Methodology to Produce Specimen-Specific Models of Vertebrae: Application to Different Species

Zapata-Cornelio, Fernando Y.; Day, Gavin A.; Coe, Ruth H.; Sikora, Sebastien N. F.; Wijayathunga, Vithanage N.; Tarsuslugil, S.; Mengoni, Marlène; Wilcox, Ruth K.

doi:10.1007/s10439-017-1883-8

Cited by 6 publications

(6 citation statements)

References 49 publications

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“…Having greater definition of the cortical shell and trabecular bone alignment also allows a better regional representation of the load transfer through the vertebrae than the more homogenized predictions seen with the direct grayscale method. This improved agreement is much stronger than the agreement found in similar studies that used a comparable methodology to the direct grayscale method and comparable to methods that used more complex, specimen‐specific material properties for each model . The conversion between grayscale and Young's modulus was comparable to studies with similar methodologies; Robson Brown et al found an equivalent conversion factor of 0.0013/GPa (0.0009/GPa in the current study), which gives a similar average bone modulus of 0.33 GPa to that of the current study, 0.25 GPa.…”

Section: Discussionsupporting

confidence: 66%

“…Two approaches to generating the models were compared (Figure ). In the first (“direct grayscale method”), the images were downsampled to 1 mm 3 and the resulting grayscale of each voxel was used to define the local bone elastic modulus (Figure 3A,B), similar to a method used by Zapata‐Cornelio et al In the second (“bone volume fraction” method), an initial threshold was applied to the 82‐μm image stack to segment the trabeculae from the trabecular spaces (Figure 3D). The selected threshold was determined as the mean across all specimens using the optimize threshold feature of the BoneJ plugin for ImageJ (version 1.4.1), which optimized the connectivity against the threshold value.…”

Section: Methodsmentioning

confidence: 99%

“…Bone materials were modeled as an isotropic linear elastic material, where the Young's modulus of each element was correlated with the grayscale value of the corresponding voxel using a linear conversion factor. The relationship between the grayscale value and Young's modulus was optimized to provide the best fit between the FE‐predicted stiffness values and the corresponding experimentally derived stiffness values using an optimization toolbox with the method employed by Zapata‐Cornelio et al Initially, the 14 vertebra models were split evenly into a build set and a validation set, with the optimization of the conversion factor carried out on the build set and this factor was then applied to the models in the validation set. Following this validation step, all 14 vertebrae were then used to optimize the conversion factor.…”

Section: Methodsmentioning

confidence: 99%

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Optimizing computational methods of modeling vertebroplasty in experimentally augmented human lumbar vertebrae

2020

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Vertebroplasty has been widely used for the treatment of osteoporotic compression fractures but the efficacy of the technique has been questioned by the outcomes of randomized clinical trials. Finite‐element (FE) models allow an investigation into the structural and geometric variation that affect the response to augmentation. However, current specimen‐specific FE models are limited due to their poor reproduction of cement augmentation behavior. The aims of this study were to develop new methods of modeling the vertebral body in both a nonaugmented and augmented state. Experimental tests were conducted using human lumbar spine vertebral specimens. These tests included micro‐computed tomography imaging, mechanical testing, augmentation with cement, reimaging, and retesting. Specimen‐specific FE models of the vertebrae were made comparing different approaches to capturing the bone material properties and to modeling the cement augmentation region. These methods significantly improved the modeling accuracy of nonaugmented vertebrae. Methods that used the registration of multiple images (pre‐ and post‐augmentation) of a vertebra achieved good agreement between augmented models and their experimental counterparts in terms of predictions of stiffness. Such models allow for further investigation into how vertebral variation influences the mechanical outcomes of vertebroplasty.

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Section: Discussionsupporting

confidence: 66%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Optimizing computational methods of modeling vertebroplasty in experimentally augmented human lumbar vertebrae

2020

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“…Computed tomography images were imported into Simpleware ScanIP (v 7.0, Synopsys, United States) after their greyscalevalues had been rescaled to enable the use of previously calibrated bone properties (Zapata-Cornelio et al, 2017). The rescaled CT images at each compression step were rigidly registered to the CT images of specimens in their initial preloaded state ("preloaded CT images"), using the most caudal vertebrae as reference.…”

Section: Image Processing and In Vitro Bulge Calculationmentioning

confidence: 99%

“…Bone was modelled as a linear elastic material, with element-byelement elastic modulus scaled using the underlying greyscale value of the CT image data, and Poisson's ratio of 0.3. In order to use a greyscale-based equation for the bone modulus (Zapata-Cornelio et al, 2017), the images underlying the highresolution segmentation were down-sampled to an isotropic resolution of 0.5 mm. The greyscale-based model requires first a normalisation of the greyscale to 0-255.…”

Section: Finite Element Modellingmentioning

confidence: 99%

Experimental and Computational Comparison of Intervertebral Disc Bulge for Specimen-Specific Model Evaluation Based on Imaging

Mengoni

Zapata-Cornelio

Wijayathunga

et al. 2021

Front. Bioeng. Biotechnol.

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Finite element modelling of the spinal unit is a promising preclinical tool to assess the biomechanical outcome of emerging interventions. Currently, most models are calibrated and validated against range of motion and rarely directly against soft-tissue deformation. The aim of this contribution was to develop an in vitro methodology to measure disc bulge and assess the ability of different specimen-specific modelling approaches to predict disc bulge. Bovine bone-disc-bone sections (N = 6) were prepared with 40 glass markers on the intervertebral disc surface. These were initially magnetic resonance (MR)-imaged and then sequentially imaged using peripheral-qCT under axial compression of 1 mm increments. Specimen-specific finite-element models were developed from the CT data, using three different methods to represent the nucleus pulposus geometry with and without complementary use of the MR images. Both calibrated specimen-specific and averaged compressive material properties for the disc tissues were investigated. A successful methodology was developed to quantify the disc bulge in vitro, enabling observation of surface displacement on qCT. From the finite element model results, no clear advantage was found in using geometrical information from the MR images in terms of the models’ ability to predict stiffness or disc bulge for bovine intervertebral disc.

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A Finite Element Model to Investigate the Stability of Osteochondral Grafts Within a Human Tibiofemoral Joint

Day,

Jones,

Mengoni

et al. 2024

Ann Biomed Eng

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Osteochondral grafting has demonstrated positive outcomes for treating articular cartilage defects by replacing the damaged region with a cylindrical graft consisting of bone with a layer of cartilage. However, factors that cause graft subsidence are not well understood. The aim of this study was to develop finite element (FE) models of osteochondral grafts within a tibiofemoral joint, suitable for an investigation of parameters affecting graft stability. Cadaveric femurs were used to experimentally calibrate the bone properties and graft-bone frictional forces for use in corresponding image-based FE models, generated from µCT scan data. Effects of cartilage defects and osteochondral graft repair were measured by examining contact pressure changes using further in vitro tests. Here, six defects were created in the femoral condyles, which were subsequently treated with osteochondral autografts or metal pins. Matching image-based FE models were created, and the contact patches were compared. The bone material properties and graft-bone frictional forces were successfully calibrated from the initial tests with good resulting levels of agreement (CCC = 0.87). The tibiofemoral joint experiment provided a range of cases that were accurately described in the resultant pressure maps and were well represented in the FE models. Cartilage defects and repair quality were experimentally measurable with good agreement in the FE model pressure maps. Model confidence was built through extensive validation and sensitivity testing. It was found that specimen-specific properties were required to accurately represent graft behaviour. The final models produced are suitable for a range of parametric testing to investigate immediate graft stability.

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Methodology to Produce Specimen-Specific Models of Vertebrae: Application to Different Species

Cited by 6 publications

References 49 publications

Optimizing computational methods of modeling vertebroplasty in experimentally augmented human lumbar vertebrae

Optimizing computational methods of modeling vertebroplasty in experimentally augmented human lumbar vertebrae

Experimental and Computational Comparison of Intervertebral Disc Bulge for Specimen-Specific Model Evaluation Based on Imaging

A Finite Element Model to Investigate the Stability of Osteochondral Grafts Within a Human Tibiofemoral Joint

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