Your search keyword '"Pahr DH"' showing total 3 results

1. HR-pQCT-based homogenised finite element models provide quantitative predictions of experimental vertebral body stiffness and strength with the same accuracy as μFE models.

Author

Pahr DH, Dall'Ara E, Varga P, and Zysset PK

Subjects

Adult, Aged, Aged, 80 and over, Biomechanical Phenomena, Bone Density, Cadaver, Compressive Strength physiology, Elasticity physiology, Female, Finite Element Analysis, Humans, In Vitro Techniques, Linear Models, Male, Middle Aged, Spine diagnostic imaging, Tomography, X-Ray Computed, Models, Biological, Spine physiology

Abstract

This study validated two different high-resolution peripheral quantitative computer tomography (HR-pQCT)-based finite element (FE) approaches, enhanced homogenised continuum-level (hFE) and micro-finite element (μFE) models, by comparing them with compression test results of vertebral body sections. Thirty-five vertebral body sections were prepared by removing endplates and posterior elements, scanned with HR-pQCT and tested in compression up to failure. Linear hFE and μFE models were created from segmented and grey-level CT images, and apparent model stiffness values were compared with experimental stiffness as well as strength results. Experimental and numerical apparent elastic properties based on grey-level/segmented CT images (N=35) correlated well for μFE (r2=0.748/0.842) and hFE models (r2=0.741/0.864). Vertebral section stiffness values from the linear μFE/hFE models estimated experimental ultimate apparent strength very well (r2=0.920/0.927). Calibrated hFE models were able to predict quantitatively apparent stiffness with the same accuracy as μFE models. However, hFE models needed no back-calculation of a tissue modulus or any kind of fitting and were computationally much cheaper.

Published

2012

2. Mineral heterogeneity has a minor influence on the apparent elastic properties of human cancellous bone: a SRμCT-based finite element study.

Author

Gross T, Pahr DH, Peyrin F, and Zysset PK

Subjects

Aged, Aged, 80 and over, Biomechanical Phenomena physiology, Bone and Bones anatomy & histology, Calcium metabolism, Computer Simulation, Elastic Modulus physiology, Female, Femur Neck physiology, Finite Element Analysis, Humans, Male, Middle Aged, Models, Anatomic, Models, Biological, Synchrotrons, X-Ray Microtomography methods, X-Ray Microtomography statistics & numerical data, Bone Density physiology, Bone and Bones diagnostic imaging, Bone and Bones physiology

Abstract

At the tissue level, the local material properties of human cancellous bone are heterogeneous due to constant remodelling. Since standard high-resolution computed tomography scanning methods are unable to capture this heterogeneity in detail, local differences in mineralisation are normally not incorporated in computational models. To investigate the effects of heterogeneous mineral distribution on the apparent elastic properties, 40 cancellous bone samples from the human femoral neck were scanned by means of synchrotron radiation microcomputed tomography (SRμCT). SRμCT-based micromechanical finite element models that accounted for mineral heterogeneity were compared with homogeneous models. Evaluation of the apparent stiffness tensor of both model types revealed that homogeneous models led to a minor but significant (p < 0.05) overestimation of the elastic properties of heterogeneous models by 2.18 ± 1.89%. Variation of modelling parameters did not affect the overestimation to a great extent. It was concluded that the heterogeneous mineralisation has only a minor influence on the apparent elastic properties of human cancellous bone.

Published

2012

3. From high-resolution CT data to finite element models: development of an integrated modular framework.

Author

Pahr DH and Zysset PK

Subjects

Computer Simulation, Femur Head diagnostic imaging, Femur Head physiology, Finite Element Analysis, Humans, Software, Spine diagnostic imaging, Spine physiology, Systems Integration, Bone and Bones diagnostic imaging, Bone and Bones physiology, Models, Biological, Radiographic Image Interpretation, Computer-Assisted methods, Software Design, Tomography, X-Ray Computed methods

Abstract

This work introduces a novel method of automating the process of patient-specific finite element (FE) model development using a mapped mesh technique. The objective is to map a predefined mesh (template) of high quality directly onto a new bony surface (target) definition, thereby yielding a similar mesh with minimal user interaction. To bring the template mesh into correspondence with the target surface, a deformable registration technique based on the FE method has been adopted. The procedure has been made hierarchical allowing several levels of mesh refinement to be used, thus reducing the time required to achieve a solution. Our initial efforts have focused on the phalanx bones of the human hand. Mesh quality metrics, such as element volume and distortion were evaluated. Furthermore, the distance between the target surface and the final mapped mesh were measured. The results have satisfactorily proven the applicability of the proposed method.

Published

2009