3D Printing of a Tissue-Engineered Structure Intended to Replace Cartilage Defects

Journal Biomed Pub Date : 2023-11-20 DOI:10.33647/2713-0428-19-3e-52-58

S. A. Machulin, T. Astrelina, D. Usupzhanova, A. O. Zavialov, T. Malivanova, А. I. Golovkova, I. Kobzeva, Y. Suchkova, V. Brunchukov, A. Rastorgueva, V. Nikitina, E. E. Lomonosova, O. G. Mihadarkina, A. Samoilov

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Abstract

This article describes the process of developing a tissue-engineered structure that meets the biocompatibility and biodegradation parameters necessary for replacing cartilage tissue defects. The study was carried out using 3D bioprinting technology, which represents a promising research direction in the biomedical field. It is known that, due to the specifics of its structure, cartilage tissue is not capable of complete regeneration of damage. The methods currently used for treating arthrosis are associated with a number of limitations and disadvantages, which makes research aimed at developing alternative methods for arthrosis treatment particularly relevant. The development of tissue-engineered structures by 3D bioprinting requires the materials not only certified for medical use but also exhibiting biocompatibility and biodegradation properties. Polylactide (PLA) and sodium alginate satisfy the above requirements; moreover, their availability and economic affordability make them one of the most popular materials for 3D bioprinting.

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三维打印组织工程结构，用于替代软骨缺陷

本文介绍了一种组织工程结构的开发过程，该结构符合替代软骨组织缺损所需的生物相容性和生物降解参数。研究采用三维生物打印技术进行，该技术是生物医学领域前景广阔的研究方向。众所周知，由于其结构的特殊性，软骨组织无法在损伤后完全再生。目前用于治疗关节病的方法存在许多局限性和弊端，因此，旨在开发关节病治疗替代方法的研究尤为重要。利用三维生物打印技术开发组织工程结构，不仅需要经过医疗认证的材料，还需要具有生物相容性和生物降解特性的材料。聚乳酸（PLA）和海藻酸钠符合上述要求；此外，它们的可获得性和经济实惠性使其成为最受欢迎的三维生物打印材料之一。

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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Journal Biomed

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