传感器
带宽(计算)
材料科学
响应度
电生理学
计算机科学
多路复用器
光电子学
电子工程
电气工程
光电探测器
电信
多路复用
工程类
神经科学
生物
作者
Amr Al Abed,Yuan Wei,Reem M. Almasri,Xinyue Lei,Han Wang,Josiah Firth,Yingge Chen,Nathalie Gouailhardou,Leonardo Silvestri,Torsten Lehmann,François Ladouceur,Nigel H. Lovell
标识
DOI:10.1088/1741-2552/ac8ed6
摘要
Objective.Biomedical instrumentation and clinical systems for electrophysiology rely on electrodes and wires for sensing and transmission of bioelectric signals. However, this electronic approach constrains bandwidth, signal conditioning circuit designs, and the number of channels in invasive or miniature devices. This paper demonstrates an alternative approach using light to sense and transmit the electrophysiological signals.Approach.We develop a sensing, passive, fluorophore-free optrode based on the birefringence property of liquid crystals (LCs) operating at the microscale.Main results.We show that these optrodes can have the appropriate linearity (µ± s.d.: 99.4 ± 0.5%,n = 11 devices), relative responsivity (µ± s.d.: 57 ± 12%V-1,n = 5 devices), and bandwidth (µ± s.d.: 11.1 ± 0.7 kHz,n = 7 devices) for transducing electrophysiology signals into the optical domain. We report capture of rabbit cardiac sinoatrial electrograms and stimulus-evoked compound action potentials from the rabbit sciatic nerve. We also demonstrate miniaturisation potential by fabricating multi-optrode arrays, by developing a process that automatically matches each transducer element area with that of its corresponding biological interface.Significance.Our method of employing LCs to convert bioelectric signals into the optical domain will pave the way for the deployment of high-bandwidth optical telecommunications techniques in ultra-miniature clinical diagnostic and research laboratory neural and cardiac interfaces.
科研通智能强力驱动
Strongly Powered by AbleSci AI