Department of Orthopedic Surgery, Rush University Medical Center, Chicago, IL, USA.
University of Illinois College of Medicine, Rockford, IL, USA.
Clin Orthop Relat Res. 2021 Sep 1;479(9):2083-2096. doi: 10.1097/CORR.0000000000001819.
Fretting and corrosion in metal-on-polyethylene total hip arthoplasty (THA) modular junctions can cause adverse tissue reactions that are responsible for 2% to 5% of revision surgeries. Damage within cobalt-chromium-molybdenum (CoCrMo) alloy femoral heads can progress chemically and mechanically, leading to damage modes such as column damage, imprinting, and uniform fretting damage. At present, it is unclear which of these damage modes are most detrimental and how they may be linked to implant alloy metallurgy. The alloy microstructure exhibits microstructural features such as grain boundaries, hard phases, and segregation bands, which may enable different damage modes, higher material loss, and the potential risk of adverse local tissue reactions.
QUESTIONS/PURPOSES: In this study, we asked: (1) How prevalent is chemically dominated column damage compared with mechanically dominated damage modes in severely damaged metal-on-polyethylene THA femoral heads made from wrought CoCrMo alloy? (2) Is material loss greater in femoral heads that underwent column damage? (3) Do material loss and the presence of column damage depend on alloy microstructure as characterized by grain size, hard phase content, and/or banding?
Surgically retrieved wrought CoCrMo modular femoral heads removed between June 2004 and June 2019 were scored using a modified version of the Goldberg visually based scoring system. Of the total 1002 heads retrieved over this period, 19% (190 of 1002) were identified as severely damaged, exhibiting large areas of fretting scars, black debris, pits, and/or etch marks. Of these, 43% (81 of 190) were excluded for metal-on-metal articulations, alternate designs (such as bipolar, dual-mobility, hemiarthroplasty, metal adaptor sleeves), or previous sectioning of the implant for past studies. One sample was excluded retroactively as metallurgical analysis revealed that it was made of cast alloy, yielding a total of 108 for further analysis. Information on patient age (57 ± 11 years) and sex (56% [61 of 108] were males), reason for removal, implant time in situ (99 ± 78 months), implant manufacturer, head size, and the CoCrMo or titanium-based stem alloy pairing were collected. Damage modes and volumetric material loss within the head tapers were identified using an optical coordinate measuring machine. Samples were categorized by damage mode groups by column damage, imprinting, a combination of column damage and imprinting, or uniform fretting. Metallurgical samples were processed to identify microstructural characteristics of grain size, hard phase content, and banding. Nonparametric Mann-Whitney U and Kruskal-Wallis statistical tests were used to examine volumetric material loss compared with damage mode and microstructural features, and linear regression was performed to correlate patient- and manufacturer-specific factors with volumetric material loss.
Chemically driven column damage was seen in 48% (52 of 108) of femoral heads, with 34% (37 of 108) exhibiting a combination of column damage and imprinting, 12% (13 of 108) of heads displaying column damage and uniform fretting, and 2% (2 of 108) exhibiting such widespread column damage that potentially underlying mechanical damage modes could not be verified. Implants with column damage showed greater material loss than those with mechanically driven damage alone, with median (range) values of 1.2 mm3 (0.2 to 11.7) versus 0.6 mm3 (0 to 20.7; p = 0.03). Median (range) volume loss across all femoral heads was 0.9 mm3 (0 to 20.7). Time in situ, contact area, patient age, sex, head size, manufacturer, and stem alloy type were not associated with volumetric material loss. Banding of the alloy microstructure, with a median (range) material loss of 1.1 mm3 (0 to 20.7), was associated with five times higher material loss compared with those with a homogeneous microstructure, which had a volume loss of 0.2 mm3 (0 to 4.1; p = 0.02). Hard phase content and grain size showed no correlation with material loss.
Chemically dominated column damage was a clear indicator of greater volume loss in this study sample of 108 severely damaged heads. Volumetric material loss strongly depended on banding (microstructural segregations) within the alloy. Banding of the wrought CoCrMo microstructure should be avoided during the manufacturing process to reduce volumetric material loss and the release of corrosion products to the periprosthetic tissue.
Approximately 30% of THAs rely on wrought CoCrMo femoral heads. Most femoral heads in this study exhibited a banded microstructure that was associated with larger material loss and the occurrence of chemically dominated column damage. This study suggests that elimination of banding from the alloy could substantially reduce the release of implant debris in vivo, which could potentially also reduce the risk of adverse local tissue reactions to implant debris.
金属对聚乙烯全髋关节置换术(THA)模块化接头中的微动腐蚀会引起不良的组织反应,导致 2% 到 5%的翻修手术。钴铬钼(CoCrMo)合金股骨头内的损伤可能会在化学和机械上逐渐发展,导致柱损伤、压痕和均匀微动损伤等损伤模式。目前,尚不清楚哪种损伤模式的危害性最大,以及它们可能与植入合金的冶金学有何关联。合金微观结构表现出晶界、硬相等微观结构特征,以及偏析带等,这些特征可能会导致不同的损伤模式、更高的材料损失以及潜在的不良局部组织反应风险。
问题/目的:在这项研究中,我们提出了以下问题:(1)在由锻造 CoCrMo 合金制成的严重损坏的金属对聚乙烯 THA 股骨头中,与机械损伤模式相比,化学主导的柱损伤有多常见?(2)经历柱损伤的股骨头的材料损失是否更大?(3)材料损失和柱损伤的出现是否取决于合金微观结构,如晶粒尺寸、硬相含量和/或带状结构?
对 2004 年 6 月至 2019 年 6 月期间取出的锻造 CoCrMo 模块化股骨进行了检索,并使用改良的 Goldberg 基于视觉的评分系统对其进行了评分。在这期间共检索到 1002 个头,其中 19%(190/1002)被认为是严重损坏的,表现为大量的微动疤痕、黑色碎屑、凹坑和/或蚀痕。其中,43%(81/190)因金属对金属关节、其他设计(如双极、双动、半髋关节置换、金属适配器套筒)或过去研究中对植入物进行的切片而被排除在外。由于金属分析显示其中一个样本是由铸造合金制成的,因此被排除在外,最终共有 108 个样本用于进一步分析。收集的信息包括患者年龄(57±11 岁)和性别(56%[61/108]为男性)、移除原因、植入原位时间(99±78 个月)、植入物制造商、股骨头大小以及 CoCrMo 或钛基柄合金配对。使用光学坐标测量机识别头锥体内的损伤模式和体积材料损失。根据柱损伤、压痕、柱损伤和压痕的组合或均匀微动损伤模式对样品进行分类。对金相样品进行处理,以确定晶粒尺寸、硬相含量和带状结构的微观结构特征。使用非参数曼-惠特尼 U 和克鲁斯卡尔-沃利斯统计检验比较损伤模式和微观结构特征与体积材料损失之间的关系,并进行线性回归以关联患者和制造商特定因素与体积材料损失。
在 108 个头骨中,有 48%(52/108)出现化学驱动的柱损伤,其中 34%(37/108)出现柱损伤和压痕的组合,12%(13/108)出现柱损伤和均匀微动损伤,2%(2/108)出现如此广泛的柱损伤,以至于潜在的机械损伤模式无法得到验证。与仅存在机械驱动损伤的植入物相比,具有柱损伤的植入物显示出更大的材料损失,中位数(范围)值分别为 1.2mm3(0.2 至 11.7)和 0.6mm3(0 至 20.7;p=0.03)。所有股骨头的中位数(范围)体积损失为 0.9mm3(0 至 20.7)。植入物原位时间、接触面积、患者年龄、性别、股骨头大小、制造商和柄合金类型与体积材料损失无关。合金微观结构的带状结构的材料损失中位数(范围)为 1.1mm3(0 至 20.7),与具有均匀微观结构的材料损失相比,其材料损失高出五倍,后者的体积损失为 0.2mm3(0 至 4.1;p=0.02)。硬相含量和晶粒尺寸与材料损失无关。
在这项研究样本中,化学主导的柱损伤是 108 个严重损坏的股骨头中体积材料损失的一个明确指标。体积材料损失强烈依赖于合金中的带状结构(微观结构偏析)。在制造过程中应避免 CoCrMo 微观结构的带状结构,以减少体积材料损失和腐蚀产物向假体周围组织的释放。
大约 30%的 THA 依赖于锻造 CoCrMo 股骨头。本研究中的大多数股骨头都表现出带状微观结构,这与更大的材料损失和化学主导的柱损伤的发生有关。本研究表明,从合金中消除带状结构可以显著减少体内植入物碎屑的释放,这也可能降低对植入物碎屑的不良局部组织反应的风险。
