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Abstract
Objective: Whether first coronal reverse vertebrae (FCRV) can directly cause biomechanical changes in adjacent segments remains unclear. The objective of this study was to explore the biomechanical changes in adjacent discs of the FCRV to better understand the stress distribution of adolescent idiopathic scoliosis (AIS).
Methods: According to the plain CT scan data of T8–T10 segment of an AIS patient, T9 was the FCRV, and a three-dimensional FE model was established accurately. The T8–T9 segment disc was defined as the adjacent upper disc (UD), axial section as half of the upper disc (HUD). Similarly, T9–T10 segment disc was the adjacent lower disc (LD), axial section as half of the lower disc (HLD). The biomechanical changes in adjacent discs of the FCRV under different loads were assessed.
Results: The maximum Von-Mises stress values of the LD were greater under various loads than those of the HLD, UD, and HUD. The average stress on the LD was greater than that of the other discs under the left lateral bending (LLB) or right lateral bending (RLB) load. It was noted that the concave side of the LD was subjected to greater stress under the neutral standing or LLB load compared with convex side. Additionally, the concave side of the LD was subjected to greater stress under the LLB or RLB load compared with that of other discs. Interestingly, the same trends were observed for the convex side of the LD.
Conclusions: FCRV caused LD to take on greater stress magnitudes. The stress showed a trend of local concentration, which was in the concave side of the scoliosis. These findings could contribute to further treatment planning for the patient and aid physicians’ management decision-making.
Keywords
adjacent disc stress
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adolescent idiopathic scoliosis
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finite element analysis
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first coronal reverse vertebrae
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Zhenguo Shang, Zhiyong Hou, Wei Chen, Hengrui Chang, Jiaxin Xu, Di Zhang, Hui Wang.
Biomechanical Characteristics of First Coronal Reverse Vertebrae in Lenke Type V Adolescent Idiopathic Scoliosis: A Study Using Finite Element Analysis.
Orthopaedic Surgery, 2025, 17(2): 563-574 DOI:10.1111/os.14294
| [1] |
S. L. Weinstein, L. A. Dolan, J. C. Cheng, A. Danielsson, and J. A. Morcuende, “Adolescent Idiopathic Scoliosis,” Lancet 371, no. 9623 (2008): 1527–1537,
|
| [2] |
F. Altaf, A. Gibson, Z. Dannawi, and H. Noordeen, “Adolescent Idiopathic Scoliosis,” BMJ 30, no. 346 (2013): f2508,
|
| [3] |
J. E. Lonstein, “Scoliosis: Surgical Versus Nonsurgical Treatment,” Clinical Orthopaedics and Related Research 443 (2006): 248–259,
|
| [4] |
M. Li, Y. Shen, Z. L. Gao, et al., “Surgical Treatment of Adult Idiopathic Scoliosis: Long-Term Clinical Radiographic Outcomes,” Orthopedics 34, no. 3 (2011): 180,
|
| [5] |
J. Dunn, N. B. Henrikson, C. C. Morrison, P. R. Blasi, M. Nguyen, and J. S. Lin, “Screening for Adolescent Idiopathic Scoliosis: Evidence Report and Systematic Review for the US Preventive Services Task Force,” Journal of the American Medical Association 319, no. 2 (2018): 173–187,
|
| [6] |
T. Zhang, C. Zhu, Y. Zhao, et al., “Deep Learning Model to Classify and Monitor Idiopathic Scoliosis in Adolescents Using a Single Smartphone Photograph,” JAMA Network Open 6, no. 8 (2023): e2330617,
|
| [7] |
S. Yang, T. Sun, L. Zhang, et al., “Stress Distribution of Different Pedicle Screw Insertion Techniques Following Single-Segment TLIF: A Finite Element Analysis Study,” Orthopaedic Surgery 15, no. 4 (2023): 1153–1164,
|
| [8] |
Q. Zhang, T. Chon, Y. Zhang, J. S. Baker, and Y. Gu, “Finite Element Analysis of the Lumbar Spine in Adolescent Idiopathic Scoliosis Subjected to Different Loads,” Computers in Biology and Medicine 136 (2021): 104745,
|
| [9] |
Z. Kamal and G. Rouhi, “Significance of Spine Stability Criteria on Trunk Muscle Forces Following Unilateral Muscle Weakening: A Comparison Between Kinematics-Driven and Stability-Based Kinematics-Driven Musculoskeletal Models,” Medical Engineering & Physics 73 (2019): 51–63,
|
| [10] |
F. H. Cheng, S. L. Shih, W. K. Chou, C. L. Liu, W. H. Sung, and C. S. Chen, “Finite Element Analysis of the Scoliotic Spine Under Different Loading Conditions,” Bio-Medical Materials and Engineering 20, no. 5 (2010): 251–259,
|
| [11] |
J. Zheng, Y. Yang, S. Lou, D. Zhang, and S. Liao, “Construction and Validation of a Three-Dimensional Finite Element Model of Degenerative Scoliosis,” Journal of Orthopaedic Surgery and Research 24, no. 10 (2015): 189,
|
| [12] |
Z. Kamal, G. Rouhi, N. Arjmand, and S. Adeeb, “A Stability-Based Model of a Growing Spine With Adolescent Idiopathic Scoliosis: A Combination of Musculoskeletal and Finite Element Approaches,” Medical Engineering & Physics 64 (2019): 46–55,
|
| [13] |
B. Stott and M. Driscoll, “Biomechanical Evaluation of the Thoracolumbar Spine Comparing Healthy and Irregular Thoracic and Lumbar Curvatures,” Computers in Biology and Medicine 160 (2023): 106982,
|
| [14] |
H. Wang, D. Zou, Z. Sun, L. Wang, W. Ding, and W. Li, “Hounsfield Unit for Assessing Vertebral Bone Quality and Asymmetrical Vertebral Degeneration in Degenerative Lumbar Scoliosis,” Spine (Phila pa 1976) 45, no. 22 (2020): 1559–1566,
|
| [15] |
H. Wang, Z. Sun, L. Wang, D. Zou, and W. Li, “Proximal Fusion Level Above First Coronal Reverse Vertebrae: An Essential Factor Decreasing the Risk of Adjacent Segment Degeneration in Degenerative Lumbar Scoliosis,” Global Spine Journal 13, no. 1 (2023): 149–155,
|
| [16] |
X. Hou, Z. Sun, W. Li, et al., “Upper Instrumented Vertebrae Selection Criteria for Degenerative Lumbar Scoliosis Based on the Hounsfield Unit Asymmetry of the First Coronal Reverse Vertebrae: An Observational Study,” Journal of Orthopaedic Surgery and Research 18, no. 1 (2023): 819,
|
| [17] |
X. Y. Cai, D. Sang, C. X. Yuchi, et al., “Using Finite Element Analysis to Determine Effects of the Motion Loading Method on Facet Joint Forces After Cervical Disc Degeneration,” Computers in Biology and Medicine 116 (2020): 103519,
|
| [18] |
J. K. Biswas, M. Rana, A. Malas, S. Roy, S. Chatterjee, and S. Choudhury, “Effect of Single and Multilevel Artificial Inter-Vertebral Disc Replacement in Lumbar Spine: A Finite Element Study,” International Journal of Artificial Organs 45, no. 2 (2022): 193–199,
|
| [19] |
A. Polikeit, S. J. Ferguson, L. P. Nolte, and T. E. Orr, “Factors Influencing Stresses in the Lumbar Spine After the Insertion of Intervertebral Cages: Finite Element Analysis,” European Spine Journal 12, no. 4 (2003): 413–420,
|
| [20] |
M. Rana, S. Roy, P. Biswas, S. K. Biswas, and J. K. Biswas, “Design and Development of a Novel Expanding Flexible Rod Device (FRD) for Stability in the Lumbar Spine: A Finite-Element Study,” International Journal of Artificial Organs 43, no. 12 (2020): 803–810,
|
| [21] |
T. Wiczenbach, L. Pachocki, K. Daszkiewicz, P. Łuczkiewicz, and W. Witkowski, “Development and Validation of Lumbar Spine Finite Element Model,” PeerJ 11, no. 11 (2023): e15805,
|
| [22] |
C. Du, Z. Mo, S. Tian, et al., “Biomechanical Investigation of Thoracolumbar Spine in Different Postures During Ejection Using a Combined Finite Element and Multi-Body Approach,” International Journal of Numerical Methods in Biomedical Engineering 30, no. 11 (2014): 1121–1131,
|
| [23] |
I. Yamamoto, M. M. Panjabi, T. Crisco, and T. Oxland, “Three-Dimensional Movements of the Whole Lumbar Spine and Lumbosacral Joint,” Spine (Phila pa 1976) 14, no. 11 (1989): 1256–1260,
|
| [24] |
I. A. Stokes and J. P. Laible, “Three-Dimensional Osseo-Ligamentous Model of the Thorax Representing Initiation of Scoliosis by Asymmetric Growth,” Journal of Biomechanics 23, no. 6 (1990): 589–595,
|
| [25] |
M. Goto, N. Kawakami, H. Azegami, Y. Matsuyama, K. Takeuchi, and R. Sasaoka, “Buckling and Bone Modeling as Factors in the Development of Idiopathic Scoliosis,” Spine (Phila Pa 1976) 28, no. 4 (2003): 364–370, discussion 371,
|
| [26] |
A. M. Huynh, C. E. Aubin, T. Rajwani, K. M. Bagnall, and I. Villemure, “Pedicle Growth Asymmetry as a Cause of Adolescent Idiopathic Scoliosis: A Biomechanical Study,” European Spine Journal 16, no. 4 (2007): 523–529,
|
| [27] |
L. Vavruch, D. Forsberg, N. Dahlström, and H. Tropp, “Vertebral Axial Asymmetry in Adolescent Idiopathic Scoliosis,” Spine Deformity 6, no. 2 (2018): 112–120.e1,
|
| [28] |
R. C. Brink, J. F. Homans, T. P. C. Schlösser, et al., “CT-Based Study of Vertebral and Intravertebral Rotation in Right Thoracic Adolescent Idiopathic Scoliosis,” European Spine Journal 28, no. 12 (2019): 3044–3052,
|
| [29] |
A. L. Jenkins, 3rd, J. O’Donnell, R. J. Chung, et al., “Redefining the Classification for Bertolotti Syndrome: Anatomical Findings in Lumbosacral Transitional Vertebrae Guide Treatment Selection,” World Neurosurgery 175 (2023): e303–e313,
|
| [30] |
S. Li, B. Xu, Y. Liu, et al., “Biomechanical Evaluation of Spinal Column After Percutaneous Cement Discoplasty: A Finite Element Analysis,” Orthopaedic Surgery 14, no. 8 (2022): 1853–1863,
|
| [31] |
M. Krismer, C. Haid, H. Behensky, P. Kapfinger, F. Landauer, and F. Rachbauer, “Motion in Lumbar Functional Spine Units During Side Bending and Axial Rotation Moments Depending on the Degree of Degeneration,” Spine (Phila Pa 1976) 25, no. 16 (2000): 2020–2027,
|
| [32] |
S. Ke, X. He, M. Yang, S. Wang, X. Song, and Z. Li, “The Biomechanical Influence of Facet Joint Parameters on Corresponding Segment in the Lumbar Spine: A New Visualization Method,” Spine Journal 21, no. 12 (2021): 2112–2121,
|
| [33] |
C. S. Chen, C. K. Cheng, C. L. Liu, and W. H. Lo, “Stress Analysis of the Disc Adjacent to Interbody Fusion in Lumbar Spine,” Medical Engineering & Physics 23, no. 7 (2001): 483–491,
|
| [34] |
N. A. Langrana, C. K. Lee, and S. W. Yang, “Finite-Element Modeling of the Synthetic Intervertebral Disc,” Spine (Phila PA 1976) 16, no. S6 (1991): S245–S252,
|
| [35] |
A. Guy and C. É. Aubin, “Finite Element Simulation of Growth Modulation During Brace Treatment of Adolescent Idiopathic Scoliosis,” Journal of Orthopaedic Research 41, no. 9 (2023): 2065–2074,
|
| [36] |
Comité Nacional de Adolescencia SAP; Comité de Diagnóstico por Imágenes SAP; Sociedad Argentina de Ortopedia y Traumatología Infantil; Sociedad Argentina de Patología de la Columna Vertebral (SAPCV); Comité de Diagnóstico por Imágenes; Colaboradores. “Consenso de escoliosis idiopática del adolescente [Adolescent Idiopathic Scoliosis],” Archivos Argentinos de Pediatría 114, no. 6 (2016): 585–594 (Spanish),
|
| [37] |
B. Yan, X. Lu, Q. Qiu, G. Nie, and Y. Huang, “Association Between Incorrect Posture and Adolescent Idiopathic Scoliosis Among Chinese Adolescents: Findings From a Large-Scale Population-Based Study,” Frontiers in Pediatrics 15, no. 8 (2020): 548,
|
| [38] |
N. Chockalingam, S. Bandi, A. Rahmatalla, P. H. Dangerfield, and E.-N. Ahmed, “Assessment of the Centre of Pressure Pattern and Moments About S2 in Scoliotic Subjects During Normal Walking,” Scoliosis 12, no. 3 (2008): 10,
|
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