SubsidieMeestersHigh throughput development platform for oligonucleotide aptamers
SPARXS is an innovative platform that enables rapid design of affinity probes by simultaneously analyzing binding kinetics and sequences of millions of aptamers for diverse applications.
Projectdetails
Introduction
The binding kinetics of an affinity probe–the speed and duration with which it attaches to a target molecule–must be precisely tuned for numerous applications in therapeutics, super-resolution microscopy, and biochemical assays. The current methods of development lack the capability to specify these binding kinetics during probe design, resulting in the potential for effective drugs and relevant biological properties to remain undiscovered.
Solution Overview
Here, I introduce a game-changing solution: Single-molecule Parallel Analysis for Rapid eXploration of Sequence space (SPARXS). SPARXS harnesses the power of single-molecule observations and subsequent high-throughput sequencing to simultaneously reveal the binding kinetics and sequences of millions of aptamers (affinity probes composed of nucleic acids). This process enables the tailored design of probes with the desired binding behavior for various applications.
Origin and Development
This technology originated from my ERC Consolidator Grant project as a research tool, and its application can fulfill multiple practical demands. As SPARXS provides a particularly excellent fit for aptamer development, I have decided to enhance the platform with aptamer-specific features.
Market Research and Commercialization
Furthermore, I will conduct market research to understand the specific demands of users seeking defined-kinetic probes, which will facilitate the commercialization of SPARXS-based aptamer design upon completion of the project.
Conclusion
In summary, SPARXS signifies a disruptive advancement in aptamer development and will revolutionize affinity probe design across the biotech industry. With minimal adaptations to the core technology, I anticipate a high potential for swift commercialization as a dedicated development platform.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 150.000 |
| Totale projectbegroting | € 150.000 |
Tijdlijn
| Startdatum | 1-3-2024 |
| Einddatum | 31-8-2025 |
| Subsidiejaar | 2024 |
Partners & Locaties
Projectpartners
- TECHNISCHE UNIVERSITEIT DELFTpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
| Project | Regeling | Bedrag | Jaar | Actie |
|---|---|---|---|---|
MANUNKIND: Determinants and Dynamics of Collaborative ExploitationThis project aims to develop a game theoretic framework to analyze the psychological and strategic dynamics of collaborative exploitation, informing policies to combat modern slavery. | ERC STG | € 1.497.749 | 2022 | Details |
Elucidating the phenotypic convergence of proliferation reduction under growth-induced pressureThe UnderPressure project aims to investigate how mechanical constraints from 3D crowding affect cell proliferation and signaling in various organisms, with potential applications in reducing cancer chemoresistance. | ERC STG | € 1.498.280 | 2022 | Details |
The Ethics of Loneliness and SociabilityThis project aims to develop a normative theory of loneliness by analyzing ethical responsibilities of individuals and societies to prevent and alleviate loneliness, establishing a new philosophical sub-field. | ERC STG | € 1.025.860 | 2023 | Details |
Uncovering the mechanisms of action of an antiviral bacteriumThis project aims to uncover the mechanisms behind Wolbachia's antiviral protection in insects and develop tools for studying symbiont gene function. | ERC STG | € 1.500.000 | 2023 | Details |
MANUNKIND: Determinants and Dynamics of Collaborative Exploitation
This project aims to develop a game theoretic framework to analyze the psychological and strategic dynamics of collaborative exploitation, informing policies to combat modern slavery.
Elucidating the phenotypic convergence of proliferation reduction under growth-induced pressure
The UnderPressure project aims to investigate how mechanical constraints from 3D crowding affect cell proliferation and signaling in various organisms, with potential applications in reducing cancer chemoresistance.
The Ethics of Loneliness and Sociability
This project aims to develop a normative theory of loneliness by analyzing ethical responsibilities of individuals and societies to prevent and alleviate loneliness, establishing a new philosophical sub-field.
Uncovering the mechanisms of action of an antiviral bacterium
This project aims to uncover the mechanisms behind Wolbachia's antiviral protection in insects and develop tools for studying symbiont gene function.
Vergelijkbare projecten uit andere regelingen
| Project | Regeling | Bedrag | Jaar | Actie |
|---|---|---|---|---|
Single-Molecule Acousto-Photonic NanofluidicsSIMPHONICS aims to develop a high-throughput, non-invasive platform for protein fingerprinting by integrating nanopore technology with acoustic manipulation and fluorescence detection. | ERC STG | € 1.499.395 | 2022 | Details |
Automated, miniaturized and accelerated drug discovery: AMADEUSAMADEUS is an automated platform for rapid, sustainable drug discovery that synthesizes thousands of small molecules daily, optimizing processes through AI to reduce costs and enhance accessibility. | ERC ADG | € 3.409.401 | 2024 | Details |
Legonucleotides for detectionChem2Sense aims to revolutionize biosensor development by creating high-affinity aptalegomers through reversible aptamer conjugation and advanced nanopore sequencing techniques. | ERC COG | € 1.999.144 | 2024 | Details |
Decoding subcellular spatial biology with high precision using RNA photocatalystsThis project aims to develop a low-cost, high-precision technology for deciphering RNA interactions, enhancing understanding of RNA networks and uncovering new therapeutic targets for diseases. | ERC COG | € 1.999.525 | 2024 | Details |
Single-Molecule Acousto-Photonic Nanofluidics
SIMPHONICS aims to develop a high-throughput, non-invasive platform for protein fingerprinting by integrating nanopore technology with acoustic manipulation and fluorescence detection.
Automated, miniaturized and accelerated drug discovery: AMADEUS
AMADEUS is an automated platform for rapid, sustainable drug discovery that synthesizes thousands of small molecules daily, optimizing processes through AI to reduce costs and enhance accessibility.
Legonucleotides for detection
Chem2Sense aims to revolutionize biosensor development by creating high-affinity aptalegomers through reversible aptamer conjugation and advanced nanopore sequencing techniques.
Decoding subcellular spatial biology with high precision using RNA photocatalysts
This project aims to develop a low-cost, high-precision technology for deciphering RNA interactions, enhancing understanding of RNA networks and uncovering new therapeutic targets for diseases.