experiments need to be performed that might be beyond the scope of the laboratory receiving funding, LabDAO — a community of laboratories — steps in, coordinating downstream development work and experimentation via other academic labs and CROs. Decentralized drug development begins to take shape. Further, the IP-NFT allows different contributors (like LabDAO members) to receive exposure to ownership in IP, in exchange for work. These organizations begin to form a modular, decentralized drug development pipeline with each organization playing to its strengths, and receiving rewards for their contributions.
All of these parts taken together begin to form the basis of a collaborative, open, and inclusive ecosystem that has the potential to permeate and shift monopolistic behavior in biotech towards something that is more strongly aligned with patient and researcher’s interests. This is the beginning of a new frontier for biotech, and this is only Day 1.
Please join us in helping build a better future for biotech.
An open BIO ecosystem for humanity
We want to help anyone that shares our dream of an open pharmaceutical system. Currently, we are helping build biotech DAOs such as:
- VitaDAO — focused on funding longevity research
- PsyDAO — focused on funding psychedelic research
- Drug repurposing DAOs such as Crowdfunded Cures
- DAOs for Rare Disease communities
At Molecule we provide:
- DAO and web3 frameworks
- Hands-on community development strategies
- Legal frameworks
- Token economic designs
- Liquidity
- We intend to provide DAOs with funding and liquidity to enable them to compete with current VC and Pharma models.
Also be sure to check out LabDAO — one of the most exciting new players in the DeSci community.
This is day one. Build the future of biotech with us.
To learn more about Molecule: Check out our documentation, blogposts, talks, podcasts, careers, website & socials here.
For researchers: List your projects for funding on our Discovery platform here.
For web3 Builders: Join our Discord and reach out to our community manager.
Want to build your own Biotech DAO? Introduce yourself on our Discord or Email us.
Thanks to Paul Kohlhaas, Niklas Rindtorff, and Vincent Weisser for their critical feedback, edits, and assistance with this draft.
AthenaDAO’s First IP-NFT Bears Fruit: Results Have Arrived, Paving the Way for Future Fundraising
In August, 2023, AthenaDAO announced their commitment to combat ovarian aging, by dedicating $120,000 to Dr. Mario Cordero at Pablo de Olavide University. Not only was the preliminary science promising, but Dr. Cordero's own journey through fertility struggles, combined with his genuine desire to connect with the community he aimed to serve demonstrated a clear alignment in values. Since then, Dr. Cordero has been hard at work generating data, and we’re happy to let you know that things have gone well!
In order to continue this important work, Dr. Cordero, together with AthenaDAO, is looking to the community for support in raising $75k to fund the next milestones. Before we look too far ahead, we thought we’d walk you through the most recent results.
Fertility 101
Fertility often influences major life decisions and future planning. Estimates suggest that one in six people experience fertility issues during their lifetime - a challenge that people usually bear privately behind closed doors, feeling isolated and confused. With no clear biomarkers to indicate how many eggs a woman has or how much time she has left to conceive, decisions about family planning can feel like a race against an invisible clock. This isn’t just about reproduction—it’s about choice. The ability to make informed decisions about when to start a family, or whether to start one at all, is crucial for many women. Even beyond fertility, ovarian aging also impacts the onset of menopause, a life-altering transition that many women may be unprepared for.
What is Ovarian Aging?
Ovarian aging is the gradual decline of the processes that maintain fertility over time. As women age, their ovarian reserve—the number of viable eggs—naturally diminishes. But this decline isn’t the same for everyone. Some women experience a faster depletion, known as diminished ovarian reserve (DOR), where fertility declines earlier than expected. This can lead to fewer reproductive options for those affected.
At birth, women have around 1-2 million eggs, but by the time they reach menopause (around age 51), only about 1,000 remain. The most significant drop in egg quality and quantity occurs between the ages of 35 and 40, contributing to reduced fertility, a higher risk of miscarriage, and an increased chance of genetic issues in embryos. Globally, millions of women are affected by this decline, with many experiencing these challenges well before the average age due to conditions like DOR.
Factors that can cause ovarian aging to occur prematurely include genetics, autoimmune disorders, certain medical treatments (like chemotherapy), and environmental exposures. These influences can fast-track the decline, often leading to fertility challenges in women as early as their late 20s or early 30s.
Understanding ovarian aging is vital for women who want to take control of their fertility and make informed choices about their future. It’s also crucial for the doctors and specialists who support them in navigating these deeply personal decisions. By recognizing the signs early and raising awareness, we can help women explore their options sooner and find ways to preserve their fertility for when they’re ready.
Tracking Ovarian Health
One key biomarker often used to track ovarian health is Anti-Müllerian Hormone (AMH), a hormone produced by cells in the ovary. As the ovarian reserves drop, so do the AMH levels, providing insights into how quickly time is catching up with a woman’s reproductive ability. But AMH isn’t the only clue! Another key hormone, Follicle-Stimulating Hormone (FSH), rises as the ovaries become less responsive to its signals, consequently, prompting the brain to pump out more FSH in an attempt to maintain fertility. This ultimately leads to a cycle of increasing FSH levels, indicating a declining ovarian reserve and reduced fertility, which results in fewer healthy follicles developing into viable eggs. In addition, these hormonal changes don’t happen in isolation. The ovaries themselves also undergo structural changes, leading to fewer healthy follicles developing into viable eggs. Together, these biomarkers form a roadmap of ovarian aging, one that researchers like Dr. Mario Cordero are actively working to understand, in an effort to uncover novel treatments.
Until now, the process of ovarian aging has seemed like a predestined path, unable to be disrupted. However, what if there were ways to change direction? What if we could slow down this process? During research funded by the AthenaDAO community, Dr. Mario Cordero uncovered a surprising biological pathway, which may hold the key to new treatments. The pathway, known for its role in immune response, is called the cGAS-STING pathway.
The Role of the cGAS-STING Pathway in Ovarian Aging
Emerging research shows that the cGAS-STING pathway might be a major cause of inflammation and tissue damage in aging ovaries. In both humans and animal models, higher levels of STING have been found in the ovaries, especially in a specific cell type called granulosa cells. These cells are crucial because they help eggs (oocytes) grow and mature, which is key to fertility. When this pathway is overactive in aging ovaries, it leads to increased production of certain inflammatory substances (such as IL-6 and Type I interferons). These substances cause inflammation and gradually reduce the ovaries' ability to function properly. When STING remains active for too long in ovarian cells, it can lead to several problems: the cells may age faster, their energy production can be disrupted, and their DNA can become damaged.
All of these issues can speed up the loss of eggs and simultaneously lower the quality of the remaining ones.
Results from Dr. Cordero’s research so far
This research was designed to look at how the cGAS-STING pathway might be linked to aging in the ovaries and how it affects fertility. The researchers also studied how this process might be involved when chemotherapy damages the ovaries. The project was divided into three main parts, called work packages (WP).
WP1: Studying How the cGAS-STING Pathway Affects Aging in Ovaries
In the first part (WP1), the scientists looked at how the cGAS-STING pathway changes as women get older. The first experiments were designed to check whether or not cGAS-STING was involved at all with ovarian aging. If not, then it wouldn’t make sense to pursue further experiments. If yes, then full steam ahead!
They found that the STING protein is more active in older ovaries, which may contribute to the ovaries aging. This was seen in both human and mouse ovaries. They discovered that cells in the ovaries, especially in granulosa cells, are where this process happens most. Both mouse and human samples were tested because mice are often used as model organisms. However, if there was a big difference between the mouse and human data, then it would not be possible to continue using mice to study these effects, and another model organism would need to be chosen.
Since the data showed that mice can be used as a tool to study these effects, Dr. Cordero’s lab continued with their plan, and used a STING knockout model to see what would happen to the ovarian reserves if the STING protein was no longer present. Knockout mice are used to study what happens in an organism when a particular gene is absent.
Dr. Cordero found that mice lacking the STING protein had more eggs and better fertility as they aged. The figure below shows mouse ovaries from ‘normal’ and ‘knockout’ mice, and the white arrows point to more follicles developing in the knockout mouse compared to the normal, wild-type mouse.
Finally, the researchers also found that women with diminished ovarian reserve had higher STING activity in their ovarian cells, as shown by higher levels of STING protein levels in samples from a healthy female compared to samples from a female with DOR.
Together, the results from WP1 suggest that blocking the cGAS-STING pathway might help women keep their fertility longer as they get older.
WP2: Looking at Chemotherapy’s Effect on Ovaries
In the second part (WP2), the researchers wanted to see if the cGAS-STING pathway also plays a role in how chemotherapy damages the ovaries. Early findings showed that chemotherapy increases STING activity in patients.
In experiments with mice, they found that mice without the STING protein were protected from the harmful effects of chemotherapy on their ovaries. This means that blocking the cGAS-STING pathway could help protect women’s ovaries during chemotherapy, potentially saving their fertility while receiving life-saving treatment.
WP3: Creating Therapies to Block the cGAS-STING Pathway
The third part (WP3) was about developing new drugs to block the cGAS-STING pathway. The scientists tested several small molecules and found one, called "A2," that works well at reducing the harmful effects of the cGAS-STING pathway, such as inflammation and cell death. This drug could be helpful in protecting or improving fertility in women as they age or undergo chemotherapy.
It's time to fundraise for the next milestones!
True to the belief in equitable and accessible scientific research, AthenaDAO will be tokenizing the Cordero IP-NFT into Intellectual Property Tokens (IPTs) with the support of Molecule. These tokens enable the distribution of IP rights to holders to both raise funds for continued scientific research and empower the community to govern the resulting IP.
Due to the successful completion of the work packages in the first milestone of the project, Dr. Mario Cordero is looking to raise $75,000 USD to continue the work in milestone 2. With these funds, he is hoping to achieve two clear goals:
- Continue the development of in vitro testing of these newly discovered inhibitors (A2) from WP3
- Test to see what happens when the cGAS-STING pathway is inhibited with Dr. Cordero’s newly developed compounds in animal models with reduced ovarian reserve
Why choose the IPT model?
By giving community members the power to co-develop research projects via IPTs, AthenaDAO is harnessing the potential of decentralized science. As the project moves forward, important decisions—such as which delivery vehicles to test, the best disease indications for clinical trials, and how to raise additional funds—will be guided by the collective expertise of the community. With the power of IP tokenization, the wisdom of the crowd will play a critical role in shaping the future of fertility research.
AthenaDAO will be sharing more details on the crowdsale soon - subscribe to their newsletter, join the community on telegram, or follow on X so you can be the first to know.
Supporting research that matters
At its core, this research is about empowering women with new options for their reproductive health. By tackling ovarian aging at a deeper level, we’re moving closer to a future where the limits of biology can be redefined. We’ve been honored to support Dr. Cordero’s partnership with AthenaDAO, and hope that you’ll join us on this journey.
References:
- Jirge, P. (2016) ‘Poor ovarian reserve’, Journal of Human Reproductive Sciences, 9(2), p. 63. doi:10.4103/0974-1208.183514.
- Moolhuijsen, L.M. and Visser, J.A. (2020) ‘Anti-müllerian hormone and Ovarian Reserve: Update on assessing ovarian function’, The Journal of Clinical Endocrinology & Metabolism, 105(11), pp. 3361–3373. doi:10.1210/clinem/dgaa513.
- Oh, S.R., Choe, S.Y. and Cho, Y.J. (2019) ‘Clinical application of serum anti-Müllerian hormone in women’, Clinical and Experimental Reproductive Medicine, 46(2), pp. 50–59. doi:10.5653/cerm.2019.46.2.50.
- Decout, A. et al. (2021) ‘The CGAS–sting pathway as a therapeutic target in inflammatory diseases’, Nature Reviews Immunology, 21(9), pp. 548–569. doi:10.1038/s41577-021-00524-z.
Molecule Partners with CryoDAO to Expand Onchain Intellectual Property and Advance Cryopreservation Research
Molecule, a leader in decentralized science (DeSci) and a pioneer in tokenized intellectual property (IP), is thrilled to announce its strategic partnership with CryoDAO, a decentralized collective dedicated to funding high-impact research to advance cryopreservation techniques.
Working on the bleeding edge of scientific innovation, CryoDAO’s mandate is to make death optional. We will be working together to further their mission, bringing cryopreservation research projects to the DeSci community utilizing Molecule IP tokens: IP-NFTs and IPTs.
Powered by Molecule IP Tokens
Molecule IP tokens transform the management of scientific IP through tokenization:
- Intellectual Property NFTs (IP-NFTs): IP-NFTs are non-fungible tokens that register scientific IP onchain. IP-NFTs provide a secure, immutable record of scientific IP ownership and rights, enabling easy IP transfer, verification, and management.
- Intellectual Property Tokens (IPTs): IPTs are fungible tokens that distribute the IP rights associated with a particular IP-NFT, decentralizing its scientific process by enabling globally distributed governance of it and transforming the way scientists engage with their online communities.
Molecule IP-NFTs and IPTs empower CryoDAO to accelerate the pace of cryopreservation research and funding by bringing scientific IP onchain.
Combining Biotech Dealflow Expertise
Working closely with the CryoDAO scientific research dealflow team, Molecule’s biotech team will aid in experimental planning, IP strategy, and negotiation, leveraging an existing partnership with Nucleate.
You can learn more about Molecule’s partnership with Nucleate to source cutting-edge scientific research for IP tokenization from all around the world here.
Together, CryoDAO and Molecule will build a pipeline of groundbreaking cryopreservation research projects and tokenize them.
Growing Onchain IP Through Cryopreservation
This collaboration marks an important step towards a more vibrant and innovative DeSci ecosystem, leveraging the strengths of both organizations to make a meaningful impact. To stay up to date on the partnership, follow Molecule on X or sign up for our newsletter.
"We are thrilled to enter into this cool partnership with CryoDAO, which accelerates our vision of tokenizing scientific IP, enabling new sources of capital to fund valuable, underfunded research areas like cryonics. We believe that DeSci has the opportunity to make crypto a force for enabling researchers to work on humanity’s biggest problems and for communities to bring discoveries to life that would never have existed otherwise. We are excited to charge the chilling growth of the CryoDAO community to make cryonics a reality and make taxes the only guarantee in life." Benji Leibowitz, COO at Molecule
“Together with Molecule, CryoDAO will push the boundaries of decentralized science, tokenizing the most important research in the world—research that will save our very lives. By calling on a global community to advance this science, we have an opportunity to change the course of human history forever. This partnership is an important first step.” Kai Micah Mills, co-founder of CryoDAO.
About Molecule
Molecule is dedicated to advancing scientific research through permissionless funding and the tokenization of intellectual property (IP). By transforming scientific IP into a liquid onchain asset, Molecule aligns the incentives of researchers and funders, fostering a more collaborative and efficient research ecosystem.
About CryoDAO
CryoDAO envisions a world where organs and tissues preserved in vast biobanks are available to patients on demand, where journeys to distant stars become journeys in slumber, and where even life can be frozen in time. CryoDAO funds research projects that have a high potential to increase the quality and capabilities of cryopreservation.
Leveraging Decentralized Funding to Combat Nonsense Mutations
Even the smallest mutations in our genetic code can have damaging effects, cascading into an array of disease pathologies. In an effort to negate these effects, VitaDAO, a key player in Decentralized Science, has partnered with Dr. Michael Torres and Artan BIO to engineer a first-in-class therapy that aims to suppress deleterious codon mutations. The VitaDAO community voted to provide $91,300 worth of funding to Dr. Torres via Molecule’s Intellectual Property Non-Fungible Token (IP-NFT) protocol. To increase the opportunity for community involvement and further funding, the IP-NFT will be tokenized into Intellectual Property Tokens (IPTs), granting governance privileges to IPT holders in the VitaDAO community and beyond.
What happens when DNA gets up to nonsense?
The ribosome, colloquially known as our protein printer, is continually walking itself down strands of genetic code, reading each building block like braille, and then summoning the corresponding amino acids, with the help of transfer RNA (tRNA). These amino acids string together, ultimately forming proteins. If a single building block, known as a nucleotide, mutates, it can alter the protein being created. Our proteins participate in every possible shade of bodily function, so changes in protein synthesis tend to cause a whole host of problems.
One such nucleotide change results in mutations known as nonsense mutations. They occur when a single nucleotide mutates and forms a stop codon, which is effectively a force-eject button. Stop codons are generally reserved for the end of the entire protein sequence when the protein is ready to be sent off into the body, but in the case of nonsense mutations, these stop codons accidentally crop up elsewhere. When this happens, protein formation is halted prematurely, resulting in half-formed, non-functional proteins which can go on to cause mayhem in the body. Finding and correcting nonsense mutations is not a novel concept. In fact, our bodies do it already! However, we’re far from perfect - issues arise when genuine stop codons are recognized as well, and overridden when they should not be. Currently, the existing treatments also fall prey to this issue.
The Science
To address the gap, Dr. Torres has invented a potential solution; an engineered system to suppress the outcome of a particular nonsense mutation, enabling the continuation of protein formation. His solution is unique in so far that it appears to be more discerning than other treatments, correctly identifying the problematic stop codon while ignoring genuine stop codons, and most importantly, not interfering with normal gene translation. Preliminary data produced in collaboration with Johns Hopkins University has supported Dr. Torres’ hypothesis, leading to VitaDAO’s decision to fund further investigation.
Additionally, Dr. Torres has identified a delivery system that is adept at sneaking into cells in the heart, liver, skeletal muscle, and central nervous system. By integrating the engineered codon suppressor into this vector, he suspects that it will be the perfect vehicle to carry the therapeutic to exactly where it needs to go. This vector comes with the bonus of already being clinically validated, which enables the team to optimize its path to first-in-human studies, as certain risks have already been addressed.
The Scientist
Dr. Torres, who holds a PhD in Cancer Biology from UT-Southwestern in Dallas, has previously co-founded ReCode Therapeutics, a clinical-stage genetic medicines company that has secured over $300M in funding. He now works as the CEO of CrossBridge Bio, an oncology-focused company focused on developing next-generation dual payload antibody-drug conjugates. Dr. Torres was introduced to Decentralized Science (DeSci) by longtime DeSci supporter Mike Baran from Pfizer Ventures, and was quickly attracted to the ability to leverage community engagement to critically evaluate and fund ideas. His extensive experience in drug development, as well as his aptitude for both science and entrepreneurship, make him the perfect candidate for VitaDAO and Molecule’s novel funding model.
“In essence, this model is a powerful tool for transforming ideas into tangible data, supporting future drug development, and creating valuable societal assets.” Dr. Michael Torres
A single solution for many diseases
As a seasoned drug developer, Dr. Torres understands the importance of having foresight when in the lab. In studying nonsense mutations, Dr. Torres observed that a specific nonsense mutation is prevalent in many proteins involved in cellular processes associated with aging such as DNA repair, epigenetic regulators, and tumor suppressors. As this mutation is conserved across many diseases, several clinical opportunities are possible. Under optimal conditions, this research has the potential to turn into a ubiquitous therapy that could be used to treat several health issues associated with aging. VitaDAO is particularly interested in the potential of a therapeutic that could reactivate tumor-suppressing proteins in cancer patients, aiming to slow down or even eradicate tumor growth, given their focus on age-related diseases. Some of the other diseases implicated with nonsense mutations are Duchenne muscular dystrophy, cystic fibrosis, spinal muscular atrophy, metabolic diseases, and neurologic disorders.
About VitaDAO
VitaDAO is a community-owned collective dedicated to funding and advancing longevity science that can improve people's lives. They have a strong presence in the Decentralized Science community and have utilized the IP-NFT model multiple times. In addition to this, together with Molecule and Dr. Viktor Korochuk, VitaDAO launched the first tokenized research project in the form of IPTs. The IPT tokens, known as VITA-FAST have enabled direct community governance - a world first.
Dr. Anthony Schwartz, a VitaDAO Entrepreneur in Residence, will act as the project manager for this project. He has founded at least 15 startups, primarily focused on autoimmune diseases and cancer, which have led to large financings and an FDA-approved product. He is also a lecturer at Johns Hopkins.
“The emerging VitaDAO model can potentially change how new drugs are funded. I'm excited and motivated to help bring that model to fruition through VitaDAO's funding of new companies and blockchain capital raises (IP-NFT/IPT) and seamlessly transition these companies into traditional VC/Pharma financing to bring new drugs to the market.” Dr. Anthony Schwartz
What is an Intellectual Property Non-Fungible Token?
Intellectual Property Non-Fungible Tokens (IP-NFTs) bring IP rights, such as the right to data and patents from drugs developed by funded research, onchain by attaching IP rights to smart contracts. By unifying data and intellectual property rights into programmable, transactable, blockchain tokens, IP-NFTs represent an evolutionary step in the development and management of scientific research IP. To date, IP-NFTs have been used to register IP of more than $1.95M in scientific research. The Torres IP-NFT adds to this growing list. You can find the IP-NFT here.
Intellectual Property Tokens invite the community to participate
“This revolutionary concept of IP tokenization allows community involvement in the drug development process, creating a mutually beneficial situation. For us, it enables unlocking additional capital in a collaborative manner. For the community, it gives them an opportunity to directly support projects in a manner previously unavailable.” Dr. Michael Torres
True to the belief of equitable and accessible scientific research, VitaDAO will be tokenizing the Torres IP-NFT into IPTs, fungible tokens enabling the distribution of IP rights to their holders, in order to raise funds for the science and empower the community to govern the resulting IP.
Funding from sales of the IPTs will enable Dr. Torres and his team to insert the engineered fragment into the chosen vector and perform in vitro testing to validate its effectiveness. IPTs will enable individuals to actively govern the project and its results, such as new drugs developed from the team’s research.
Granting community members the power to co-develop research projects harnesses the potential of incentive-aligned expertise, furthering decentralized science. Many decisions need to occur as this project unfolds, such as which other possible delivery vehicles to test, which disease indication is best suited for clinical testing, and how to raise additional funds. With the power of IP tokenization, the wisdom of the crowd now has the chance to influence those decisions.
Join VitaRNA Crowdsale
Molecule is building the first Solana-native DeSci funding platform: Pump.Science
DeSci Breaks Ground on Solana
Just like pump.fun is the poster child of Solana’s memecoin bull run, pump.science will be the poster child of Solana’s DeSci movement.
Using bonding curves and a simple UX, pump.fun made launching meme coins (which used to be a somewhat mysterious process) simple, fast, fun, and transparent. Pump.fun showed that when the barriers to creation fall, more good ideas rise, and new users are drawn into crypto. It was proof that culture eats strategy for breakfast.
We are no strangers to bonding curves. Molecule’s founder was yapping about bonding curves funding science back in 2019. Molecule’s newest product, Catalyst, leverages a unique bonding curve for funding early-stage scientific research with IP tokens. But Catalyst is on Ethereum (Base). Solana is faster. And scientific progress must accelerate.
Pump.science: Betting on How to Live Forever
Molecule is developing pump.science, a platform for funding and streaming longevity experiments powered by Wormbot.
On pump.science, anyone can submit or fund experiments with drug regimens for C. elegans worms trying to extend their 20-day lifespan. Every experiment gets a token named after the drug regimen and seeks to answer the question, “Does this regimen extend the worm's lifespan?”
Anyone can buy the drug regimen’s tokens, watch the experiments unfold on Wormbot, and, if the regimen extends the worm’ lifespan, have a stake in the resulting drug development and distribution. The goal? Bet on the winning regimen, get it to humans, and live forever.
This isn’t just fun. It's science.
Learn more about pump.science by joining our Telegram and following us on Twitter.
About Molecule
Molecule is dedicated to advancing scientific research through democratized funding and the tokenization of intellectual property (IP). By transforming IP into liquid, onchain assets, Molecule aligns the incentives of researchers and funders, fostering a more collaborative and efficient research ecosystem.
Gamifying Longevity: Increasing Participation & Accelerating Breakthroughs
What is longevity research?
In a recent episode of The DeSci Podcast, we welcomed Krister Kauppi, founder Rapamycin Longevity Lab, and Dr Mitchell Lee, CEO and co-founder at Ora Biomedical. The conversation focused on two major themes: how to accelerate research in the longevity space and the potential of gamification and decentralized incentives to push longevity research forward.
Longevity, in its simplest form, refers to extending human healthspan — the period of life spent in good health. While much of modern medicine is focused on treating ailments, longevity research aims to target the root causes of aging. Traditional research is expensive, bureaucratic, and slow-moving in the best of circumstances, and this is particularly true in the longevity field. With people dying from old age every single day this slow rate of progress just won’t cut it.
The Wormbot
Enter Ora Biomedical and the Wormbot. The Wormbot is a low-cost, rapid experimental platform developed by Ora Biomedical, founded by Dr. Matt Kaeberlein and Dr. Mitchell Lee to inexpensively and efficiently test a large number of potential longevity regimens on C. elegans, a worm with an average lifespan of 20 days. This robotic system performs automatic population-level imaging, capturing worm survival, movement, interactions, and more on a scale that is exponentially larger than other labs,
“A single one of our worm bot platforms does the work of about five full-time research scientists.” Dr Mitchell Lee
When it comes to testing anti-aging compounds, there is a concept known as the ‘Longevity Trilema’ - systems need to be fast enough for multiple iterations, cheap enough to test many variations, and high quality enough that the data gathered is relevant. Given the Wormbot 20-day turnaround time, $100-per-run price tag, and the choice to use C.elegans, we’d say that the Wormbot solves the longevity trilemma. Additionally, traditional science often follows a "one molecule" approach, testing a single compound from start to finish, which can take up to 15 years. In practice, however, we often end up using medications in combination, and these combinations can have both positive and negative effects. One of the exciting aspects of Wormbot is its ability to test various longevity "cocktails" efficiently.
“Our goal is to facilitate finding the best breakthrough, game-changing, disruptive interventions that extend healthy lifespan and fight the diseases associated with aging all at the same time.” Dr Mitchell Lee
Why choose to work on worms?
Worms are actually able to tell us more than you think - 40% of their proteins are similar to ours. Interestingly enough the Nobel Prize for Medicine in 2024 was granted to two researchers for their work on C.elegans, because the model organism was responsible for driving forward so many developments in healthcare. They are by no means a perfect match for humans, but they’re an excellent starting point for basic research.
“At the end of the day, the things that drive aging are so highly evolutionarily conserved that the same things that drive aging in a worm drive aging in a human, in a companion pet, in a mouse.” Dr Mitchell Lee
Democratizing Science
DeSci is a movement that leverages blockchain technology and decentralized networks to fund and coordinate scientific research. The concept rests on the idea of democratizing science — allowing anyone with an internet connection to contribute ideas, resources, and data to scientific experiments. This model is seen as a way to break free from the limitations of traditional funding systems and push the field forward faster. Additionally, DeSci allows for the creation of more open, transparent, and collaborative research models.
A core belief of Decentralized Science (DeSci) is that science should be accessible, with minimal barriers to participation and contribution. This belief is shared by the team at Ora Biomedical. They have launched the Million Molecule Challenge, where anyone in the world can choose to get involved in longevity research.
“You can propose an idea and have an intervention tested. In terms of the enthusiasm and interest, this is really where we're seeing this incredibly exciting signal. People want to participate in science. They want to have this process demystified. They are not excited with the slow rate of progress that we're seeing. And there is an opportunity with our system to actually take the lead, accelerate, grab the reins of science. Let us be your scientific team, and we'll test your ideas.
At Molecule we’re big fans of the ‘hive-mind’ concept - the upside to sourcing ideas from a varied range of people is the ability to discover novel answers you never would’ve reached by yourself.
“The interventions that have been sponsored by Citizen Science and the Million Molecule Challenge, I never would have thought to test. Nobody else on my team would have thought to test. People are bringing ideas and insights to the table that we would not have prioritized. So your ideas are important, critical, and this is a place for you to vet those hypotheses.” Dr Mitchell Lee
Pump.science
We recently announced the vision for Pump Science at Solana Breakpoint:to create focused on longevity compounds with the support of Ora Biomedical’s Wormbot. The ultimate goal of Pump.science is to let anyone submit longevity regimen ideas (drug strategies) to be tested on the Wormbot (and soon - other experiments), own the intellectual property (IP), and stream the experiment results.
Here's how it will work:
- Submit a regimen idea or back someone else's by buying tokens
- Once the regimen reaches a certain market cap, the Wormbot experiment is run
- Watch the experiment data stream as the regimen is tested on real worms
- Buy tokens if you think the compounds can extend life and the regimen is valuable
The goal? Predict which treatments extend human lifespan.
To date, two compounds have launched on Pump Science (Rifampicin and Urolithin A). More compounds and additional experiement types will be launching soon. Follow Pump Science on X or join the Telegram for updates.
Why do we think gamification is the answer?
We’re all dopamine addicts at the end of the day, and games are your one-stop-shop for dopamine. Gamification refers to applying game design principles to non-game contexts to encourage engagement and participation. By introducing game mechanics such as rewards, leaderboards, or challenges, people feel a sense of competition and accomplishment, which drives more consistent participation and data collection. Rather than being passive subjects, participants actively contribute and even make decisions that influence the direction of experiments. Pump. science aims to rapidly accumulate and progress valuable data on aging and longevity, creating a feedback loop that accelerates the development of anti-aging interventions.
Hurdles faced by longevity researchers
While developments like the wormbot are primed to supercharge longevity research, we’d be remiss not to mention two of the primary hurdles that researchers come up against time and time again.
- Aging is not classified as a disease, which means the FDA does not approve clinical trials specifically aimed at combating it. The current interventions targeting aging on the market were largely discovered by accident—initially approved for treating specific diseases and later found to improve overall healthspan and lifespan. Another approach is to develop supplements, which can go directly to market without FDA approval, however, this has resulted in the market flooded with products with varying effectiveness. It is up to the supplement developers to hold an unwavering standards.
- What do you measure as a proxy of aging? There is the challenge of choosing biomarkers that are highly predictive of biological aging. For something as systemic as aging there isn’t one single pathway that you can measure and then conclude that lifespan will be improved.
“Another major thing that isn't doesn't have the attention to it that it deserves is natural genetic variation. Even when we find these interventions, just like aspirin doesn't work across the board the same way for everybody, these interventions are not likely to be magic bullets that equally work as well for every single person. So we really actually have to develop a toolkit of these interventions along with precision approaches to apply those interventions to the right people who will maximally benefit.” Dr Mitchell Lee
A case study: the mTOR pathway
The mTOR pathway is a highly conserved master regulator of nutrient signaling, playing a critical role in determining how cells respond to their nutrient state—whether to proliferate, grow, or remain dormant. By targeting mTOR, we can potentially rebalance nutrient signaling, offering a promising intervention point for influencing cellular behavior. Rapamycin is a well-known drug that targets the mTOR pathway and has shown significant effects on healthspan and longevity. Interestingly, rapamycin itself was discovered by accident - it was approved to be an immunosuppressant during organ transplants, but at much lower dosages it was found to be beneficial to longevity.
Krister Kauppi of the Rapamycin Longevity Lab believes that there are better mTOR inhibitors out there but they haven’t been found due to the regulatory hurdles surrounding longevity clinical trials. This blocker isn’t a reason to abandon the process however, and using the Wormbot Krister begun collecting data on other potential compounds.
“The first thing I did was to test five mTOR inhibitors that I found in their library. Thanks to that, we found one mTOR inhibitor, which is better than rapamycin. So yeah, step by step, we move forward. I'm confident that we will find even better ones when we screen the 568 additional mTOR inhibitors.” Krister Kauppi
What does the future hodl
By allowing more people to conduct experiments, share their findings, and collaborate with experts, the DeSci movement could unlock entirely new avenues of research. The combination of decentralized funding, gamification, and citizen science can revolutionize the longevity space. Instead of waiting for large institutions to fund and conduct studies, individuals and small groups can contribute directly.
“We see ourselves as the medicine cabinet for longevity biotech. We're going to be the source for the best breakthrough interventions, things that don't just, you know, give a five or ten percent increase in lifespan, but could give thirty, fifty, double lifespan. Those kind of big, audacious goals pushing the limits of what a single or combination intervention can do in a physiological system.” Dr Mitchell Lee
Many thanks to Krister Kauppi and Dr Mitchell Lee for taking the time to talk to us, and to our own Benji and Jillian for guiding the conversation. You can find the full podcast on our YouTube. Subscribe to our newsletter for more insights on DeSci topics, and follow our podcast to stay updated on engaging conversations.
pump.science: The Tokenized Prediction Market for Longevity Regimens
Life is the ultimate multiplayer game. We're all logged in, whether we choose to be or not. Some of us are grinding for XP, increasing the skill and resources of our character. Others are watching from the sidelines as our avatar slowly loses health. There is one universal truth for all of us in this game: it will end.
Let's face it, death is the final boss. It's the game over screen nobody wants to see. But what if you could develop your own infinite health cheat code? What if we could keep playing the game indefinitely?
Enter the world of longevity research, where science can potentially unlock the secret to extended playtime — a.k.a. lifespan.
The Longevity Trilemma
Finding this cheat code isn’t easy. If it were, we would have found it already. To change how our bodies interact with time, we need better potions (supplements), better gear (drugs), and better strategies (regimens). But like any cheat code, it’s only good if you know it actually works. When it comes to longevity, having proof-of-cheat-code is a must — after all, we only have one “life” in this game. So how do we know what works?
Human trials? Too slow. Testing on mice? Still too slow. Consider this, there are more potential drug compounds than atoms in the universe! When it comes to longevity, you don’t want to settle for any option—you want the best.
These dynamics create a Longevity Trilemma, and longevity research must balance three key factors:
- Speed: We need results fast. Time is ticking.
- Cost: It can't break the wallet. We have to efficiently use resources to test the large chemical space.
- Quality: The data must accurately predict how drug candidates will impact the lifespan of humans.
AI can help, but it needs lots of top-notch training data to propose potential life-extending treatments. So, how do we strike the perfect balance?
The Longevity Drug Testing Protocol
Based on all available information, we believe a protocol to test new combinations to optimize human lifespan is as follows.
Testing compounds in C. elegans (worms) → Daphnia Magna or Drosophila Melanogaster (fruit flies) → mice → rats → 1 human → 2 humans → n + 1 humans → broader public. This protocol ensures that data is generated on the least expensive organisms with the shortest lifespan before taking on more risk to cost and health.
If a regimen proves effective on C.elegans, further experiments can be run on flies or mice, with live data streamed to users. The goal is to eventually bring online testing on worms, and other organisms as well, letting the market decide which regimens and experiments should be performed among the menu of options.
Of course, regimens can enter at any point in the protocol (e.g. “mouse” instead of “C elegans”) based on the proposed mechanism of action and the financial and personal health risk profile of those funding or taking the regimen.
Minimizing cost and health risk is what makes C elegans the ideal first experiment.
Enter the Wormbot: The Unlikely Speedrunner
Meet Wormbot, our unlikely hero in our quest for immortality.
The Wormbot is a low-cost, rapid experimental platform developed by Ora Biomedical, founded by Matt Kaeberlein and Mitchell Lee to inexpensively test a large number of potential longevity regimens on C. elegans, a worm with a lifespan of 20 days.
Why worms? Well, 40% of their proteins are similar to ours. They're like the tutorial level for human biology. Plus, they've shown an impressive correlation with how treatments affect mice's lifespans. It's not a 1:1 match for humans by any means, but it's a great starting point. The data from the chart below shows that compounds extending life in mice also extend life in the worms.
Regimens are cultured with ~30 worms per well, monitored by a camera recording the worms’ movement and lifespan. This platform can be used to inexpensively test whether regimens may increase the lifespan in larger organisms (mice and humans).
Pump.Science: Where Crypto Meets Immortality
This is where you come in. Pump.science is a platform that lets anyone submit longevity regimen ideas (drug strategies) to be tested on the Wormbot (and soon - other experiments), own the intellectual property (IP), and stream the results. It’s like gladiators in the Coliseum, if the Coliseum were a petri dish, the gladiators were microscopic worms, and their weapons were experimental longevity cocktails. Are you not entertained?
Here's how it works:
- Submit a regimen idea or back someone else's by buying tokens
- Once the regimen reaches a certain market cap, the Wormbot experiment is run
- Watch the experiment data stream as the regimen is tested on real worms
- Buy tokens if you think the compounds can extend life and the regimen is valuable
The goal? Predict which treatments extend human lifespan. We're swapping financial yield (APY) for "time yield" – Percentage Life Extension (PLE).
Gamifying the Longevity Game
Pump.science gamifies the Wormbot. The objective of the game is to predict whether a longevity regimen will increase lifespan in humans using the worm experiments as a signal. The higher the PLE, the greater the chance of winning.
To play, users either submit a regimen for testing, which launches a new token, or fund others’ regimen ideas by purchasing their regimens’ tokens.
To submit a regimen for testing, users can select from a list of available ones.
To buy tokens in an existing regimen, users can choose live tokens from the marketplace of all the regimens currently being tested.
For each regimen’s market, users see a stream of the latest images taken by the Wormbot and some raw data (movement, growth) that can serve as leading indicators for whether the regimen is increasing lifespan.
In other words, pump.science turns Wormbot into a tokenized prediction market for longevity regimens with a goal of increasing PLE in humans.
Why is the platform called pump.science?
Pump.fun is a token launchpad on the Solana blockchain that launched in January 2024 and amassed well over 100 billion USD in volume in a period of months, and is now responsible for the greatest number of transactions on the Solana blockchain. The key innovation of pump.fun is enabling the creator economy for meme tokens, lowering the cost of creating a new coin to $2.
Pump.science is built on top of pump.fun, so we called it pump.science. The key innovation of pump.science is enabling a creator economy for science tokens, starting with longevity regimens, by lowering the barrier to entry to fundraise and execute lifespan experiments while streaming the data for maximum transparency on the performance of each regimen. In other words, it’s pump.fun for science.
We want to lower the friction to submitting, supporting, and justifying the products that will increase the duration of our lives.
This kind of stadium science, scientific research with live, open-sourced data and real-time speculation, has not been sufficiently explored. Traditional biotech markets release data once experiments (typically clinical trials) are completed. Real-time data readouts in stadium science provide more opportunities for odds to change and enable continuous speculation by market participants. Participants can look at the data and make educated guesses on a continuous basis - either based on their a priori scientific understanding or by watching the experiment run. To propose a new regimen will likely require a deeper level of scientific understanding, but anyone can speculate on the regimen’s experiment. That means anyone can bet on the next longevity breakthrough on pump.science.
Why is this something people want?
Finding ground truth data on longevity regimens is hard. Many advocates (marketers) for particular regimens have a financial interest in doing so. It is also commonly argued that longevity is a ‘problem for rich people,’ but time is the most valuable asset for all of us. We want to democratize not only the funding discovery of longevity breakthroughs but also their supporting evidence and products because those should be available to everyone. With pump.science, we hope to create a fair and open system for longevity and a new blueprint for science at large.
Come play with our worms. It’s the only game that isn’t wasting time - it’s creating it.
Let's pump.science
Are you ready to pump.science? Visit the website, follow pump.science on X, or join the telegram.
Acknowledgements
Thank you to Krister Kauppi, Jesse Hudson, Hated by Fate, and Ora Biomedical for their inspiration and support.
AthenaDAO’s First IP-NFT Bears Fruit: Results Have Arrived, Paving the Way for Future Fundraising
In August, 2023, AthenaDAO announced their commitment to combat ovarian aging, by dedicating $120,000 to Dr. Mario Cordero at Pablo de Olavide University. Not only was the preliminary science promising, but Dr. Cordero's own journey through fertility struggles, combined with his genuine desire to connect with the community he aimed to serve demonstrated a clear alignment in values. Since then, Dr. Cordero has been hard at work generating data, and we’re happy to let you know that things have gone well!
In order to continue this important work, Dr. Cordero, together with AthenaDAO, is looking to the community for support in raising $75k to fund the next milestones. Before we look too far ahead, we thought we’d walk you through the most recent results.
Fertility 101
Fertility often influences major life decisions and future planning. Estimates suggest that one in six people experience fertility issues during their lifetime - a challenge that people usually bear privately behind closed doors, feeling isolated and confused. With no clear biomarkers to indicate how many eggs a woman has or how much time she has left to conceive, decisions about family planning can feel like a race against an invisible clock. This isn’t just about reproduction—it’s about choice. The ability to make informed decisions about when to start a family, or whether to start one at all, is crucial for many women. Even beyond fertility, ovarian aging also impacts the onset of menopause, a life-altering transition that many women may be unprepared for.
What is Ovarian Aging?
Ovarian aging is the gradual decline of the processes that maintain fertility over time. As women age, their ovarian reserve—the number of viable eggs—naturally diminishes. But this decline isn’t the same for everyone. Some women experience a faster depletion, known as diminished ovarian reserve (DOR), where fertility declines earlier than expected. This can lead to fewer reproductive options for those affected.
At birth, women have around 1-2 million eggs, but by the time they reach menopause (around age 51), only about 1,000 remain. The most significant drop in egg quality and quantity occurs between the ages of 35 and 40, contributing to reduced fertility, a higher risk of miscarriage, and an increased chance of genetic issues in embryos. Globally, millions of women are affected by this decline, with many experiencing these challenges well before the average age due to conditions like DOR.
Factors that can cause ovarian aging to occur prematurely include genetics, autoimmune disorders, certain medical treatments (like chemotherapy), and environmental exposures. These influences can fast-track the decline, often leading to fertility challenges in women as early as their late 20s or early 30s.
Understanding ovarian aging is vital for women who want to take control of their fertility and make informed choices about their future. It’s also crucial for the doctors and specialists who support them in navigating these deeply personal decisions. By recognizing the signs early and raising awareness, we can help women explore their options sooner and find ways to preserve their fertility for when they’re ready.
Tracking Ovarian Health
One key biomarker often used to track ovarian health is Anti-Müllerian Hormone (AMH), a hormone produced by cells in the ovary. As the ovarian reserves drop, so do the AMH levels, providing insights into how quickly time is catching up with a woman’s reproductive ability. But AMH isn’t the only clue! Another key hormone, Follicle-Stimulating Hormone (FSH), rises as the ovaries become less responsive to its signals, consequently, prompting the brain to pump out more FSH in an attempt to maintain fertility. This ultimately leads to a cycle of increasing FSH levels, indicating a declining ovarian reserve and reduced fertility, which results in fewer healthy follicles developing into viable eggs. In addition, these hormonal changes don’t happen in isolation. The ovaries themselves also undergo structural changes, leading to fewer healthy follicles developing into viable eggs. Together, these biomarkers form a roadmap of ovarian aging, one that researchers like Dr. Mario Cordero are actively working to understand, in an effort to uncover novel treatments.
Until now, the process of ovarian aging has seemed like a predestined path, unable to be disrupted. However, what if there were ways to change direction? What if we could slow down this process? During research funded by the AthenaDAO community, Dr. Mario Cordero uncovered a surprising biological pathway, which may hold the key to new treatments. The pathway, known for its role in immune response, is called the cGAS-STING pathway.
The Role of the cGAS-STING Pathway in Ovarian Aging
Emerging research shows that the cGAS-STING pathway might be a major cause of inflammation and tissue damage in aging ovaries. In both humans and animal models, higher levels of STING have been found in the ovaries, especially in a specific cell type called granulosa cells. These cells are crucial because they help eggs (oocytes) grow and mature, which is key to fertility. When this pathway is overactive in aging ovaries, it leads to increased production of certain inflammatory substances (such as IL-6 and Type I interferons). These substances cause inflammation and gradually reduce the ovaries' ability to function properly. When STING remains active for too long in ovarian cells, it can lead to several problems: the cells may age faster, their energy production can be disrupted, and their DNA can become damaged.
All of these issues can speed up the loss of eggs and simultaneously lower the quality of the remaining ones.
Results from Dr. Cordero’s research so far
This research was designed to look at how the cGAS-STING pathway might be linked to aging in the ovaries and how it affects fertility. The researchers also studied how this process might be involved when chemotherapy damages the ovaries. The project was divided into three main parts, called work packages (WP).
WP1: Studying How the cGAS-STING Pathway Affects Aging in Ovaries
In the first part (WP1), the scientists looked at how the cGAS-STING pathway changes as women get older. The first experiments were designed to check whether or not cGAS-STING was involved at all with ovarian aging. If not, then it wouldn’t make sense to pursue further experiments. If yes, then full steam ahead!
They found that the STING protein is more active in older ovaries, which may contribute to the ovaries aging. This was seen in both human and mouse ovaries. They discovered that cells in the ovaries, especially in granulosa cells, are where this process happens most. Both mouse and human samples were tested because mice are often used as model organisms. However, if there was a big difference between the mouse and human data, then it would not be possible to continue using mice to study these effects, and another model organism would need to be chosen.
Since the data showed that mice can be used as a tool to study these effects, Dr. Cordero’s lab continued with their plan, and used a STING knockout model to see what would happen to the ovarian reserves if the STING protein was no longer present. Knockout mice are used to study what happens in an organism when a particular gene is absent.
Dr. Cordero found that mice lacking the STING protein had more eggs and better fertility as they aged. The figure below shows mouse ovaries from ‘normal’ and ‘knockout’ mice, and the white arrows point to more follicles developing in the knockout mouse compared to the normal, wild-type mouse.
Finally, the researchers also found that women with diminished ovarian reserve had higher STING activity in their ovarian cells, as shown by higher levels of STING protein levels in samples from a healthy female compared to samples from a female with DOR.
Together, the results from WP1 suggest that blocking the cGAS-STING pathway might help women keep their fertility longer as they get older.
WP2: Looking at Chemotherapy’s Effect on Ovaries
In the second part (WP2), the researchers wanted to see if the cGAS-STING pathway also plays a role in how chemotherapy damages the ovaries. Early findings showed that chemotherapy increases STING activity in patients.
In experiments with mice, they found that mice without the STING protein were protected from the harmful effects of chemotherapy on their ovaries. This means that blocking the cGAS-STING pathway could help protect women’s ovaries during chemotherapy, potentially saving their fertility while receiving life-saving treatment.
WP3: Creating Therapies to Block the cGAS-STING Pathway
The third part (WP3) was about developing new drugs to block the cGAS-STING pathway. The scientists tested several small molecules and found one, called "A2," that works well at reducing the harmful effects of the cGAS-STING pathway, such as inflammation and cell death. This drug could be helpful in protecting or improving fertility in women as they age or undergo chemotherapy.
It's time to fundraise for the next milestones!
True to the belief in equitable and accessible scientific research, AthenaDAO will be tokenizing the Cordero IP-NFT into Intellectual Property Tokens (IPTs) with the support of Molecule. These tokens enable the distribution of IP rights to holders to both raise funds for continued scientific research and empower the community to govern the resulting IP.
Due to the successful completion of the work packages in the first milestone of the project, Dr. Mario Cordero is looking to raise $75,000 USD to continue the work in milestone 2. With these funds, he is hoping to achieve two clear goals:
- Continue the development of in vitro testing of these newly discovered inhibitors (A2) from WP3
- Test to see what happens when the cGAS-STING pathway is inhibited with Dr. Cordero’s newly developed compounds in animal models with reduced ovarian reserve
Why choose the IPT model?
By giving community members the power to co-develop research projects via IPTs, AthenaDAO is harnessing the potential of decentralized science. As the project moves forward, important decisions—such as which delivery vehicles to test, the best disease indications for clinical trials, and how to raise additional funds—will be guided by the collective expertise of the community. With the power of IP tokenization, the wisdom of the crowd will play a critical role in shaping the future of fertility research.
AthenaDAO will be sharing more details on the crowdsale soon - subscribe to their newsletter, join the community on telegram, or follow on X so you can be the first to know.
Supporting research that matters
At its core, this research is about empowering women with new options for their reproductive health. By tackling ovarian aging at a deeper level, we’re moving closer to a future where the limits of biology can be redefined. We’ve been honored to support Dr. Cordero’s partnership with AthenaDAO, and hope that you’ll join us on this journey.
References:
- Jirge, P. (2016) ‘Poor ovarian reserve’, Journal of Human Reproductive Sciences, 9(2), p. 63. doi:10.4103/0974-1208.183514.
- Moolhuijsen, L.M. and Visser, J.A. (2020) ‘Anti-müllerian hormone and Ovarian Reserve: Update on assessing ovarian function’, The Journal of Clinical Endocrinology & Metabolism, 105(11), pp. 3361–3373. doi:10.1210/clinem/dgaa513.
- Oh, S.R., Choe, S.Y. and Cho, Y.J. (2019) ‘Clinical application of serum anti-Müllerian hormone in women’, Clinical and Experimental Reproductive Medicine, 46(2), pp. 50–59. doi:10.5653/cerm.2019.46.2.50.
- Decout, A. et al. (2021) ‘The CGAS–sting pathway as a therapeutic target in inflammatory diseases’, Nature Reviews Immunology, 21(9), pp. 548–569. doi:10.1038/s41577-021-00524-z.
Artan Bio Advances Nonsense Mutation Research Through Democratized Funding via Molecule’s IP Protocol
Artan Bio Background
Artan Bio made its debut late last year when the VitaDAO community used Molecule’s IP-NFT framework to fund $91,300 worth of work for developing and testing tRNA suppressors in cells with specific mutations. This funding led to the creation of in vitro assays and the development of 15 potential drug candidates.
Since then, the VitaDAO community has further supported Artan Bio through a successful crowdsale of IP Tokens, raising an additional $300,000 USD in 10 days (token ticker: $VitaRNA). . The goal of these funds was to find and further develop lead drug candidate(s) via in vitro assays, package candidates into a drug delivery modality, and then move them into animal models to assess efficacy. Of the 15 drug candidates that were developed, at least 2 showed some promise in correcting nonsense mutations in the cell line used in the experiments. Let’s explore their approach and review the findings in detail.
What Is a DNA Mutation?
To start, let’s give some background on DNA mutations. DNA mutations are changes or "mistakes" in our DNA, the molecule that carries the instructions for building and maintaining our bodies. Think of DNA as a recipe book that contains all the information needed to create proteins, the building blocks that make up our cells. A mutation is like a typo in this recipe book—sometimes it’s harmless, but other times it can cause serious problems by producing a faulty protein or no protein at all.
Types of DNA Mutations
There are several types of DNA mutations. Some of the most common include:
- Silent Mutations: These mutations do not change the final protein produced, so they often go unnoticed.
- Missense Mutations: These mutations change one of the "letters" in the DNA, which can result in a different protein being made.
- Nonsense Mutations: Nonsense mutations create a premature “stop” signal (codon) in the DNA. Imagine reading a sentence, and suddenly there is a period in the middle of a word. The result is an incomplete protein that doesn’t work correctly or at all. These mutations are the focus of Artan Bio.
Nonsense Mutations and Codons
To understand nonsense mutations better, we need to know about codons. Codons are like words in the DNA language. Each codon consists of three DNA "letters" (nucleotides) that tell the cell which amino acid (building block of protein) to add next.
One important codon is CGA, which instructs the cell to add the amino acid arginine. Nonsense arginine mutations are common in proteins related to DNA damage, neurodegeneration, and tumor suppression. The Artan BIO team is specifically focused on restoring protein levels and function for arginine nonsense mutations to treat age-related diseases.
Targeting Mutations for Treatment: Viruses to the Rescue
Researchers at Artan Bio are focused on finding ways to correct these CGA nonsense mutations to restore healthy protein levels. To correct these mutations, the researchers are using a gene therapy approach, which involves delivering a healthy copy of the gene directly into cells to replace or repair the faulty one. Artan Bio is using what’s called a “suppressor tRNA” system which is able to recognize the mutation in DNA letters, and inserts the correct letter in its place. To do this, we can use the skills of an old enemy-turned-friend: adenoviruses.
What Are Adenoviruses and Why Are They Used in Treatments?
Imagine you need to deliver a very important package to a specific address. You could try many different delivery methods, but you’d probably choose the most reliable one that reaches the most places. In medicine, when scientists need to deliver a new gene or treatment directly into cells, they can use a “delivery vehicle” called a vector—and that’s where adenoviruses like AAV9 come in.
Adenoviruses are a type of virus that usually cause mild illnesses, like the common cold. However, scientists have found a way to turn them into helpful tools for delivering treatments. AAV9 (Adeno-Associated Virus 9) is a special type of adenovirus that is FDA approved, and has been modified in the lab to remove its ability to cause disease. So, while AAV9 is technically still a virus, it’s like a harmless delivery truck that can carry helpful genetic instructions into the cells.
How Is Artan BIO Using AAV9 Vectors in Their Treatment?
In gene therapy, scientists use AAV9 to deliver healthy copies of a gene into cells to replace or fix faulty genes that cause diseases. In the case of Artan Bio, the virus is used to carry and deliver their engineered suppressor system that specifically recognizes nonsense mutations in CGA codon to restore normal protein levels and function.
Tools to measure that a treatment is working
To make sure their gene therapy approach is effective, Artan Bio is using several tests to measure the important variables.
One key test is a Western blot, which allows scientists to answer questions like
- Is a certain protein present in a sample (yes/no)
- At what level is that protein expressed, and how does it compare to a healthy vs diseased state (how much)
In the current data, p53 (a key protein involved in tumor suppression), is measured in a cell line that carries the arginine nonsense mutation of interest (Calu-6 cells). The cells naturally carry this mutation, so if you leave them to grow on their own, they will not produce the full p53 protein since the mutation is blocking this process. However, if you add a virus carrying Artan Bio’s suppressor system to the cells, it looks like some of the tested conditions were able to “suppress” the mutation and restore the cells’ natural ability to produce the protein - a successful initial result! Let’s take a look at the results more deeply to understand how the researchers were able to draw these conclusions.
Artan Bio In Vitro Results
Results 1: Restoring Production of p53 Protein
In their tests, Artan Bio designed several vectors to rescue an arginine nonsense mutation in p53 in the Calu-6 cell line. Of the 5 vectors tested, 2 showed positive results for rescuing p53 protein levels (lanes 4 and 5 in the image above; labels Vec2 and Vec3). These results are from a technique called a “Western blot”, and the darkness of the band is indicative of how much protein is present (darker band = more protein). These results show that the suppression vectors that have been created by Artan Bio are able to increase p53 protein production in the tested cell line.
The important thing to note here is that these vectors can be effective if they are able to get into the cell. This is easy to test and control for in cells tested in the lab, but the methods here cannot be used to treat people. In order for the vector to reach where it needs to go in humans, it needs to be packaged into its delivery vehicle. This is where the AAV9 virus comes back in. Therefore, the next thing to test for was the ability of the AAV9 virus to enter the same cell line, showing that (1) it would be capable of delivering the vector cargo and (2) the vector cargo could then go on to increase p53 protein production.
Results 2: Confirmation that AAV9 carrying vector cargo can enter Calu-6 cells and increase p53 protein production
As always, optimization steps are needed before the “real” experiment can start. As mentioned, the team needed to see what concentration of virus would be required to get the cargo into the cell. Too little, and not enough cargo will be delivered. Too much, and the virus will cause too much toxicity and kill the cells. This relationship is referred to as the multiplicity of infection, or MOI, which is the ratio of infectious agents (AAV9 virus here) to infection targets (the target cell, here Calu-6 cells).
In this first experiment, two conditions were tested (Artan-101 and Artan-102). Cells had virus added to them at two different concentrations to assess which combination of virus concentration and vector would be the most effective at restoring levels of p53 protein. Positive results were obtained in lanes 4 and 6 in the image above, with the most effective condition being seen in lane 6, with a very strong band visible for p53.
Conclusion: The suppressor system (vector), when packaged into the virus, can enter cells and effectively overcome the nonsense mutation to restore the production of the p53 protein in the tested cell line.
What’s Next for Artan Bio’s Research?
With these promising results, the next steps involve scaling up the production Artan-102, the lead candidate, and more extensive studies in animals. Artan Bio will submit a proposal to VITARNA tokenholders to support the feasibility study. This will produce high-quality material sufficient for safety and efficacy studies; critical experiments are needed before testing in humans is possible. If all goes well, this innovative approach could one day help treat or even cure diseases caused by DNA mutations, such as neurodegeneration and cancer.
What Artan Bio Means for DeSci?
While still in its early stages, Artan Bio embodies more than just research advancements— it is proof that decentralized communities can come together to quickly fund and advance innovative research that otherwise would have laid dormant. By using new technologies to democratize funding and create new incentive mechanisms, Artan Bio has not only advanced our scientific understanding of mutations in aging but has moved us one step closer to the transparent and inclusive vision of decentralized science.
Quick Start Guide to Catalyst
Welcome to Catalyst, the DeSci funding machine that lets you decide the future of science. Whether you are a Web3 native, or just jumping in, Catalyst is for everyone to participate in funding innovative research. This guide will walk you through the steps to start your journey on Catalyst, from connecting your wallet to funding your first project.
Step 1: Visit the Catalyst Website
Start by heading over to Catalyst. This is where you'll discover a variety of projects seeking funding. You can explore projects related to longevity, neuroscience, and more.
Step 2: Login or Connect Your Wallet
Connect Your MetaMask Wallet
To participate, you'll need a MetaMask wallet. If you don't have one, you can easily set one up by downloading the MetaMask extension for your browser or the mobile app. If you need additional support, follow this complete setup guide.
Login with Email or Socials
You can also choose to log in using your email or social account using Privy. Privy allows you to use Catalyst using just your email. You will be able to fund your wallet in Catalyst through Coinbase Pay or Moonpay.
To fund using Moonpay, click on your wallet in the top right corner, click “Get ETH,” and then click “Moonpay.” You will be taken to Moonpay’s application where you can purchase ETH and fund your wallet.
Once your wallet is set up, click the "Connect" button at the top of the Catalyst homepage. Follow the prompts to link your MetaMask wallet to the platform.
Step 3: Bridge to Base
Catalyst operates on Base, a blockchain network optimized for secure and low-cost transactions. To interact with projects on Catalyst, you'll need to bridge your ETH from the Ethereum mainnet to Base. This can be done directly within MetaMask or once you have connected your wallet to Catalyst, you can click ‘ Get ETH’ and select the bridging option as shown below. :
If you are briding using Open your MetaMask wallet:
In the network dropdown, select "Base" or add it as a custom network if it's not listed. Use the bridge option in MetaMask to transfer ETH from the Ethereum mainnet to the Base network.
Once your ETH is successfully bridged to Base, you'll be ready to fund projects.
Step 4: Find a Project and Fund It
Browse through the available projects on Catalyst. When you find a project that aligns with your interests, click on it to learn more.
To contribute, simply enter the amount of ETH you want to contribute in the funding section. Confirm the transaction in your MetaMask wallet, and your contribution will be processed.
Step 5: Receive IPTs
To receive IP Tokens, the project must reach its funding goal, and a research agreement must be successfully finalized between the researchers and sponsors. If the funding goal isn’t met or an agreement isn’t reached, your funds will be refunded.
When the project’s funding goal is met and a successful negotiation is finalized, you’ll receive your IP Tokens, giving you governance rights over the IP generated by the research you’ve funded.After funding a project, you'll receive IP tokens (IPTs) in return. IPTs represent your share in the intellectual property generated by the research you're funding.
You're ready to fund!
That's it! You've successfully connected to Catalyst, bridged to Base, and funded a project. By supporting these groundbreaking initiatives, you're not only contributing to scientific progress but also becoming a part of the DeSci community. Welcome aboard!
Gamifying Longevity: Increasing Participation & Accelerating Breakthroughs
What is longevity research?
In a recent episode of The DeSci Podcast, we welcomed Krister Kauppi, founder Rapamycin Longevity Lab, and Dr Mitchell Lee, CEO and co-founder at Ora Biomedical. The conversation focused on two major themes: how to accelerate research in the longevity space and the potential of gamification and decentralized incentives to push longevity research forward.
Longevity, in its simplest form, refers to extending human healthspan — the period of life spent in good health. While much of modern medicine is focused on treating ailments, longevity research aims to target the root causes of aging. Traditional research is expensive, bureaucratic, and slow-moving in the best of circumstances, and this is particularly true in the longevity field. With people dying from old age every single day this slow rate of progress just won’t cut it.
The Wormbot
Enter Ora Biomedical and the Wormbot. The Wormbot is a low-cost, rapid experimental platform developed by Ora Biomedical, founded by Dr. Matt Kaeberlein and Dr. Mitchell Lee to inexpensively and efficiently test a large number of potential longevity regimens on C. elegans, a worm with an average lifespan of 20 days. This robotic system performs automatic population-level imaging, capturing worm survival, movement, interactions, and more on a scale that is exponentially larger than other labs,
“A single one of our worm bot platforms does the work of about five full-time research scientists.” Dr Mitchell Lee
When it comes to testing anti-aging compounds, there is a concept known as the ‘Longevity Trilema’ - systems need to be fast enough for multiple iterations, cheap enough to test many variations, and high quality enough that the data gathered is relevant. Given the Wormbot 20-day turnaround time, $100-per-run price tag, and the choice to use C.elegans, we’d say that the Wormbot solves the longevity trilemma. Additionally, traditional science often follows a "one molecule" approach, testing a single compound from start to finish, which can take up to 15 years. In practice, however, we often end up using medications in combination, and these combinations can have both positive and negative effects. One of the exciting aspects of Wormbot is its ability to test various longevity "cocktails" efficiently.
“Our goal is to facilitate finding the best breakthrough, game-changing, disruptive interventions that extend healthy lifespan and fight the diseases associated with aging all at the same time.” Dr Mitchell Lee
Why choose to work on worms?
Worms are actually able to tell us more than you think - 40% of their proteins are similar to ours. Interestingly enough the Nobel Prize for Medicine in 2024 was granted to two researchers for their work on C.elegans, because the model organism was responsible for driving forward so many developments in healthcare. They are by no means a perfect match for humans, but they’re an excellent starting point for basic research.
“At the end of the day, the things that drive aging are so highly evolutionarily conserved that the same things that drive aging in a worm drive aging in a human, in a companion pet, in a mouse.” Dr Mitchell Lee
Democratizing Science
DeSci is a movement that leverages blockchain technology and decentralized networks to fund and coordinate scientific research. The concept rests on the idea of democratizing science — allowing anyone with an internet connection to contribute ideas, resources, and data to scientific experiments. This model is seen as a way to break free from the limitations of traditional funding systems and push the field forward faster. Additionally, DeSci allows for the creation of more open, transparent, and collaborative research models.
A core belief of Decentralized Science (DeSci) is that science should be accessible, with minimal barriers to participation and contribution. This belief is shared by the team at Ora Biomedical. They have launched the Million Molecule Challenge, where anyone in the world can choose to get involved in longevity research.
“You can propose an idea and have an intervention tested. In terms of the enthusiasm and interest, this is really where we're seeing this incredibly exciting signal. People want to participate in science. They want to have this process demystified. They are not excited with the slow rate of progress that we're seeing. And there is an opportunity with our system to actually take the lead, accelerate, grab the reins of science. Let us be your scientific team, and we'll test your ideas.
At Molecule we’re big fans of the ‘hive-mind’ concept - the upside to sourcing ideas from a varied range of people is the ability to discover novel answers you never would’ve reached by yourself.
“The interventions that have been sponsored by Citizen Science and the Million Molecule Challenge, I never would have thought to test. Nobody else on my team would have thought to test. People are bringing ideas and insights to the table that we would not have prioritized. So your ideas are important, critical, and this is a place for you to vet those hypotheses.” Dr Mitchell Lee
Pump.science
We recently announced the vision for Pump Science at Solana Breakpoint:to create focused on longevity compounds with the support of Ora Biomedical’s Wormbot. The ultimate goal of Pump.science is to let anyone submit longevity regimen ideas (drug strategies) to be tested on the Wormbot (and soon - other experiments), own the intellectual property (IP), and stream the experiment results.
Here's how it will work:
- Submit a regimen idea or back someone else's by buying tokens
- Once the regimen reaches a certain market cap, the Wormbot experiment is run
- Watch the experiment data stream as the regimen is tested on real worms
- Buy tokens if you think the compounds can extend life and the regimen is valuable
The goal? Predict which treatments extend human lifespan.
To date, two compounds have launched on Pump Science (Rifampicin and Urolithin A). More compounds and additional experiement types will be launching soon. Follow Pump Science on X or join the Telegram for updates.
Why do we think gamification is the answer?
We’re all dopamine addicts at the end of the day, and games are your one-stop-shop for dopamine. Gamification refers to applying game design principles to non-game contexts to encourage engagement and participation. By introducing game mechanics such as rewards, leaderboards, or challenges, people feel a sense of competition and accomplishment, which drives more consistent participation and data collection. Rather than being passive subjects, participants actively contribute and even make decisions that influence the direction of experiments. Pump. science aims to rapidly accumulate and progress valuable data on aging and longevity, creating a feedback loop that accelerates the development of anti-aging interventions.
Hurdles faced by longevity researchers
While developments like the wormbot are primed to supercharge longevity research, we’d be remiss not to mention two of the primary hurdles that researchers come up against time and time again.
- Aging is not classified as a disease, which means the FDA does not approve clinical trials specifically aimed at combating it. The current interventions targeting aging on the market were largely discovered by accident—initially approved for treating specific diseases and later found to improve overall healthspan and lifespan. Another approach is to develop supplements, which can go directly to market without FDA approval, however, this has resulted in the market flooded with products with varying effectiveness. It is up to the supplement developers to hold an unwavering standards.
- What do you measure as a proxy of aging? There is the challenge of choosing biomarkers that are highly predictive of biological aging. For something as systemic as aging there isn’t one single pathway that you can measure and then conclude that lifespan will be improved.
“Another major thing that isn't doesn't have the attention to it that it deserves is natural genetic variation. Even when we find these interventions, just like aspirin doesn't work across the board the same way for everybody, these interventions are not likely to be magic bullets that equally work as well for every single person. So we really actually have to develop a toolkit of these interventions along with precision approaches to apply those interventions to the right people who will maximally benefit.” Dr Mitchell Lee
A case study: the mTOR pathway
The mTOR pathway is a highly conserved master regulator of nutrient signaling, playing a critical role in determining how cells respond to their nutrient state—whether to proliferate, grow, or remain dormant. By targeting mTOR, we can potentially rebalance nutrient signaling, offering a promising intervention point for influencing cellular behavior. Rapamycin is a well-known drug that targets the mTOR pathway and has shown significant effects on healthspan and longevity. Interestingly, rapamycin itself was discovered by accident - it was approved to be an immunosuppressant during organ transplants, but at much lower dosages it was found to be beneficial to longevity.
Krister Kauppi of the Rapamycin Longevity Lab believes that there are better mTOR inhibitors out there but they haven’t been found due to the regulatory hurdles surrounding longevity clinical trials. This blocker isn’t a reason to abandon the process however, and using the Wormbot Krister begun collecting data on other potential compounds.
“The first thing I did was to test five mTOR inhibitors that I found in their library. Thanks to that, we found one mTOR inhibitor, which is better than rapamycin. So yeah, step by step, we move forward. I'm confident that we will find even better ones when we screen the 568 additional mTOR inhibitors.” Krister Kauppi
What does the future hodl
By allowing more people to conduct experiments, share their findings, and collaborate with experts, the DeSci movement could unlock entirely new avenues of research. The combination of decentralized funding, gamification, and citizen science can revolutionize the longevity space. Instead of waiting for large institutions to fund and conduct studies, individuals and small groups can contribute directly.
“We see ourselves as the medicine cabinet for longevity biotech. We're going to be the source for the best breakthrough interventions, things that don't just, you know, give a five or ten percent increase in lifespan, but could give thirty, fifty, double lifespan. Those kind of big, audacious goals pushing the limits of what a single or combination intervention can do in a physiological system.” Dr Mitchell Lee
Many thanks to Krister Kauppi and Dr Mitchell Lee for taking the time to talk to us, and to our own Benji and Jillian for guiding the conversation. You can find the full podcast on our YouTube. Subscribe to our newsletter for more insights on DeSci topics, and follow our podcast to stay updated on engaging conversations.
Exploring Decentralized Science with Balaji Srinivasan on The Desci Podcast
Introduction of Balaji and the Network State
Balaji Srinivasan, is the former CTO of Coinbase, former general partner at Andreessen Horowitz, twitter.com/balajis and Balajis.com
The era of traditional academia is ending, and the new era of decentralized academia, decentralized media, decentralized science is beginning. The way that the nation state justifies itself is it says that everything it's doing because of “science”, This intersection is captured in the book, The Network State, and it's at thenetworkstate.com.
There's a huge difference between science in the sense of Maxwell's equations, which are independently reproduced, "science" in the sense of just peer reviewed publications, which are often not independently reproduced or even reproducible, and it mimics the form. The journal publication, the citation, and the prestige and so on, without the substance, which is the ability to do an independent replication. And this is this core difference between, "science" and actual science.
Timestamps:
00:00 - Intro
01:30 - Introduction of Balaji & The Network State
06:45 - Key factors holding back scientific progress
14:17 - How to change the research & funding structure
21:00 - Commonalities between New York Times and the nature of the Scientific Journals
38:00 - How does scientific progress unfold?
44:50 - Can AI be a dominant driver here?
49:10 - How to make predictions in technology
54:40 - The cyclical approach of history
01:02:48 - Advice for builders in the DeSci space
01:04:29 - Last words, book advice & outro
Balaji:
There's actually only one thing that's more prestigious than science, you know, that is? Math. It may sound almost trivial, but we don't normally think of them as opposed, right? You know, the king and the queen of you know, like stem, right, that are to get our STEM science. One way of thinking about it is, crypto economics is based fundamentally on math.
It is based on the fact that we can go and download the Bitcoin blockchain and run a bunch of mathematical computations, to verify it to verify all the past transactions, same with the Ethereum blockchain.
And that's different from academic economics, which claims to be based on "science", where it has gotten to this realm where you cannot verify everything.
What do you think are the key factors holding back scientific progress globally?
The entire Vannevar Bush thing of centralizing research around and after the time of World War Two, has run its course. And so, the fundamental thing holding back scientific progress globally is the choke point. That is the US government.
So all of these funds that were appropriated and centralized for the federal government, all the research that was centralized there, there's a certain school of thought that comes where it's, you know, grants, and it's papers, there's choke points that happened.
How would you change that legacy research and funding structure
The NIH budget is actually pretty large, It's several dollars a year. Giving full control would essentially shatter the entire thing into many funding sources.
More effort should be on bringing down cost, increasing reproducibility and increasing automation.
Fund independent investigators and fund relatively low cost you know maybe it's like one to three years and unlike the traditional academia you don't have to write a grant where basically everything is done beforehand.
Give people like perhaps one to three years of funding okay, and it's usually like one person or maybe like a very small group, and they're trying to do the basic science and prove it out and then if it works that technological fire you know catches then they start a company, or they turn that into a company okay and if it doesn't then you know like they either find somebody who wants to continue the funding or they shut it down.
Commonalities between the New York Times and Nature, the scientific journal for us?
Absolutely. Academia moves slower than legacy media. The pre-internet power centers of the US, like: 1) DC, which is regulation
2) Harvard, as a mechanism for academia
3) Hollywood, which is film
4) New York, which is media.
DC, and academia and Hollywood even take years to multiple years to turn something around, a paper or a film, or especially a rule or regulation that can take multiple years to turn something around, media had a 24/7 metabolism, CNN and others, like media is used to shipping a newspaper every single day. So they were the only legacy institution that had the same metabolism and speed of people who are deploying on the internet.
Legacy media, they're attacking everybody they're attacking every country every movement within the U.S. everything that possibly could contest the US establishment whether it's France or Hungary or china or India or Russia or conservatives or centrist liberals or tech people or crypto people or whatever right there's like a new enemy every single day.
How does scientific progress unfold?
Replication is massively underestimated as a driver of the use of science.
Just as an example like you guys have used tons of GitHub you know based open source projects what do you'll download it you'll run it if it doesn't run on your computer it's an amateurish project. And you know like how many times do you quote replicate their claims you're literally executing the software and if it doesn't replicate or work on your computer it's useless.
Can AI be a common driver here?
It's complicated. Crypto can be sort of corrupted or repurposed for centralization with the CBDC's and so on, but AI can also of course be decentralized with federated machine learning or if you're seeing, you know there are knockoffs of dolly 2 and other things that happen very quickly you know they're not as good.
But they very quickly get out there and moreover these models are difficult to train but as you know relatively cheap to evaluate, and so they're actually just bags of coefficients, and probably in the fullness of time they'll either get reverse engineered or hacked or something like that, once it's known that it's possible for people to catch, and we are not sure of how defensible those things are.
How to make predictions in technology?
There's different there's to pull from history, and one of the things to consider an unsolved problem is to determine whether a historical analogy is accurate.
It's like it's not just an analogy, it's a mathematical analogy where you have a second or differential equation. Mathematical analogies are the best kind because there is an isomorphism between the objects here and the objects here, and manipulating these gives you insight into these and vice versa.
The cyclical approach to history
The cycle theory is a parametric curve where you're just going around the loop, and we just come back to where we are.
If you watch the collapse of civilization's podcast, sobering to realize that in a sense we're like the guys who got to the last level of a video game and were made the most successful up to this point.
Previous human civilizations to our knowledge had gotten to like space travel and so on, but that may just mean that like our final flame out is like really chaotic, so it's actually good to decentralize to have eggs in multiple baskets to get to other planets, and you know that's what a lawn talks about backing up humanity
One of the things Steve Jobs did with an apple is he built um he pushed secrecy why do you push secrecy, so you could have multiple teams that didn't know about each other that were working on the same thing, but they were innovative since they couldn't copy from each other right, and they didn't feel competitive with each other because they didn't know about each other.
Advice for people in Desci
Build a demonstration of truly reproducible research, take two statistics papers where one cites the other okay and maybe actually uses a function from the other, have them both be on chain
maybe with the data and stuff on our weave.
Just show how you did that that would be a huge breakthrough just focus on something very specific then we've got you know that proof of technological fire where we can show here's the paper here's another one it's like arpanet you know sending like the first packet right that first on-chain citation as a function call where you have composable science will be a milestone.
Use some kind of decentralized platform to show that you can get composable science that can get composable finance.
Show-notes of the episode:
https://balajis.com/the-purpose-of-technology/
https://twitter.com/patrickc/status/1544067890403389441
A huge thanks again to Balaji for taking the time and for the valuable input - We hope you all can take something away from this episode on your DeSci journey.
Feel free to skip around the timestamps to find your favorite topics! Also, if you prefer listening to podcasts on audio apps, feel free to search for "The DeSci Podcast" on Spotify, Google Podcasts & Apple Podcasts.
If you want to join us on the show as a speaker or have guest ideas, please shoot us a mail at podcast@molecule.to
You can also find all links to our Spotify, Discord and Twitter here.
Special thanks to:
Vitalik Buterin on Decentralized Science, Aging, AI and Scientific Progress
Vitalik had a lot to say about DeSoc (decentralized society) and the possibilities it brings to science, including how important attestation protocols are in science and the need for a contribution graph to identify participants and contributors. In particular, how DeSoc is laying the groundwork for future decentralized protocols.
He also gave a deeper insight into his interests in longevity research and retroactive research. There's also mention of his works and contributions towards COVID relief, especially Balvi. Vatalik highlighted how Balvi contributed to the funding of numerous initiatives aiming to cover the full range of COVID detection and eventual treatment, including open source initiatives RaDVaC that focused on sterilizing vaccines and nasal vaccines, among others.
On the note of the things holding back the growth of scientific progress, Vitalik highlighted the problem of public goods being underfunded and suggested that providing funds for projects with as low as a 100:1 benefit-to-cost ratio would signify a large amount of progress. He continued by discussing ideas and information accessibility to open up additional avenues for everyone to make contributions, regardless of age, socioeconomic situation, or geography. He also discussed how the rise of cryptocurrency has reawakened the positive collective human ability to advance our knowledge of the world and contribute to having a positive impact on the world and our physical environment despite the fact that the conservative mentality has decreased interest in many scientific fields.
Timestamps
0:00 How do you define decentralized science?
1:36 Mistakes made with cryptocurrency.
7:29 How complicated is the contribution graph?
12:47 The areas of science that he is most excited about.
15:33 Full spectrum covid support and educating people about science.
22:21 Setting up an organization that is explicitly not meant to survive forever.
28:24 Differences between crypto and other frontier tech industries and the importance of international networks.
31:02 What’s holding back scientific progress?
36:37 The digital world’s impact on longevity
41:49 Potential Curveballs and unknowns
45:09 Decentralized science and prediction markets.
Snippet:
Vitalik Buterin 0:00
What if we fix aging? Right? And you know, what if all those numbers are off by a factor of two, you know, what if there is a radical cultural change that causes people to have like much more, much fewer children, there's just so many different curveballs that could happen. What if, you know, we do discover evidence of alien life, like even if it is bacteria, right? And that just creates a big, big philosophical awakening in people; there's just so many of these big unknowns.
Vincent Weisser 0:36
Yeah, it's great to have you, Vitalik, for this conversation about the intersection of science and crypto called "decentralized science," hosted at DeSci London at the Francis Crick Institute there; maybe we get directly into it. So on decentralized science, I would be curious how you define decentralized science and which aspects of it are you most excited about.
Vitalik Buterin 0:59
Hmm, I guess I view a decentralized science as a collection of ideas that basically have to do with trying to answer the question of what are some ways in which emerging open and decentralized technologies can make us, science better and can improve the institutions of science, in a broad sense, can improve mental health, people who are just excited to collaborate with each other and get a get things out to the broader public? So I think some like, examples of this would include one is just funding right. So I think the interesting thing about cryptocurrency is, first of all, that it's just a very effective fundraising tool by itself, right? Because I've used cryptocurrency to donate money to various kinds of charities, like some of them giving money directly to the poor, some of them, you know, doing existential risk research, some of them also doing longevity research, or doing other kinds of science.
I think my most recent, really big and significant one was donating some amount of money to Impetus Grants, which is doing longevity. So just crypto as payments, I think was one big part of it, and like just in addition to providing more funding for science, I think it's fascinating how it provides for more diverse funding, right, like, it's not just traditional institutions, it's also a yet, you know, pretty wide array of, of individuals that can now provide funding in a lot of cases. And then going a bit beyond that there's, you know, things like DAOs, and things like quadratic funding, and all of these different tools that tried to create a more crypto native and more structured approach to funding different kinds of science projects. So quadratic funding, in general, it's a set of the decentralized and democratic ways of choosing where the funds for a particular funding will go. So one way to think about it is that it's like a matching system. So if people donate to one project, then the matching pool also contributes its money. But the unique thing about quadratic funding is that the match is greater the larger the number of distinct people that contribute to a project, right? So if project A, let's say, gets $10,000, each from two people, but project B gets $1, each from 20,000 people, then project B is going to get a much, much higher match than project A does. There's some really interesting mathematical reasoning for why quadratic funding is economically optimal in a certain sense. And if people want to read up on, like, my explanation of that, I'm on my blog. vitalik.ca. I Yeah, have uh, it's just like a quick roll up for quadratic, you can find my post on this, the quadratic mechanisms in general. And then I think we also want to kind of go a bit beyond quadratic funding by itself.
There's the concept of DAOs in general, and there have been more and more DAOs. There is VitaDAO, there are other kinds of DAOs now that are trying to organize the process of deciding who to fund in all kinds of structured ways that even go beyond just the funding question. There's also potentially the concept of you know, using like Blockchain traceability or NFTs or soul bound tokens or anything like that, to try to do what better job of just maintaining the graph of like, who contributed how much to what, right because one of the big issues in academia is the whole peer review system. And the way that that by itself has basically turned into its own game that is unfair in a lot of ways and gets exploited in a lot of ways and exclusive in a lot of ways and creates a very misaligned behavior as people try to chase citations in a lot of ways. And the question of, can we both try to make better versions of what the peer review and or what the citation graph tries to do and what the peer review process tries to do, and also use blockchain and these toolkits to really kind of weave that into the process of doing things and the process of funding things and, you know, really make rewarding people for any contributions to the things that we set, you know important results downstream, be something that happens and much more seamlessly and much more automatically. You know, retroactive funding by optimism is one good example. Right? So I think just zooming out of edits, so there's a large collection of things that people are doing with blockchains, with DAOs, with cryptocurrencies, you know, with soulbound tokens, and you know, with ZK, and all of these different tools that try to reform or replace or improve on all kinds of processes in, like, how we do science as a civilization.
Vincent Weisser 6:37
Yeah, makes a lot of sense. I think, maybe we want to double-click on public goods. So I think it's really interesting to see the first experiments with quadratic funding also showing some of the ways that it could potentially be improved. So we'd be curious, on public goods experiments, like for quadratic funding and retroactive funding, which experiments, would you like to see in the context of science that you haven't seen yet? Also, are there potential improvements to quadratic funding or retroactive funding? Yeah, that we should attempt.
Vitalik Buterin 7:13
Yeah, I think science is actually a great place to try to do experiments with, like, more sophisticated forms of retroactive funding, because science is the one place where it's, like, more obvious than anywhere else. I think it's true everywhere. But it's particularly obvious in science, like just how complicated the contribution graph leading to any particular result is, right? Like, if, let's say, someone invents some new zero-knowledge proof protocol, usually, that protocol itself is a version of some other idea. And it uses, you know, some particular polynomial commitment scheme that was invented by someone 2 to 10 years ago. And then it builds on top of this other results, and that polynomial commitment scheme also builds on top of other results, and it's basically, you know, people building on stuff, that's built on stuff, that's built on stuff that, you know, goes all the way back to RSA and Shannon, and other stuff in the 1940s, the 1970s, and, ultimately, stuff even long before then, right. And there's more of a tradition within science of like being explicit about that graph, which I think is fascinating. And what that means is that it's an opportunity to try to solve what I think might be one of the critiques of retro funding in practice, which is basically the last step in a particular chain that leads to some outcome getting funded but some of the less glamorous intermediate steps don't. So everyone has a big incentive to try to play up how big their contributions are and, like, be really loud about what they're doing. And that's like trying to reward not just the people directly responsible but also, you know, the people who are responsible for the parents and the grandparents of a particular result. I can do that in a way that's incentive-compatible. I think it's a really fascinating thing to think more about. And I think in the, it's a good idea at every space, but in the decentralized side space, in particular, be interesting to really try to start
Vincent Weisser 9:32
Which ideas from decentralized society, also called "DeSoc," that you coined with Glen Weyl and Puja and broadly in social technologies are you most excited about in the context of science?
Vitalik Buterin 9:47
I think there is definitely a big overlap right because DeSoc is in a lot of ways all about exploring the nonfinancial ways to try to encode different kinds of relationships. So we have things like POAPs that encode, you know, whether or not someone attended a particular event, we have things like proof of humanity, we yet, you know, have a bunch of various attestation protocols that people are working on. And I think all of those have a big voice in DeSci. Because, like, as I was mentioning before, one of the big things that I think that DeSci space could do was really try to, like do better things with having a higher quality, I mean of contribution graph. And that's something that we could get more of automatically just by, you know, having more of that kind of information committed to the chain everywhere, right? So the more of, you know, there are these public commitments of like, what contributed to what, who participated in what and you know, who was a part of a particular community, the more it becomes possible to do more of those kinds of experiments. So I view DeSoc as being a space that's going to create and really yet build out a base layer that will make available information that a lot of these decentralized protocols are going to end up making use of.
Vincent Weisser 11:29
Yeah on decentralized society. I wonder, do you see the first use case being mainly around identity and soulbound tokens and then enabling a bunch of other use cases? Like, what could some MVPs of this look like? If a builder is listening, who wants to build something at the intersection of DeSoc and DeSci, like, for example, the Gitcoin passport, which I think is interesting, but there might be other identity solutions or other DeSoc ideas that one could build?
Vitalik Buterin 11:57
I think the other really natural one is basically trying to, think through it and figure out what it actually would mean in practice to have some kind of POAP. That's proof of attendance token that represents the contribution to some particular piece of scientific research, right? Now it could mean that like, you get one by being an author of some paper. Or some posts, it could mean, just being involved in a particular community or at a particular event that's doing research in a particular area. I don't know yet. But that's one of the challenges that's worth figuring out.
Vincent Weisser 12:51
You mentioned earlier some of the amazing initiatives that you supported; maybe you could paint a picture of the areas of science that you're most excited about and why you're excited about them.
Vitalik Buterin 13:04
Sure. So one that I've obviously been excited about for a long time is longevity research. Yeah, I read Aubrey's book, Ending Aging, when I was a teenager, and I was immediately convinced and definitely really inspired by the vision. And since then, that's always something—a space that I have dreams that I could somehow be helpful too. And so I started donating to well, longevity pretty much as soon as I started having significant amounts of money, I try to continue being more supportive of different groups in the space in various ways.
In addition to longevity, one of the others that I've started going into recently is COVID research; this was actually one that kind of happened accidentally, in that, you know, I got these Dogecoins back in 2021. And I needed to send the Dogecoins somewhere. And right at that exact same time, India was getting hit really hard by the COVID situation, right? This was like late April, early May 2021. And there was this group called Crypto COVID Relief India that was just starting to get help in India, trying to make its way through the crisis. And I sent some Dogecoins to crypto relief, like these are the Shiba Inu tokens that I got that just somehow ballooned to a really huge market cap. And at the time, I thought that it was not going to be a huge amount of money. And so we didn't really think much of it, but they ended up being able to get far more money out of it than I had imagined it would be possible like I imagined they'd be able to get maybe $10 or $20 million, and then Shiba would crash to zero, but they ended up cashing out like a bit over 400 million USDC then They started funding a lot of projects in India. And then I also started basically working on this effort called Balvi with some other people who are into infectious disease science.
And we really understood the COVID situation and I knew that this would be what also simultaneously use some of that money for some more kind of potentially speculative and high-risk, but also potentially really valuable projects. Right. So this is basically like full spectrum COVID support. So it included projects that are working on masks, projects that are working on vaccines, UV radiation, air filtering, you know, wastewater surveillance, just like the entire spectrum of figuring out a lot of ways to detect COVID, Testing is the other one, you know, both betas, like antigen tests and lab tests and PCRs, and everything in between. And then finally, try to deal with COVID, treat it, and make it less of a problem in the event that someone does get it. And what was interesting was that Balvi did end up funding a lot of different work and even ended up funding a lot of open-source work. So one of those things was RaDVaC, which was an open-source project that was working on vaccines for COVID. And they were one of the early ones that started working on nasal vaccines, right, because they know, there's this fact about COVID, that the place where it's like easiest and most practical to stop, it actually is like basically in the middle upper respiratory system. And if you don't get that, then basically, you're not actually going to create a vaccine that completely stops COVID. Because like, you could easily get it and pass it on to someone, even if the rest of your body outside the respiratory system is immune. So if you want to make what's called a sterilizing vaccine, then, you have to get pretty close to the source. And also like nasal vaccines, you know, they get don't require an injection, are potentially easier to administer, potentially, you could just give the belt to people at a less scary and all that. And they were one of the earliest projects that we're doing that, there are a bunch of other projects as well other vaccine projects, other projects in a whole bunch of other areas.
So what was fascinating there, I think was that, like one just cryptocurrency ended up being are an extremely convenient funding method, especially for all of these different international things, right, it's just so much easier than sending a bank wire, even with the controls that we had, like we had a multi SIG wallet and multiple people had to sign off to prevent the money from getting stolen, right, like, which definitely adds like a bit of bureaucracy and checking, but like, even with that, it's just so much easier than, you know, sending bank wires for everything and dealing with all kinds of banking systems and it arrives instantly, then the other one, I think, is just like the value of, you know, a model of philanthropy that's more willing to trust people, right, like a lot of donors to this project say, yeah, be like, try really hard to inject to their own opinions into everything and basically say, you know, hey, you know, you have to put all your money into this and put all your money into that and that there's no way I'm gonna let you spend anything on overhead because everyone agrees that overhead is, you know, totally unacceptable and bad. And you know, these things add up actually, hamstringing a lot of people right, and with Balvi, we're trying to be a win trying to intentionally not do that and I think that led to a lot of good outcomes. And then I think it also counts as science you know, even though it's not biology but the whole “zero knowledge” space.
I feel like I've been trying to support the zero-knowledge space in multiple ways so one of them is obviously the Ethereum Foundation funding a lot of zero-knowledge research. I did like actually contributed a bit myself to a couple of zero-knowledge projects. A tiny feature accredited to myself ended up making its way into one of the original plug protocols, which I thought was kind of fun. The other really big thing was just making these exploiters, write these blog posts to try to make the math behind zero-knowledge protocols and a whole bunch of other cryptography really accessible to people. What I basically felt like I was doing was trying to fill what I thought was this missing middle niche where, on the one hand, you have academic papers, which are just like horrible and unreadable, and, like, part of the reason why they're horrible and unreadable is not because, you know, academics are like bad people who are elitist, No, there definitely is some elitist.
So it's just because, you know, the incentive structure encourages writing to a particular audience, and I think changing the incentive structure is part of what DeSci is supposed to be about. So, either you have PDFs that are basically unreadable, unless you're almost part of the same lab. And then on the other hand, you have Pop-sci writing, which is extremely accessible, but it just, like, doesn't explain, you know, pretty much anything right, it's like trying to explain physics to people. And then, oh, so there's this thing called a light cone. And you can imagine a light cone by imagining something like one of the pyramids of Egypt, except it's circular. And like, you know, it gives an image in people's head, but it doesn't actually help people, like, understand the science in the sense of like, being able to, like getting insights about how the world works, that would like help them actually understand or predict anything. And I wanted to fill the big missing middle of like writing that's both accessible to some number of people. And wouldn't, you know, yes, you will have to know a bit of undergraduate math and you also have to work hard, but at the same time, he could still understand it, but still, like actually being accurate and like actually describing the whole protocol.
And I think, part of my vision, there was definitely just inspired by my own experience as a self-taught person in a lot of areas and just being frustrated by you know, all the unreadable PDF papers and the, you know, extremely superficial Pop-sci material and trying to create something better for people who are not taking the conventional University path. And that's good, you know, ended up getting a lot of good feedback on a lot of those pieces. And it feels like that's turned into more of a trend, with a lot more people writing that kind of stuff now, which I think is good, right? I actually think educating people in a decentralized education about science really should be viewed as being part of decentralized science, right? Popularizing knowledge and even popularizing knowledge across disciplines is so valuable, right? Because so many of the important contributions, I think, come from intersections of different disciplines. So those are some of the things that I've done, and I definitely look forward to doing more things in the future.
Vincent Weisser 22:39
Amazing! What strikes me as unique with your kind of efforts is just like the variety of different approaches like even from the Ethereum foundation to Balvi to some of those academic efforts to much more on non-traditional ones like what have been some surprising learnings between for example, how something like Arc institute even or Impetus and Balvi setup and being kind of in the trenches with something like Balvi be super curious like which learnings you incorporated from remember Ethereum foundation and other things into setting up Balvi and how you structure it, which might be different from like a traditional foundation or brand given body?
Vitalik Buterin 23:21
I think being lean is one of the warnings, right? So basically, another one is setting up an organization that is explicitly not trying to have an infinite lifespan. And I think to some extent, those two are connected, right, in the sense that, there was this, I think it was Venkatesh Rao for one of the new things called internet philosophers, who has a lot of interesting ideas, but one of them is, I think he called it, Neotenism, it's like the opposite of the Lindy effect, where the Lindy effect is like saying, I trust things more if they're old. Because they stood the test of time that he is saying, like, I trust things more if they're new because they haven't been corrupted by these yet inevitable pressures of social entropy yet. And like part of the reason why you know structures gain entropy over time is because they go through, you know, disasters, and those disasters will lead to calls for defending against things and creating layers of accountability and defending against more problems, over time that just leads to structures that have like, good defenses against though leading to problems but also unfortunately, you know good defenses against being able to move quickly into new things as well. And like the thing that the Ethereum foundation and Balvi have in common is that they're explicitly not entities that are meant to survive forever. The thing with the Ethereum foundation, it's, like, more open-ended, but there's definitely a big strand to the original vision that says that, well, maybe the thing is going to disappear eventually.
Or maybe the thing is going to turn into a DAO eventually. And Balvi is explicitly intended to start with a pool of money, spend it and then say that we're done, right? So, like, explicitly say that the goal is to disappear so as to not have the pressures that we had to create some of these permanent bureaucracies and, you know, avoid the pressures of negative people more and more people trying to exploit it over time. So that kind of approach I think, has been fascinating to see it. Another one is just appealing internationally. Right? So one of the big differences between crypto and a lot of other frontier tech industries is that like, if you look at AI, for example, AI is completely based in the Bay Area, like OpenAI Bay area, Stable diffusion Bay Area, you know, Deep Mind and like the, you know, the entire kind of Google alphabet bubble, you know, largely Bay Area, right, Meta, you know, what's in there? It's, like, huge Bay Area dominance. Crypto is not like that at all, right? Like the Ethereum Foundation, which is legally based in Switzerland with a major satellite in Singapore, it has a large number of developers in Berlin.
It has, you know, people in you know, the US and even within the US, actually, Ethereum's primary American hub is Denver, which is, it's like, you know, neither SF nor New York, nor one of the kinds of mainstream contrarian hubs like Austin or Miami; it's like, hey, Denver, and it's like, you know, right in the middle, and then it's, it's there, and it's cool. The Z cash is also there, by the way, well, technically Ethereum foundation is more in Boulder, and Z cash is more in Denver, but like, you know, to me as an airplane person, if it shares an airport, it's part of the same city. But then, you know, Canada, we have developers in Taiwan, we have developers in all kinds of European countries, and Justin has been creating more and more of a research bubble in the UK. And there are places like Cambridge, you know, strong community in Taiwan all the way through more and more of a Chinese community growing, right, more and more of a Latin American community growing. A lot of Ethereum people in places like Argentina. So crypto has been, I think, practically more successful than most tech industries at international diversity in that way. And I think, what Balvi in particular, also had that always as part of its vision, right, I mean Balvi had crypto relief. And that crypto relief was about supporting, you know, India, and this was happening at a time when this was, as I remember, one of my bigger disappointments. The whole India crypto situation was just bubbling up on Twitter. And I remember, but even in the US, like, almost nobody was talking about it except for basically a couple of middle Silicon Valley people.
And this was actually one of the things that I still respect Silicon Valley for, I thought the Silicon Valley elites were more on the ball and recognizing that there was a problem happening in India and trying to think through like what, you know, what, what they could do to help than like pretty much anyone inside the Biden administration. And it was only when the Twitter noise became really, really just like unbearably wild doesn't, you know, they came out and made one kind of a statement. Right? So that was, I thought kind of testaments to, like more non-political organizations' greater ability to care about things that time you know, go beyond the kinds of countries that you and me and probably even most people listening to this are going to be based in. But then Balvi itself, you know, went all the way beyond the idea and supported, you know, stuff in Thailand, stuff in the US, stuff in the UK, a lot of stuff in Latin America, stuff in China, stuff in all kinds of countries. And I thought, you know, it was good that we did that. And it was only possible, I think, because of the international networks that we leveraged and international networks that were actually only available to me because I had made that decision on you know, nine and a half years ago to start roaming around and be a crypto Nomad instead of being based somewhere. So yeah, being international, I think those are really key.
Just being willing to trust people and process grants quickly. That was something that the EF definitely has done at various times and sometimes it takes longer, but it's I think, it's obviously not always the right approach for the long term, especially because if you do it too much, then eventually the Grifters kind of catch up And that's probably one of the main reasons to become more careful. But like, when your goal is scaling up quickly, and when your goal is helping a lot of people quickly, and especially when you start off being kind of not an established donor in a space it can be, it could be a good approach. So, yeah, those are some examples. And, you know, I'm hoping that those aren't just the models that we're going to be stuck with, you know, I hope that things like DeSci and, you know, reputation systems, and POAPs and all of these things are going to do an even better job at helping to solve the problem of, for example, who is trustworthy and what kind of people are worthy of more of a fast track process, right? And trying to, like, really get closer to the frontier between, like, accountability where it's necessary and, you know, giving people the freedom to do their job in places where that's obviously the right approach.
Vincent Weisser 32:01
Yeah, totally agree. Like it's kind of crazy that how much of the science and everything else like a centering around for example, SF or Boston, and like, how many cities and places kind of leaving out kind of shifting gears towards scientific progress? I would be curious, on your take on like, what is broadly holding back progress, maybe like in a scientific and technological sense, globally, but also kind of relates to add, like which scientific breakthroughs you're most excited about to see in your lifetime? And hopefully, your lifetime is fairly long, but that might be a breakthrough. That might extend the amount of braces you see in your lifetime. But we'd be super curious, especially also under the lens of like, Tyler Cowen and Peter Thiel and others and Patrick Collison saying we are in stagnation and that we'd like need to get back onto the track of growth and scientific progress. Be curious on your take.
Vitalik Buterin 32:00
Yeah, I think there are a bunch of factors, probably the biggest is always just the fact that public goods are chronically underfunded because it's hard to create a business model for them. Right? Like, if you're just a small actor, and at a global scale, everyone is a small actor that you only get, at most, a few percent of the benefit, maybe even a fraction or percentage points of the benefit of anything that you fund, right? And that is just always the biggest problem. That's a problem that humanity has been stuck with, and that’s a problem that is going to be hard to get past. But you know, if we can get from, only funding things that have a 10,000:1 benefit-cost ratio, and then all the way down to, you know, funding everything that has more than, let's say, 100:1 benefit-cost ratio, that's already a huge amount of progress. Other things, I think, definitely, like exclusive in essence silos. The fact that there is a lot of knowledge that's sort of generated by particular academic communities, and it's stuck in particular academic communities and very smart people who would be able to contribute just don't have that knowledge be accessible to them, because we've invented a path that basically says that you only get the required background knowledge by you know age 24, if and only if you're wealthy and privileged enough to like go through a particular university path. And the reality is if you enable people, there are lots of people who would make huge contributions when they're 15. Right. So trying to create paths that are accessible to more people and, you know, across wealth levels, across age levels across, you know, kind of regional and national levels, I think, its something that's going to be really valuable. ideology is also, I think, another one, right, like, there is the whole line.
And I think Tyler Cowen is one of the people who has kind of, you know, reblogged things about this, that basically sometime after, you know, World War II, and then kind of going further over time, a lot of people became much more conservative in certain ways about the physical world, and there was this mentality that, you know, actually kind of keeping the world pristine is good, and like large-scale, intentional human change is, by default, a bad thing. And, you know, the physical world is something that we should not touch. And that, you know, like, we see that in a lot of, in a lot of different contexts. So like, they're like that probably, you know, massively reduced the the amount of research into nuclear power, for example, similar things are definitely, reducing the level of interest into longevity research, similar things are reducing the level of interest into just you know, all kinds of areas that were improving as human lives ultimately involve some, you know, changing either ourselves or the physical world. But the big irony is that the digital world ended up being completely exempt from that mentality. And so he basically had a couple of decades where a lot of the smartest people basically went into, you know, creating social networks, creating all kinds of these, like Internet tools and creating all kinds of just ways for people to play, in some cases, increasingly negative of some internet games with each other. And lately, we've been seeing a backlash against that, which is interesting, right?
Like, we've been seeing a lot more interest in solar power, a lot more interested in nuclear power, a lot more interest in nuclear fusion, a lot more of just kind of like, human positivity and even, you know, positivity available large scale human intentional action, right. This is one of the things one of the ideas that I feel Palladium does a good job of promoting, for example, also the rise of the developing world, right, because the developing world, I think, never really went through the same phase of like getting a little bit disillusioned with everything that these you know, the rich country West did. And, you know, we've been seeing a lot of Indians, for example, getting into science with some very different perspectives. And also like the crypto space by itself, one way that I think you can critique the crypto space is you can say that, oh, actually, it's just part of the exact same phenomenon of people in the 2000s and in the 2010s. Like just forgetting about the physical world and thinking that they can do everything they want by just, you know, creating new tools for people to interact with each other digitally.
I think one of the interesting things about like network states, for example, is that its an instance of people in a lot of cases definitely kind of like crypto ideological ill lineage, but like rediscovering the fact that the physical world is important. And aside from network states, probably another example is the radical exchange movements, which have definitely different ideological beds, but I think it's also about physical spaces to some extent, in the same way. And there's a lot of crypto adoption going on, like crypto-inspired people going in that direction, too. Right. So, I think, you know, just having an ideology that's, you know, positive about the collective human ability to improve our understanding about the world and, you know, even have an impact on the world, and on physical space, and, like, an understanding of what it means to like this, you know, do the right thing and not do the wrong thing in those in those areas without just like falling back on saying, like, you know, let's set you know, let's not go here entirely, is one of the things that I think is like changing and slowly coming back and they just going also bring more people into science in the future.
Vincent Weisser 38:33
Being curious on this century broadly, people like Holden Karnofsky called it potentially the most important century for many reasons, including, of course, existential risks, AI progress, and broader technological and scientific progress. What's your view on how you could imagine the century to play out, especially in regards to, for example, AI progress, the singularity, or specific existential risks from AI to others? Kind of like, top of your mind for you for this century?
Vitalik Buterin 39:08
It's a good question.
Vincent Weisser 39:10
It's kind of like a vision or forecast.
Vitalik Buterin 39:12
The interesting thing is that there's a lot of curveballs this century, right? So, like, I mean, 2020 to 2022 have been this, like, crazy, long, three-year period of, you know, curveballs and some, a lot of negative curveballs and some curveballs that are, you know, either positive or negative, depending on your views on AI risk. But definitely be lots of curveballs, either way. And over the next century, there's just all these different potential curveballs that we just don't know yet. right? So one of them is what the AI future is going to look like.
Like, basically, are we in more of a kind of film world where it's just inevitable that some broad AI project, once it gets powerful enough, is just going to self-improve until it can basically control the world? And it's up to us to make sure that it controls the world in a way that's agreeable to us, despite us being very, very far away from being good at being able to put concrete goals of any kind into AIs at this point, or are we in more of a Robin Hanson world where there's no single AI that's might have particularly far ahead of all the other AIs. And so we're going to see a politically multipolar world, going into the foreseeable future. And then, like, there isn't really an existential risk, but there is just like this ongoing battle of offense versus defense technology, and our job is to try to make sure that no offense doesn't overtake defense by too much. Or, you know, also are we in a world where, you know, the current LLM approach is basically you know, that plus scale literally is all we need or are we in a world where, look, we're already starting with what GPT4 is going to be close to the last major piece of progress that we get from LLMs. Otherwise, LLMs are exhausted, and we need some really significant, more innovations. Another curveball is geopolitics. Right. So, you know, obviously, last year has seen a really unfortunate, you know, negative curveball in relations between Europe and Russia and the next two decades, or we could easily see a very negative curveball and relations between the US and China, we could see a very negative curveball in relations between India and China. Or nuclear proliferation. That's another one. Like, you know, this is something no one's expecting, but you know, what, if, like, just any one of these countries that has a big grudge against the United States just like decides to go into, you know, sell nukes with full plans for how to build more of them for, you know, 10 million bucks a pop to a bunch of randos. And we're up to having 30 nuclear states within two decades. And, you know, some of them start declaring a nuclear war against each other, like, Bio is another curveball right?
So we get, oh, we have one big COVID, which, I guess right now, the smart people are still like confused and like, what it's still 50/50, about whether it was like a wet market or a yellow lab leak. And but you know, blood leaks do happen all the time. And it's, you know, we could see more of them as we see more labs. And you know, we could see more intentional ones at some point, right? There's just that. But then on the other hand, you know, what if, like, it turns out that longevity does get solved, like, literally 20 years from now? And so, you know, what's that going to do? Like, what's that going to do to Peter Zeihan's, you know, demographic projections, right? It's like, everyone has these numbers that say, like, oh, in 2100, India is going to have a population of 1.4 billion China is going to be 0.7 Billion US is going to be 0.4 5 billion Africa is going to be like, somewhere around four. But look, what if we fix aging? Right? And you know, what, if all those numbers are off by a factor of two, you know, what if there is a radical cultural change there causes people to have like, much more much fewer children? You know, what if there is that the combination of you know, having a richer society and having like one tier or more of automation suddenly makes it more practical for every family to have five kids each? There are just so many different curveballs that could happen.
What if, you know, we do discover evidence of alien life, even if it is bacteria, right? And that just creates a big philosophical awakening and people, there are just so many of these big unknowns. And you know, a lot of the ones that I've mentioned are negative, but no, I think we could easily see a lot of positive unknowns as well, I'm, yeah, it's definitely going to be a really big century, and it's definitely going to be a really important one. I think I mean obviously the 21st century is more important than any century that came before. But the question is, like, is this 22nd century going to be even more important? Like, is that you know, is this the final boss of humanity? Or are we really at step n minus 2? Or do we really have the model wrong, and we're gonna see it, you know, extremely radical change that like, looks very radical, even from the inside keeping you going forward for millennia? I don't know yet.
Vincent Weisser 44:36
Maybe, to close off to kind of like also the audience of builders in decentralized science. You mentioned some of the ideas you'd be excited about. What are maybe some other ideas you haven't mentioned yet that, like the DeSci London hackathon, you would be excited for people to see built?
Vitalik Buterin 44:54
Things they’ll be excited to see built. Yeah, I think one would definitely be some kind of like, you know, whether it's attestation-based or soulbound token-based or POAP-based or something, some kind of solution for trying to like assign credit and assign credit recursively for things, possibly an implementation of retroactive public goods funding, tries to incorporate those kinds of ideas, possibly, what else simply build the education side would be interesting, right? So like trying to whether proactively or retroactively public funds, education, in different kinds of, you know, scientific disciplines, and the different ways that I've tried to evaluate like, Which ones of those are actually effective? prediction markets, actually, this is one we didn't talk about at all right? Well, this is—I know, Robin Hanson is really into this. And this is one of his big primary ideas, but there's just such a natural tie-in between decentralized science and prediction markets, right? And basically using them as a way of, like, trying to predict what paths in scientific research are more likely to be valuable retroactive public goods funding to some extent, it'd be like saying that kind of applies to prediction markets, right? Because the whole idea is that you know, you're gonna have investors that try to get participate in these retroactive rewards and that's how this stuff gets funded but like prediction markets more generally and their applications to science is another interesting area and with layer twos and Poly markets and prediction markets are getting more and more viable and more and more adoption so expanding number definitely be really interesting. So yeah, those are a few examples; otherwise, I'm sure people can come up with a lot of their own too.
Vincent Weisser 46:48
Amazing yeah, I'll collect all the older show notes and things like the DeSoc paper and other things we've discussed. Maybe it's like the very last but is there a specific book, blog post or podcast you would recommend to people specifically in the context of science you enjoyed reasonably
Vitalik Buterin 47:08
That's a good question. I mean, you know, 80,000 hours is always good. I feel like there are lots of very interesting and very smart people talking about all of the different areas that we brought up today. I don't know; I feel like we need to. It would be interesting to just have a podcast focusing on decentralized science, particularly at this point, and like, does something like that exist yet? Maybe you should start one?
Vincent Weisser 47:37
This will also go up on the DeSci podcast. So we also have a long conversation with a bunch of different people. I'll share the link in the show notes. But we have a bunch of other awesome conversations coming up, and all the talks and workshops from the DeSci conferences are already up. Find it in the comments. And on the view of the talks, I really enjoyed the intersection of DeSci and DeSoc, so I think that's a good related one, but thank you so much, Vitalik, for taking the time, and yeah, I wish you a great day.
Vitalik Buterin 48:09
Have a good day too.
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