QCT-based finite element models predict human vertebral strength in vitro significantly better than simulated DEXA
about
Predicting mouse vertebra strength with micro-computed tomography-derived finite element analysis.Prediction of proximal femur strength by a quantitative computed tomography-based finite element method--Creation of predicted strength data of the proximal femur according to age range in a normal population.Spinal Compression Fracture Management: A Review of Current Treatment Strategies and Possible Future Avenues.Evaluating bone quality in patients with chronic kidney disease.The ratio of anterior and posterior vertebral heights reinforces the utility of DXA in assessment of vertebrae strength.Advanced CT based in vivo methods for the assessment of bone density, structure, and strength.In-vivo assessment of femoral bone strength using Finite Element Analysis (FEA) based on routine MDCT imaging: a preliminary study on patients with vertebral fracturesAssociation of MRS-Based Vertebral Bone Marrow Fat Fraction with Bone Strength in a Human In Vitro Model.Osteoporosis imaging: effects of bone preservation on MDCT-based trabecular bone microstructure parameters and finite element models.Discordance between Prevalent Vertebral Fracture and Vertebral Strength Estimated by the Finite Element Method Based on Quantitative Computed Tomography in Patients with Type 2 Diabetes Mellitus.The Effectiveness of Percutaneous Vertebroplasty Is Determined by the Patient-Specific Bone Condition and the Treatment Strategy.Modelling of bone fracture and strength at different length scales: a review.Specimen-specific vertebral fracture modeling: a feasibility study using the extended finite element method.Comparative effects of teriparatide and risedronate in glucocorticoid-induced osteoporosis in men: 18-month results of the EuroGIOPs trialAccuracy of finite element analyses of CT scans in predictions of vertebral failure patterns under axial compression and anterior flexionEffect of Low-Dose MDCT and Iterative Reconstruction on Trabecular Bone Microstructure Assessment.Effect of specimen-specific anisotropic material properties in quantitative computed tomography-based finite element analysis of the vertebraCombining areal DXA bone mineral density and vertebrae postero-anterior width improves the prediction of vertebral strength.Early changes in biochemical markers of bone formation during teriparatide therapy correlate with improvements in vertebral strength in men with glucocorticoid-induced osteoporosisThe quartic piecewise-linear criterion for the multiaxial yield behavior of human trabecular bone.Quantitative Computed Tomography (QCT) derived Bone Mineral Density (BMD) in finite element studies: a review of the literature.Assessment of incident spine and hip fractures in women and men using finite element analysis of CT scansBone quality: the determinants of bone strength and fragility.A biomechanical sorting of clinical risk factors affecting osteoporotic hip fracture.Micro Finite Element models of the vertebral body: Validation of local displacement predictionsClinical Evaluation of Bone Strength and Fracture Risk.Effect of boundary conditions on yield properties of human femoral trabecular bone.Osteoporosis drug effects on cortical and trabecular bone microstructure: a review of HR-pQCT analyses.Finite Element Analysis of Denosumab Treatment Effects on Vertebral Strength in Ovariectomized Cynomolgus Monkeys.The Initial Slope of the Variogram, Foundation of the Trabecular Bone Score, Is Not or Is Poorly Associated With Vertebral Strength.Effects of Scan Resolutions and Element Sizes on Bovine Vertebral Mechanical Parameters from Quantitative Computed Tomography-Based Finite Element Analysis.Embedding of human vertebral bodies leads to higher ultimate load and altered damage localisation under axial compression.Precision study of DXA-based patient-specific finite element modeling for assessing hip fracture risk.Trabecular bone structure analysis of the spine using clinical MDCT: can it predict vertebral bone strength?Bone mineral density measurements in vertebral specimens and phantoms using dual-layer spectral computed tomography.Differences in Trabecular Microarchitecture and Simplified Boundary Conditions Limit the Accuracy of QCT-based Finite Element Models of Vertebral Failure.Emerging Research on Bone Health Using High-Resolution CT and MRI
P2860
Q30385252-711BB352-94D0-4468-A959-75A08CB353C4Q30940964-1AB2F7C4-9AB7-42F5-8081-0E4988F6DC28Q33590002-ABF10564-06D3-460F-88A9-A0E3527AB3EBQ33602332-38257FE7-2F35-497A-BB0A-8AF2F30C9938Q33922107-E50C8D61-4D2A-4B54-AAD4-23EE5D1D62C8Q34742707-1D6C9522-283F-45A9-AD68-2C0D19398984Q35130486-7D10704B-BF9A-4C85-8939-F01F81A943C8Q35563467-EE04174A-0615-428F-8B1D-43AAECB8F4FDQ35675072-39064824-FE9B-4CD9-978C-ADC46D2DA794Q35862537-0901BBAD-6BC9-4026-B1CD-F400BBA5C860Q35995913-9DC887DC-AB1A-4BA8-9700-36C38D7F3814Q36390723-B6D5452E-DA68-4BB1-91DE-B0FD67A3ADE0Q36855882-C2BA2C8C-66A1-4074-A69C-18B4D06054E2Q37001737-C4055F40-425F-431C-8E4E-F01B45F07CA4Q37113984-EA766A80-CCA4-4344-9ABF-0BC124639A51Q37119257-9361A4B8-3B66-4553-B8B9-B40F0D82E03CQ37219925-82283494-90A9-46A3-AAB1-A7A9338DA004Q37298454-2F7D9090-C06E-4A25-8DC4-652C67C2D3ADQ37337557-478E4347-287D-469B-8A0B-5E16432CBEB8Q37401818-1F27431D-B78A-4C85-A603-DC6ED11B7AD8Q37585408-BB0CCA46-1A2E-4F7D-93A3-D29608F73739Q37587054-17702A12-8A9F-44D1-AC30-5BE507FDF13BQ38149092-68782145-3163-41CE-ADB7-0E2831DD778EQ38585164-D65719C2-2127-4AC9-94EF-DE0E5DCD8C14Q38682373-C8DC950E-B9B0-4B3C-A7C5-0B18099319CEQ38759091-208803D8-5B6D-4EC7-961B-1762D6AD823BQ38948088-A1C0FFC8-8A07-4B0D-89A1-3D6659666E6CQ38951630-55D2BAB8-6809-4CCB-8175-F358A3719A0AQ39791628-D7C67B35-F36C-4349-8924-A02276D09464Q40668913-ECBBE50D-B0BD-405F-9D4D-757878728F3CQ42998928-1AC0AF40-FC3D-4A67-A7F0-E43D6D9AAC7BQ43832284-7BE5991F-C8C3-4253-A899-5931693B18F5Q44157071-0F5D19E9-A53F-4926-8E8C-CF778ECB1221Q44660908-B6C2538F-C0D8-485D-8655-73E948D96799Q47130372-B5DCC75E-CB32-4BF1-98C8-981F81840F8FQ47291634-CB33C3D9-6815-47B4-B7E9-AAFACADEBDAEQ57644176-8C71790C-59F3-4F35-A380-FE17D94263E0
P2860
QCT-based finite element models predict human vertebral strength in vitro significantly better than simulated DEXA
description
article
@en
im Februar 2011 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в лютому 2011
@uk
name
QCT-based finite element model ...... tly better than simulated DEXA
@en
QCT-based finite element model ...... tly better than simulated DEXA
@nl
type
label
QCT-based finite element model ...... tly better than simulated DEXA
@en
QCT-based finite element model ...... tly better than simulated DEXA
@nl
prefLabel
QCT-based finite element model ...... tly better than simulated DEXA
@en
QCT-based finite element model ...... tly better than simulated DEXA
@nl
P2860
P50
P1476
QCT-based finite element model ...... tly better than simulated DEXA
@en
P2093
F Kainberger
P2860
P2888
P304
P356
10.1007/S00198-011-1568-3
P407
P577
2011-02-23T00:00:00Z