Michael C. Dahl PhD , Stephen Jacobsen MD , Newton Metcalf Jr , Rick Sasso MD , Randal P. Ching PhD
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Ten of each nucleus type underwent three separate mechanical testing protocols to measure 1) dynamic stiffness, 2) quasi-static stiffness, 3) energy absorption, and 4) energy dissipation. The results were compared using analysis of variance.</p></div><div><h3>Results</h3><p>PU had the lowest mean dynamic stiffness (435 ± 13 N/mm, P < .0001) and highest energy absorption (19.4 ± 0.1 N/mm, P < .0001) of all three nucleus materials tested. PU was found to have significantly higher energy dissipation (viscous damping ratio 0.017 ± 0,001, P < .0001) than the PE or TI nuclei. PU had the lowest quasi-static stiffness (598 ± 23 N/mm, P < .0001) of the nucleus materials tested. A biphasic response curve was observed for all of the PU nuclei tests.</p></div><div><h3>Conclusions</h3><p>Polyurethane absorbs and dissipates more energy and is less stiff than either polyethylene or titanium.</p></div><div><h3>Level of Evidence</h3><p>Basic Science/Biomechanical Study.</p></div><div><h3>Clinical Relevance</h3><p>This study characterizes important differences in biomechanical properties of materials that are currently being used for different cervical disc prostheses.</p></div>","PeriodicalId":88695,"journal":{"name":"SAS journal","volume":"5 2","pages":"Pages 48-54"},"PeriodicalIF":0.0000,"publicationDate":"2011-06-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://sci-hub-pdf.com/10.1016/j.esas.2011.01.002","citationCount":"8","resultStr":"{\"title\":\"A comparison of the shock-absorbing properties of cervical disc prosthesis bearing materials\",\"authors\":\"Michael C. 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引用次数: 8
摘要
与传统的脊柱融合术相比,颈椎关节置换术具有理论上的优势,包括消除邻近节段疾病和消除假关节形成的风险。颈椎关节置换术的初步研究显示出有希望的结果,然而,椎间盘置换术的理想设计特征尚未确定。目前的研究旨在量化三种常用材料在颈椎椎间盘置换术中减震特性的差异。方法在湿度和温度控制的实验室内对聚氨酯(PU)、聚乙烯(PE)和钛合金(Ti)三种不同的核材料进行了测试。每种类型的10个核进行了三种不同的力学测试方案,以测量1)动态刚度,2)准静态刚度,3)能量吸收和4)能量耗散。采用方差分析对结果进行比较。结果spu的平均动刚度最低(435±13 N/mm);.0001)和最高能量吸收(19.4±0.1 N/mm, P <三种核材料测试的0.0001)。发现PU具有明显更高的能量耗散(粘滞阻尼比0.017±0.001,P <.0001),比PE或TI原子核高。PU具有最低的准静刚度(598±23 N/mm);0.0001)的核材料测试。所有PU核试验均观察到双相反应曲线。结论聚氨酯比聚乙烯和钛吸收和耗散更多的能量,硬度更小。基础科学/生物力学研究。临床相关性本研究描述了目前用于不同颈椎间盘假体的材料在生物力学特性上的重要差异。
A comparison of the shock-absorbing properties of cervical disc prosthesis bearing materials
Background Data
Cervical arthroplasty offers theoretical advantages over traditional spinal fusion, including elimination of adjacent segment disease and elimination of the risk of pseudoarthrosis formation. Initial studies of cervical arthroplasty have shown promising results, however, the ideal design characteristics for disc replacement constructs have not been determined. The current study seeks to quantify the differences in the shock absorption characteristics of three commonly used materials in cervical disc arthroplasty.
Methods
Three different nucleus materials, polyurethane (PU), polyethylene (PE) and a titanium-alloy (Ti) were tested in a humidity- and temperature-controlled chamber. Ten of each nucleus type underwent three separate mechanical testing protocols to measure 1) dynamic stiffness, 2) quasi-static stiffness, 3) energy absorption, and 4) energy dissipation. The results were compared using analysis of variance.
Results
PU had the lowest mean dynamic stiffness (435 ± 13 N/mm, P < .0001) and highest energy absorption (19.4 ± 0.1 N/mm, P < .0001) of all three nucleus materials tested. PU was found to have significantly higher energy dissipation (viscous damping ratio 0.017 ± 0,001, P < .0001) than the PE or TI nuclei. PU had the lowest quasi-static stiffness (598 ± 23 N/mm, P < .0001) of the nucleus materials tested. A biphasic response curve was observed for all of the PU nuclei tests.
Conclusions
Polyurethane absorbs and dissipates more energy and is less stiff than either polyethylene or titanium.
Level of Evidence
Basic Science/Biomechanical Study.
Clinical Relevance
This study characterizes important differences in biomechanical properties of materials that are currently being used for different cervical disc prostheses.
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