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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 潘永寧(Yung-Ning Pan) | |
dc.contributor.author | Hung-Ming Lin | en |
dc.contributor.author | 林宏銘 | zh_TW |
dc.date.accessioned | 2021-06-16T06:57:10Z | - |
dc.date.available | 2019-07-29 | |
dc.date.copyright | 2014-07-29 | |
dc.date.issued | 2014 | |
dc.date.submitted | 2014-07-18 | |
dc.identifier.citation | 1. Erbulut DU, Zafarparandeh I, Ozer AF, Goel VK (2013) Biomechanics of posterior dynamic stabilization systems. AdvOrthop: 451956
2. Andersson GB (1999) Epidemiological features of chronic low-back pain. Lancet 354(9178): 581-585 3. McKinnon ME, Vickers MR, Ruddock VM, Townsend J, Meade TW (1997) Community studies of the health service implications of low back pain. Spine 22(18): 2161-2166 4. Modic MT, Ross JS (2007) Lumbar degenerative disk disease. Radiology 245(1): 43-61 5. Crow WT, Willis DR (2009) Estimating cost of care for patients with acute low back pain: a retrospective review of patient records. J Am Osteopath Assoc 109(4): 229-233 6. Schizas C, Kulik G, Kosmopoulos V (2010) Disc degeneration: current surgical options. Eur Cell Mater 20: 306-315 7. Kuslich SD, Ulstrom CL, and Michael CJ (1991) The tissue origin of low back pain and sciatica: a report of pain response to tissue stimulation during operations on the lumbar spineusing local anesthesia. Orthop Clin North Am 22(2): 181-187 8. Palepu V, Kodigudla M, Goel VK (2012) Biomechanics of disc degeneration. Adv Orthop 2012: 726210 9. An HS, Anderson PA, Haughton VM, Iatridis JC, Kang JD, Lotz JC, Natarajan RN, Oegema TR Jr, Roughley P, Setton LA, Urban JP, Videman T, Andersson GB, Weinstein JN (2004) Introduction: disc degeneration: summary. Spine 29(23): 2677-2678 10. Panjabi MM, White AA (1990) Clinical Biomechanics of the Spine. Lippincott-Raven 11. Zhang QH, Teo EC (2008) Finite element application in implant research for treatment of lumbar degenerative disc disease. Med Eng Phys 30(10): 1246-1256 12. Szpalski M, Gunzburg R, Rydevik BL, Huec JCL, Mayer M (2010) Surgery for low back pain. Springer 13. Iatridis JC, Mente PL, Stokes IA, Aronsson DD, Alini M (1999) Compression-induced changes in intervertebral disc properties in a rat tail model. Spine 24(10): 996-1002 14. Kroeber MW, Unglaub F, Wang H, Schmid C, Thomsen M, Nerlich A, Richter W (2002) New in vivo animal model to create intervertebral disc degeneration and to investigate the effects of therapeutic strategies to stimulate disc regeneration. Spine 27(23): 2684-2690 15. Lotz JC, Chin JR (2000) Intervertebral disc cell death is dependent on the magnitude and duration of spinal loading. Spine 25(12): 1477-1483 16. Lotz JC, Colliou OK, Chin JR, Duncan NA, Liebenberg E (1998) Compression-induced degeneration of the intervertebral disc: an in vivo mouse model and finite-element study. Spine 23(23): 2493-2506 17. Eck JC, Humphreys SC, Hodges SD (1999) Adjacent-segment degeneration after lumbar fusion: a review of clinical, biomechanical, and radiologic studies. Am J Orthop 28(6): 336-340 18. Schlegel JD, Smith JA, Schleusener RL (1996) Lumbar motion segment pathology adjacent to thoracolumbar, lumbar, and lumbosacral fusions. Spine 21(8): 970-981 19. Niosi CA, Zhu QA, Wilson DC, Keynan O, Wilson DR, Oxland TR (2006) Biomechanical characterization of the three-dimensional kinematic behaviour of the Dynesys dynamic stabilization system: an in vitro study. Eur Spine J 15(6): 913-922 20. Sangiorgio SN, Sheikh H, Borkowski SL, Khoo L, Warren CR, Ebramzadeh E (2011) Comparison of three posterior dynamic stabilization devices. Spine 36(19): E1251-E1258 21. Chang CL, Chen CS, Huang CH, Hsu ML (2012) Finite element analysis of the dental implant using a topology optimization method. Med Eng Phys 34(7): 999-1008 22. Liao YC, Feng CK, Tsai MW, Chen CS, Cheng CK, Ou YC (2007) Shape modification of the Boston brace using a finite element method with topology optimization. Spine 32(26): 3014-3019 23. Zhong ZC, Wei SH, Wang JP, Feng CK, Chen CS, Yu CH (2006) Finite element analysis of the lumbar spine with a new cage using a topology optimization method. Med Eng Phys 28(1): 90-98 24. Benzel EC, Francis TB (2012) Spine surgery: techniques, complication avoidance, and management. 3rd edition, Philadelphia, PA: Elsevier/Saunders 25. Goel VK, Weinstein JN (1990) Biomechanics of the spine: Clinical and surgical perspective. CRC Press Inc, United States 26. MA Adams (2013) The biomechanics of back pain. 3rd edition, Edinburgh, New York: Churchill Livingstone/Elsevier 27. http://www.backpain-guide.com/Chapter_Fig_folders/Ch05_Anatomy_Folder/4OverallSpine.html 28. Bogduk N (2012) Clinical and radiological anatomy of the lumbar spine. 5th edition, Edinburgh: Elsevier/Churchill Livingstone 29. Frankel VH, Nordin M (2001) Basic biomechanics of the musculoskeletal system. Philadelphia: Lippincott Williams & Wilkins 30. http://5minuteconsult.com/ViewImage/2027581 31. http://www.spineinfo.co.uk/conditions/facet-joint-disease/ 32. http://www.scoliosisassociates.com/subject.php?pn=lumbar-sprains-strains-001 33. Pfirrmann CW, Metzdorf A, Zanetti M, Hodler J, Boos N (2001) Magnetic resonance classification of lumbar intervertebral disc degeneration. Spine 26(17): 1873-1878 34. Cheung KM, Samartzis D, Karppinen J, Mok FP, Ho DW, Fong DY, Luk KD (2010) Intervertebral disc degeneration: new insights based on skipped level disc pathology. Arthritis Rheum 62(8): 2392-2400 35. Issever AS, Walsh A, Lu Y, Burghardt A, Lotz JC, Majumdar S (2003) Micro-computed tomography evaluation of trabecular bone structure on loaded mice tail vertebrae. Spine 28(2): 123-128 36. MacLean JJ, Lee CR, Grad S, Ito K, Alini M, Iatridis JC (2003) Effects of immobilization and dynamic compression on intervertebral disc cell gene expression in vivo. Spine 28(10): 973-981 37. Walsh AJ and Lotz JC (2004) Biological response of the intervertebral disc to dynamic loading. J Biomech 37(3): 329-337 38. Liang QQ, Zhou Q, Zhang M, Hou W, Cui XJ, Li CG, Li TF, Shi Q, Wang YJ (2008) Prolonged upright posture induces degenerative changes in intervertebral discs in rat lumbar spine. Spine 33(19): 2052-2058 39. Dreischarf M, Zander T, Shirazi-Adl A, Puttlitz CM, Adam CJ, Chen CS, Goel VG, Kiapour A, Kim YH, Labus YM, Little JP, Park WM, Wang YH, Wilke HJ, Rohlmann A, Schmidt H (2014) Comparison of eight published static finite element models of the intact lumbar spine: predictive power of models improves when combined together. J Biomech 47(8): 1757-1766 40. Shih SL, Liu CL, Huang LY, Huang CH, Chen CS (2013) Effects of cord pretension and stiffness of the Dynesys system spacer on the biomechanics of spinal decompression-a finite element study. BMC Musculoskelet Disord 14: 191 41. Shih SL, Chen CS, Lin HM, Huang LY, Liu CL, Huang CH, Cheng CK (2012) Effect of the diameter of spacers of the Dynesys dynamic stabilization system on the biomechanics of the lumbar Spine: A finite element analysis. J Spinal Disord Tech 25(5): E140-E149 42. Liu CL, Zhong ZC, Hsu HW, Shih SL, Wang ST, Hung C, Chen CS (2011) Effect of the cord pretension of the Dynesys dynamic stabilization system on the biomechanics of the lumbar spine: a finite element analysis. Eur Spine J 20(11): 1850-1858 43. Liu CL, Zhong ZC, Shih SL, Hung C, Lee YE, Chen CS (2010) Influence of Dynesys system screw profile on adjacent segment and screw. J Spinal Disord Tech 23(6): 410-417 44. Chen SH, Zhong ZC, Chen CS, Chen WJ, Hung C (2009) Biomechanical comparison between lumbar disc arthroplasty and fusion. Med Eng Phys 31(2): 244-253 45. Zhong ZC, Chen SH, Hung CH (2009) Load- and displacement controlled finite element analyses on fusion and non-fusion spinal implants. Proc Inst Mech Eng H 223(2): 143-157 46. Lu YM, Hutton WC, Gharpuray VM (1996) Do Bending, Twisting, and Diurnal Fluid Changes in the Disc Affect the Propensity to Prolapse? A Viscoelastic Finite Element Model. Spine 21(22): 2570-2579 47. Schmidt H, Heuer F, Simon U, Kettler A, Rohlmann A, Claes L, and Wilke HH (2006) Application of a new calibration method for a three-dimensional finite element model of a human lumbar annulus fibrosus. Clin Biomechanics 21(4): 337-344 48. Rohlmann A, Zander T, Bergmann G (2005) Effects of total disc replacement with ProDisc on intersegmental rotation of the lumbar spine. Spine 30(7): 738-743 49. Shirazi-Adl A, Ahmed AM, Shrivastava SC (1986) Mechanical response of a lumbar motion segment in axial torque alone and combined with compression. Spine 11(9): 914-927 50. Polikeit A, Ferguson SJ, Nolte LP, Orr TE (2003) Factors influencing stresses in the lumbar spine after the insertion of intervertebral cages: finite element analysis. Eur Spine J 12(4): 413-420 51. Panagiotacopulos ND, Pope MH, Krag MH, Block R (1987) Water content in human intervertebral discs. Part I. Measurement by magnetic resonance imaging. Spine 12(9): 912-917 52. Goel VK, Kim YE, Lim TH, Weinstein JN (1988) An analytical investigation of the mechanics of spinal instrumentation. Spine 13(9): 1003-1011 53. Goel VK, Monroe BT, Gilbertson LG, Brinckmann P (1995) Interlaminar Shear Stresses and Laminae Separation in a Disc: Finite Element Analysis of the L3-L4 Motion Segment Subjected to Axial Compressive Loads. Spine 20(6): 689-698. 54. Rohlmann A, Zander T, Bergmann G (2006) Effects of fusion-bone stiffness on the mechanical behavior of the lumbar spine after vertebral body replacement. Clinical Biomechanics 21(3): 221-227 55. Chen CS, Cheng CK, Liu CL, Lo WH (2001) Stress analysis of the disc adjacent to interbody fusion in lumbar spine. Med Eng Phys 23(7): 485-493 56. Agur AMR and Lee MJ (1999) Grant’s atlas of anatomy. 10th ed, Philadelphia, PA: Lippincott Williams & Wilkins: 268 57. Lee KK, Teo EC, Fuss FK, Vanneuville V, Qiu TX, Ng HW, Yang K, Sabitzer RJ (2004) Finite-element analysis for lumbar interbody fusion under axial loading. IEEE Trans Biomed Eng 51(3): 393-400 58. Fraldi M, Esposito L, Perrella G, Cutolo A, Cowin SC (2010) Topological optimization in hip prosthesis design. Biomech Model Mechanobiol 9(4): 389-402 59. Boyle C, Kim IY (2011) Comparison of different hip prosthesis shapes considering micro-level bone remodeling and stress-shielding criteria using three-dimensional design space topology optimization. J Biomech 44(9): 1722-1728 60. Sutradhar A, Park J, Carrau D, & Miller M J (2014) Experimental validation of 3D printed patient-specific implants using digital image correlation and finite element analysis. Comput Biol Med 52C: 8-17 61. Xiao DM, Yang YQ, Su XB, Wang D, Luo ZY (2012) Topology optimization of microstructure and selective laser melting fabrication for metallic biomaterial scaffolds. T Nonferr Metal Soc 22(10): 2554-2561 62. Almeida HDA, da Silva Bartolo PJ (2010) Virtual topological optimisation of scaffolds for rapid prototyping. Med Eng Phys 32(7): 775-782 63. Lin CY, Schek RM, Mistry AS, Shi X, Mikos AG, Krebsbach PH, Hollister SJ (2005) Functional bone engineering using ex vivo gene therapy and topology-optimized, biodegradable polymer composite scaffolds. Tissue Eng 11(9-10): 1589-1598 64. Jang IG, Kim IY (2010) Application of design space optimization to bone remodeling simulation of trabecular architecture in human proximal femur for higher computational efficiency. Finite Elem Anal Des 46(4): 311-319 65. Nowak M (2006) Structural optimization system based on trabecular bone surface adaptation. Struct Multidiscip O 32(3): 241-249 66. Kutuk MA, Gov I (2013) Application of topology optimization to the tibial osteotomy fixation plates. Appl Bionics Biomech 10(2): 125-133 67. Guimaraes TA, Oliveira SAG, Duarte MA (2008) Application of the topological optimization technique to the stents cells design for angioplasty. J Braz Soc Mech Sci & Eng 30(3): 261-268 68. Guimaraes TA, Duarte MA, Oliveira SA (2005) Topology optimization of the stents cells plane model with maximum hardening and flexibility. Inverse Probl Sci Eng 2: 191. 69. Ridzwan MIZ, Shuib S, Hassan AY, Shokri AA, Ibrahim MNM (2006) Optimization in implant topology to reduce stress shielding problem. J Appl Sci 6: 2768-2773. 70. Tovar A, Gano SE, Mason JJ, Renaud JE (2005) Optimum design of an interbody implant for lumbar spine fixation. Adv Eng Softw 36(9): 634-642 71. Chuah HG, Rahim IA, Yusof MI (2010) Topology optimisation of spinal interbody cage for reducing stress shielding effect. Comput Methods Biomech Biomed Engin 13(3): 319-326 72. Lin CY, Hsiao CC, Chen PQ, Hollister SJ (2004) Interbody fusion cage design using integrated global layout and local microstructure topology optimization. Spine (Phila Pa 1976) 29(16): 1747-1754 73. Lin CY, Wirtz T, LaMarca F, Hollister SJ (2007) Structural and mechanical evaluations of a topology optimized titanium interbody fusion cage fabricated by selective laser melting process. J Biomed Mater Res A 83(2): 272-279 74. Erbulut DU, Zafarparandeh I, Ozer AF, Goel VK (2013) Biomechanics of posterior dynamic stabilization systems. Adv Orthop 2013: 451956 75. Rohlmann A, Burra NK, Zander T, and Bergmann G (2007) Comparison of the effects of bilateral posterior dynamic and rigid fixation devices on the loads in the lumbar spine: a finite element analysis. Eur Spine J 16(8): 1223-1231 76. Schmoelz W, Huber JF, Nydegger T, Dipl-Ing, Claes L, Wilke HJ (2003) Dynamic stabilization of the lumbar spine and its effects on adjacent segments: an in vitro experiment. J Spinal Disord Tech 16(4): 418-423 77. Schmoelz W, Huber JF, Nydegger T, Claes L, Wilke HJ (2006) Influence of a dynamic stabilisation system on load bearing of a bridged disc: an in vitro study of intradiscal pressure. Eur Spine J 15(8): 1276-1285 78. Beastall J, Karadimas E, Siddiqui M, Nicol M, Hughes J, Smith F, Wardlaw D (2007) The Dynesys lumbar spinal stabilization system: a preliminary report on positional magnetic resonance imaging findings. Spine 32(6): 685-690 79. Schmidt H, Heuer F, Wilke HJ (2009) Which axial and bending stiffnesses of posterior implants are required to design a flexible lumbar stabilization system? J Biomech 42(1): 48-54 80. Schulte TL, Hurschler C, Haversath M, Liljenqvist U, Bullmann V, Filler TJ, Osada N, Fallenberg EM, Hackenberg L (2008) The effect of dynamic, semi-rigid implants on the range of motion of lumbar motion segments after decompression. Eur Spine J 17(8): 1057-1065 81. Wilke HJ, Heuer F, Schmidt H (2009) Prospective design delineation and subsequent in vitro evaluation of a new posterior dynamic stabilization system. Spine 34(3): 255-261 82. Hashimoto T, Oha F, Shigenobu K, Kanayama M, Harada M, Ohkoshi Y, Tada H, Yamamoto K, Yamane S (2001) Mid-term clinical results of Graf stabilization for lumbar degenerative pathologies. a minimum 2-year follow-up. Spine J 1(4): 283-289 83. Kanayama M, Hashimoto T, Shigenobu K (2005) Rationale, biomechanics, and surgical indications for Graf ligamentoplasty. Orthop Clin North Am 36(3): 373-377 84. Stoffel M, Behr M, Reinke A, Stuer C, Ringel F, Meyer B (2010) Pedicle screw-based dynamic stabilization of the thoracolumbar spine with the Cosmic-system: a prospective observation. Acta Neurochir (Wien) 152(5): 835-843 85. Meyers K, Tauber M, Sudin Y, Fleischer S, Arnin U, Girardi F, Wright T (2008) Use of instrumented pedicle screws to evaluate load sharing in posterior dynamic stabilization systems. Spine J 8(6): 926-932 86. Ozer AF, Crawford NR, Sasani M, Oktenoglu T, Bozkus H, Kaner T, Aydin S (2010) Dynamic lumbar pedicle screw-rod stabilization: two-year follow-up and comparison with fusion. Open Orthop J 4: 137-141 87. von Strempel A (2008) Dynamic stabilisation: cosmic system. Interactive Surgery 3(4): 229-236 88. Smith ZA, Armin S, Raphael D, Khoo LT (2011) A minimally invasive technique for percutaneous lumbar facet augmentation: Technical description of a novel device. Surg Neurol Int 2: 165 89. Masala S, Tarantino U, Nano G, Iundusi R, Fiori R, Da Ros V, Simonetti G (2013) Lumbar spinal stenosis minimally invasive treatment with bilateral transpedicular facet augmentation system. Cardiovasc Intervent Radiol 36(3): 738-747 90. Mandigo CE, Sampath P, Kaiser MG (2007) Posterior dynamic stabilization of the lumbar spine: pedicle based stabilization with the AccuFlex rod system. Neurosurg Focus 22(1): E9 91. Reyes-Sanchez A, Zarate-Kalfopulos B, Ramirez-Mora I, Rosales-Olivarez LM, Alpizar-Aguirre A, Sanchez-Bringas G (2010) Posterior dynamic stabilization of the lumbar spine with the Accuflex rod system as a stand-alone device: experience in 20 patients with 2-year follow-up. Eur Spine J 19(12): 2164-2170 92. Cho BY, Murovic J, Park KW, Park J (2010) Lumbar disc rehydration postimplantation of a posterior dynamic stabilization system. J Neurosurg Spine 13(5): 576-580 93. Sangiorgio SN, Sheikh H, Borkowski SL, Khoo L, Warren CR, Ebramzadeh E (2011) Comparison of three posterior dynamic stabilization devices. Spine 36(19): E1251-E1258 94. Zhang HY, Park JY, Cho BY (2009) The BioFlex system as a dynamic stabilization device: does it preserve lumbar motion? J Korean Neurosurg Soc 46(5): 431-436 95. Heo DH, Cho YJ, Cho SM, Choi HC, Kang SH (2012) Adjacent segment degeneration after lumbar dynamic stabilization using pedicle screws and a nitinol spring rod system with 2-year minimum follow-up. J Spinal Disord Tech 25(8): 409-414 96. http://www.paonan.com.tw/products/04_1.html 97. Umehara S, Tadano S, Abumi K, Katagiri K, Kaneda K, Ukai T (1996) Effects of degeneration on the elastic modulus distribution in the lumbar intervertebral disc. Spine 21(7): 811-819 98. Ruberte LM, Natarajan RN, Andersson GBJ (2009) Influence of single-level lumbar degenerative disc disease on the behavior of the adjacent segments-A finite element model study. J Biomech 42(3): 341-348 99. Kettler A, Rohlmann F, Ring C, Mack C, Wilke HJ (2011) Do early stages of lumbar intervertebral disc degeneration really cause instability? Evaluation of an in vitro database. Eur Spine J 20(4): 578-584 100. Wilke HJ, Rohlmann F, Neidlinger-Wilke C, Werner K, Claes L, Kettler A (2006) Validity and interobserver agreement of a new radiographic grading system for intervertebral disc degeneration: Part I. Lumbar spine. Eur Spine J 15(6): 720-730 101. Chiang MF, Teng JM, Huang CH, Cheng CK, Chen CS, Chang TK, Chao SH (2004) Finite element analysis of cage subsidence in cervical interbody fusion. J Med Biol Eng 4(24): 201-208 102. Galbusera F, Bellini CM, Anasetti F, Ciavarro C, Lovi A, Brayda-Bruno M (2011) Rigid and flexible spinal stabilization devices: a biomechanical comparison. Med Eng Phys 33(4): 490-496 103. Zhu Q, Larson CR, Sjovold SG, Rosler DM, Keynan O, Wilson DR, Cripton PA, Oxland TR (2007) Biomechanical evaluation of the total facet arthroplasty system: 3-dimensional kinematics. Spine 32(1): 55-62 104. Phillips FM, Tzermiadianos MN, Voronov LI, Havey RM, Carandang G, Renner SM, Rosler DM, Ochoa JA, Patwardhan AG (2009) Effect of the total facet arthroplasty system after complete laminectomy-facetectomy on the biomechanics of implanted and adjacent segments. Spine J 9(1): 96-102 105. Goel VK, Mehta A, Jangra J, Faizan A, Kiapour A, Hoy RW, Fauth AR (2007) Anatomic facet replacement system (AFRS) restoration of lumbar segment mechanics to intact: a finite element study and in vitro cadaveric investigation. SAS J 1(1): 46-54 106. Goel VK, Grauer JN, Patel TCh, Biyani A, Sairyo K, Vishnubhotla S, Matyas A, Cowgill I, Shaw M, Long R, Dick D, Panjabi MM, Serhan H (2005) Effects of charite’ artificial disc on the implanted and adjacent spinal segments mechanics using a hybrid testing protocol. Spine 30(24): 2755-2764 107. Panjabi M, Henderson G, Abjornson C, Yue J (2007) Multidirectional testing of one- and two-level ProDisc-L versus simulated fusions. Spine 32(12): 1311-1319 108. Yamamoto I, Panjabi MM, Crisco T, Oxland T (1989) Three-dimension movement of the whole lumbar spine and lumbosacral joint. Spine 14(11): 1256-1260 109. Freudiger S, Dubios G, Lorrain M (1999) Dynamic neutralization of the lumbar spine confirmed on a new lumbar spine simulator in vitro. Arch Orthop Trauma Surg 119(3-4): 127-132 110. Kiapour A, Ambati D, Hoy RW, Goel VK (2012) Effect of graded facetectomy on biomechanics of Dynesys dynamic stabilization system. Spine 37(10): E581-E589 111. Stoll TM, Dubois G, Schwarzenbach O (2002) The dynamic neutralization system for the spine: a multi-center study of a novel non-fusion system. Eur Spine J 11(Suppl 2): S170-S178 112. Vaga S, Brayda-Bruno M, Perona F, Fornari M, Raimondi MT,Petruzzi M, Grava G, Costa F, Caiani EG, Lamartina C (2009) Molecular MR imaging for the evaluation of the effect of dynamic stabilization on lumbar intervertebral discs. Eur Spine J 18(Suppl 1): 40-48 113. Schaeren S, Broger I, Jeanneret B (2008) Minimum four-year follow-up of spinal stenosis with degenerative spondylolisthesis treated with decompression and dynamic stabilization. Spine 33(18): 636-642 114. Kim H, Lim DH, Oh HJ, Lee KY, Lee SJ (2011) Effects of nonlinearity in the materials used for the semi-rigid pedicle screw systems on biomechanical behaviors of the lumbar spine after surgery. Biomed Mater 6(5): 055005 115. Park WM, Kim K, Kim YH (2013) Effects of degenerated intervertebral discs on intersegmental rotations, intradiscal pressures, and facet joint forces of the whole lumbar spine. Comput Biol Med 43(9): 1234-1240 116. Taddei F, Pancanti A, Viceconti M. (2004) An improved method for the automatic mapping of computed tomography numbers onto finite element models. Med Eng Phys 26(1): 61-69 117. Lin HM, Pan YN, Liu CL, Huang LY, Huang CH, Chen CS (2013) Biomechanical comparison of the K-ROD and Dynesys dynamic spinal fixator systems-a finite element analysis. Biomed Mater Eng 23(6): 495-505 118. Lin HM, Liu CL, Pan YN, Huang CH, Shih SL, Wei SH, Chen CS (2014) Biomechanical analysis and design of a dynamic spinal fixator using topology optimization: a finite element analysis. Med Biol Eng Comput 52(5): 499-508 119. Chang BS, Brown PR, Sieber A, Valdevit A, Tateno K, Kostuik JP (2004) Evaluation of the biological response of wear debris. Spine J 4(6 Suppl): 239S-244S 120. Jiang Y, Jia T, Gong W, Wooley PH, Yang SY (2013) Effects of Ti, PMMA, UHMWPE, and Co-Cr wear particles on differentiation and functions of bone marrow stromal cells. J Biomed Mater Res A 101(10): 2817-2825 121. Abu-Amer Y, Darwech I, Clohisy JC (2007) Aseptic loosening of total joint replacements: Mechanisms underlying osteolysis and potential therapies. Arthritis Res Ther 9(Suppl 1): S6 122. Manolagas SC, Jilka RL, Girasole G, Passeri G, Bellido T (1993) Estrogen, cytokines, and the control of osteoclast formation and bone resorption in vitro and in vivo. Osteoporos Int 3(Suppl 1): 114-116 | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/57671 | - |
dc.description.abstract | Surgeons often use spinal fixators to manage spinal instability. Dynamic spinal fixators, such as the Dynesys (DY) and K-ROD (KD) systems, are designed to restore spinal stability and to provide flexibility. The long-term complications of implant breakage and the biomechanics of the adjacent and the bridged levels using KD system are still unknown. In addition, it is important to optimize the dynamic implant stiffness for desired spinal range of motion (ROM) achievement. As first, this study investigates stiffness of KD system and shows the stiffer structure from KD system. Afterwards, this study is to design a new spinal fixator using topology optimization (topology design (TD) system) to reduce the overall stiffness. Also, this study proceeds to investigate and compare the biomechanical effects of DY, KD, and TD system. Here, this study constructed finite element (FE) models of degenerative disc disease (DDD), DY, KD, and TD system. A hybrid-controlled analysis was applied to each of the four FE models. The rod structure of the topology optimization was modeled at a 39% reduced volume compared with the rigid rod. The FE results indicated that KD system supplies the greater stiffness during extension and the lower stiffness during flexion, in contrast to DY system. In contrast to DY system, KD system increased zygapophysial joint force of adjacent level, but this system decreased the cranial adjacent disc and pedicle screw stress during flexion. Additionally, KD and DY systems increased stiffness to within 47% of the value in the DDD model in all motions. As for TD system, it provided the softer rigidly structure during flexion in contrast to KD and DY system and was similar to DY system in terms of rigidly construct during extension, lateral bending, and torsion. TD system reduced the load in cranial adjacent disc and adjacent zygapophysial joint. The implant was burdened with TD system. Hence, topology design system is possible to avoid early adjacent disc and zygapophysial joint degeneration. Nevertheless, in contrast to KD and DY system, the lower load in the pedicle screw of TD system may prolong the life of pedicle screw in fatigue performance. | en |
dc.description.provenance | Made available in DSpace on 2021-06-16T06:57:10Z (GMT). No. of bitstreams: 1 ntu-103-D95522005-1.pdf: 9812851 bytes, checksum: 5eebe8ec12d38fe80ee4efa127b164b5 (MD5) Previous issue date: 2014 | en |
dc.description.tableofcontents | Abstract (Chinese) III
Abstract (English) IV Chapter 1: Introduction 1 1.1 Overview 1 1.2 Motivation and Objectives 2 1.3 Outline 2 Chapter 2: Background 4 2.1 Spinal anatomy and behavior 4 2.2 Biomechanics for lumbar spine 20 2.3 Disc degeneration 25 2.4 Computational model 27 2.5 Spinal topological optimized implant 34 2.6 Pedicle screw-based stabilization systems 42 Chapter 3: Material and Method 49 3.1 Validation of the FE model 49 3.2 FE model of DY and KD systems 53 3.3 New design of dynamic spinal fixator using topology optimization 53 3.4 Boundary and loading conditions 61 Chapter 4: Result 62 4.1 K-Rod and Dynesys 62 4.1.1 ROM of lumbar spine 62 4.1.2 Stress of adjacent disc and lumbar spine 62 4.1.3 Facet contact forces 62 4.1.4 Pedicle screw stress 68 4.2 Topology Optimization 68 4.2.1 ROM of lumbar spine 68 4.2.2 Stress on the adjacent disc 71 4.2.3 Facet contact forces 71 4.2.4 Stress on the pedicle screw 76 Chapter 5: Discussion 79 Chapter 6: Conclusion and Future work 89 Reference 93 Curriculum Vitae 106 | |
dc.language.iso | en | |
dc.title | 腰椎手術之三維有限元素分析:動態脊椎內固定器之拓樸最佳化設計 | zh_TW |
dc.title | Three-dimensional Finite Element Analysis of a Human Lumbar Spinal Surgery: Topology Optimization Design of the Dynamic Spinal Fixator | en |
dc.type | Thesis | |
dc.date.schoolyear | 102-2 | |
dc.description.degree | 博士 | |
dc.contributor.coadvisor | 陳振昇(Chen-Sheng Chen) | |
dc.contributor.oralexamcommittee | 陳文斌(Weng-Pin Chen),張定國(Ting-Kuo Chang),林峻立(Chun-Li Lin) | |
dc.subject.keyword | 拓樸最佳化,有限元素分析,脊椎生物力學,動態脊椎穩定器,Dynesys,K-ROD, | zh_TW |
dc.subject.keyword | topology optimization,finite element analysis,spinal biomechanics,dynamic spinal stabilization devices,Dynesys,K-ROD, | en |
dc.relation.page | 107 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2014-07-18 | |
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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