The pursuit of precisely recording and localizing neural activities in brain cortical regions drives the development of advanced electrocorticography(ECoG)devices.Remarkable progress has led to the emergence of micro-...The pursuit of precisely recording and localizing neural activities in brain cortical regions drives the development of advanced electrocorticography(ECoG)devices.Remarkable progress has led to the emergence of micro-ECoG(μECoG)devices with sub-millimeter resolutions.This review presents the current research status,development directions,potential innovations and applications of high-density,high-throughputμECoG devices.First,we summarize the challenges associated with accurately recording single or multiple neurons using existingμECoG devices,including passive multielectrode and active transistor arrays.Second,we focus on cutting-edge advancements in passiveμECoG devices by discussing the design principles and fabrication strategies to optimize three key parameters:impedance,mechanical flexibility,and biocompatibility.Furthermore,recent findings highlight the need for further research and development in active transistor arrays,including silicon,metal oxide,and solution-gated transistors.These active transistor arrays have the potential to unlock the capabilities of high-density,high-throughputμECoG devices and overcome the limitations of passive multielectrode arrays.The review explores the potential innovations and applications ofμECoG devices,showcasing their effectiveness for both brain science research and clinical applications.展开更多
基金supported by the National Natural Science Foundation of China(T2425003,52272277 and T2241026).
文摘The pursuit of precisely recording and localizing neural activities in brain cortical regions drives the development of advanced electrocorticography(ECoG)devices.Remarkable progress has led to the emergence of micro-ECoG(μECoG)devices with sub-millimeter resolutions.This review presents the current research status,development directions,potential innovations and applications of high-density,high-throughputμECoG devices.First,we summarize the challenges associated with accurately recording single or multiple neurons using existingμECoG devices,including passive multielectrode and active transistor arrays.Second,we focus on cutting-edge advancements in passiveμECoG devices by discussing the design principles and fabrication strategies to optimize three key parameters:impedance,mechanical flexibility,and biocompatibility.Furthermore,recent findings highlight the need for further research and development in active transistor arrays,including silicon,metal oxide,and solution-gated transistors.These active transistor arrays have the potential to unlock the capabilities of high-density,high-throughputμECoG devices and overcome the limitations of passive multielectrode arrays.The review explores the potential innovations and applications ofμECoG devices,showcasing their effectiveness for both brain science research and clinical applications.
