An FE investigation simulating intra-operative corrective forces applied to correct scoliosis deformity

Little, J. Paige; Izatt, Maree T.; Labrom, Robert D.; Askin, Geoffrey N.; Adam, Clayton J.

doi:10.1186/1748-7161-8-9

Cited by 24 publications

(39 citation statements)

References 27 publications

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“…Rib cage global parameters, such as rib cage volume, spinal penetration index and rib hump angle (Dubousset et al 2003) and other morphological parameters complete the spine analysis, particularly for the deformed thorax which can raise clinically relevant issues for pulmonary restrictive disease (Sabourin et al 2010;Johnston et al 2011). Furthermore, 3D models are necessary for the development of realistic subject-specific finite element models (FEM) which are used to understand the mechanisms of initiation of structural deformation and predict treatment effects (Nie et al 2009;Clin et al 2010;Drevelle et al 2010;Little et al 2013) or used in crash simulation to investigate injury mechanisms.…”

Section: Introductionmentioning

confidence: 99%

3D reconstruction of rib cage geometry from biplanar radiographs using a statistical parametric model approach

Aubert

Vergari

Ilharreborde

et al. 2014

Computer Methods in Biomechanics and Biomedical Engineering: Im

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is an open access repository that collects the work of Arts et Métiers ParisTech researchers and makes it freely available over the web where possible. This is an author-deposited version published in: https://sam.ensam.eu Handle ID AbstractRib cage 3D reconstruction is an important prerequisite for thoracic spine modelling, particularly for studies of the deformed thorax in adolescent idiopathic scoliosis. This study proposes a new method for rib cage 3D reconstruction from biplanar radiographs, using a statistical parametric model approach.Simplified parametric models were defined at the hierarchical levels of rib cage surface, rib midline and rib surface, and applied on a database of 86 trunks. The resulting parameter database served to statistical models learning which were used to quickly provide a first estimate of the reconstruction from identifications on both radiographs. This solution was then refined by manual adjustments in order to improve the matching between model and image. Accuracy was assessed by comparison with 29 rib cages from CT scans in terms of geometrical parameter differences and in terms of line-to-line error distance between the rib midlines. Intra and inter-observer reproducibility were determined regarding 20 scoliotic patients.The first estimate (mean reconstruction time of 2'30) was sufficient to extract the main rib cage global parameters with a 95% confidence interval lower than 7%, 8%, 2% and 4° for rib cage volume, antero-posterior and lateral maximal diameters and maximal rib hump, respectively. The mean error distance was 5.4 mm (max 35mm) down to 3.6 mm (max 24 mm) after the manual adjustment step (+3'30).The proposed method will improve developments of rib cage finite element modeling and evaluation of clinical outcomes.

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Section: Introductionmentioning

confidence: 99%

3D reconstruction of rib cage geometry from biplanar radiographs using a statistical parametric model approach

Aubert

Vergari

Ilharreborde

et al. 2014

Computer Methods in Biomechanics and Biomedical Engineering: Im

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“…In some studies, intervertebral discs are simulated and analyzed while they considered as one-piece. 25 In some other articles, the annulus section and nucleus part are simulated and analyzed separately. 32 To investigate this issue, all the results of this section compared between one-piece and two-piece intervertebral discs.…”

Section: Resultsmentioning

confidence: 99%

“…24 After precise finite element modeling of a patient with scoliosis in the thoracic-lumbar region and estimating the number of modification forces needed, Little and his colleagues found that in addition to the internal forces, the imposition of external forces to reform this condition was essential. 25 Also, in other research, 26 according to CT-scan images, they used the finite element method to model the thoracic-lumbar region of the vertebrae of a patient with scoliosis and investigated the modified vertebrae by orthopedic rods.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of Useful Biomechanical Parameters On Scoliosis Using Finite Element Method

Khademi

Nikoo

2020

Int Clin Neurosci J

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Background: Scoliosis is a deformity of the vertebral column, and shape-changing and deformation of the spine are some critical factors that can cause this abnormality. This condition causes some problems like deflection of the spine in the coronal plane toward medial or lateral. Cobb angle is a measurement for the investigation of the severity of this condition. There are several effective therapies suggested for the reduction of the Cobb angle for patients who has this abnormality. It has suggested that before applying external forces to correct this condition, biomechanical evaluation of this deformity, can be useful during diagnosis. Methods: The purpose of this study is the evaluation of Cobb angle correction using external forces. For this aim first, the dimensional data of the patient’s vertebrae are extracted from CT-scan images using Mimics software, and the vertebral column modeled in Catia software for finite element analysis (FEA). Afterward, the model was imported into Abaqus software to evaluate the effect of forces on the spine model. The study was done by assuming two cases for the spine, one-piece (without a nucleus) and two-piece (with a nucleus) intervertebral disc. Results: After studying the results of this simulation, it concluded that after applying gravity force to these two cases, the percentage of Cobb angle’s reduction was about 0.05 for a two-piece disc and about -0.18 for the one-piece disc. Therefore, the two-piece disc assumption was better for analyzing this parameter. The results of maximum displacement and von misses stress show that the two-piece disc is accurate. Conclusion: In order to investigate which analysis is appropriate to be selected, choosing a twopiece intervertebral disc model is superlative. Whether our goal is only to examine the stress which is present in the patient model, choosing a one-piece disc is a more optimal duo to take much less time.

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“…They found the correlation between the intensity of the force and the angle of correction by measuring the applied force. Little et al [19] tried to find out how deformation was affected by the severity of corrective forces to predict the severity of the tension required to treat spinal curvature in scoliosis abnormalities. Their research showed that there is a direct relationship between the compressive forces of the connections used and the degree of curvature change.…”

Section: Introductionmentioning

confidence: 99%

System reliability analysis of the scoliosis disorder

Nouri

Ghasemi

Lee

2020

BMC Musculoskelet Disord

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Background: Scoliosis is a spine abnormal deviation, which is an idiopathic disorder among children and adolescents. As a matter of the fact, distribution of loads on the patient's spine and load-carrying capacity of the vertebral column are both random variables. Therefore, the probabilistic approach may consider as a sophisticated method to deal with this problem. Method: Reliability analysis is a probabilistic-based approach to consider the uncertainties of load and resistance of the vertebral column. The main contribution of this paper is to compare the reliability level of a normal and scoliosis spinal. To do so, the numerical analyses associated with the inherent random parameters of bones and applied load are performed. Then, the reliability indices for all vertebrae and discs are determined. Accordingly, as the main innovation of this paper, the system reliability indices of the spinal column for both normal and damaged backbone systems are represented. Results: Based on the required reliability index for normal spinal curvature the target system reliability level for scoliosis disorder is proposed. Conclusion: Since the proposed target reliability index is based on the strength limit state of the vertebral column, it can be considered as a reliability level for any proposed treatment approaches.

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An FE investigation simulating intra-operative corrective forces applied to correct scoliosis deformity

Cited by 24 publications

References 27 publications

3D reconstruction of rib cage geometry from biplanar radiographs using a statistical parametric model approach

3D reconstruction of rib cage geometry from biplanar radiographs using a statistical parametric model approach

Evaluation of Useful Biomechanical Parameters On Scoliosis Using Finite Element Method

System reliability analysis of the scoliosis disorder

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