人工膝關節所用超高分子量聚乙烯磨耗分析

Chan-Hsien Chen; 陳政賢

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/34441

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	蘇侃
dc.contributor.author	Chan-Hsien Chen	en
dc.contributor.author	陳政賢	zh_TW
dc.date.accessioned	2021-06-13T06:08:45Z	-
dc.date.available	2006-06-05
dc.date.copyright	2006-06-05
dc.date.issued	2006
dc.date.submitted	2006-05-25
dc.identifier.citation	1. J.N. Insall, “Historical development, classification, and characteristics of knee prostheses,”Surgery of knee, Chapter23, Edited by Insall J.N., Second edition. Churchill Livingstone Inc. 1992. 1. R. W. Hood, T. M. Wright, and A. H.Burstein, “Retrieval analysis of total knee prostheses: A method and its application to 48 total condylar prostheses,”J Biomed Master Res, Vol. 17, 1986, pp.829-842. 2. S. Goodman, and L. Lidgren, “Polyethylene wear in knee-A review,”Acta Orthop Scand, Vol.63(3),1992,pp.358-364. 3. T. M. Wright, C. M.Rimnac, and S. D. Stulberg,”Wear of polyethylene in total joint replacements.-Observations from retrieved PCA implants,”Clinical Orthopedics Vol. 276, 1992, pp126-134. 4. T. M. Wright, and D.L.Bartel,“The problem of surface damage in polyethylene total knee components,”Clinical Orthopedics Vol.205,1986, pp.67-74. 5. M.A.Ritter,S.A.Pherbst, and E.M.keating,“Long-term survival analysis of a posterior cruciate-retaining total knee arthroplasty,” Clinical Orthopedics Vol.309,1994,pp.136-145. 6. D.L.Bartel , C.M. Rimnac and T.M.Wright : Evaluation and Design of the Articular Surface. Controversies of Total Knee Arthroplasty.61-63(1991) 7. A. Verneuil, “De la creation d’une fausse articulation par section ou resection partielle de l’ os maxillaire inferieur,comme moyen de remedier a l’ankylose vraie ou fausse de la machoire inferieure,”Arch Gen Med 15(ser.5):1860,p.174-188. 8. W.C.Campell,“Interposition of vitallium plates in arthroplasties of knee: preliminary report,”Am J Surg, Vol.47,1940,pp.639-652. 9. D.L.MacIntosh,“Hemiarthroplasty of the knee using a space occupying prosthesis for painful varus and valgus deformities,”J Bone Joint Surg[Am],Vol.40,1958,pp.1431. 10. D.C.Mckeever,“Tibial plateau ptosthesis,”Clinical Orthopedics,Vol.18,1960,pp.86. 11. F.H.Guston, “Polycentric knee arthroplasty:prosthetic Simulation of normal knee movement,”J Bone Joint Surg[Br], Vol.66,1971,pp.272. 13. M.A.R.Freeman, S.A.V. Swanson, R.C.Todd,“Total replacement of the knee using the freeman-swanson knee prosthesis,”Clinical Orthopedics,Vol.94,1973.pp.153 14. B. Walldius, “Arthroplasty of the knee joint using Endoprosthesis,”Acta orthop Scandia [Suppl], Vol.24,1957 ,pp.19 15. L.G.P.Shiers, “Arthroplasty of the knee : preliminary Report of a new method,”J Bone Joint Surg[Br],Vol.36,1954 ,pp.553. 16. J.N.Insall,C.S.Ranawat, W.N.Scott et al.,“Total knee replacement:prelimiminary report,”Clinical Orthropaedics,Vol.120,1976,pp.149. 17. F.C.Ewald,M.A.Jacobs,R.E.Miegel et al,“Duo-patella total knee arthroplasty in rheumatoid arthritis,”OrthopTrans,Vol.2,1978,pp.202. 18. D. S. Hangerford, R. V. Kenna, K. A. Krackow, “The porous-coated anatomic total knee,”Orthop Clin North Am, Vol.13(1),198,pp.103. 19. Huang, CH., Lee, YM.,Lai, JH., et al.,“Failure of ALL-Plyethylene Patellar Component After Total Knee Arthroplasty,” The Joural of arthroplasty ,Vol. 14,No. 8,1999,pp.940-944. 20. P. S. Walker, “Bearing surface design in total knee replacement,”Engin Med, Vol.17,1988,pp.149-156 21. S. Goodman, V.Fornasier, J.Lee, and J. Kei,”The histological effect of implantation of different sizes of polyethylene particles in the rabbit tibia,”J Biomed Master Res, Vol.24,1990,pp.517-524. 22. E. Barth, T. Sullivan, and E. W. Berg, “Particle size versus chemical composition of biomaterials as determining factors in macrophage activation,”Presented at the 37th Annual Meeting of the Orthopaedic research Society, Anaheim, California,1991. 23. M. Jasty, S. James, C. R. Bargdon, D. Goetz, K. R. Lee, A. E. Hanson, and W. H. Harris, “Patterns and mechanisms Of wear in polyethylene acetabular components retrieved At revision sugery,”Transactions of 20th Annual Meeting of Society for Biomaterials, Minneapolis,pp.103. 24. H. A. Mckellop, P. Campbell, S. H. Park, T. P. Schmaizned, P. Grigoris, H. C. Amstutz, and A. Sarmiento,“The origin of submicron polyethylene wear debris in total hip arthroplasty,”Clin Orthop, Vol.311,1995,pp.3-20. 25. J. M. Lee, E. A. Salvati, F. Betts, E. F. Dicarlo, S. B. Doty,and P. G. Bullough,“Size of metallic and polyethylene debris particles in failed cemented total hip replacements,”J Bone Joint Surg, Vol 74-B1992,pp.380-384 26. 蘇侃, 李勇達, “人工膝關節磨耗試驗機”,中華民國專利新型第一四0五七0號，1999. 27. M. A. Lafortune, P. R. Cavanagh, H. J. Sommer Ⅲ, A. Kalenak ,“Three dimensional kinematics of the human knee during Walking,”J Biomech, Vol.25(4),1992,pp.347-357. 28. J. B. Morrison, “The mechanics of the knee joint in relation to normal walking,”J Biomech, Vol.3,1970,pp. 55-61. 29. 李勇達, “人工膝關節脛股骨接觸面的最佳化研究及其磨耗行為探討”,博士論文, 台灣大學, 2003. 30. Laubenthal KN, Smidt GL, Kettelkamp DB “A quantitative analysis of knee motion during activities of daily living” Phys Ther. Jan,1972,52(1),pp.34-43. 31. Girgis, et al., “The cruciate ligament of Knee Joint-anatomical, Funciational and Experimental Analysis,”Clinical Orthopedics and Related-Research, NO.106, 1975, pp.216-231.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/34441	-
dc.description.abstract	本文探討人工膝關節的磨耗型態，以試驗機模擬人體一個步態週期中人工膝關節磨耗情形，包括其正向受力，前後移動及彎曲伸直的各項運動。在本文中採用兩種不同接觸壓應力大小作磨耗試驗，分別為16.5MPa和9.76MPa。實驗結果顯示在較大應力作用下，在前半段區域由於受到高應力及滑動的影響，產生明顯的刮痕，其磨耗的深度也大於其他區域。而在縱剖面的影響也較為顯著，在應力較大的試片中，可以觀察到縱剖面的疲勞發生處會伴隨垂直表面的裂縫，在壓應力16.5MPa週期數100萬次以及200萬次之試片皆可觀察到有貫穿試片的垂直裂縫。在9.76MPa壓應力作用下的試片，表面磨耗型態皆較為平坦，前半段區域並無明顯刮痕，整體的磨耗深度也較小，在縱剖面的觀察下，垂直表面的裂縫也大大減少，說明由於壓應力的減少，可以改變磨屑型態，進而降低磨耗的速度。臨床取下來的聚乙烯試片中，可以觀察到和人工膝關節磨耗試驗機所模擬之試片具有相似的磨耗型態，大體上和較高應力的試片結果較為類似，其因滑動產生的刮痕和片狀脫落的磨屑以及多層重疊的結果都和本文實驗結果相似。	zh_TW
dc.description.abstract	The wear patterns of ultra high molecular weight polyethylene (UHMWPE) used in artificial knee joint were studied in this research. A knee joint simulator was used to simulate the vertical load, anterior-posterior translation, flexion-extension and internal-external rotation in a complete walking cycle. Two different contact compressive stresses of 16.5MPa and 9.76MPa were set in this experiment. The experimental results show that obvious wear print would be observed in anterior area, it was caused by bearing high stress and relative sliding. The wear depth in this area was also deeper than that in other area. Subjected to the higher stress (i.e. 16.5MPa), fatigue cracks occurred in axial section perpendicular to the wear surface of the specimens subjected to 1x106 cycle and 2x106 cycle-tests. Subjected to the compressive stress of 9.76MPa, wear situation of the UHMWPE specimen was mild, and no obvious scrape in anterior area. The total wear depth was smaller, only some perpendicular cracks were observed. The similar wear patterns were observed on both the clinically used polyethylene and simulated one, especially on the specimens subjected to higher stress. The wear phenomena of delamination wear、stacks of wear debris and scratched marks on the simulated specimens were similar to those on the clinically used UHMWPE.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T06:08:45Z (GMT). No. of bitstreams: 1 ntu-95-R92522523-1.pdf: 13536982 bytes, checksum: 63bd6826bb3f608ff0454e5782305754 (MD5) Previous issue date: 2006	en
dc.description.tableofcontents	第一章緒論 1-1 簡介..................................................1 1-2 人體膝關節簡介........................................2 1-3 人工膝關節簡介........................................5 1-4 人工膝關節的設計......................................8 1-5 文獻回顧.............................................10 第二章人工膝關節磨耗試驗 2-1 人工膝關節磨耗試驗...................................12 2-1-1 磨耗試驗機儀器...............................15 2-1-2 其他實驗儀器.................................16 2-1-3 試片準備.....................................17 2-1-4 實驗步驟.....................................18 2-2 實驗條件.............................................19 第三章超高分子聚乙烯磨耗結果 3-1 試片磨耗區分.........................................25 3-2 磨耗結果.............................................26 3-2-1 16.5MPa 50萬次磨耗試片結果...................26 3-2-2 16.5MPa 100萬次磨耗試片結果..................37 3-2-3 9.76MPa 200萬次磨耗試片結果..................49 3-2-4 9.76MPa 100萬次磨耗試片結果..................65 3-2-5 16.5MPa 200萬次磨耗試片結果..................80 第四章結果與討論 4-1 步態週期之運動機制與路徑.............................92 4-2 應力大小對磨耗深度的影響.............................92 4-3 應力大小對磨耗型態的影響.............................93 4-4 縱剖面結果..........................................101 4-4-1 16.5MPa 200萬次.............................102 4-4-2 16.5MPa 100萬次.............................105 4-4-3 9.76MPa 200萬次.............................108 4-4-4 16.5MPa 50萬次..............................111 4-4-5 9.76MPa 100萬次.............................114 4-5 試片縱剖面結果討論..................................117 4-6 臨床取下試片與實驗結果之比較........................118第五章結論與未來研究方向 5-1 結論與未來研究方向..................................124 參考文獻...............................................125
dc.language.iso	zh-TW
dc.subject	磨耗	zh_TW
dc.subject	人工膝關節	zh_TW
dc.subject	超高分子量聚乙烯	zh_TW
dc.subject	wear	en
dc.subject	UHMWPE	en
dc.subject	polyethylene	en
dc.subject	artificial knee joint	en
dc.title	人工膝關節所用超高分子量聚乙烯磨耗分析	zh_TW
dc.title	The wear analysis of ultra high molecular weight polyethylene in artificial knee joint	en
dc.type	Thesis
dc.date.schoolyear	94-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	陳博光,吳興盛
dc.subject.keyword	人工膝關節,超高分子量聚乙烯,磨耗,	zh_TW
dc.subject.keyword	artificial knee joint,wear,polyethylene,UHMWPE,	en
dc.relation.page	130
dc.rights.note	有償授權
dc.date.accepted	2006-05-25
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	機械工程學研究所	zh_TW
顯示於系所單位：	機械工程學系

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