Biocompatible conductors are important components for soft and stretchable bioelectronics
for digital healthcare, which have attracted extensive research efforts. Natural biopolymers …

Hydrogels have been attracting increasing attention for application in wearable electronics,
due to their intrinsic biomimetic features, highly tunable chemical–physical properties …

Natural biopolymer-based conductive hydrogels, which combine inherent renewable,
nontoxic features, biocompatibility and biodegradability of biopolymers, and excellent …

Pollution caused by nondegradable plastics has been a serious threat to environmental
sustainability. Natural polymers, which can degrade in nature, provide opportunities to …

Eutectogels are a new class of soft ion conductive materials that are attracting attention as
an alternative to conventional hydrogels and costly ionic liquid gels to build wearable …

The widespread adoption of renewable and sustainable elastomers in stretchable
electronics has been impeded by challenges in their fabrication and lacklustre performance …

Multifunctional conductive hydrogels have triggered extensive research interest owing to
their potential in artificial intelligence, human motion detection, soft electronic skins, and …

Over the past few decades, Bombyx mori silk fibroin has become a ubiquitous material for
applications ranging from biomedical devices to optics, electronics, and sensing, while also …

Flexible electronic devices to obtain accurate and efficient information interactions between
humans and machines have gained increasing attention in recent years. A series of soft …

High adhesion, flexibility, and performance stability are of great importance for wearable
electronics. Extensive efforts have been devoted to developing conductive poly (3, 4 …