Hatton A, Nevelos J E, Nevelos A A, Banks R E, Fisher J, Ingham E
School of Biochemistry & Molecular Biology, University of Leeds, UK.
Biomaterials. 2002 Aug;23(16):3429-40. doi: 10.1016/s0142-9612(02)00047-9.
The aims of this study were to investigate the tissues from uncemented Mittelmeier alumina ceramic-on-ceramic total hip replacements using histological methods and to isolate and characterise the ceramic wear debris using laser capture microdissection and electron microscopy. Tissues from around 10 non-cemented Mittelmeier alumina ceramic on ceramic THRs were obtained from patients undergoing revision surgery. Tissues were also obtained from six patients who were undergoing revisions for aseptic loosening of Charnley, metal-on-polyethylene prostheses. Tissue sections were analysed using light microscopy to determine histological reactions and also the location and content of alumina ceramic wear debris. Tissue samples were extracted from sections using laser capture microdissection and the characteristics of the particles subsequently analysed by TEM and SEM. The tissues from around the ceramic-on-ceramic prostheses all demonstrated the presence of particles, which could be seen as agglomerates inside cells or in distinct channels in the tissues. The tissues from the ceramic-on-ceramic retrievals had a mixed pathology with areas that had no obvious pathology, areas that were relatively rich in macrophages and over half of the tissues had in the region of 60% necrosis/necrobiosis. In comparison, the Charnley tissues showed a granulomatous cellular reaction involving a dense macrophage infiltrate and the presence of giant cells and < 30% necrosis/necrobiosis. The tissues from the ceramic prostheses also showed the presence of neutrophils and lymphocytes, which were not evident in the tissues from the Charnley retrievals. There were significantly more macrophages (p < 0.05), and giant cells (p < 0.01) in the Charnley tissues and significantly more neutrophils (p < 0.01) in the ceramic-on-ceramic tissues. TEM of the laser captured tissue revealed the presence of very small alumina wear debris in the size range 5-90 nm, mean size + SD of 24 +/- 19nm whereas SEM (lower resolution) revealed particles in the 0.05-3.2 microm size range. This is the first description of nanometre sized ceramic wear particles in retrieval tissues. The bi-modal size range of alumina ceramic wear debris overlapped with the size ranges commonly observed with metal particles (10-30 nm) and particles of ultra-high molecular weight polyethylene (0.1-1,000 microm). It is possible that the two size ranges of contributed to the mixed tissue pathology observed. It is speculated that the two types of ceramic wear debris are generated by two different wear mechanisms in vivo, under normal articulating conditions, relief polishing wear and very small wear debris is produced. while under conditions of microseparation of the head and cup and rim contact, intergranular and intragranular fracture and larger wear particles are generated.
本研究的目的是使用组织学方法研究非骨水泥型米特尔迈尔氧化铝陶瓷对陶瓷全髋关节置换术的组织,并使用激光捕获显微切割和电子显微镜分离和表征陶瓷磨损颗粒。从接受翻修手术的患者中获取了约10个非骨水泥型米特尔迈尔氧化铝陶瓷对陶瓷全髋关节置换术周围的组织。还从6名因查恩利金属对聚乙烯假体无菌性松动而接受翻修的患者身上获取了组织。使用光学显微镜分析组织切片,以确定组织学反应以及氧化铝陶瓷磨损颗粒的位置和含量。使用激光捕获显微切割从切片中提取组织样本,随后通过透射电子显微镜(TEM)和扫描电子显微镜(SEM)分析颗粒的特征。陶瓷对陶瓷假体周围的组织均显示存在颗粒,这些颗粒可在细胞内聚集体或组织中的不同通道中看到。陶瓷对陶瓷翻修组织的病理表现混合,有无明显病理的区域、巨噬细胞相对丰富的区域,超过一半的组织有60%左右的坏死/渐进性坏死。相比之下,查恩利组织显示出肉芽肿性细胞反应,包括密集的巨噬细胞浸润、巨细胞的存在以及<30%的坏死/渐进性坏死。陶瓷假体组织中还显示存在中性粒细胞和淋巴细胞,而在查恩利翻修组织中则不明显。查恩利组织中的巨噬细胞(p<0.05)和巨细胞(p<0.01)明显更多,陶瓷对陶瓷组织中的中性粒细胞(p<0.01)明显更多。激光捕获组织的透射电子显微镜显示存在尺寸范围为5 - 90纳米的非常小的氧化铝磨损颗粒,平均尺寸±标准差为24±19纳米,而扫描电子显微镜(分辨率较低)显示颗粒尺寸在0.05 - 3.2微米范围内。这是在翻修组织中首次描述纳米级陶瓷磨损颗粒。氧化铝陶瓷磨损颗粒的双峰尺寸范围与金属颗粒(10 - 30纳米)和超高分子量聚乙烯颗粒(0.1 - 1000微米)通常观察到的尺寸范围重叠。有可能这两种尺寸范围导致了观察到的混合组织病理。据推测,两种类型的陶瓷磨损颗粒是在体内正常关节活动条件下由两种不同的磨损机制产生的,即 relief polishing磨损产生非常小的磨损颗粒,而在股骨头与髋臼杯微分离和边缘接触的条件下,产生晶间和晶内骨折以及较大的磨损颗粒。
