Increasing the proximity of microelectrode arrays(MEA)to targeted neural tissues can establish efficient neural interfaces for both recording and stimulation applications.This has been achieved by constructing protrud...Increasing the proximity of microelectrode arrays(MEA)to targeted neural tissues can establish efficient neural interfaces for both recording and stimulation applications.This has been achieved by constructing protruding three-dimensional(3D)structures on top of conventional planar microelectrodes via additional micromachining steps.However,this approach adds fabrication complexities and limits the 3D structures to certain shapes.We propose a one-step fabrication of MEAs with versatile microscopic 3D structures via“microelectrothermoforming(μETF)”of thermoplastics,by utilizing 3D-printed molds to locally deform planar MEAs into protruding and recessing shapes.Electromechanical optimization enabled a 3D MEA with 80μm protrusions and/or recession for 100μm diameter.Its simple and versatile shaping capabilities are demonstrated by diverse 3D structures on a single MEA.The benefits of 3D MEA are evaluated in retinal stimulation through numerical simulations and ex vivo experiments,confirming a threshold lowered by 1.7 times and spatial resolution enhanced by 2.2 times.展开更多
基金supported by the National Research Foundation of Korea(NRF)grant funded by the Korean government(MSIT)(NRF-2022R1C1C1010422,RS-2023-00217893,and NRF 2020R1C1C1010505)。
文摘Increasing the proximity of microelectrode arrays(MEA)to targeted neural tissues can establish efficient neural interfaces for both recording and stimulation applications.This has been achieved by constructing protruding three-dimensional(3D)structures on top of conventional planar microelectrodes via additional micromachining steps.However,this approach adds fabrication complexities and limits the 3D structures to certain shapes.We propose a one-step fabrication of MEAs with versatile microscopic 3D structures via“microelectrothermoforming(μETF)”of thermoplastics,by utilizing 3D-printed molds to locally deform planar MEAs into protruding and recessing shapes.Electromechanical optimization enabled a 3D MEA with 80μm protrusions and/or recession for 100μm diameter.Its simple and versatile shaping capabilities are demonstrated by diverse 3D structures on a single MEA.The benefits of 3D MEA are evaluated in retinal stimulation through numerical simulations and ex vivo experiments,confirming a threshold lowered by 1.7 times and spatial resolution enhanced by 2.2 times.
