[1] Fang XG, Zhao GP, Wang CX, Bai LL, Yan WT, Ma T. Construction and analysis of finite element model of L4 ∼ L5 lumbar motion segment from CT images. Chinese Journal of Biomechanical Engineering. 2014;33(4):487-492.
[2] Ferguson SJ, Steffen T. Biomechanics of the aging spine. European Spine Journal. 2003;12(0):S97-S103.
[3] Belytschko T, Kulak RF, Schultz AB, Galante JO. Finite element stress analysis of an intervertebral disc. Journal of Biomechanics. 1974;7(3):277-285.
[4] Yoganandan N, Kumaresan S, Voo L, Pintar FA. Finite Element Model of the Human Lower Cervical Spine: Parametric Analysis of the C4-C6 Unit. Journal of Biomechanical Engineering. 1997;119(1):87-92.
[5] Goel VK, Kong W, Han JS, Weinstein JN, Gilbertson LG. A Combined Finite Element and Optimization Investigation of Lumbar Spine Mechanics With and Without Muscles. Spine. 1993;18(11):1531-1541.
[6] Wu JSS, Chen JH. Clarification of the mechanical behaviour of spinal motion segments through a three-dimensional poroelastic mixed finite element model. Medical Engineering & Physics. 1996;18(3):215-224.
[7] Gilbertson LG, Goel VK, Kong WZ, Clausen JD. Finite Element Methods in Spine Biomechanics Research. Critical Reviews in Biomedical Engineering. 1995;23(5-6):411-473.
[8] Feng Y. Biomechanical Study of the Effect of Different Lumbar Fusion Cage on Adjacent Segments. Chinese Journal of Biomedical Engineering. 2010;29(5):717-723.
[9] Rohlmann A, Bauer L, Zander T, Bergmann G, Wilke H-J. Determination of trunk muscle forces for flexion and extension by using a validated finite element model of the lumbar spine and measured in vivo data. Journal of Biomechanics. 2006;39(6):981-989.
[10] XU H, ZHANG M, LI Y. Real-time measure of displacement and intra-stress of normal lumbar disc during simulating rotatory ma-nipulation in sitting position. Chinese Journal of Rehabilitation Medicine. 2005;20(8):563-565.
[11] Wan K, Li Y. Application of finite element method in lumbar spine research. Chinese Journal of Bone and Joint Injury. 2006;21(2):158-160.
[12] Qin JS, Yu W, Peng XQ, Jiang YG. Three-dimensional finite element modeling of whole lumbar spine and its biomechanical analysis. Journal of Medical Biomechanics. 2013;28(3):321-325.
[13] Qin D, Zhang X, Nie W. FEM on simulation of change characteristics in human lumbar vertebrae under different motion status. J Med Biomech. 2017;32(4):355-362.
[14] Zhao W-T, Qin D-P, Zhang X-G, Wang Z-P, Tong Z. Biomechanical effects of different vertebral heights after augmentation of osteoporotic vertebral compression fracture: a three-dimensional finite element analysis. Journal of Orthopaedic Surgery and Research. 2018;13(1).
[15] Liu Y, Chen Q. Recent advance in finite element research of disc degeneration and lumbar intervertebral fusion. J Int Journal of Biomech Eng. 2007;30(1):14-17.
[16] Lu YM, Hutton WC, Gharpuray VM. The Effect of Fluid Loss on the Viscoelastic Behavior of the Lumbar Intrevertebral Disc in Compression. Journal of Biomechanical Engineering. 1998;120(1):48-54.
[17] Chen H, Xu H, Zhang M. Real-time monitoring of internal stress of lumbar vertebra by means of sitting position rotation. Chinese Journal of Clinical Anatomy. 2005;23(4):420-422.
[18] Wang J-L, Parnianpour M, Shirazi-Adl A, Engin AE. Viscoelastic Finite-Element Analysis of a Lumbar Motion Segment in Combined Compression and Sagittal Flexion. Spine. 2000;25(3):310-318.
[19] Zhang X, Qin D, Son M. Effects of stress distribution of the degenerative intervertebral disc during lumbar pulling and pressing manipulation by FEM. China Journal of TCM and Pharmacy. 2013;28(10):3108-3114.
[20] Faizan A, Sairyo K, Goel VK, Biyani A, Ebraheim N. Biomechanical rationale of ossification of the secondary ossification center on apophyseal bony ring fracture: A biomechanical study. Clinical Biomechanics. 2007;22(10):1063-1067.
[21] Xiang P, Cheng-Fei DU, Zhao MY, Shan T, Wang LZ, Fan YB. Modal analysis of human lumbar spine using finite element method. Journal of Medical Biomechanics. 2014;29(2):154-160.
[22] Chen S-H, Zhong Z-C, Chen C-S, Chen W-J, Hung C. Biomechanical comparison between lumbar disc arthroplasty and fusion. Medical Engineering & Physics. 2009;31(2):244-253.
[23] Polikeit A, Ferguson SJ, Nolte LP, Orr TE. Factors influencing stresses in the lumbar spine after the insertion of intervertebral cages: finite element analysis. European Spine Journal. 2003;12(4):413-420.
[24] Jin SU, Zhao WZ, Chen BZ, Bin LI, Sheng-Wei HE, Fan X. Establishing finite element contact model of human L1~L5 lumbar segments. Journal of Medical Biomechanics. 2010;25(3):200-205.
[25] Yan JZ, Wu ZH, Wang XS, et al. [Finite element analysis on stress change of the lumbar disc degeneration]. Acta Academiae Medicinae Sinicae. 2009;31(4):464-467.
[26] Fu S, Huang J. Lumbar Spine FEM and Its Clinical Significance. Chinese Medical Equipment Journal. 2012;33(10):76-78.
[27] Liu G, Yi B. Thoracolumbar Vertebra Osteoporosis of Stress Distribution and Clinical Significance. JiLin Med J. 2010;30(19):3126-3127.
[28] Markolf KL, Morris JM. The Structural Components of the Intervertebral Disc. The Journal of Bone & Joint Surgery. 1974;56(4):675-687.
[29] Markolf KL. Deformation of the Thoracolumbar Intervertebral Joints in Response to External Loads. The Journal of Bone & Joint Surgery. 1972;54(3):511-533.
[30] Li J, Zhang X, Yang X. The examples on the manipulation of“three steps and three postures and nine practices” that professor Song Gui jie treats the prolapse of lumbar intervertebral disc. Journal of GanSu University of TCM. 2007;24(6):1-3.
[31] Chen J, Cai G. Computer-aided engineering analysis. Beijing: China press of railway; 2001.
[32] Zhao W, Su J, Chen B. Application of FEM in lumbar spine biomechanical study. Journal of Clinical Rehabilitative Tissue Engineering Research. 2009;13(30):5928-5930.
[33] Bao C, Liu J. Innovative design on finishing device of double grooved Grinding wheel based on TRIZ. Jouranl of Machine Design. 2009;26(9):62-64.
[34] Li L-T, Xue HJ. Investigation on the Relation between Sitting Posture Comfort and Time by Stress Distribution Analysis of L4-L5 centrum. Science Technology & Engineering. 2009;9:2424-2428.
[35] Bao C, Liu J. Lumbar Spine Subjected Stress Characteristic for Operators Using Chain Saw in Forest Harvesting and Finite Element Analysis. Scientia Silvae Sinicae. 2009;45(3):96-100.
[36] Li Y, Zhong S. A new idea of basic research of spine massage: computer simulation and visualization technology. Chinese Journal of Rehabilitation Medicine. 2003;18(7):431-432.
[37] Xu H, Zhang M, Xu D. FEM of lumbar intervertebral disc action by means of three anterior flexural rotations. Chin J Convalescent Med. 2008;17(2):65-67.
[38] Wang G, Zhang M, Li Y. Comparison of lumbar rotation manipulation in three lumbar flexion levels. The Journal of Cervicodynia and Lumbodynia. 2008;29(1):24-26.
[39] Schmidt H, Kettler A, Heuer F, Simon U, Claes L, Wilke H-J. Intradiscal Pressure, Shear Strain, and Fiber Strain in the Intervertebral Disc Under Combined Loading. Spine. 2007;32(7):748-755.
[40] Kozanek M, Wang S, Passias PG, et al. Range of Motion and Orientation of the Lumbar Facet Joints In Vivo. Spine. 2009;34(19):E689-E696.
[41] Ayturk UM, Garcia JJ, Puttlitz CM. The Micromechanical Role of the Annulus Fibrosus Components Under Physiological Loading of the Lumbar Spine. Journal of Biomechanical Engineering. 2010;132(6).
[42] Kuo C-S, Hu H-T, Lin R-M, et al. Biomechanical analysis of the lumbar spine on facet joint force and intradiscal pressure - a finite element study. BMC Musculoskeletal Disorders. 2010;11(1).
[43] Qin M, Chai S, Huang L. Three-dimensional finite element model analysis of lumbar motion segment under different working conditions. Journal of GuangXi Medical University. 2010;27(3):417-419.
[44] Kamińska J, Roman-Liu D, Zagrajek T, Borkowski P. Differences in Lumbar Spine Load Due to Posture and Upper Limb External Load. International Journal of Occupational Safety and Ergonomics. 2010;16(4):421-430.
[45] Xu H, Xu D, Li Y. Analyses of intra-stress and displacement of degenerate lumbar disc during simulating rotatory manipulation by finite element. Chinese Journal of Rehabilitation Medicine. 2007;22(9):769-771.
[46] Wu S, Zhang M, Li Y. FEM of the stress and displacement of lumbar vertebrae of two sitting rotations. Guangdong Medical Journal. 2010;31(8):992-994.
[47] Hua HU, Xiong CY. [Finite element analysis of lumbar pelvic and proximal femur model with simulate lumbar rotatory manipulation]. Zhongguo gu shang = China journal of orthopaedics and traumatology. 2012;25(7):582.
[48] Yang X, Zhang X, Li J. A Three-dimensional Finite Element Model for Simulating Strctching and Pressing Manipulations on Lumbar Vertebrae. Chinese J Trad Traum&Orthop. 2013;21(7):4-6.
[49] Zhang X, Dong J, Yang X. Biomechanical analysis of simulating pulling, extension and compression on the three-dimensional finite element model of lumbar segments. Journal of Clinical Rehabilitative Tissue Engineering Research. 2010;14(22):4000-4004.
[50] Xu H, Li S, Liu L. FEM of the intervertebral disc during lumbar obligue-pulling manipulation. Journal of Clinical Rehabilitative Tissue Engineering Research. 2011;15(13):2335-2338.
[51] Wang Y, Zhang Q, Liu K. Advances in the application of finite element method in lumbar kinematics analysis. Chinese Journal of Rehabilitation Medicine. 2013;28(7):688-690.