Flexible intracerebral probes for neural recording and electrical stimulation have been the focus of many research works to achieve better compliance with the surrounding tissue while minimizing rejection.Strategies h...Flexible intracerebral probes for neural recording and electrical stimulation have been the focus of many research works to achieve better compliance with the surrounding tissue while minimizing rejection.Strategies have been explored to find the best way to insert flexible probes into the brain while maintaining their flexibility once positioned.Here,we present a novel and versatile scalable batch fabrication approach to deliver ultrathin and flexible probes consisting of a silk-parylene bilayer.The biodegradable silk layer,whose degradation time is programmable,provides a temporary and programmable stiffener to allow the insertion of ultrathin parylene-based flexible devices.Our innovative and robust batch fabrication technology allows complete freedom over probe design in terms of materials,size,shape,and thickness.We demonstrate successful ex vivo insertion of the probe with acute high-fidelity recordings of epileptic seizures in field potentials as well as single-unit action potentials in mouse brain slices.Our novel technological solution for implanting ultraflexible devices in the brain while minimizing rejection risks shows high potential for use in both brain research and clinical therapies.展开更多
基金The authors acknowledge funding from the Agence Nationale de la Recherche(ANR-19-CE19-0002-01 and ANR ANR-15-CE19-0006)This work was supported by the French RENATECH network。
文摘Flexible intracerebral probes for neural recording and electrical stimulation have been the focus of many research works to achieve better compliance with the surrounding tissue while minimizing rejection.Strategies have been explored to find the best way to insert flexible probes into the brain while maintaining their flexibility once positioned.Here,we present a novel and versatile scalable batch fabrication approach to deliver ultrathin and flexible probes consisting of a silk-parylene bilayer.The biodegradable silk layer,whose degradation time is programmable,provides a temporary and programmable stiffener to allow the insertion of ultrathin parylene-based flexible devices.Our innovative and robust batch fabrication technology allows complete freedom over probe design in terms of materials,size,shape,and thickness.We demonstrate successful ex vivo insertion of the probe with acute high-fidelity recordings of epileptic seizures in field potentials as well as single-unit action potentials in mouse brain slices.Our novel technological solution for implanting ultraflexible devices in the brain while minimizing rejection risks shows high potential for use in both brain research and clinical therapies.
