Decellularization of various tissues and organs through chemical methods

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-10-05 DOI:10.1016/j.tice.2024.102573

Tayebeh Sadat Tabatabai , Majid Salehi , Leila Rezakhani , Zohreh Arabpour , Ali R. Djalilian , Morteza Alizadeh

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Abstract

Due to the increase in demand for donor organs and tissues during the past 20 years, new approaches have been created. These methods include, for example, tissue engineering in vitro and the production of regenerative biomaterials for transplantation. Applying the natural extracellular matrix (ECM) as a bioactive biomaterial for clinical applications is a unique approach known as decellularization technology. Decellularization is the process of eliminating cells from an extracellular matrix while preserving its natural components including its structural and functional proteins and glycosaminoglycan. This can be achieved by physical, chemical, or biological processes. A naturally formed three-dimensional structure with a biocompatible and regenerative structure is the result of the decellularization process. Decreasing the biological factors and antigens at the transplant site reduces the risk of adverse effects including inflammatory responses and immunological rejection. Regenerative medicine and tissue engineering applications can benefit from the use of decellularization, a promising approach that provides a biomaterial that preserves its extracellular matrix.

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通过化学方法使各种组织和器官脱细胞。

过去 20 年间，由于对捐献器官和组织的需求不断增加，新的方法应运而生。这些方法包括体外组织工程和生产用于移植的再生生物材料等。将天然细胞外基质（ECM）作为生物活性生物材料应用于临床是一种独特的方法，被称为脱细胞技术。脱细胞是将细胞从细胞外基质中去除，同时保留其天然成分（包括结构性和功能性蛋白质以及糖胺聚糖）的过程。这可以通过物理、化学或生物过程来实现。脱细胞过程的结果是自然形成具有生物相容性和再生性的三维结构。减少移植部位的生物因子和抗原可降低不良反应的风险，包括炎症反应和免疫排斥反应。再生医学和组织工程应用可从脱细胞技术中获益，这种前景广阔的方法可提供一种保留细胞外基质的生物材料。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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