Computational study of estimating 3D trabecular bone microstructure for the volume of interest from CT scan data

Kim, Jung Jin; Nam, Jimin; Jang, In Gwun

doi:10.1002/cnm.2950

Cited by 21 publications

(8 citation statements)

References 60 publications

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“…These results demonstrate the potential of the proposed phantomless HU-to-BMD conversion to conduct reliable FEA-based quantitative assessment using routine CT images without the aid of QCT examination. Accurate voxelwise BMD estimation is also essential for the bone microstructure reconstruction approach recently proposed [47, 48].…”

Section: Discussionmentioning

confidence: 99%

Patient-Specific Phantomless Estimation of Bone Mineral Density and Its Effects on Finite Element Analysis Results: A Feasibility Study

Lee

Kim

Jang

2019

Computational and Mathematical Methods in Medicine

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Objectives This study proposes a regression model for the phantomless Hounsfield units (HU) to bone mineral density (BMD) conversion including patient physical factors and analyzes the accuracy of the estimated BMD values. Methods The HU values, BMDs, circumferences of the body, and cross-sectional areas of bone were measured from 39 quantitative computed tomography images of L2 vertebrae and hips. Then, the phantomless HU-to-BMD conversion was derived using a multiple linear regression model. For the statistical analysis, the correlation between the estimated BMD values and the reference BMD values was evaluated using Pearson's correlation test. Voxelwise BMD and finite element analysis (FEA) results were analyzed in terms of root-mean-square error (RMSE) and strain energy density, respectively. Results The HU values and circumferences were statistically significant (p < 0.05) for the lumbar spine, whereas only the HU values were statistically significant (p < 0.05) for the proximal femur. The BMD values estimated using the proposed HU-to-BMD conversion were significantly correlated with those measured using the reference phantom: Pearson's correlation coefficients of 0.998 and 0.984 for the lumbar spine and proximal femur, respectively. The RMSEs of the estimated BMD values for the lumbar spine and hip were 4.26 ± 0.60 (mg/cc) and 8.35 ± 0.57 (mg/cc), respectively. The errors of total strain energy were 1.06% and 0.91%, respectively. Conclusions The proposed phantomless HU-to-BMD conversion demonstrates the potential of precisely estimating BMD values from CT images without the reference phantom and being utilized as a viable tool for FEA-based quantitative assessment using routine CT images.

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Section: Discussionmentioning

confidence: 99%

Patient-Specific Phantomless Estimation of Bone Mineral Density and Its Effects on Finite Element Analysis Results: A Feasibility Study

Lee

Kim

Jang

2019

Computational and Mathematical Methods in Medicine

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“…To enhance computational efficiency, this work excluded the trabecular structure. 19,21 In addition, to simulate a 32-A3 femoral shaft fracture, a transverse gap of 2.1 mm was created in the middle of the cortical bone. The transverse fracture introduces symmetry along the fracture gap, and the size of the transverse gap is consistent with previous studies, within the range of 2-5 mm.…”

Section: Methodsmentioning

confidence: 99%

Biomechanical analysis of combi-hole locking compression plate during fracture healing: A numerical study of screw configuration

Li,

Pollard,

Smith

et al. 2024

Proc Inst Mech Eng H

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Locking compression plates (LCPs) have become a widely used option for treating femur bone fractures. However, the optimal screw configuration with combi-holes remains a subject of debate. The study aims to create a time-dependent finite element (FE) model to assess the impacts of different screw configurations on LCP fixation stiffness and healing efficiency across four healing stages during a complete fracture healing process. To simulate the healing process, we integrated a time-dependent callus formation mechanism into a FE model of the LCP with combi-holes. Three screw configuration parameters, namely working length, screw number, and screw position, were investigated. Increasing the working length negatively affected axial stiffness and healing efficiency ( p < 0.001), while screw number or position had no significant impact ( p > 0.01). The time-dependent model displayed a moderate correlation with the conventional time-independent model for axial stiffness and healing efficiency (ρ ≥ 0.733, p ≤ 0.025). The highest healing efficiency (95.2%) was observed in screw configuration C125 during the 4–8-week period. The results provide insights into managing fractures using LCPs with combi-holes over an extended duration. Under axial compressive loading conditions, the use of the C125 screw configuration can enhance callus formation during the 4–12-week period for transverse fractures. When employing the C12345 configuration, it becomes crucial to avoid overconstraint during the 4–8-week period.

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“…Deep learning in neural networks can detect fractures in materials with up to 98% accuracy, according to recent research [11]. In the same way, image processing can be used to detect gradients, which are analyzed to find the best value [12]. In a recent study [13], the authors compared the detection of cracks in concrete walls using both methods.…”

Section: Introductionmentioning

confidence: 99%

Application of Microfracture Analysis to Fatigue Fractures in Materials through Non-Destructive Tests

Sánchez-Santana,

Presbítero-Espinosa,

Quiroga-Arias

2024

Materials

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Fatigue fractures in materials are the main cause of approximately 80% of all material failures, and it is believed that such failures can be predicted and mathematically calculated in a reliable manner. It is possible to establish prediction modalities in cases of fatigue fractures according to three fundamental variables in fatigue, such as volume, number of fracture cycles, as well as applied stress, with the integration of Weibull constants (length characteristic). In this investigation, mechanical fatigue tests were carried out on specimens smaller than 4 mm2, made of different industrial materials. Their subsequent analysis was performed through precision computed tomography, in search for microfractures. The measurement of these microfractures, along with their metrics and classifications, was recorded. A convolutional neural network trained with deep learning was used to achieve the detection of microfractures in image processing. The detection of microfractures in images with resolutions of 480 × 854 or 960 × 960 pixels is the primary objective of this network, and its accuracy is above 95%. Images that have microfractures and those without are classified using the network. Subsequently, by means of image processing, the microfracture is isolated. Finally, the images containing this feature are interpreted using image processing to obtain their area, perimeter, characteristic length, circularity, orientation, and microfracture-type metrics. All values are obtained in pixels and converted to metric units (μm) through a conversion factor based on image resolution. The growth of microfractures will be used to define trends in the development of fatigue fractures through the studies presented.

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Computational study of estimating 3D trabecular bone microstructure for the volume of interest from CT scan data

Cited by 21 publications

References 60 publications

Patient-Specific Phantomless Estimation of Bone Mineral Density and Its Effects on Finite Element Analysis Results: A Feasibility Study

Patient-Specific Phantomless Estimation of Bone Mineral Density and Its Effects on Finite Element Analysis Results: A Feasibility Study

Biomechanical analysis of combi-hole locking compression plate during fracture healing: A numerical study of screw configuration

Application of Microfracture Analysis to Fatigue Fractures in Materials through Non-Destructive Tests

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