生物电子学
材料科学
生物传感器
石墨烯
纳米技术
信号(编程语言)
电极
电阻抗
神经活动
制作
计算机科学
神经形态工程学
脑功能
生物医学工程
数码产品
信号处理
可扩展性
电子工程
灵敏度(控制系统)
脑植入物
柔性电子器件
神经系统
相容性(地球化学)
作者
Xin Liao,Dengyu Lu,Y N Wu,Yaxin Chen,L Wang,Xufang Wang,Wenrong Yan,Mengying Yan,Cheng Zhong,Yi Lu
标识
DOI:10.1002/adfm.202531604
摘要
ABSTRACT Accurate monitoring of physiological and neural electrophysiological signals is crucial for understanding brain function and its underlying biological mechanisms. Here, we report flexible laser‐induced graphene (LIG) bioelectronics that achieve mechanical compatibility with soft tissues and enable multimodal recording across species. Through optimized fabrication and multistep surface modification, we developed bilateral LIG (BiL‐LIG) biosensors with an extended working range (up to 40% improvement compared with single‐layer LIG) and high sensitivity at high strain (gauge factor of 3.77), as well as interfacially engineered LIG (IntE‐LIG) neural electrode arrays exhibiting high signal fidelity, markedly reduced impedance (up to 98.5% reduction), and long‐term in vivo stability (maintained signal quality for up to 4 weeks). The BiL‐LIG biosensors captured subtle movements and vital physiological signals, including heart rate and respiration, in human volunteers, non‐human primates, and rodents, while the IntE‐LIG electrodes enabled stable long‐term neural recordings in vivo. Integrating these devices yielded a flexible physiological‐electrophysiological monitoring system (PEMS) validated in a mouse model of epilepsy, which simultaneously tracked heart rate and neural activity during seizures and pharmacological intervention. This work establishes a scalable platform for multimodal bioelectronic integration, providing new opportunities for precise seizure detection and for advancing research into neuropsychiatric disorders and brain function.
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