骨植入用多孔磷酸钙生物陶瓷的研究进展

A. Naqshbandi, I. Sopyan, Gunawan
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引用次数: 30

摘要

本文简要介绍了多孔磷酸钙生物陶瓷的制备技术、性能和骨植入应用等方面的最新专利和期刊。生物活性陶瓷是一类能够直接与宿主骨结合的材料。这些材料很容易被人体吸收,被认为是可生物降解的。研究表明,羟基磷灰石或羟基磷灰石(HA)与磷酸三钙(TCP)的复合材料制备的人工骨具有良好的生物相容性和接近人骨的性能,是天然骨的理想替代品。由透明质酸制成的生物陶瓷以致密和多孔的形式存在。多孔磷酸钙生物陶瓷的制备在临床骨科领域已经取得了一定的进展。这些努力的实现可以从许多关于制备用于骨植入应用的多孔磷酸钙生物陶瓷的方法的专利申请中观察到。许多多孔透明质酸陶瓷已被开发用于组织工程和药物输送系统。多孔体在人体内是可分解的,为细胞的增殖和生长提供了一个表面,这些细胞从周围的组织中渗透出来,这样新的骨骼就会生长到毛孔中,从而防止植入物的任何移动或松动。因此,它们可以用于填充受损骨,修复骨折骨,甚至可以用作硬组织替代物。多孔支架的制备采用了几种加工技术。其中突出的技术有凝胶铸造、滑动铸造、莰烯基冷冻铸造和聚合物-海绵铸造。
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Development of Porous Calcium Phosphate Bioceramics for Bone Implant Applications: A Review
The present review briefly outlines the most recent patents and journals on various aspects of porous calcium phosphate bioceramics including techniques of preparation, properties and bone implant applications. Bioactive ceramics are a class of materials that have capability to bond directly with the host bone. These materials can be easily assimilated by the body and are considered to be biodegradable. Researches have revealed that artificial bones made from hydroxya- patite or a combination of hydroxyapatite (HA) and tricalcium phosphate (TCP) is a perfect substitute for natural bone owing to its excellent biocompatibility and properties close to that of human bone. Bioceramics made of HA are available in dense and porous forms. Several efforts on the fabrication of porous calcium phosphate bioceramics have been carried upon in the field of clinical orthopaedics. The realisation of these efforts can be observed from the fact that numerous pat- ents have been filed on methods of preparing porous calcium phosphate bioceramics for bone implant applications. A number of porous HA ceramics have been developed for applications in both tissue engineering and drug delivery sys- tems. Porous bodies are decomposable in human body and provide a surface for proliferation and growth of cells that are infiltrated from the surrounding tissues so that a new bone grows into the pores and prevents any movement or loosening of the implants. Consequently, these can be used for filling the damaged bone, repair of fractured bone and even can be used as hard tissue replacements. Several processing techniques have been employed for fabrication of porous scaffolds. Among prominent techniques are gel casting, slip casting, camphene-based freeze casting and polymeric-sponge method.
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