Porous bioactive glass matrix in reconstruction of articular osteochondral defects.

Annales chirurgiae et gynaecologiae Pub Date : 1999-01-01
H O Ylänen, T Helminen, A Helminen, J Rantakokko, K H Karlsson, H T Aro
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Abstract

Background and aims: This study was carried out to investigate the use of porous bioactive glass implants in promotion of articular cartilage and subchondral bone repair in large osteochondral joint defects.

Material and methods: Two conical osteochondral defects (top diameter 3.0-3.2 mm) were drilled into the patellar grooves of the distal femurs in the rabbit. The defects, extending (approximately 6-7 mm) from the surface of the articular cartilage to the subchondral marrow space, were reconstructed with size-matched porous conical implants made of sintered bioactive glass microspheres (microsphere diameter 250-300 microm, structural implant compression strength 20-25 MPa) using press-fit technique. The implant surface was smoothened to the level of the surrounding articular cartilage. One of the two defects in each femur was left empty to heal naturally and to serve as the control. At 8 weeks, the defect healing was analyzed with use of a semiquantitative histological grading system, histomorphometry of subchondral bone repair, back-scattered electron imaging of scanning electron microscopy (BEI-SEM), and a microindentation test for characterization for the stiffness properties of the cartilage repair tissue.

Results: The porous structure of the bioactive glass implants, extending from the articular defect of the patellar groove into the posterior cortex of the femur, was extensively filled by new bone. Cartilage repair varied from near-complete healing by hyaline cartilage to incomplete healing predominantly by fibrocartilage or fibrous tissue. There were, however, no statistical differences in the histological scores of repair between the glass-filled and control defects, although the sum of the averages of each category was lowest for the bioactive glass filled defects. The indentation stiffness values of all the defects were also significantly lower than that of normal cartilage on the patellar groove.

Conclusions: Porous textures made by sintering bioactive glass microspheres may expand the opportunities in reconstruction of deep osteochondral defects of weight-bearing joints. The implants act mechanically as a supporting scaffold and facilitate the penetration of stromal bone marrow cells and their chondrogenic and osteogenic differentiation. Ionic properties of the bioactive glasses make the substances highly potential even as delivery systems for adjunct growth factor therapy.

多孔生物活性玻璃基质在关节骨软骨缺损重建中的应用。
背景与目的:本研究旨在探讨多孔生物活性玻璃植入物在促进大骨软骨关节缺损的关节软骨和软骨下骨修复中的应用。材料与方法:在兔股骨远端髌骨沟内钻取2个锥形骨软骨缺损(顶径3.0 ~ 3.2 mm)。缺损从关节软骨表面延伸至软骨下骨髓间隙(约6-7 mm),采用加压配合技术,用烧结生物活性玻璃微球(微球直径250-300微米,结构种植体抗压强度20-25 MPa)制成尺寸匹配的多孔锥形种植体进行重建。将种植体表面磨平至周围关节软骨的水平。每根股骨的两个缺陷中有一个是空的,以自然愈合并作为对照。8周时,使用半定量组织学分级系统、软骨下骨修复组织形态学测量、扫描电镜背散射电子成像(BEI-SEM)和微压痕测试来分析软骨修复组织的刚度特性。结果:生物活性玻璃假体的多孔结构从髌骨沟的关节缺损延伸到股骨后皮质,被新骨广泛填充。软骨修复从透明软骨的接近完全愈合到主要由纤维软骨或纤维组织的不完全愈合不等。然而,在修复的组织学评分上,玻璃填充和对照缺陷之间没有统计学差异,尽管生物活性玻璃填充缺陷的每一类平均值的总和是最低的。所有缺损的压痕刚度值也明显低于髌沟正常软骨的压痕刚度值。结论:生物活性玻璃微球烧结制备多孔结构可扩大负重关节深部骨软骨缺损的修复机会。植入物机械上充当支撑支架,促进基质骨髓细胞的渗透及其软骨和成骨分化。生物活性玻璃的离子特性使这些物质具有很高的潜力,甚至可以作为辅助生长因子治疗的输送系统。
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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