| Literature DB >> 34045731 |
Enming Song1,2, Zhaoqian Xie3,4, Wubin Bai5,6, Haiwen Luan5, Bowen Ji7, Xin Ning8, Yu Xia9, Janice Mihyun Baek9, Yujin Lee9, Raudel Avila10, Huang-Yu Chen5, Jae-Hwan Kim9, Surabhi Madhvapathy5, Kuanming Yao2, Dengfeng Li2, Jingkun Zhou2, Mengdi Han5, Sang Min Won11, Xinyuan Zhang12, Daniel J Myers5,13, Yongfeng Mei12, Xu Guo3,4, Shuai Xu5,13, Jan-Kai Chang14, Xinge Yu15, Yonggang Huang16,17,18,19, John A Rogers20,21,22,23,24.
Abstract
Evaluating the biomechanics of soft tissues at depths well below their surface, and at high precision and in real time, would open up diagnostic opportunities. Here, we report the development and application of miniaturized electromagnetic devices, each integrating a vibratory actuator and a soft strain-sensing sheet, for dynamically measuring the Young's modulus of skin and of other soft tissues at depths of approximately 1-8 mm, depending on the particular design of the sensor. We experimentally and computationally established the operational principles of the devices and evaluated their performance with a range of synthetic and biological materials and with human skin in healthy volunteers. Arrays of devices can be used to spatially map elastic moduli and to profile the modulus depth-wise. As an example of practical medical utility, we show that the devices can be used to accurately locate lesions associated with psoriasis. Compact electronic devices for the rapid and precise mechanical characterization of living tissues could be used to monitor and diagnose a range of health disorders.Entities:
Year: 2021 PMID: 34045731 DOI: 10.1038/s41551-021-00723-y
Source DB: PubMed Journal: Nat Biomed Eng ISSN: 2157-846X Impact factor: 25.671