SubsidieMeestersA sonogenetic brain-machine interface for neurosciences and visual restoration
Developing a novel sonogenetic brain-machine interface for remote, precise control of neuronal networks in large primate brains to advance treatments for neurological disorders.
Projectdetails
Introduction
Brain-machine interfaces are classically based on multi-electrode arrays. Optogenetics has revolutionized this ability to control neuronal activity through ectopic opsin expression, but its application to large brains remains limited because of tissue light absorption and scattering.
Ultrasound as a Modulation Tool
Ultrasound waves have been proposed for remote neuromodulation, but this approach has remained restricted to low-frequency excitation to prevent brain tissue overheating, at the expense of spatial resolution. The expression of mechanosensitive proteins in neurons has recently made it possible to achieve the ultrasound (US) activation of neurons at high US frequencies, an approach named “sonogenetic”.
Proof of Concept
Using the MscL mechanosensitive ionic channel, we recently provided a first proof of concept in rodents that cortical neurons can be activated in vivo by ultrasounds at a high spatiotemporal resolution and low intensity.
Project Proposal
Here, we propose to develop an integrated sonogenetic strategy for distant activation/inhibition of neuronal networks by ultrasound waves in large primate brains. The project includes:
- Optimizing and diversifying the sonogenetics actuators for safe neuronal control
- Designing technologies for patterned ultrasound stimulations
- Demonstrating efficacy and high spatiotemporal resolution of the sonogenetic approach in controlling the primate visual cortex
Expertise and Collaboration
This project is based on a unique synergistic combination of expertise, with a synthetic biologist in ion channel engineering, a neurobiologist with expertise in vision, and a physicist with expertise in ultrasound technologies. These three PIs will be supported by an expert in AAV vector-mediated delivery.
Expected Outcomes
The project outcomes will be a novel brain-machine interface for investigating neural circuit function even deep within large brains through contactless sonogenetics. This sonogenetic technology will open new avenues for treating neurological dysfunction, such as restoring vision in blind patients.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 7.817.939 |
| Totale projectbegroting | € 7.817.939 |
Tijdlijn
| Startdatum | 1-6-2024 |
| Einddatum | 31-5-2030 |
| Subsidiejaar | 2024 |
Partners & Locaties
Projectpartners
- INSTITUT NATIONAL DE LA SANTE ET DE LA RECHERCHE MEDICALEpenvoerder
- UNIVERSITA DEGLI STUDI DI MILANO
- SORBONNE UNIVERSITE
Land(en)
Vergelijkbare projecten binnen European Research Council
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|---|---|---|---|---|
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Remote controlling biological systems by sonopharmacology and sonogenetics
This project aims to develop biocompatible ultrasound technology to control drug, protein, and gene activity, enhancing therapies for cancer, diabetes, and tissue engineering while minimizing side effects.
A two-photon compound fiberscope to study the brain at all spatial and temporal scales.
Developing a novel 2P compound fiberscope to enable imaging and manipulation of neuronal circuits in freely moving animals, enhancing our understanding of brain function and behavior.
Soft optoelectronics and ion-based circuits for diagnostics and closed-loop neuromodulation of the auditory pathway
Develop a fully implantable, biocompatible electro-optical neurostimulation system using ion gated transistors and OLEDs to enhance neural signal acquisition and treatment of sensory dysfunctions.
Non-invasive patterned electrical neurostimulation of the retina
This project aims to develop non-invasive trans-orbital stimulation techniques and bi-directional interfaces for retinal neurostimulation to enhance artificial vision in patients with retinal degenerative diseases.
measuriNg nEURal dynamics with label-free OpticaL multI-DomAin Recordings
This project aims to innovate label-free optical methods for monitoring neural dynamics in the brain, enhancing understanding and treatment of brain diseases without exogenous reporters.
Vergelijkbare projecten uit andere regelingen
| Project | Regeling | Bedrag | Jaar | Actie |
|---|---|---|---|---|
MagnetoElectric and Ultrasonic Technology for Advanced BRAIN modulationMETA-BRAIN aims to develop non-invasive, precise control of brain activity using magnetoelectric nanoarchitectures and ultrasonic technologies, enhancing treatment for neurological disorders. | EIC Pathfinder | € 2.987.655 | 2024 | Details |
High-dimensional electrical stimulation for visual prosthesisThe project aims to enhance visual prostheses by developing sophisticated stimulation protocols for existing microelectrodes, achieving a 20X improvement in spatial resolution to restore vision in blind patients. | EIC Pathfinder | € 2.105.228 | 2022 | Details |
A synaptic mechanogenetic technology to repair brain connectivityDeveloping a mechanogenetic technology using magnetic nanoparticles to non-invasively regulate neural circuits for treating treatment-resistant brain disorders like stroke and epilepsy. | EIC Pathfinder | € 3.543.967 | 2023 | Details |
AEGEUS - A Novel EEG Ultrasound Device for Functional Brain Imaging and NeurostimulationDevelop a novel wearable device combining ultrasound imaging and EEG for enhanced diagnosis and treatment of neurological disorders, aiming for improved patient outcomes and research advancements. | EIC Pathfinder | € 2.998.988 | 2023 | Details |
Wireless deep BRAIN STimulation thrOugh engineeRed Multifunctinal nanomaterialsBRAINSTORM aims to develop a scalable wireless neuromodulation technology using smart magnetic nanomaterials to selectively control deep brain neurons for therapeutic applications in Fragile X syndrome. | EIC Pathfinder | € 3.083.850 | 2023 | Details |
MagnetoElectric and Ultrasonic Technology for Advanced BRAIN modulation
META-BRAIN aims to develop non-invasive, precise control of brain activity using magnetoelectric nanoarchitectures and ultrasonic technologies, enhancing treatment for neurological disorders.
High-dimensional electrical stimulation for visual prosthesis
The project aims to enhance visual prostheses by developing sophisticated stimulation protocols for existing microelectrodes, achieving a 20X improvement in spatial resolution to restore vision in blind patients.
A synaptic mechanogenetic technology to repair brain connectivity
Developing a mechanogenetic technology using magnetic nanoparticles to non-invasively regulate neural circuits for treating treatment-resistant brain disorders like stroke and epilepsy.
AEGEUS - A Novel EEG Ultrasound Device for Functional Brain Imaging and Neurostimulation
Develop a novel wearable device combining ultrasound imaging and EEG for enhanced diagnosis and treatment of neurological disorders, aiming for improved patient outcomes and research advancements.
Wireless deep BRAIN STimulation thrOugh engineeRed Multifunctinal nanomaterials
BRAINSTORM aims to develop a scalable wireless neuromodulation technology using smart magnetic nanomaterials to selectively control deep brain neurons for therapeutic applications in Fragile X syndrome.