Research Progress of Human Biomimetic Self‐Healing Materials

Humans can heal themselves after injury, which inspires researchers to develop bionic self‐healing materials. Such materials not only equipped with the self‐repair capacities akin to those of the human body, but also emulate the mechanical properties of human organs, including the tensile resilience...

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Veröffentlicht in:	Small (Weinheim an der Bergstrasse, Germany) Germany), 2025-01, Vol.21 (1), p.e2408199-n/a
Hauptverfasser:	Zhang, Jingyi, Sun, Fuyao, Xu, Jianhua, Zhao, Zi‐Han, Fu, Jiajun
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Sprache:	eng
Schlagworte:	biomimetic Biomimetic materials Biomimetic Materials - chemistry Biomimetics - methods Bionics Bond energy Corrosion prevention Fatigue Fatigue strength Healing Human performance Humans Mechanical properties Muscular fatigue Organs polymer materials Polymers - chemistry Protective coatings Self healing materials self‐healing Skin resistance Strain
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creator	Zhang, Jingyi Sun, Fuyao Xu, Jianhua Zhao, Zi‐Han Fu, Jiajun
description	Humans can heal themselves after injury, which inspires researchers to develop bionic self‐healing materials. Such materials not only equipped with the self‐repair capacities akin to those of the human body, but also emulate the mechanical properties of human organs, including the tensile resilience of muscles, the fatigue resistance of skin, and the elevated modulus typical of cartilage. Based on the design concept of imitating the structure of human organs, the bionic self‐healing material perfectly solves the problem of poor mechanical properties of self‐healing materials caused by weak bond energy and inter‐chain flow. This review discusses various organ‐inspired self‐healing materials in detail, summarizes their synthetic principles and introduces their fascinating mechanical properties. Finally, the application prospects of bionic self‐healing polymer materials, such as bio‐strain sensors, self‐healing anticorrosive coatings, biomedical detection, etc., are outlined. Considering the excellent comprehensive performance and multi‐functions of human biomimetic self‐healing polymers, more outstanding sustainable materials will be developed, accelerating research progress in self‐healing materials and realizing environmentally friendly products in multiple fields. This review introduces and discusses the recent research development of self‐healing materials inspired by various human organs (such as skin, muscle, cartilage, etc) in detail, summarizes their synthetic principles and their fascinating performances (mechanical properties and self‐healing ability), as well as outlines the multiple applications of these human biomimetic materials.
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subjects	biomimetic Biomimetic materials Biomimetic Materials - chemistry Biomimetics - methods Bionics Bond energy Corrosion prevention Fatigue Fatigue strength Healing Human performance Humans Mechanical properties Muscular fatigue Organs polymer materials Polymers - chemistry Protective coatings Self healing materials self‐healing Skin resistance Strain
title	Research Progress of Human Biomimetic Self‐Healing Materials
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