Summary
BioFunctional IntraNeural Electrodes : In BioFINE we will develop flexible intraneural multielectrode arrays, capable of interfacing peripheral nerves e.g. to transfer input/output signals from bionic limbs. Specifically, we address the challenge of long term tissue integration and chronic stability, by addressing three aspects of biocompatibility: 1) We develop novel fabrication methods allowing the intraneural interface to be defined at even finer resolution than before; 2) we explore functionalizations which will control the tissue response by combined surface anchored and surface eluted agents; 3) we address structural biocompatibility on a system level by engineering novel implantable interconnects which reduced tethering forces and improve prospects for high channel count interfaces. Fine-tuned bioactivity will safe-guard surrounding neural tissue in the initial stages of healing, and implants of sub-cellular dimensions and tissue compatible biomechanics, will safe-guard tissue healthy in the longer term. The combined approach will offer optimal conditions to bridge the gap from electrode to neuron and generate a long term functional peripheral nerve interface. Indeed, each of the three technological advancements would on their own have substantial impact on neurotechnology, reaching far beyond intraneural interfaces.
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| Web resources: | https://cordis.europa.eu/project/id/101099366 |
| Start date: | 01-04-2023 |
| End date: | 31-03-2026 |
| Total budget - Public funding: | 1 945 622,00 Euro - 1 945 622,00 Euro |
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Original description
BioFunctional IntraNeural Electrodes : In BioFINE we will develop flexible intraneural multielectrode arrays, capable of interfacing peripheral nerves e.g. to transfer input/output signals from bionic limbs. Specifically, we address the challenge of long term tissue integration and chronic stability, by addressing three aspects of biocompatibility: 1) We develop novel fabrication methods allowing the intraneural interface to be defined at even finer resolution than before; 2) we explore functionalizations which will control the tissue response by combined surface anchored and surface eluted agents; 3) we address structural biocompatibility on a system level by engineering novel implantable interconnects which reduced tethering forces and improve prospects for high channel count interfaces. Fine-tuned bioactivity will safe-guard surrounding neural tissue in the initial stages of healing, and implants of sub-cellular dimensions and tissue compatible biomechanics, will safe-guard tissue healthy in the longer term. The combined approach will offer optimal conditions to bridge the gap from electrode to neuron and generate a long term functional peripheral nerve interface. Indeed, each of the three technological advancements would on their own have substantial impact on neurotechnology, reaching far beyond intraneural interfaces.Status
SIGNEDCall topic
HORIZON-EIC-2022-PATHFINDEROPEN-01-01Update Date
31-07-2023
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