骨外科用现代高分子复合材料:问题与展望

P. A. Povernov, L. Shibryaeva, L. R. Lusova, A. Popov
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This review summarizes the research works devoted to the creation of materials used for bone implants and issues involved in their practical testing, as well as analyzes and synthesizes data of scientific articles on the following topics: rationale for the use of biodegradable materials in bone surgery; biodegradation and bioreparation bone graft processes; requirements for degradable polymer composite materials (PCMs) for biomedical applications; overview of polymeric materials suitable for use in implant practice; impact of modifications of the PCM on the structure and biological activity of the material in biological media; effect of exhaust and heat treatment on the molecular structure of polyalkanoates.Results. The most promising biodegradable resorbable materials for reparative bone surgery to date are compared. The requirements for these types of materials are formulated and a rationale for their use is provided that takes into account the advantages over traditional metal and ceramic implants. The features of the kinetics and mechanism of biodegradation of implants in their interaction with the bone biological environment of the body from the moment of implant insertion to complete wound healing are considered. As a result of the analysis, factors that may affect the activity of implant decomposition and methods of adjusting the decomposition rate and mechanical characteristics of the material, such as chemical functionalization, the creation of block copolymers, the inclusion of fibers and mineral fillers in the composite, as well as heat treatment and extraction of the composite at the manufacturing stage, were identified. Among the main factors, the influence of the structure of the composite material on its biological activity during interaction with biological media was evaluated. 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引用次数: 0

摘要

目标。探讨基于聚合物组合物制备骨外科用现代骨整形材料的主要问题及前景。本文综述了用于骨植入材料的研究工作及其实际测试中涉及的问题,并分析和综合了以下主题的科学文章数据:在骨外科中使用生物可降解材料的基本原理;骨移植过程的生物降解和生物修复;生物医学用可降解高分子复合材料(PCMs)的要求;适用于种植体实践的高分子材料综述PCM修饰对生物介质中材料的结构和生物活性的影响;排气和热处理对聚烷酸酯分子结构的影响。比较了迄今为止最有希望用于骨修复手术的生物可降解可吸收材料。对这些类型的材料的要求进行了阐述,并提供了其使用的基本原理,考虑到与传统金属和陶瓷植入物相比的优势。考虑了从植入到伤口愈合过程中,植入物与体内骨生物环境相互作用过程中生物降解的动力学特征和机制。通过分析,确定了可能影响植入物分解活性的因素以及调整材料分解速率和机械特性的方法,例如化学功能化、嵌段共聚物的产生、复合材料中纤维和矿物填料的包含以及复合材料在制造阶段的热处理和提取。在主要因素中,评价了复合材料的结构对其与生物介质相互作用时生物活性的影响。高分子材料中,主要关注的是在医学上广泛应用的最常见的可生物降解聚合物:微生物来源的聚羟基丁酸酯(PHB)、聚乳酸(PLA)等基于聚乳酸、聚己内酯(PCL)的聚合物。考察了羟基磷灰石(HAP)、几丁质和壳聚糖、β-磷酸三钙(β-TCF)等添加剂对其改性的影响。基于PHB的材料由于其对无毒产物(二氧化碳和水)的完全生物降解性和良好的生物相容性而被认为是最有前途的材料。然而,现有的PHB复合材料也存在着脆弱性、低弹性、加工过程中高温暴露、植入成型、灭菌等不稳定等缺点,无论是在聚合物改性方面还是在组合物的组成方面都需要改进。该综述考虑了实现完美植入物所需材料性能的方法。对种植体的主要要求是优化骨再生基质的吸收时间,使骨再生基质的吸收与骨再生过程及时同步。为了达到这些要求,有必要应用技术,包括通过影响化学成分和结构来改性聚合物复合材料;填料介绍;采用化学功能化、取向萃取、热处理。基于生物可降解聚合物的骨材料的成功使用是基于对种植体组合物中各种成分的作用机制的准确理解,以及严格遵守种植技术日益严格的监管要求。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Modern polymer composite materials for bone surgery: Problems and prospects
Objectives. To discuss the main problems and prospects of creating modern osteoplastic materials based on polymer compositions used for bone surgery.Methods. This review summarizes the research works devoted to the creation of materials used for bone implants and issues involved in their practical testing, as well as analyzes and synthesizes data of scientific articles on the following topics: rationale for the use of biodegradable materials in bone surgery; biodegradation and bioreparation bone graft processes; requirements for degradable polymer composite materials (PCMs) for biomedical applications; overview of polymeric materials suitable for use in implant practice; impact of modifications of the PCM on the structure and biological activity of the material in biological media; effect of exhaust and heat treatment on the molecular structure of polyalkanoates.Results. The most promising biodegradable resorbable materials for reparative bone surgery to date are compared. The requirements for these types of materials are formulated and a rationale for their use is provided that takes into account the advantages over traditional metal and ceramic implants. The features of the kinetics and mechanism of biodegradation of implants in their interaction with the bone biological environment of the body from the moment of implant insertion to complete wound healing are considered. As a result of the analysis, factors that may affect the activity of implant decomposition and methods of adjusting the decomposition rate and mechanical characteristics of the material, such as chemical functionalization, the creation of block copolymers, the inclusion of fibers and mineral fillers in the composite, as well as heat treatment and extraction of the composite at the manufacturing stage, were identified. Among the main factors, the influence of the structure of the composite material on its biological activity during interaction with biological media was evaluated. Of polymer materials, the main attention is paid to the most common biodegradable polymers widely used in medicine: polyhydroxybutyrate (PHB) of microbiological origin, polylactide (PLA) and other polymers based on polylactic acid, polycaprolactone (PCL). The effect of their modification by such additives as hydroxyapatite (HAP), chitin and chitosan, and beta-tricalcium phosphate (β-TCF) is considered. Materials based on PHB are concluded as the most promising due to their complete biodegradability to non-toxic products (carbon dioxide and water) and good biocompatibility. Nevertheless, existing compositions based on PHB are not without disadvantages, which include fragility, low elasticity, unstable behavior under high-temperature exposure during processing, implant molding, sterilization, etc., which requires improvement both in terms of polymer modification and in terms of composition of compositions.Conclusions. The review considers approaches to achieving the properties of materials required for perfect implants. The main requirements for implants are optimization of the time of resorption of the osteoplastic matrix, facilitating the resorption of the osteoplastic matrix synchronized in time with the process of bone regeneration. To achieve these requirements, it is necessary to apply technologies that include modification of polymer composite materials by affecting the chemical composition and structure; introduction of fillers; use of chemical functionalization, orientation extraction, heat treatment. The success of using bone materials based on biodegradable polymers is based on an accurate understanding of the mechanism of action of various components of the implant composition and strict compliance with the tightening regulatory requirements of implantation technology.
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