Finite element modelling of hybrid stabilization systems for the human lumbar spine

Eylul, Demir; Éltes, Péter Endre; Castro, A. P. G.; Lacroix, Damien; Toktaş, İhsan

doi:10.1177/0954411920946636

Cited by 12 publications

(16 citation statements)

References 63 publications

(103 reference statements)

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“…Fusion fixation reduces thoracolumbar motion, as shown in previous studies [ 15 , 19 ]. Lu and Lu found that the short-segment fusion fixed model decreased by 52–94% compared with the intact model [ 20 ].…”

Section: Discussionsupporting

confidence: 74%

“…Finite element analysis reconstructs the shape of the spine using computer simulation. It then directly interprets spinal biomechanics changes caused by internal fixation by loading its material parameters and loading conditions and guiding the surgical plan [ 15 ]. Finite element analysis can be repeatedly applied, saving medical resources while safely and efficiently simulating complicated surgical procedures.…”

Section: Discussionmentioning

confidence: 99%

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Biomechanical finite element analysis of vertebral column resection and posterior unilateral vertebral resection and reconstruction osteotomy

Han

Wang

et al. 2021

J Orthop Surg Res

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Background Regarding the repair of vertebral compression fractures, there is a lack of adequate biomechanical verification as to whether only half of the vertebral body and the upper and lower intervertebral discs affect spinal biomechanics; there also remains debate as to the appropriate length of fixation. Methods A model of old vertebral compression fractures with kyphosis was established based on CT data. Vertebral column resection (VCR) and posterior unilateral vertebral resection and reconstruction (PUVCR) were performed at T12; long- and short-segment fixation methods were applied, and we analyzed biomechanical changes after surgery. Results Range of motion (ROM) decreased in all fixed models, with lumbar VCR decreasing the most and short posterior unilateral vertebral resection and reconstruction (SPUVCR) decreasing the least; in the long posterior unilateral vertebral resection and reconstruction (LPUVCR) model, the internal fixation system produced the maximum VMS stress of 213.25 mPa in a lateral bending motion and minimum stress of 40.22 mPa in a lateral bending motion in the SVCR. Conclusion There was little difference in thoracolumbar ROM between PUVCR and VCR models, while thoracolumbar ROM was smaller in long-segment fixation than in short-segment fixation. In all models, the VMS was most significant at the screw-rod junction and greatest at the ribcage–vertebral body interface, partly explaining the high probability of internal fixation failure and prosthesis migration in these two positions.

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Section: Discussionsupporting

confidence: 74%

Section: Discussionmentioning

confidence: 99%

Biomechanical finite element analysis of vertebral column resection and posterior unilateral vertebral resection and reconstruction osteotomy

Han

Wang

et al. 2021

J Orthop Surg Res

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show abstract

“…Fusion xation reduces thoracolumbar motion, as shown in previous studies [15,19]. Lu and Lu found that the short-segment fusion xed model decreased by 52-94% compared with the intact model [20].…”

Section: Discussionsupporting

confidence: 60%

“…Finite element analysis reconstructs the shape of the spine using computer simulation, and then directly interprets changes of spinal biomechanics caused by internal xation by loading its material parameters and loading conditions, and then guiding the clinical surgical plan [15]. Finite element analysis can be repeatedly applied, saving medical resources, while safely and e ciently simulating some di cult surgical procedures.…”

Section: Discussionmentioning

confidence: 99%

Treatment of Old Vertebral Compression Fracture With Kyphosis by Different Reconstruction Methods: a Finite Element Analysis

Han¹,

Wang²,

Wu³

et al. 2020

Preprint

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Background: In repair of vertebral compression fractures, there is a lack of effective biomechanical verification as to whether only half of the vertebral body and the upper and lower intervertebral discs has any effect on spinal biomechanics; there also remains debate as to the appropriate length of fixation.Methods: A model of old vertebral compression fractures with kyphosis was established based on CT data. Vertebral column resection (VCR) and posterior unilateral vertebral resection and reconstruction (PUVCR) were performed at T12; long- and short-segment fixation methods were applied, and we analyzed biomechanical changes after surgery.Results: Range of motion (ROM) decreased in all fixed models, with lumbar VCR decreasing the most and short posterior unilateral vertebral resection and reconstruction (SPUVCR) decreasing the least; in the long posterior unilateral vertebral resection and reconstruction (LPUVCR) model, the internal fixation system produced the maximum VMS stress of 213.25 MPa in a lateral bending motion, and a minimum stress of 40.22 MPa in a lateral bending motion in the SVCR.Conclusion: There was little difference in thoracolumbar ROM between PUVCR and VCR models, while thoracolumbar ROM was smaller in long-segment fixation than in short-segment fixation. In all models, the VMS was greatest at the screw-rod junction and greatest at the ribcage–vertebral body interface, which partly explains the high probability of internal fixation failure and prosthesis migration in these two positions.

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“…In fact, FE modelling has already led to relevant conclusions and supported many preclinical studies, namely in what concerns to IVD behaviour or implant development [8,[37][38][39][40]. Additionally, it has also motivated the development of new computational tools (imaging reconstruction methods, FE solvers or even kinematics simulators) that have later led to wider achievements in biomechanics and tissue engineering [41][42][43][44][45][46][47].…”

Section: Computational Biomechanicsmentioning

confidence: 99%

Computational Challenges in Tissue Engineering for the Spine

Castro

2021

Bioengineering

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This paper deals with a brief review of the recent developments in computational modelling applied to innovative treatments of spine diseases. Additionally, it provides a perspective on the research directions expected for the forthcoming years. The spine is composed of distinct and complex tissues that require specific modelling approaches. With the advent of additive manufacturing and increasing computational power, patient-specific treatments have moved from being a research trend to a reality in clinical practice, but there are many issues to be addressed before such approaches become universal. Here, it is identified that the major setback resides in validation of these computational techniques prior to approval by regulatory agencies. Nevertheless, there are very promising indicators in terms of optimised scaffold modelling for both disc arthroplasty and vertebroplasty, powered by a decisive contribution from imaging methods.

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Finite element modelling of hybrid stabilization systems for the human lumbar spine

Cited by 12 publications

References 63 publications

Biomechanical finite element analysis of vertebral column resection and posterior unilateral vertebral resection and reconstruction osteotomy

Biomechanical finite element analysis of vertebral column resection and posterior unilateral vertebral resection and reconstruction osteotomy

Treatment of Old Vertebral Compression Fracture With Kyphosis by Different Reconstruction Methods: a Finite Element Analysis

Computational Challenges in Tissue Engineering for the Spine

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