生物电子学
电容器
电容感应
无线
材料科学
电容
电介质
生物传感器
电容耦合
纳米技术
联轴节(管道)
生物相容性材料
离子液体
微电极
电子工程
离子键合
光电子学
小型化
纳米传感器
转导(生物物理学)
LC电路
电气工程
信号(编程语言)
数码产品
电子线路
串扰
离子
电化学
计算机科学
电阻抗
天线(收音机)
感应耦合
灵敏度(控制系统)
导电聚合物
电极
压力传感器
作者
Ji Hong Kim,Haerim Kim,Jaewon Rhee,Joo Sung Kim,Hanbin Choi,Won Hyuk Choi,Yoseph Park,Jong Hwi Kim,So Young Kim,Seungyoung Ahn,Do Hwan Kim
标识
DOI:10.1038/s41467-026-70331-4
摘要
Wireless bioelectronics demand transduction strategies that are simultaneously sensitive, noise-resilient, and biologically safe. Conventional wireless sensors typically rely on dielectric capacitors with inherently low capacitance, necessitating operation at MHz frequencies. Such high-frequency coupling often introduces electromagnetic interference, tissue heating, and degraded signal fidelity in biological environments. Here we present a wireless low-frequency electrochemical sensing (WiLECS) platform that couples ionic dynamics with low-frequency LC resonant circuits. The device combines a biocompatible ion gel, composed of a choline-malate ionic liquid embedded in a chitosan matrix with functionalized Au nanoparticles, with a miniaturized LC antenna. Unlike conventional capacitive sensors, WiLECS employs piezo-driven ion redistribution to modulate the dielectric environment of the circuit, enabling sustainable wireless transduction below 1 MHz with high sensitivity and reliability. This approach directly bridges ionic dynamics and electronic resonance, allowing mechanical stimuli to be transduced into biologically safe low-frequency electronic signals. As proof of concept, we demonstrate real-time wireless blood-pressure monitoring in artificial arteries with atherosclerotic plaque, showing resolution of subtle pressure variations under clinically relevant conditions.
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