Biomechanical role of osteoporosis in the vibration characteristics of human spine after lumbar interbody fusion

Guo, Li‐Xin

doi:10.1002/cnm.3402

Cited by 10 publications

(4 citation statements)

References 65 publications

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“…In TLIF surgery, osteoporosis can lead to disc bulging in the adjacent intervertebral space, affecting the insertional torque and cyclic loading of pedicle screws, increasing the pressures on the upper and lower endplates and the internal fixation system, ultimately resulting in CS, screw loosening, broken screw or rod, and increased lumbar instability. 31,32 These complications at the fusion level can directly or indirectly lead to endplate damage and induce the occurrence of postoperative sclerotic MCs. Patients with osteopenia may also develop pseudarthrosis after LIF, 33 and the pseudarthrosis may experience a certain range of motion in the intervertebral space with lumbar spine movement.…”

Section: Discussionmentioning

confidence: 99%

“…Osteoporosis is characterized by osteopenia and the destruction of the trabecular and cortical bone microarchitecture. In TLIF surgery, osteoporosis can lead to disc bulging in the adjacent intervertebral space, affecting the insertional torque and cyclic loading of pedicle screws, increasing the pressures on the upper and lower endplates and the internal fixation system, ultimately resulting in CS, screw loosening, broken screw or rod, and increased lumbar instability 31,32 . These complications at the fusion level can directly or indirectly lead to endplate damage and induce the occurrence of postoperative sclerotic MCs.…”

Section: Discussionmentioning

confidence: 99%

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Postoperative Sclerotic Modic Changes after Transforaminal Lumbar Interbody Fusion

Xiao,

Zhu,

Xiu

et al. 2023

Spine

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Study Design. A retrospective cohort study. Objective. This study aimed to assess postoperative sclerotic Modic changes (MCs) following transforaminal lumbar interbody fusion (TLIF) for lumbar degenerative disc disease (LDD), investigating their prevalence, risk factors and association with clinical outcomes. Summary of Background Data. Sclerotic MCs may occur in patients with LDD after lumbar interbody fusion. The incidence and characteristics of postoperative sclerotic MCs, as well as their clinical impact, are unknown. Methods. The study included 467 patients (510 levels) who underwent single or two-level TLIF surgery, divided into a postoperative sclerotic MC group (60 patients, 66 levels) and non-MC group (407 patients, 444 levels). The time of development and location of postoperative sclerotic MCs, fusion rate, cage subsidence, bilateral process decompression, and cross-link usage were recorded. Preoperative, postoperative, and follow-up VAS and ODI scores were collected. Multivaraible logistic regression was used to evaluate factors associated with the development of postoperative sclerotic MCs. Results. The prevalence of postoperative sclerotic MCs was 12.8%. The postoperative sclerotic MC group had higher BMI. The postoperative sclerotic MC group demonstrated a fusion rate of 47%, significantly lower than that of the non-MC group (71%) at 6 months post-operation. At final follow-up, the fusion rate in the postoperative sclerotic MC group was 62%, significantly lower than that of the non-MC group (86%). Post-operative VAS and ODI scores were significantly higher in the group with postoperative sclerotic MCs. BMI and osteoporosis were significantly associated with the development of postoperative sclerotic MCs. Conclusion. Postoperative sclerotic MCs generally appear within the first year after surgery, with a prevalence of 12.8%. The presence of postoperative sclerotic MCs can adversely impact post-operative outcomes. To prevent postoperative sclerotic MCs, we postulate extending the immobilization period with external bracing and improving the management of BMI and osteoporosis in the peri-operative time window.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Postoperative Sclerotic Modic Changes after Transforaminal Lumbar Interbody Fusion

Xiao,

Zhu,

Xiu

et al. 2023

Spine

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“…Simplifications are an integral part of any model and have to be taken into consideration when it comes to the interpretation of the results. To understand and evaluate their influence, MBS models have been used to systematically investigate common assumptions, such as the reduction of complex mechanics of the functional spine unit (FSU) [37,115]. Further, the sensitivity of the model accuracy to assumed positions of intervertebral centers of rotation [23,36] or muscle insertions [75] have been analyzed.…”

Section: 1 Studies With Methodological Focusmentioning

confidence: 99%

Multibody Models of the Thoracolumbar Spine: A Review on Applications, Limitations, and Challenges

et al. 2023

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Numerical models of the musculoskeletal system as investigative tools are an integral part of biomechanical and clinical research. While finite element modeling is primarily suitable for the examination of deformation states and internal stresses in flexible bodies, multibody modeling is based on the assumption of rigid bodies, that are connected via joints and flexible elements. This simplification allows the consideration of biomechanical systems from a holistic perspective and thus takes into account multiple influencing factors of mechanical loads. Being the source of major health issues worldwide, the human spine is subject to a variety of studies using these models to investigate and understand healthy and pathological biomechanics of the upper body. In this review, we summarize the current state-of-the-art literature on multibody models of the thoracolumbar spine and identify limitations and challenges related to current modeling approaches.

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“…Furthermore, the surgeon must consider the limitations of the stand-alone (SA) and lateral plate-screw (LPS) fixations in OLIF, which may not provide adequate stability for osteoporotic patients ( Bereczki et al, 2021 ; Wang et al, 2021b ). Under whole-body vibration (WBV), the osteoporosis of the fused vertebrae may make the adjacent segments more unstable, increasing the risk of adjacent segment disease, subsidence, cage failure, rod failure, and lumbar instability ( Wang and Guo, 2020 ). These findings may contribute to a better understanding of the effect of osteoporosis on the static and vibration characteristics of lumbar spine fusion, as well as provide clinical treatment references for lumbar interbody fusion and lumbar vertebrae osteoporosis.…”

Section: Fea Advances In Icsmentioning

confidence: 99%

Recent advancement in finite element analysis of spinal interbody cages: A review

Wang

2023

Front. Bioeng. Biotechnol.

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Finite element analysis (FEA) is a widely used tool in a variety of industries and research endeavors. With its application to spine biomechanics, FEA has contributed to a better understanding of the spine, its components, and its behavior in physiological and pathological conditions, as well as assisting in the design and application of spinal instrumentation, particularly spinal interbody cages (ICs). IC is a highly effective instrumentation for achieving spinal fusion that has been used to treat a variety of spinal disorders, including degenerative disc disease, trauma, tumor reconstruction, and scoliosis. The application of FEA lets new designs be thoroughly “tested” before a cage is even manufactured, allowing bio-mechanical responses and spinal fusion processes that cannot easily be experimented upon in vivo to be examined and “diagnosis” to be performed, which is an important addition to clinical and in vitro experimental studies. This paper reviews the recent progress of FEA in spinal ICs over the last six years. It demonstrates how modeling can aid in evaluating the biomechanical response of cage materials, cage design, and fixation devices, understanding bone formation mechanisms, comparing the benefits of various fusion techniques, and investigating the impact of pathological structures. It also summarizes the various limitations brought about by modeling simplification and looks forward to the significant advancement of spine FEA research as computing efficiency and software capabilities increase. In conclusion, in such a fast-paced field, the FEA is critical for spinal IC studies. It helps in quantitatively and visually demonstrating the cage characteristics after implanting, lowering surgeons’ learning costs for new cage products, and probably assisting them in determining the best IC for patients.

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Biomechanical role of osteoporosis in the vibration characteristics of human spine after lumbar interbody fusion

Cited by 10 publications

References 65 publications

Postoperative Sclerotic Modic Changes after Transforaminal Lumbar Interbody Fusion

Postoperative Sclerotic Modic Changes after Transforaminal Lumbar Interbody Fusion

Multibody Models of the Thoracolumbar Spine: A Review on Applications, Limitations, and Challenges

Recent advancement in finite element analysis of spinal interbody cages: A review

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