SubsidieMeestersExtracting the Human Motor Null Space from Muscles - A new framework to measure human neural activity
ECHOES aims to develop a novel neuroimaging technology by decoding non-motor neural signals in muscles, enhancing understanding of the central nervous system and enabling advancements in human-machine interfaces and movement disorder diagnostics.
Projectdetails
Introduction
By contracting our muscles, we move and interact with the world. In turn, the activated muscles act as signal repeaters of the neural inputs they receive.
Neural Inputs and Muscle Interaction
Muscles do not only receive inputs determining how they need to contract (and thereby how we move), but they also receive a rich set of neural information originating in the central nervous system and traveling through nerves and muscles without directly altering motor commands.
The Concept of 'Motor Null Space'
This 'motor null space' in the muscles may represent a unique opportunity to explore the human central nervous system in an unobtrusive, spatially selective, and robust way, thereby overcoming the most critical inherent limitations of currently available non-invasive neuroimaging technologies.
Research Objectives
To test this novel concept, fundamental research is needed to develop methods to extract, separate, and interpret the non-motor neural projections to human muscles.
ECHOES Project Framework
ECHOES will capitalize on recent breakthroughs in decoding the spinal outputs to muscles to develop a theoretical and experimental framework to unveil the 'motor null space' in human muscles.
Potential Benefits
The project will then demonstrate the potential benefits of the extracted neural information in three scientific fields with growing societal and clinical impact:
- Human-machine interfaces
- Targeted brain neuromodulation
- Diagnosis of movement disorders
Expected Outcomes
I expect that the project's multidisciplinary research program will further our understanding of the origin and relevance of neural signals generated by the human brain and spinal cord.
Future Implications
This will markedly improve future research aimed to understand, use, and modulate human neural activity by providing a first-of-its-kind, minimally invasive, and robust neuroimaging technology with unprecedented spatio-temporal resolution.
Conclusion
By achieving these goals, ECHOES technology will enable the development of new applications for the clinical and industry fields.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 1.499.608 |
| Totale projectbegroting | € 1.499.608 |
Tijdlijn
| Startdatum | 1-10-2023 |
| Einddatum | 30-9-2028 |
| Subsidiejaar | 2023 |
Partners & Locaties
Projectpartners
- UNIVERSIDAD DE ZARAGOZApenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
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|---|---|---|---|---|
A Direct Sensorimotor Connection with the Spared Neural Code of Movement to Regain Motor FunctionThis project aims to develop a bidirectional neural interface that enhances motor function in paralyzed individuals by precisely mapping and engaging spinal motor neurons through advanced sensing and feedback methods. | ERC Starting... | € 1.495.271 | 2024 | Details |
Simulation-enhanced High-density Magnetomyographic Quantum Sensor Systems for Decoding Neuromuscular Control During MotionThis project aims to develop high-density Magnetomyography using quantum sensors to decode neuromuscular control, enabling breakthroughs in diagnostics and treatment of neurodegenerative diseases. | ERC Advanced... | € 3.499.763 | 2022 | Details |
Induction of NEuromuscular Plasticity for natural motor rehabilitaTIONINcEPTION aims to enhance neurorehabilitation by optimizing stimulation protocols through real-time estimation of neural connectivity from EMG signals, promoting recovery in stroke and cancer survivors. | ERC Consolid... | € 1.999.533 | 2022 | Details |
Robotic bioreactors for the longitudinal control of restorative remodelling in the human skeletal muscleROBOREACTOR aims to develop robots that deliver electro-mechanical stimuli to enhance muscle remodeling and control inflammation over time, improving rehabilitation for neuromuscular disorders. | ERC Consolid... | € 2.000.000 | 2024 | Details |
EARTHWORM: pEristAlsis in Real-Time Human mri to study the interWOven fRequency & Microstructural propertiesEARTHWORM aims to revolutionize MRI techniques to study peristaltic motion and microstructure in the human body, enhancing diagnosis and modeling of related diseases. | ERC Starting... | € 1.494.536 | 2024 | Details |
A Direct Sensorimotor Connection with the Spared Neural Code of Movement to Regain Motor Function
This project aims to develop a bidirectional neural interface that enhances motor function in paralyzed individuals by precisely mapping and engaging spinal motor neurons through advanced sensing and feedback methods.
Simulation-enhanced High-density Magnetomyographic Quantum Sensor Systems for Decoding Neuromuscular Control During Motion
This project aims to develop high-density Magnetomyography using quantum sensors to decode neuromuscular control, enabling breakthroughs in diagnostics and treatment of neurodegenerative diseases.
Induction of NEuromuscular Plasticity for natural motor rehabilitaTION
INcEPTION aims to enhance neurorehabilitation by optimizing stimulation protocols through real-time estimation of neural connectivity from EMG signals, promoting recovery in stroke and cancer survivors.
Robotic bioreactors for the longitudinal control of restorative remodelling in the human skeletal muscle
ROBOREACTOR aims to develop robots that deliver electro-mechanical stimuli to enhance muscle remodeling and control inflammation over time, improving rehabilitation for neuromuscular disorders.
EARTHWORM: pEristAlsis in Real-Time Human mri to study the interWOven fRequency & Microstructural properties
EARTHWORM aims to revolutionize MRI techniques to study peristaltic motion and microstructure in the human body, enhancing diagnosis and modeling of related diseases.
Vergelijkbare projecten uit andere regelingen
| Project | Regeling | Bedrag | Jaar | Actie |
|---|---|---|---|---|
Oro Muscles Analytics DevelopmentBlackTop Labs ontwikkelt een prototype voor een analytisch systeem dat spieractiviteit en beweging analyseert om fysiotherapeuten te ondersteunen bij revalidatie en pijnbestrijding. | Mkb-innovati... | € 190.890 | 2022 | Details |
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 |
Mapping the brain-spinal cord interaction towards understanding and treatment of movement disordersMove2Treat aims to develop a novel bi-directional brain-spinal cord interface to enhance understanding and treatment of movement disorders through advanced neuronal circuit mapping. | EIC Pathfinder | € 2.996.048 | 2024 | 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 |
Distributed and federated cross-modality actuation through advanced nanomaterials and neuromorphic learningCROSSBRAIN aims to revolutionize brain condition treatment using implantable microbots for real-time, adaptive neuromodulation and sensing in rodent models of Parkinson's Disease and Epilepsy. | EIC Pathfinder | € 4.034.074 | 2022 | Details |
Oro Muscles Analytics Development
BlackTop Labs ontwikkelt een prototype voor een analytisch systeem dat spieractiviteit en beweging analyseert om fysiotherapeuten te ondersteunen bij revalidatie en pijnbestrijding.
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.
Mapping the brain-spinal cord interaction towards understanding and treatment of movement disorders
Move2Treat aims to develop a novel bi-directional brain-spinal cord interface to enhance understanding and treatment of movement disorders through advanced neuronal circuit mapping.
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.
Distributed and federated cross-modality actuation through advanced nanomaterials and neuromorphic learning
CROSSBRAIN aims to revolutionize brain condition treatment using implantable microbots for real-time, adaptive neuromodulation and sensing in rodent models of Parkinson's Disease and Epilepsy.