Influence of cement-augmented pedicle screw instrumentation in an osteoporotic lumbosacral spine over the adjacent segments: a 3D finite element study

Zhou, Quan-kun; Zeng, Fan-hui; Tu, Jian-long; Dong, Zhang-qing; Ding, Zhi-Hui

doi:10.1186/s13018-020-01650-5

Cited by 19 publications

(13 citation statements)

References 33 publications

(36 reference statements)

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“…The collected raw data in the DICOM format were imported into Mimics research 19.0 (Materialize, Leuven, Belgium) to generate 3D vertebral models in a standard triangle language (STL). Subsequently, the STL data generated were imported into ANSYS 19.2 in the form of solid 3D structure ( Peng et al, 2020 ; Zhou et al, 2020 ), which was built of 10-node tetrahedral element meshes ( Ulrich et al, 1998 ). Screws were positioned and oriented in the desired locations.…”

Section: Methodsmentioning

confidence: 99%

“…Spinal rods were modeled with a cross-sectional diameter of 5.5 mm, Young’s modulus of 420 GPa, and Poisson’s ratio of 0.3 according to CoCr alloy properties ( Yamada et al, 2020 ). The screws were modeled as cylinders with a length of 30 mm, cross-sectional diameter of 5.5 mm, Young’s modulus of 5,000 MPa, and Poisson’s ratio of 0.3 ( Zhou et al, 2020 ). Rods and screws were modeled with materials of isotropic elastic linear material properties.…”

Section: Methodsmentioning

confidence: 99%

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Surgical Outcome Prediction Using a Four-Dimensional Planning Simulation System With Finite Element Analysis Incorporating Pre-bent Rods in Adolescent Idiopathic Scoliosis: Simulation for Spatiotemporal Anatomical Correction Technique

Tachi

Kato

Abe

et al. 2021

Front. Bioeng. Biotechnol.

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An optimal surgical strategy for adolescent idiopathic scoliosis (AIS) is to provide maximal deformity correction while preserving spinal mobile segments as much as possible and obtaining a balanced posture. From a spatiotemporal deformity correction standpoint, we recently showed that anatomical four-dimensional (4D) spinal correction could be accomplished by curving the rod. In the surgical procedure, two rods are bent identically to confirm spinal anatomical alignment without referring to the intraoperative alignment of the deformity. Therefore, anatomically designed rods have been developed as notch-free, pre-bent rods for easier anatomical reconstruction. In addition to providing the best spinal instrumentation configurations as pre-bent rods, prediction of surgical outcome along with its biomechanical impact can be obtained by simulation of the surgical procedures with computer modeling. However, an objective model that can simulate the surgical outcome in patients with AIS has not been completely elucidated. The present study aimed to compare simulated deformity corrections based on our newly developed spatiotemporal morphological 4D planning simulation system incorporating pre-bent rods and actual deformity corrections in patients with AIS. A consecutive series of 47 patients who underwent anatomical posterior correction for AIS curves were prospectively evaluated. After multilevel facetectomy, except for the lowest instrumented segment, 11 types of pre-bent rods were used. Patient demographic data, radiographic measurements, and sagittal rod angles were analyzed within 1 week of surgery. Our simulation system incorporating pre-bent rods showed a significant correlation with the actual postoperative spinal alignment. The present study demonstrated the feasibility of our simulation system and the ability to simulate the surgical procedure using the pre-bent rods. The simulation system can be used to minimize the differences between the optimal and possible outcomes related to the instrumentation levels and rod shapes. Preoperative assumption of rod shape and length can contribute to a reduction in operative time which decreases blood loss and risk of infection. The results of the finite element analysis in the simulation system measured for each individual patient would also provide a more realistic representation of the surgical procedures.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Surgical Outcome Prediction Using a Four-Dimensional Planning Simulation System With Finite Element Analysis Incorporating Pre-bent Rods in Adolescent Idiopathic Scoliosis: Simulation for Spatiotemporal Anatomical Correction Technique

Tachi

Kato

Abe

et al. 2021

Front. Bioeng. Biotechnol.

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“…( 2020 ) Friction coefficient of 0.1 Linear elastic: , = 0.4 Zhou et al. ( 2020 ) Friction coefficient of 0.2 Linear elastic: , = 0.3 Ayturk and Puttlitz ( 2011 ); Du et al. ( 2016a ) Frictionless Neo Hooke Holzapfel and Stadler ( 2006 ) Friction coefficient of 0.06 Neo Hooke Schmidt et al.…”

Section: Methodologies For Facet Joints Modelsmentioning

confidence: 99%

Biomechanical modelling of the facet joints: a review of methods and validation processes in finite element analysis

Mengoni

2020

Biomech Model Mechanobiol

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There is an increased interest in studying the biomechanics of the facet joints. For in silico studies, it is therefore important to understand the level of reliability of models for outputs of interest related to the facet joints. In this work, a systematic review of finite element models of multi-level spinal section with facet joints output of interest was performed. The review focused on the methodology used to model the facet joints and its associated validation. From the 110 papers analysed, 18 presented some validation of the facet joints outputs. Validation was done by comparing outputs to literature data, either computational or experimental values; with the major drawback that, when comparing to computational values, the baseline data was rarely validated. Analysis of the modelling methodology showed that there seems to be a compromise made between accuracy of the geometry and nonlinearity of the cartilage behaviour in compression. Most models either used a soft contact representation of the cartilage layer at the joint or included a cartilage layer which was linear elastic. Most concerning, soft contact models usually did not contain much information on the pressure-overclosure law. This review shows that to increase the reliability of in silico model of the spine for facet joints outputs, more needs to be done regarding the description of the methods used to model the facet joints, and the validation for specific outputs of interest needs to be more thorough, with recommendation to systematically share input and output data of validation studies.

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“…A 1 mm bony end plate was simulated on either end of each vertebra (Fig. 2) [13] . The material properties of the various spinal components were derived from the literature [16][17][18][19] , as speci ed in Table 1.…”

Section: Methodsmentioning

confidence: 99%

“…Finite element analysis (FEA) is a numerical method simulating and analyzing the behavior or mechanism of structures or components, which is initially developed in the 1950s in the aircraft industry [10] . FEA has already been applied to characterize the complex biomechanical properties of the lumbar vertebrae in previous studies [11][12][13][14][15] . Nevertheless, to the best of our knowledge, few studies have illustrated the detailed biomechanical mechanisms of L5-S1 and L5-S2 alar xation in spondylolisthesis patients with osteoporosis.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of S2 alar and traditional S1 pedicle fixation for severe lumbar spondylolisthesis in different bone mineral densities: a finite element analysis

Wang

Chen

Yang

et al. 2020

Preprint

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Purpose: Little is known about the biomechanical performance of L5-S2 alar internal fixation constructs after posterior lumbar interbody fusion. This study aimed to compare the biomechanical effect of L5-S1 internal fixation and L5-S2 alar internal fixation on severe lumbar spondylolisthesis. Methods: A normal male volunteer without a history of spinal disease was selected, lumbar CT data was collected. An intact L5-S2 three-dimensional finite element model was created by Mimics and Geomagic.Two kinds of fixation methods were reconstructed including (1) the L5-S1 screw fixation model and (2) the L5-S2 alar fixation model. The inverse repair was performed using Geomagic software, the internal fixation device was drawn using Creo software, and the model parameters were set and analyzed using ANSYS Workbench software. Results: The validity of the intact model shows that the ROM of the model is similar to that of a reported cadaveric study. The average stress of the L5-S2 alar internal fixation device was 86.9-111% higher(P＜0.001) than that of the L5-S1 fixation device when the bone of the S1 screw path reached the yield threshold. The maximal stress of the S1 screw in the L5-S2 alar fixation was significantly lower (P＜0.001) than it in the L5-S1 fixation when the stress exceeds the S1 bone yield threshold. When the S1 screw path bone yielded, the maximal deformation value of the S1 screw path was similar in both models (P>0.05), while the average deformation value of the S1 screw path in L5-S2 alar fixation was significantly higher (P＜0.01) than it in L5-S1 fixation. Conclusion: Extending fixation to the S2 wing can significantly improve internal fixation device stability and reduce the risk of intraoperative and postoperative fractures while avoiding injury to the sacroiliac joint, reducing the difficulty of surgery and the risk of injury to surrounding tissues. It is a reasonable plan for the treatment of moderate and severe lumbar spondylolisthesis with osteoporosis.

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Influence of cement-augmented pedicle screw instrumentation in an osteoporotic lumbosacral spine over the adjacent segments: a 3D finite element study

Cited by 19 publications

References 33 publications

Surgical Outcome Prediction Using a Four-Dimensional Planning Simulation System With Finite Element Analysis Incorporating Pre-bent Rods in Adolescent Idiopathic Scoliosis: Simulation for Spatiotemporal Anatomical Correction Technique

Surgical Outcome Prediction Using a Four-Dimensional Planning Simulation System With Finite Element Analysis Incorporating Pre-bent Rods in Adolescent Idiopathic Scoliosis: Simulation for Spatiotemporal Anatomical Correction Technique

Biomechanical modelling of the facet joints: a review of methods and validation processes in finite element analysis

Evaluation of S2 alar and traditional S1 pedicle fixation for severe lumbar spondylolisthesis in different bone mineral densities: a finite element analysis

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