Introduction

Pump Science is an innovative platform that merges cryptocurrency and scientific research, specifically focusing on longevity experiments. It is part of the emerging Decentralized Science (DeSci) movement, which aims to make scientific research more open, transparent, and community-driven. By utilizing blockchain technology, Pump Science allows participants to fund, track, and trade tokens linked to real scientific experiments.

The platform operates by launching tokens representing different experimental compounds, enabling users to support research through token purchases. These funds are then used to conduct experiments on various biological models, starting with simple organisms like worms (C. elegans) and progressing to more complex ones like flies and mice. As experimental data becomes available, participants can monitor progress and trade tokens based on the results.

The primary goal of Pump Science is to decentralize and accelerate scientific research by introducing market-driven funding mechanisms. Traditional research funding is often slow, competitive, and limited to institutional grants, but Pump Science creates an alternative model where anyone can contribute and benefit from scientific advancements.

What is Pump Science?

Source: Pump Science website

Pump Science is a blockchain-based platform designed to fund and conduct scientific research, primarily in longevity studies. It operates on a decentralized model, allowing researchers and investors to participate in scientific experiments through a token-based system.

The platform extends Molecule, a decentralized science (DeSci) protocol that connects intellectual property (IP) with blockchain technology. Molecule has been instrumental in creating IP-NFTs (intellectual property non-fungible tokens) to tokenize and democratize access to research funding. Pump Science leverages Molecule’s infrastructure to bring a prediction market model to longevity research, making science more accessible and community-driven.

Pump Science enables the creation of crypto tokens linked to specific compounds being tested for potential health benefits. These tokens act as funding mechanisms and tradable assets, allowing users to support research and engage in speculative trading based on experimental progress.

Using Molecule’s IP tokenization framework, Pump Science integrates research funding, decentralized ownership, and transparent data sharing, further aligning with the broader DeSci movement. This relationship ensures that Pump Science benefits from Molecule’s expertise in building scalable blockchain solutions for scientific innovation.

History of Pump Science, Origins, and Key Persons

Pump Science was introduced in September 2024 at Solana’s Breakpoint conference by Paul Kohlhaas, a veteran in the crypto space since 2016. The platform was developed in approximately three weeks, with support from the Solana Foundation, which provided a grant for its development.

The platform’s initial focus was conducting longevity experiments using C. elegans (worms) to test the effects of various compounds on lifespan. This approach was inspired by the work of Ora Biomedical, founded by Matt Kaeberlein and Mitchell Lee, who developed the WormBot—a low-cost, rapid experimental platform designed to test potential longevity regimens on C. elegans.

Pump Science operates on the Solana blockchain and is built on top of Pump.fun, a platform that enables creating and trading memecoins. 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 November 2024, Pump Science faced a security incident where its private key was leaked on GitHub, allowing a known attacker to create fraudulent tokens using its Pump.fun profile. The platform responded by changing its Pump.fun profile name to “dont_trust” to prevent people from buying fraudulent tokens. It partnered with blockchain security firm Blockaid to flag new mints from compromised addresses.

Despite this setback, Pump Science continues to develop its platform, aiming to expand its experimental protocols to include other organisms and further integrate decentralized science (DeSci) principles into its operations.

How Does Pump Science Work?

Pump Science operates through a structured process integrating community involvement with scientific experimentation. Researchers, known as “drug developers,” propose compounds or interventions for testing. Upon approval, a unique token representing the compound is created. Interested participants purchase these tokens, providing the necessary funds for the experiments.

Then experiments are conducted in stages, starting with simpler organisms and progressing to more complex ones:

• Worms: Initial tests on C. elegans using the WormBot at Ora Biomedical.
• Flies: Successful compounds proceed to tests on flies at Tracked Biotechnologies using the FlyBox.
• Mice: Promising results lead to experiments on mice at Tracked Biotechnologies via MouseWatcher.

Participants can monitor live data updates to observe the effects of compounds in real-time. Based on experimental outcomes, token holders can trade their tokens, creating a dynamic market driven by scientific results.

Key Features of Pump Science

Decentralized Research Funding

Pump Science eliminates the need for traditional research grants by allowing anyone to contribute funds through token purchases. This system removes institutional barriers and enables more participants to support scientific research.

Funding is released in phases based on experiment’s progress. Rather than providing all funds upfront, the model ensures that only promising experiments receive continued financial support. This approach prevents wasted resources and speculative funding without scientific backing.

Tokenized Research and Market Influence

Each scientific experiment is linked to a specific crypto token. These tokens act as financial assets that can be bought, sold, or held, providing an investment mechanism tied to research progress.

Token prices fluctuate based on experimental outcomes. If research shows positive results, demand for the associated token may increase. If results are negative or inconclusive, token value may decline. This creates a market-driven approach to research funding.

Unlike traditional research investments, where funding is locked for years, Pump Science allows participants to exit anytime by selling their tokens. This provides a liquid market for research investments but also introduces volatility and risk.

Multi-Stage Experimental Process

Pump Science conducts experiments in phases to ensure that compounds undergo progressive validation before reaching advanced stages.

• Phase 1: Worm Testing (C. elegans) – Initial testing is conducted on worms using the WormBot system at Ora Biomedical. Worms are chosen for their short lifespan and genetic similarities to higher organisms.
• Phase 2: Fly Testing (Drosophila) – Successful compounds move to fly experiments using the FlyBox system at Tracked Biotechnologies, providing additional aging and metabolic data.
• Phase 3: Mouse Testing (Rodents) – If a compound is effective in worms and flies, it progresses to mice, a more relevant model for human research.

This staged process ensures that scientific credibility is maintained and that funding is allocated to compounds with proven effects in lower organisms before advancing.

Open-Access Data and Real-Time Monitoring

Unlike traditional research, where results are published months or years later, Pump Science provides real-time data streaming. This system allows users to monitor experimental progress instantly.

All research data is publicly available, ensuring that participants can evaluate scientific progress in real time. This transparency reduces data manipulation risks and allows investors to make informed trading decisions.

Community Participation and Governance

Research funding is typically controlled by government agencies, universities, or private companies. Pump Science shifts decision-making power to token holders, allowing them to support or reject research projects.

Holding tokens gives participants voting power on key protocol decisions. This ensures that funding is distributed based on community input rather than institutional control.

Integration with the Decentralized Science (DeSci) Movement

Scientific research is often slow, expensive, and limited to institutions. Pump Science aligns with the DeSci movement, which aims to make research faster, transparent, and publicly funded.

Pump Science applies blockchain principles to biomedical research, allowing funding, governance, and data-sharing to be decentralized. This reduces bureaucracy and enables immediate funding for promising experiments.

Is Pump Science a Good Investment?

Investing in Pump Science involves purchasing tokens associated with specific compounds under investigation. Experimental outcomes and market dynamics influence the value of these tokens.

While the platform offers a novel approach to funding scientific research, potential investors should be aware of the inherent risks, including market volatility and the speculative nature of token trading. As with any investment, thorough research and careful consideration are advised.

How Can You Own $RIF and $URO?

To acquire Pump Science tokens like $RIF (Rifampicin) and $URO (Urolithin A):

• Visit the Pump Science Platform: Explore ongoing experiments and select a compound of interest.
• Purchase Tokens: Tokens can be bought through the platform’s integrated trading system, which operates on the Solana blockchain.
• Participate in the Ecosystem: Monitor experimental progress and engage in token trading based on real-time data.

It’s important to note that only $RIF and $URO are officially issued by the Pump Science team; the platform does not endorse other tokens.

Tokenomics of $RIF and $URO

Pump Science utilizes a token-based funding model, with a specific cryptocurrency token representing each scientific experiment. $RIF (Rifampicin) and $URO (Urolithin A) are the first two tokens launched on the platform, linked to longevity research.

Source: Documentation

The token starts with an approximate valuation of $5,000. As more tokens are purchased, their price increases following the bonding curve model. Once the token reaches a liquidity threshold of 85 SOL, its liquidity is moved to Meteora (Solana-based AMM).

Total Supply and Distribution

Each token has a maximum supply of 1 billion tokens.

• 79.3% (793.1 million tokens): Released through the bonding curve for public purchase.
• 15.7% (156.9 million tokens): Migrated to liquidity pools to facilitate trading.
• 5% (50 million tokens): Reserved for airdrops and rewards.

The airdrops are distributed proportionally based on the compound’s success in different experimental models (worms, flies, mice, humans).

Trading Fees and Research Funding

Pump Science funds its research primarily through trading fees generated from token transactions.

• 75% of trading fees are allocated to fund ongoing and future experiments.
• 25% of trading fees are retained by Pump Science as a platform fee.

Anti-Bot Measures and Fair Trading

Pump Science implements high initial trading fees that gradually decrease over time to prevent automated bots from dominating token purchases. This system discourages early price manipulation and ensures that tokens are fairly distributed.

Airdrop and Reward Mechanism

Pump Science periodically distributes free tokens (airdrops) to holders of successful research-backed tokens. For example, token holders may receive additional rewards if $RIF tokens correspond to a longevity increase in worms.

Roadmap of Pump Science

Source: Documentation

Pump Science has outlined a strategic roadmap for 2025 to expand its research capabilities and community engagement:

Q1 2025

• Mice Experiments Begin: Conduct tests on mice for compounds $URO and $RIF.
• New Compound Launches: Introduce additional compounds for longevity research in partnership with VitaDAO.
• Marketplace Launch: Roll out a marketplace for supplement preorders.
• Supplement Pre-orders: Enable users to pre-order compounds based on experimental results.

Q2 2025

• Decentralized Human Trials: Begin trials involving human participants in a decentralized framework.
• Decentralized Compound Launching: Expand the system to allow for community-driven compound proposals and launches.
• Broader Experiment Types: Include new experimental approaches for additional animals and human research.

Conclusion

Pump Science introduces a new model for funding and conducting scientific research, specifically targeting longevity studies. By integrating blockchain technology, decentralized finance (DeFi), and experimental science, the platform allows for public participation in research funding, real-time data tracking, and token-based speculation on scientific outcomes.

The platform operates on a structured funding mechanism, where research-backed tokens such as $RIF and $URO represent financial contributions to specific experiments. These tokens are tradeable assets, allowing investors to speculate on the success of scientific trials. Unlike traditional research funding models that rely on grants and institutional backing, Pump Science enables market-driven funding, where liquidity is generated through bonding curves, liquidity pools, and trading fees.

The multi-stage experimental process, starting with worms (C. elegans) and progressing to flies and mice, ensures that research is validated progressively before reaching advanced stages. Real-time data sharing allows investors and researchers to track experimental outcomes without waiting for delayed scientific publications.

From an investment perspective, Pump Science offers opportunities but also high risks. The speculative nature of token prices, combined with market volatility and security concerns, makes it a high-risk, high-reward investment. Additionally, the lack of regulatory oversight and potential ethical concerns surrounding decentralized research funding may impact its long-term adoption.