Stimuli-responsive Hydrogels for Bone Tissue Engineering

Overview

Journal Biomater Transl

Specialty Biomedical Engineering

Date 2024 Dec 30

PMID 39734705

Authors

Congyang Xue

Liping Chen

Nan Wang

Heng Chen

Wenqiang Xu

Zhipeng Xi

Qing Sun

Ran Kang

Lin Xie

Xin Liu

Affiliations

Soon will be listed here.

Abstract

The treatment of bone defects remains a great clinical challenge. With the development of science and technology, bone tissue engineering technology has emerged, which can mimic the structure and function of natural bone tissues and create solutions for repairing or replacing human bone tissues based on biocompatible materials, cells and bioactive factors. Hydrogels are favoured by researchers due to their high water content, degradability and good biocompatibility. This paper describes the hydrogel sources, roles and applications. According to the different types of stimuli, hydrogels are classified into three categories: physical, chemical and biochemical responses, and the applications of different stimuli-responsive hydrogels in bone tissue engineering are summarised. Stimuli-responsive hydrogels can form a semi-solid with good adhesion based on different physiological environments, which can carry a variety of bone-enhancing bioactive factors, drugs and cells, and have a long retention time in the local area, which is conducive to a long period of controlled release; they can also form a scaffold for constructing tissue repair, which can jointly promote the repair of bone injury sites. However, it also has many defects, such as poor biocompatibility, immunogenicity and mechanical stability. Further studies are still needed in the future to facilitate its clinical translation.

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