β-磷酸三钙复合材料在骨科中的应用现状。
Current application of β-tricalcium phosphate composites in orthopaedics.
机构信息
Center for Medical Device Evaluation of State Food and Drug Administration, Beijing, China.
出版信息
Orthop Surg. 2012 Aug;4(3):139-44. doi: 10.1111/j.1757-7861.2012.00189.x.
Abstract
Presently, bioceramic materials have been extensively used in spinal surgery as bone grafts; however, there are some limitations for bioceramic materials. Calcium sulfate is rapidly absorbed in vivo, the degradation of which often occurs prior to the formation of new bones. Hydroxyapatite (HA) is hardly absorbed, which blocks the formation of new bones and remodeling, and results in poor local stability or permanent stress concentration. Only β-tricalcium phosphate (β-TCP) is relatively balanced between scaffold absorption and bone formation. And it is a good biodegradable ceramic material that could supply a large quantity of calcium ion and sulfate ion as well as scaffold structure for bone regeneration. However, the problem of single β-TCP is lack of osteoinductivity and osteogenicity, which restricts its application. Therefore β-TCP composite materials have been used in the field of orthopaedics in recent decades, which fully use excellent properties of other bone repairing materials, such as biodegradability, osteoinductivity, osteogenicity and osteoconductivity. These materials make up for the deficiencies of single β-TCP and endow β-TCP with more biological and physical properties.
摘要
目前,生物陶瓷材料已广泛应用于脊柱外科作为骨移植材料;然而,生物陶瓷材料也存在一些局限性。硫酸钙在体内吸收迅速,其降解往往发生在新骨形成之前。羟基磷灰石(HA)几乎不被吸收,这会阻碍新骨的形成和重塑,导致局部稳定性差或永久性应力集中。只有β-磷酸三钙(β-TCP)在支架吸收和骨形成之间相对平衡。它是一种良好的可生物降解陶瓷材料,可为骨再生提供大量的钙离子和硫酸根离子以及支架结构。然而,β-TCP 的单一性问题是缺乏成骨诱导性和成骨性,这限制了它的应用。因此,近几十年来,β-TCP 复合材料已应用于骨科领域,充分利用了其他骨修复材料的优良性能,如生物降解性、成骨诱导性、成骨性和成骨传导性。这些材料弥补了单一β-TCP 的不足,赋予β-TCP 更多的生物学和物理性能。
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