3D-printed Epifluidic Electronic Skin for Machine Learning-powered Multimodal Health Surveillance

Overview

Journal Sci Adv

Specialties Biology
Science

Date 2023 Sep 13

PMID 37703361

Authors

Yu Song

Roland Yingjie Tay

Jiahong Li

Changhao Xu

Jihong Min

Ehsan Shirzaei Sani

Gwangmook Kim

Wenzheng Heng

InHo Kim

Wei Gao

Affiliations

Soon will be listed here.

Abstract

The amalgamation of wearable technologies with physiochemical sensing capabilities promises to create powerful interpretive and predictive platforms for real-time health surveillance. However, the construction of such multimodal devices is difficult to be implemented wholly by traditional manufacturing techniques for at-home personalized applications. Here, we present a universal semisolid extrusion-based three-dimensional printing technology to fabricate an epifluidic elastic electronic skin (e-skin) with high-performance multimodal physiochemical sensing capabilities. We demonstrate that the e-skin can serve as a sustainable surveillance platform to capture the real-time physiological state of individuals during regular daily activities. We also show that by coupling the information collected from the e-skin with machine learning, we were able to predict an individual's degree of behavior impairments (i.e., reaction time and inhibitory control) after alcohol consumption. The e-skin paves the path for future autonomous manufacturing of customizable wearable systems that will enable widespread utility for regular health monitoring and clinical applications.

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