Research progress in creep characteristics of lumbar intervertebral disc_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

WANG Chao ,  SHI Zhicai

Department of Spine Surgery, Changhai Hospital Affiliated to Naval Medical University, Shanghai, 200433, P.R.China;

Corresponding author：

SHI Zhicai, Email: zhicaishi@vip.sina.com

Keywords：

Intervertebral disc; viscoelasticity; creep characteristics; research progress

DOI：

10.7507/1002-1892.202002167

Video：

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Objective To summarize the research progress in creep characteristics of lumbar intervertebral disc.Methods The relevant literature at home and abroad was systematically searched. Then, the concept and structural basis of lumbar disc creep, the description of creep characteristics, and the latest progress of its influencing factors were summarized and analyzed.Results The intervertebral disc is viscoelastic. After loading, the deformation increases with time. However, the degree of increase is not linear with time. That is creep, which plays an important role in buffering the load generated by human activities and absorbing energy in order to maintain stable movement of the spine. Both experimental and simulation studies can well describe the creep behavior of intervertebral disc. Various models including standard linear solid model and corresponding constitutive equations can quantify and compare the creep characteristics, which can be obviously changed by the degeneration of intervertebral disc and the mode of loading stress.Conclusion Creep is an important mechanical properties of intervertebral discs, and an in-depth understanding of the creep characteristics of lumbar intervertebral discs is of great guiding significance for the intervention and treatment of low back pain.

Citation： WANG Chao, SHI Zhicai. Research progress in creep characteristics of lumbar intervertebral disc. Chinese Journal of Reparative and Reconstructive Surgery, 2020, 34(12): 1624-1629. doi: 10.7507/1002-1892.202002167 Copy

1.	Castro AP, Wilson W, Huyghe JM, et al. Intervertebral disc creep behavior assessment through an open source finite element solver. J Biomech, 2014, 47(1): 297-301.
2.	王宏杰, 张永兴, 赵庆华. 椎间盘源性腰痛疼痛机制的研究进展. 中国矫形外科杂志, 2019, 27(3): 248-250.
3.	Molladavoodi S, McMorran J, Gregory D. Mechanobiology of annulus fibrosus and nucleus pulposus cells in intervertebral discs. Cell Tissue Res, 2020, 379(3): 429-444.
4.	张伟, 宫赫, 王丽珍, 等. 腰椎间盘退行性变及损伤的生物力学研究进展. 生物医学工程与临床, 2015, 19(2): 201-207.
5.	Ohshima H, Tsuji H, Hirano N, et al. Water diffusion pathway, swelling pressure, and biomechanical properties of the intervertebral disc during compression load. Spine (Phila Pa 1976), 1989, 14(11): 1234-1244.
6.	Johannessen W, Vresilovic EJ, Wright AC, et al. Intervertebral disc mechanics are restored following cyclic loading and unloaded recovery. Ann Biomed Eng, 2004, 32(1): 70-76.
7.	van der Veen AJ, Bisschop A, Mullender MG, et al. Modelling creep behaviour of the human intervertebral disc. J Biomech, 2013, 46(12): 2101-2103.
8.	O’Connell GD, Jacobs NT, Sen S, et al. Axial creep loading and unloaded recovery of the human intervertebral disc and the effect of degeneration. J Mech Behav Biomed Mater, 2011, 4(7): 933-942.
9.	Velísková P, Bashkuev M, Shirazi-Adl A, et al. Computational study of the role of fluid content and flow on the lumbar disc response in cyclic compression: Replication of in vitro and in vivo conditions. J Biomech, 2018, 70: 16-25.
10.	Campana S, Charpail E, de Guise JA, et al. Relationships between viscoelastic properties of lumbar intervertebral disc and degeneration grade assessed by MRI. J Mech Behav Biomed Mater, 2011, 4(4): 593-599.
11.	Keller TS, Spengler DM, Hansson TH. Mechanical behavior of the human lumbar spine. Ⅰ. Creep analysis during static compressive loading. J Orthop Res, 1987, 5(4): 467-478.
12.	柳松扬, 朱东明, 孙长祝, 等. 人体椎间盘粘弹性特性的研究. 北京生物医学工程, 1989, 8(3): 129-135.
13.	杨秀萍, 栾义超, 张静静, 等. 不同加载条件下的腰椎间盘蠕变实验研究. 山东大学学报 (理学版), 2017, 52(5): 31-36.
14.	Hwang D, Gabai AS, Yu M, et al. Role of load history in intervertebral disc mechanics and intradiscal pressure generation. Biomech Model Mechanobiol, 2012, 11(1-2): 95-106.
15.	Cassidy JJ, Silverstein MS, Hiltner A, et al. A water transport model for the creep response of the intervertebral disc. Journal of Materials Science: Materials in Medicine, 1990, 1(2): 81-89.
16.	Argoubi M, Shirazi-Adl A. Poroelastic creep response analysis of a lumbar motion segment in compression. J Biomech, 1996, 29(10): 1331-1339.
17.	李睿, 郭立新. 低频振动作用下人体椎间盘多孔弹性单元的研究. 应用力学学报, 2013, 30(4): 635-640.
18.	李睿, 罗跃纲, 郭立新, 等. 基于多孔弹性模型的脊椎关节生物力学特性和体液流动特性研究. 应用力学学报, 2020, 37(1): 225-230.
19.	Guo LX, Li R, Zhang M. Biomechanical and fluid flowing characteristics of intervertebral disc of lumbar spine predicted by poroelastic finite element method. Acta Bioeng Biomech, 2016, 18(2): 19-29.
20.	Schmidt H, Galbusera F, Rohlmann A, et al. What have we learned from finite element model studies of lumbar intervertebral discs in the past four decades? J Biomech, 2013, 46(14): 2342-2355.
21.	庞胤, 尹帅, 赵长义, 等. 脊柱腰段三维有限元模型的构建与椎间盘应力分析. 河北医科大学学报, 2019, 40(12): 1368-1371.
22.	Vergroesen PP, Kingma I, Emanuel KS, et al. Mechanics and biology in intervertebral disc degeneration: a vicious circle. Osteoarthr Cartil, 2015, 23(7): 1057-1070.
23.	Nikkhoo M, Wang JL, Parnianpour M, et al. Biomechanical response of intact, degenerated and repaired intervertebral discs under impact loading—Ex-vivo and In-Silico investigation. J Biomech, 2018, 70: 26-32.
24.	Detiger SE, Hoogendoorn RJ, van der Veen AJ, et al. Biomechanical and rheological characterization of mild intervertebral disc degeneration in a large animal model. J Orthop Res, 2013, 31(5): 703-709.
25.	Nikkhoo M, Hsu YC, Haghpanahi M, et al. A meta-model analysis of a finite element simulation for defining poroelastic properties of intervertebral discs. Proc Inst Mech Eng H, 2013, 227(6): 672-682.
26.	Vergroesen PA, Emanuel KS, Peeters M, et al. Are axial intervertebral disc biomechanics determined by osmosis? J Biomech, 2018, 70: 4-9.
27.	Johannessen W, Cloyd JM, O’Connell GD, et al. Trans-endplate nucleotomy increases deformation and creep response in axial loading. Ann Biomed Eng, 2006, 34(4): 687-696.
28.	朱松峰, 杨秀萍, 栾义超, 等. 压缩载荷下猪腰椎间盘髓核摘除后力学行为的实验研究. 生物医学工程学杂志, 2019, 36(4): 590-595.
29.	Vergroesen PP, van der Veen AJ, van Royen BJ, et al. Intradiscal pressure depends on recent loading and correlates with disc height and compressive stiffness. Eur Spine J, 2014, 23(11): 2359-2368.
30.	Yang X, Cheng X, Luan Y, et al. Creep experimental study on the lumbar intervertebral disk under vibration compression load. Proc Inst Mech Eng H, 2019, 233(8): 858-867.
31.	Hartvigsen J, Hancock MJ, Kongsted A, et al. What low back pain is and why we need to pay attention. Lancet, 2018, 391(10137): 2356-2367.
32.	Xue Y, Ding T, Wang D, et al. Endoscopic rhizotomy for chronic lumbar zygapophysial joint pain. J Orthop Surg Res, 2020, 15(1): 4-9.

1. Castro AP, Wilson W, Huyghe JM, et al. Intervertebral disc creep behavior assessment through an open source finite element solver. J Biomech, 2014, 47(1): 297-301.
2. 王宏杰, 张永兴, 赵庆华. 椎间盘源性腰痛疼痛机制的研究进展. 中国矫形外科杂志, 2019, 27(3): 248-250.
3. Molladavoodi S, McMorran J, Gregory D. Mechanobiology of annulus fibrosus and nucleus pulposus cells in intervertebral discs. Cell Tissue Res, 2020, 379(3): 429-444.
4. 张伟, 宫赫, 王丽珍, 等. 腰椎间盘退行性变及损伤的生物力学研究进展. 生物医学工程与临床, 2015, 19(2): 201-207.
5. Ohshima H, Tsuji H, Hirano N, et al. Water diffusion pathway, swelling pressure, and biomechanical properties of the intervertebral disc during compression load. Spine (Phila Pa 1976), 1989, 14(11): 1234-1244.
6. Johannessen W, Vresilovic EJ, Wright AC, et al. Intervertebral disc mechanics are restored following cyclic loading and unloaded recovery. Ann Biomed Eng, 2004, 32(1): 70-76.
7. van der Veen AJ, Bisschop A, Mullender MG, et al. Modelling creep behaviour of the human intervertebral disc. J Biomech, 2013, 46(12): 2101-2103.
8. O’Connell GD, Jacobs NT, Sen S, et al. Axial creep loading and unloaded recovery of the human intervertebral disc and the effect of degeneration. J Mech Behav Biomed Mater, 2011, 4(7): 933-942.
9. Velísková P, Bashkuev M, Shirazi-Adl A, et al. Computational study of the role of fluid content and flow on the lumbar disc response in cyclic compression: Replication of in vitro and in vivo conditions. J Biomech, 2018, 70: 16-25.
10. Campana S, Charpail E, de Guise JA, et al. Relationships between viscoelastic properties of lumbar intervertebral disc and degeneration grade assessed by MRI. J Mech Behav Biomed Mater, 2011, 4(4): 593-599.
11. Keller TS, Spengler DM, Hansson TH. Mechanical behavior of the human lumbar spine. Ⅰ. Creep analysis during static compressive loading. J Orthop Res, 1987, 5(4): 467-478.
12. 柳松扬, 朱东明, 孙长祝, 等. 人体椎间盘粘弹性特性的研究. 北京生物医学工程, 1989, 8(3): 129-135.
13. 杨秀萍, 栾义超, 张静静, 等. 不同加载条件下的腰椎间盘蠕变实验研究. 山东大学学报 (理学版), 2017, 52(5): 31-36.
14. Hwang D, Gabai AS, Yu M, et al. Role of load history in intervertebral disc mechanics and intradiscal pressure generation. Biomech Model Mechanobiol, 2012, 11(1-2): 95-106.
15. Cassidy JJ, Silverstein MS, Hiltner A, et al. A water transport model for the creep response of the intervertebral disc. Journal of Materials Science: Materials in Medicine, 1990, 1(2): 81-89.
16. Argoubi M, Shirazi-Adl A. Poroelastic creep response analysis of a lumbar motion segment in compression. J Biomech, 1996, 29(10): 1331-1339.
17. 李睿, 郭立新. 低频振动作用下人体椎间盘多孔弹性单元的研究. 应用力学学报, 2013, 30(4): 635-640.
18. 李睿, 罗跃纲, 郭立新, 等. 基于多孔弹性模型的脊椎关节生物力学特性和体液流动特性研究. 应用力学学报, 2020, 37(1): 225-230.
19. Guo LX, Li R, Zhang M. Biomechanical and fluid flowing characteristics of intervertebral disc of lumbar spine predicted by poroelastic finite element method. Acta Bioeng Biomech, 2016, 18(2): 19-29.
20. Schmidt H, Galbusera F, Rohlmann A, et al. What have we learned from finite element model studies of lumbar intervertebral discs in the past four decades? J Biomech, 2013, 46(14): 2342-2355.
21. 庞胤, 尹帅, 赵长义, 等. 脊柱腰段三维有限元模型的构建与椎间盘应力分析. 河北医科大学学报, 2019, 40(12): 1368-1371.
22. Vergroesen PP, Kingma I, Emanuel KS, et al. Mechanics and biology in intervertebral disc degeneration: a vicious circle. Osteoarthr Cartil, 2015, 23(7): 1057-1070.
23. Nikkhoo M, Wang JL, Parnianpour M, et al. Biomechanical response of intact, degenerated and repaired intervertebral discs under impact loading—Ex-vivo and In-Silico investigation. J Biomech, 2018, 70: 26-32.
24. Detiger SE, Hoogendoorn RJ, van der Veen AJ, et al. Biomechanical and rheological characterization of mild intervertebral disc degeneration in a large animal model. J Orthop Res, 2013, 31(5): 703-709.
25. Nikkhoo M, Hsu YC, Haghpanahi M, et al. A meta-model analysis of a finite element simulation for defining poroelastic properties of intervertebral discs. Proc Inst Mech Eng H, 2013, 227(6): 672-682.
26. Vergroesen PA, Emanuel KS, Peeters M, et al. Are axial intervertebral disc biomechanics determined by osmosis? J Biomech, 2018, 70: 4-9.
27. Johannessen W, Cloyd JM, O’Connell GD, et al. Trans-endplate nucleotomy increases deformation and creep response in axial loading. Ann Biomed Eng, 2006, 34(4): 687-696.
28. 朱松峰, 杨秀萍, 栾义超, 等. 压缩载荷下猪腰椎间盘髓核摘除后力学行为的实验研究. 生物医学工程学杂志, 2019, 36(4): 590-595.
29. Vergroesen PP, van der Veen AJ, van Royen BJ, et al. Intradiscal pressure depends on recent loading and correlates with disc height and compressive stiffness. Eur Spine J, 2014, 23(11): 2359-2368.
30. Yang X, Cheng X, Luan Y, et al. Creep experimental study on the lumbar intervertebral disk under vibration compression load. Proc Inst Mech Eng H, 2019, 233(8): 858-867.
31. Hartvigsen J, Hancock MJ, Kongsted A, et al. What low back pain is and why we need to pay attention. Lancet, 2018, 391(10137): 2356-2367.
32. Xue Y, Ding T, Wang D, et al. Endoscopic rhizotomy for chronic lumbar zygapophysial joint pain. J Orthop Surg Res, 2020, 15(1): 4-9.

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Research progress in creep characteristics of lumbar intervertebral disc

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