The past two decades have witnessed remarkable progress in flexible and stretchable bioelectronics,which have substantially improved the integration of implantable devices with biological tissues[1-5].Compared with ri...The past two decades have witnessed remarkable progress in flexible and stretchable bioelectronics,which have substantially improved the integration of implantable devices with biological tissues[1-5].Compared with rigid metallic electrodes,flexible probes offer superior mechanical compliance,reduce immune rejection,and enable long-term monitoring of physiological signals[6-9].Among various device geometries,fiber-shaped probes are particularly advantageous due to their small dimensions,which minimize immune responses,and their capability for multifunctional integration[10-14].展开更多
基金supported by the National Natural Science Foundation of China(62121003,T2293730,T2293731,62171434,62333020,62401083,62471291,and 62501572)the National Key Research and Development Program of China(2022YFC2402501 and 2022YFB3205602)+3 种基金the Major Program of Scientific and Technical Innovation 2030(2021ZD02016030)the Joint Foundation Program of the Chinese Academy of Sciences(8091A170201)the Scientific,Instrument Developing Project of the Chinese Academy of Sciences(PTYQ2024BJ0009)the Natural Science Foundation of Beijing(F252069)。
文摘The past two decades have witnessed remarkable progress in flexible and stretchable bioelectronics,which have substantially improved the integration of implantable devices with biological tissues[1-5].Compared with rigid metallic electrodes,flexible probes offer superior mechanical compliance,reduce immune rejection,and enable long-term monitoring of physiological signals[6-9].Among various device geometries,fiber-shaped probes are particularly advantageous due to their small dimensions,which minimize immune responses,and their capability for multifunctional integration[10-14].
