Computational and experimental studies of strength properties and durability of implants made of titanium nickelide and vertebral bone tissue during intervertebral disc replacement in a segment of the cervical spine
The paper presents the results of a computer study of the durability of cylindrical endoprostheses made of titanium nickelide, porosity of 60-67%, and vertebral bone tissue of different densities when replacing the intervertebral disc of the cervical segment of the spine. Implants of different sizes were obtained by self-propagating high-temperature synthesis. Loading curves for the porous prostheses under consideration under uniaxial compression were experimentally obtained, from which the mechanical characteristics used in modeling were determined. The assessment of durability when the segment is tilted forward was carried out on the basis of calculations of the stress state of the segment with prostheses and expressions approximating experimental data on cyclic loading of porous samples made of titanium nickelide and bone tissue. As a result of the study, it has been established that the service life of the endoprostheses under consideration is at least 35 years. After the service life of the endoprostheses under consideration, fatigue failure can begin mainly in the outer parts of the prosthesis adjacent to the vertebrae of the segment. Installation of porous endoprostheses made of titanium nickelide will not entail fatigue destruction of the bone tissue of the vertebrae of the segment throughout a person’s life.
Download file
Counter downloads: 3
Keywords
computational and experimental studies, implants made of porous titanium nickelide, segment of the cervical spine, stress-strain state, bone tissue, durabilityAuthors
| Name | Organization | |
| Chaykovskaya Tat’yana V. | Tomsk State University | kolmakova@ftf.tsu.ru |
| Marchenko Ekaterina S. | Tomsk State University | 89138641814@mail.ru |
| Vetrova Anna V. | Tomsk State University | aniuta-vetrova@mail.ru |
References
Formica M., Divano S., Cavagnaro L. et al. Lumbar total disc arthroplasty: outdated surgery or here to stay procedure? A systematic review of current literature // Journal of Orthopaedics and Traumatology. 2017. № 18. P. 197-215.
Verkhozina T.K., Ippolitova E.G., Tsyslyak E.S, Sklyarenko O.V., Koshkareva Z.V. Changes in bone density in patients with osteochondrosis of the cervical spine // Acta Biomedica Scientifica 2019. V. 4 (6). P. 26-31.
Kaiser J., Allaire B., Fein P.M., Lu D., Jarraya M., Guermazi A., Demissie S., Samelson E.J., Bouxsein M.L., Morgan E.F. Correspondence between bone mineral density and intervertebral disc degeneration across age and sex // Arch Osteoporos. 2018. V. 13 (1). Art. 123. 10.1007/s11657-018-0538-1. PMID: 30421154; PMCID: PMC6291246.
Kushchayev S.V., Glushko T., Jarraya M. et al. ABCs of the degenerative spine // Insights Imaging. 2018. № 9. P. 253-274.
Holewijn R.M., de Kleuver M., van der Veen A.J. et al. A novel spinal implant for fusionless scoliosis correction: a biomechanical analysis of the motion preserving properties of a posterior periapical concave distraction device // Global Spine Journal. 2017. № 7. Art. 400-9.
Gunther V.E., Khodorenko V.N. Development of biocompatible superelastic materials and shape memory implants based on titanium nickelide for the creation of highly effective medical technologies // Issues of Reconstructive and Plastic Surgery. 2022. V. 25 (2). P. 45-56.
Seaman S., Kerezoudis P., Bydon M. et al. Titanium vs. polyetheretherketone (PEEK) inter body fusion: meta-analysis and review of the literature // Journal of Clinical Neuroscience. 2017. № 44. Art. 23-9.
Warburton A., Girdler S.J., Mikhail Ch.M., Ahn A., Cho S.K. Biomaterials in spinal implants: a review // Neurospine. 2020. V. 17 (1). P. 101-110.
Panzer M.B. Numerical modeling of the human cervical spine in frontal impact: dissertation for the degree of master of applied science in mechanical engineering. Waterloo, Ontario, Canada, 2006. 248 p.
Ивченко О.А., Гюнтер В.Э., Дамбаев Г.Ц. и др. Медицинские материалы и имплантаты с памятью формы: в 14 т. Томск: Изд-во МИЦ, 2012. Т. 10.
Ланшаков В.А., Гюнтер В.Э., Плоткин Г.Л. и др. Медицинские материалы и имплантаты с памятью формы: в 14 т. Томск: Изд-во МИЦ, 2012. Т. 2.
Topolnitsky E., Chekalkin T.L., Marchenko E.S., Yasenchuk Y.F. et al.Combination of solid and porous nitinol implants in surgical treatment of extensive post-excision thoracic defects in cancer patients // International conference on shape memory and superelastic technologies (SMST 2022). 2022. P. 79-80.
Сысолятин П.Г., Гюнтер В.Э., Миргазизов М.З. и др. Медицинские материалы и имплантаты с памятью формы: в 14 т. Томск: Изд-во МИЦ, 2012. Т. 4.
Gunther V.E., Yasenchuk Yu.F., Gyunter S.V., Marchenko E.S., Iuzhakov M.M. Biocompatibility of porous shs-tini // Materials Science Forum. 2019. V. 970. P. 320-327.
Wang W., Kong C., Pan F. et al. Effects of dynamic and rigid implantation on biomechanical characteristics of different sagittal alignment lumbar after single- or double-level spinal fixations: a finite-element modeling study // European Journal of Medical Research. 2023. № 28. Art. 583.
Biswas J.K., Rana M., Malas A., Roy S., Chatterjee S., Choudhury S. Effect of single and multilevel artificial inter-vertebral disc replacement in lumbar spine: A finite element study // The International Journal of Artificial Organs. 2022. V. 45 (2). P. 193-199.
Zhang W., Zhao J., Li L., Yu C., Zhao Y., Si H. Modelling tri-cortical pedicle screw fixation in thoracic vertebrae under osteoporotic condition: A finite element analysis based on computed tomography // Computer Methods and Programs in Biomedicine. 2020. V. 187. Art. 105035.
Rohlmann A. et al.Comparison of the effects of bilateral posterior dynamic // European Spine Journal. 2007. V. 16 (8). P. 1223-1231.
Kolmakova T.V. Study of the influence of degenerative intervertebral disc changes on the deformation behavior of the cervical spine segment in flexion // AIP Conference Proceedings. 2016. V. 1783. Art. 020095.
Hernandez C.J., Beaupre G.S., Keller T.S., Carter D.R. The influence of bone volume fraction and ash fraction on bone strength and modulus // Bone. 2001. V. 29 (1). P. 74-78.
Ng H.W., Teo E.C., Lee V.S. Statistical factorial analysis on the material property sensitivity of the mechanical responses of the C4-C6 under compression, anterior and posterior shear // Journal of Biomechanics. 2004. V. 37. P. 771-777.
Hueston S., Makola М., Mabe I., Goswami T. Cervical spine anthropometric and finite element biomechanical analysis // Human Musculoskeletal Biomechanics. Wright State University, 2012. P. 107-158.
Rapillard L., Charlebois M., Zysset P.K.Compressive fatigue behavior of human vertebral trabecular bone // Journal of Biomechanics. 2006. V. 39. P. 2133-2139. 10.1016/ j.jbiomech.2005.04.033.
Yuan B., Zhu M., Chung C.Y. Biomedical porous shape memory alloys for hard tissue replacement materials // Materials. 2018. V. 11. Art. 1716. P. 1-53.
Cobian D.G., Sterling A.C., Anderson P.A., Heiderscheit B.C. Task specific frequencies of neck motion measured in healthy young adults over a 5 day period // Spine. 2009. V. 34 (6). P. E202-E207.
Computational and experimental studies of strength properties and durability of implants made of titanium nickelide and vertebral bone tissue during intervertebral disc replacement in a segment of the cervical spine | Vestnik Tomskogo gosudarstvennogo universiteta. Matematika i mekhanika – Tomsk State University Journal of Mathematics and Mechanics. 2024. № 92. DOI: 10.17223/19988621/92/14
Download full-text version
Counter downloads: 99
