Biomechanical role of osteoporosis affects the incidence of adjacent segment disease after percutaneous transforaminal endoscopic discectomy

Li, Jingchi; Wang, Xu; Zhang, Xiaoyu; Xi, Zhaodong; Li, Jingchi

doi:10.1186/s13018-019-1166-1

Cited by 35 publications

(54 citation statements)

References 38 publications

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“…FEA models from L3 to S1 were constructed by standard curves. Bone structures include cortical, cancellous, and posterior structures reconstructed in our previous studies which were used as the templates for model construction [8,9,24]. Different parts of the templates were layered, and the outline in each layer was traced by standard curves.…”

Section: Model Constructionmentioning

confidence: 99%

“…In comparison with traditional open posterior surgery, PED should decrease the risk of adjacent segment disease (ASD) which was partly caused by a wide range of postoperative paraspinal muscle atrophy and epidural adhesion [2][3][4]. According to the literature, PED could nonetheless lead to biomechanical deterioration, the most important factor in the development of ASD [5][6][7][8][9].…”

Section: Introductionmentioning

confidence: 99%

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Indications Selection for Surgeons Training in the Translaminar Percutaneous Endoscopic Discectomy Based on Finite Element Analysis

Wang

Jiang

et al. 2020

BioMed Research International

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Background. Translaminar percutaneous endoscopic discectomy (PED) was used widely in the treatment of lumbar disc herniation (LDH), especially for the training of novice surgeons. A larger range of osteotomy was a suitable method to get enough operation space and reduce intraoperative risks. But osteotomy, especially facetectomy, may be associated with the biomechanical deterioration and resulting adjacent segment diseases (ASD). Hence, the objects of this study were to investigate whether different levels of surgical experience in performing different ranges of osteotomy (especially facetectomy) affected the risk for ASD and to identify the safe indications for the training of PED novice surgeons. Study Design. In this study, a three-dimensional lumbosacral model was constructed and validated. Corresponding translaminar PED models with different ranges of osteotomy for armpit, periradicular, and shoulder types of LDH were constructed. The von Mises stress on the endplates, the shear stress on the annulus, the intradiscal pressure, and the range of motion (ROM) in the L3-L4 segment disc were computed. Results. Computational results in our well-validated model indicated that large ranges of osteotomy led to deterioration in most of the biomechanical indicators, and this trend was most significant in the shoulder-type LDH model. Conclusions. To ensure the appropriateness of the surgical prognosis, armpit and periradicular types of LDH can be seen as suitable indications for the training of novice PED surgeons, and shoulder-type LDH should be excluded from such indications until novices can perform PED within a relatively small range of osteotomy. Mini Abstract. Based on biomechanical variations in our finite element analysis, armpit and periradicular types of LDH can be seen as suitable indications for the training of novice PED surgeons, and shoulder-type LDH should be excluded until novices can perform PED within a relatively small range of osteotomy.

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Section: Model Constructionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Indications Selection for Surgeons Training in the Translaminar Percutaneous Endoscopic Discectomy Based on Finite Element Analysis

Wang

Jiang

et al. 2020

BioMed Research International

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“…Finally, we can only de ne the relative nucleus position as being 'slightly posterior' to the centre of the disc, such that the lowest ACC of our model was lower than 70%, which needs to be improved further, even though the model validation process was veri ed in our previously published studies. Therefore, the calibration of the relative nucleus position and the investigation of a reliable ratio to de ne the above indicators are vital for improving the ACC of FEA, a widely used research method in the investigation of pathogenesis of DDD and optimization of spine surgical methods [6,9,13,27,33].…”

Section: Discussionmentioning

confidence: 99%

Measurement and calibration of the nucleus position and its cross-sectional area ratio to increase the accuracy of finite element analysis

Xi¹,

Zhang²,

Sun³

et al. 2020

Preprint

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Background: As a widely used biomechanical research method, finite element analysis (FEA) is an important tool for investigating the pathogenesis of disc degenerative diseases and optimizing spine surgical methods. However, the definitions of the relative nucleus position and its cross-sectional area ratio do not conform to a uniform standard, thus affecting the accuracy (ACC) of the FEA. Hence, this study aimed to determine a precise definition of the relative nucleus position and its cross-sectional area ratio to increase the ACC of the following FEA studies. Methods: The lumbar relative nucleus position and its cross-sectional area ratio were measured from magnetic resonance imaging data and then calibrated and validated via FEA. Imaging data from patients without disc degeneration were used. The L4-L5 nucleus and disc cross-sectional areas and the distances between the edges of the annulus and nucleus were measured; the ratios between these values were calculated as P1 and P2, respectively. The FEA model was constructed using these measured values, and the relative nucleus position was calibrated by estimating the differences in the range of motion (ROM) between the model, wherein the ligaments, facet joints and nucleus were suppressed, and that of an in vitro study. Then, the ACC was re-estimated in the model with all non-bony structures by comparing the ROM, the intradiscal pressure (IDP), the facet contact force (FCF) and the disc compression (DC) under different sizes and directions of moments magnitudes to validate the measured and calibrated indicators. Results: The interobserver homogeneity was acceptable, and the measured P1 and P2 values were 1.22 and 38%, respectively. Furthermore, an ACC of up to 99% was attained for the model under flexion–extension conditions when the calibrated P1 value (1.62) was used, with a model validation of greater than 90% attained under al most all of the loading conditions considering the different indicators and moment magnitude s. Conclusion: The measured and calibrated relative nucleus position and its cross-sectional area ratio increase the ACC of the FEA model and can therefore be used in subsequent studies.

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“…Six different ligaments and a capsule of facet joints were constructed during the FEA preprocessing phase ( Fig. 4) [11,23,24]. The de nition of the relative nucleus position and its cross-sectional area ratio were con rmed according to P1 and P2, and the outer contour of the nucleus was obtained using the same ratio reduction as that of the disc contour to ensure that the intervertebral disc and nucleus have the same central point, for easy adjustment during the calibration process.…”

Section: Calibration and Validation Of The Fea Modelmentioning

confidence: 99%

“…4), with smaller sizes (mesh re nement) being used in areas that experienced serious mesh distortion, and the cartilage-cartilage contact was de ned as frictionless [4,15,25]. Material properties of current models was de ned in consistent with our published studies [10,23,24]. Six degrees of freedom were rigidly xed under the inferior of L5, and moments were applied to the superior of L4 [13,14].…”

Section: Boundary and Loading Conditionsmentioning

confidence: 99%

Measurement and calibration of the nucleus position and its cross-sectional area ratio to increase the accuracy of finite element analysis

Zhang

et al. 2020

Preprint

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Backgrounds: As a widely used biomechanical research method, finite element analysis (FEA) is an important tool for investigating the pathogenesis of disc degenerative diseases and optimizing spine surgical methods. However, the definitions of the relative nucleus position and its cross-sectional area ratio do not conform to a uniform standard, thus affecting the accuracy (ACC) of the FEA.Objectives: This study aimed to determine a precise definition of the relative nucleus position and its cross-sectional area ratio to increase the ACC of the following FEA studies.Methods: The lumbar relative nucleus position and its cross-sectional area ratio were measured from magnetic resonance imaging data and then calibrated and validated via FEA. Imaging data from patients without disc degeneration were used. The L4-L5 nucleus and disc cross-sectional areas and the distances between the edges of the annulus and nucleus were measured; the ratios between these values were calculated as P1 and P2, respectively. The FEA model was constructed using these measured values, and the relative nucleus position was calibrated by estimating the differences in the range of motion (ROM) between the model, wherein the ligaments, facet joints and nucleus were suppressed, and that of an in vitro study. Then, the ACC was re-estimated in the model with all non-bony structures by comparing the ROM, the intradiscal pressure (IDP), the facet contact force (FCF) and the disc compression (DC) under different sizes and directions of moments magnitudes to validate the measured and calibrated indicators.Results: The interobserver homogeneity was acceptable, and the measured P1 and P2 values were 1.22 and 38%, respectively. Furthermore, an ACC of up to 99% was attained for the model under flexion–extension conditions when the calibrated P1 value (1.62) was used, with a model validation of greater than 90% attained under almost all of the loading conditions considering the different indicators and moment magnitudes.Conclusions: The measured and calibrated relative nucleus position and its cross-sectional area ratio increase the ACC of the FEA model and can therefore be used in subsequent studies.

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Biomechanical role of osteoporosis affects the incidence of adjacent segment disease after percutaneous transforaminal endoscopic discectomy

Cited by 35 publications

References 38 publications

Indications Selection for Surgeons Training in the Translaminar Percutaneous Endoscopic Discectomy Based on Finite Element Analysis

Indications Selection for Surgeons Training in the Translaminar Percutaneous Endoscopic Discectomy Based on Finite Element Analysis

Measurement and calibration of the nucleus position and its cross-sectional area ratio to increase the accuracy of finite element analysis

Measurement and calibration of the nucleus position and its cross-sectional area ratio to increase the accuracy of finite element analysis

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