Next generation tissue-engineered skin scaffolds promise to provide sensory restoration
through electrical stimulation in addition to effectively rebuilding and repairing skin. The …

Using smart electroactive hydrogels with emerging bioelectronics to monitor wound status
wirelessly in real-time is a promising approach as an unremitting therapy for refractory …

Inherently tissue‐like feature and multifunctional property of hydrogels make themself
excellent materials for flexible electronics. However, conventional hydrogels with insufficient …

Wounds at joints are difficult to treat and tend to recover more slowly due to the frequent
motions. When using traditional hydrogel dressings, they are easy to crack and undergo …

Chronic diabetic wound with persistent inflammatory responses is still a serious threat to
human health and life. Ideal wound dressings can be applied not only for covering the injury …

Flexible epidermal sensors based on conductive hydrogels hold great promise for various
applications, such as wearable electronics and personal healthcare monitoring. However …

Electronic skins (e‐skins) have the potential to turn into breakthroughs in biomedical
applications. Herein, a novel acellular dermal matrix (ADM)‐based bioelectronic skin (e …

As an important part of artificial intelligence, electronic skin has received more and more
attention recently. However, two serious issues, slow self-healing and lack of direction …

Flexible epidermic sensors made from conductive hydrogels are holding bright potential in
personalized healthcare, multifunctional electronic skins, and human‐machine interfaces …

Flexible bioelectronics for biomedical applications requires a stretchable, conductive, self-
healable, and biocompatible material that can be obtained by cost-effective chemicals and …