Bioinspired Two-in-one Nanotransistor Sensor for the Simultaneous Measurements of Electrical and Mechanical Cellular Responses

Overview

Journal Sci Adv

Specialties Biology
Science

Date 2022 Aug 24

PMID 36001656

Authors

Hongyan Gao

Feiyu Yang

Kianoosh Sattari

Xian Du

Tianda Fu

Shuai Fu

Xiaomeng Liu

Jian Lin

Yubing Sun

Jun Yao

Affiliations

Soon will be listed here.

Abstract

The excitation-contraction dynamics in cardiac tissue are the most important physiological parameters for assessing developmental state. We demonstrate integrated nanoelectronic sensors capable of simultaneously probing electrical and mechanical cellular responses. The sensor is configured from a three-dimensional nanotransistor with its conduction channel protruding out of the plane. The structure promotes not only a tight seal with the cell for detecting action potential via field effect but also a close mechanical coupling for detecting cellular force via piezoresistive effect. Arrays of nanotransistors are integrated to realize label-free, submillisecond, and scalable interrogation of correlated cell dynamics, showing advantages in tracking and differentiating cell states in drug studies. The sensor can further decode vector information in cellular motion beyond typical scalar information acquired at the tissue level, hence offering an improved tool for cell mechanics studies. The sensor enables not only improved bioelectronic detections but also reduced invasiveness through the two-in-one converging integration.

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