{"title":"In Vitro Assessment of Serum-Saline Ratios for Fluid Simulator Testing of Highly Modular Spinal Implants With Articulating Surfaces","authors":"Nadim Hallab PhD , Ashutosh Khandha , George Malcolmson , J.P. Timm","doi":"10.1016/S1935-9810(08)70036-7","DOIUrl":null,"url":null,"abstract":"<div><h3>Background</h3><p>The increasing complexity of articulating spinal implants prohibits the use of serum-supplemented simulator fluid testing because multicomponent interfaces retain residual protein and preclude gravimetric measurement. Our original hypothesis was that simulator testing of a posterior dynamic stabilization implant that has metal-on-metal articulating bearings will not produce dramatically different wear debris when tested using pure saline versus testing in saline supplemented with 20% serum.</p></div><div><h3>Methods</h3><p>This hypothesis was tested using simulator testing of 12 dynamic stabilization spinal implants, 6 in 100% saline and 6 in 20%-serum saline. Gravimetric and particle analysis were performed after every million cycles up to 10 million cycles, with flexion of 11.3/extension of 5.6° coupled with axial rotation of ± 4°.</p></div><div><h3>Results</h3><p>The mean gravimetric weight loss was approximately 200<!--> <!-->mg over 10 million cycles for the implants tested in 100% saline, while the mean weight loss for those tested in 20%-serum saline was below the method detection limits (<<!--> <!-->10<!--> <!-->mg over 10 million cycles). For the 100%-saline and 20%-serum simulator fluids, the average particle size over the course of 0 to 10<!--> <!-->million cycles remained relatively constant at 0.2<!--> <!-->μm-dia (saline) and 3.2<!--> <!-->μm-dia (20%-serum saline). Testing in 100% saline generated ><!--> <!-->1000-fold more particles, compared to testing in 20% serum-supplemented saline. Energy-dispersive X-ray (EDAX) analyses of particles demonstrated that the 100% saline debris was composed of Co-Cr-P-O (Cr-Co metal oxides), and for the 20%-serum saline debris only bulk metal Co-Cr was detected.</p></div><div><h3>Conclusion</h3><p>Our initial hypothesis was not supported. There were significant differences in gravimetric wear, average size, and type of wear debris that were mechanistically attributable to the type of simulator fluid used. The over-protective effect of serum proteins appears to underscore the importance of using both saline and serum when establishing upper and lower bounds of predictive implant debris generation modeling, where saline represents a worst-case scenario and as little as 20% serum masks all weight loss completely in highly modular articulating implants.</p></div><div><h3>Clinical Relevance</h3><p>Clinical Relevance<!--> <!-->=<!--> <!-->5 (Oxford Centre for Evidence-based Medicine Levels of Evidence). Study findings are limited to a greater understanding of the science associated with predictive wear testing of articulating spinal implants.</p></div>","PeriodicalId":88695,"journal":{"name":"SAS journal","volume":"2 4","pages":"Pages 171-183"},"PeriodicalIF":0.0000,"publicationDate":"2008-12-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://sci-hub-pdf.com/10.1016/S1935-9810(08)70036-7","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"SAS journal","FirstCategoryId":"1085","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S1935981008700367","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Background
The increasing complexity of articulating spinal implants prohibits the use of serum-supplemented simulator fluid testing because multicomponent interfaces retain residual protein and preclude gravimetric measurement. Our original hypothesis was that simulator testing of a posterior dynamic stabilization implant that has metal-on-metal articulating bearings will not produce dramatically different wear debris when tested using pure saline versus testing in saline supplemented with 20% serum.
Methods
This hypothesis was tested using simulator testing of 12 dynamic stabilization spinal implants, 6 in 100% saline and 6 in 20%-serum saline. Gravimetric and particle analysis were performed after every million cycles up to 10 million cycles, with flexion of 11.3/extension of 5.6° coupled with axial rotation of ± 4°.
Results
The mean gravimetric weight loss was approximately 200 mg over 10 million cycles for the implants tested in 100% saline, while the mean weight loss for those tested in 20%-serum saline was below the method detection limits (< 10 mg over 10 million cycles). For the 100%-saline and 20%-serum simulator fluids, the average particle size over the course of 0 to 10 million cycles remained relatively constant at 0.2 μm-dia (saline) and 3.2 μm-dia (20%-serum saline). Testing in 100% saline generated > 1000-fold more particles, compared to testing in 20% serum-supplemented saline. Energy-dispersive X-ray (EDAX) analyses of particles demonstrated that the 100% saline debris was composed of Co-Cr-P-O (Cr-Co metal oxides), and for the 20%-serum saline debris only bulk metal Co-Cr was detected.
Conclusion
Our initial hypothesis was not supported. There were significant differences in gravimetric wear, average size, and type of wear debris that were mechanistically attributable to the type of simulator fluid used. The over-protective effect of serum proteins appears to underscore the importance of using both saline and serum when establishing upper and lower bounds of predictive implant debris generation modeling, where saline represents a worst-case scenario and as little as 20% serum masks all weight loss completely in highly modular articulating implants.
Clinical Relevance
Clinical Relevance = 5 (Oxford Centre for Evidence-based Medicine Levels of Evidence). Study findings are limited to a greater understanding of the science associated with predictive wear testing of articulating spinal implants.
背景:关节式脊柱植入物日益复杂,禁止使用血清补充模拟器液体测试,因为多组分界面保留了残留的蛋白质,并且妨碍了重量测量。我们最初的假设是,当使用纯生理盐水和添加20%血清的生理盐水进行测试时,具有金属对金属关节轴承的后路动态稳定植入物的模拟器测试不会产生明显不同的磨损碎片。方法对12例动态稳定脊柱植入物进行模拟试验,其中6例置入100%生理盐水,6例置入20%血清盐水。每100万次循环至1000万次循环后进行重量和颗粒分析,屈曲11.3°/延伸5.6°,轴向旋转±4°。结果在100%生理盐水中测试的植入物在1000万周期内的平均重量损失约为200 mg,而在20%血清盐水中测试的植入物的平均重量损失低于方法的检测限(<每1000万次10毫克)。对于100%生理盐水和20%血清模拟液,在0到1000万次循环过程中,平均粒径保持相对恒定,分别为0.2 μm-dia(生理盐水)和3.2 μm-dia(20%生理盐水)。100%生理盐水测试;与在20%血清补充盐水中测试相比,颗粒多1000倍。粒子的能量色散x射线(EDAX)分析表明,100%的生理盐水碎片由Co-Cr- p - o (Cr-Co金属氧化物)组成,而20%的血清生理盐水碎片仅检测到大块金属Co-Cr。结论我们最初的假设不成立。在重量磨损、平均尺寸和磨损碎屑类型方面存在显著差异,这在机械上可归因于所使用的模拟器流体的类型。血清蛋白的过度保护作用似乎强调了在建立预测植入物碎片生成模型的上界和下界时同时使用生理盐水和血清的重要性,其中生理盐水代表最坏情况,而在高度模块化关节植入物中,只有20%的血清完全掩盖了所有体重减轻。临床相关性:临床相关性= 5(牛津循证医学证据水平中心)。研究结果仅限于对关节脊柱植入物预测磨损测试相关科学的更深入理解。
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