Ying Chen

TL;DR: A strategy for biocompatible flexible temperature sensors, inspired by skin, possessing the excellent permeability of air and high quality of water-proof by using semipermeable film with porous structures as substrate is reported.

TL;DR: The results show the peak-to-peak voltage can reach as high as 3 V when the ultra-flexible piezoelectric device is fixed from left ventricular apex to right ventricle, demonstrating the possibility and feasibility of fully using the biomechanical energy from heart motion in human body for sustainably driving implantable devices.

TL;DR: The authors propose all-in-one suspension structure to achieve the stretchability and conformability for surrounding environment, and they propose a two-step transfer printing method for hybrid integrating III-V group emitting elements, Si-based photodetector, and interconnects.

TL;DR: A theoretical model via the virtual work principle for predicting the precise blood pressure and suppressing motion artifacts is introduced, and optical difference in the frequency domain for stable optical measurements in terms of skin-like devices is proposed.