Your search keyword '"Pierre-Louis Ricci"' showing total 3 results

1. Influence of pubic symphysis stiffness on pelvic load distribution during single leg stance

Author

T. Gerich, Stefan Maas, Jens Kelm, and Pierre-Louis Ricci

Subjects

musculoskeletal diseases, Finite Element Analysis, 0206 medical engineering, Biomedical Engineering, Pubic symphysis, 02 engineering and technology, Single leg stance, 030204 cardiovascular system & hematology, Pelvis, Inverse dynamics, Weight-Bearing, 03 medical and health sciences, 0302 clinical medicine, medicine, Humans, Molecular Biology, Sacroiliac joint, Applied Mathematics, Pubic Symphysis, Stiffness, Anatomy, musculoskeletal system, Sacrum, 020601 biomedical engineering, humanities, Stiffening, body regions, medicine.anatomical_structure, Computational Theory and Mathematics, Modeling and Simulation, medicine.symptom, Software, Geology

Abstract

This study focuses on the influence of the softening and stiffening of pubic symphysis on the load distribution within the bones of the pelvic ring under the physiological loadings of the single leg stance. Muscle forces and joint reaction forces were first determined by inverse dynamics and applied to a linear finite element model of the pelvis. With normal pubic symphysis stiffness, high Von Mises stresses are located on the anterior surface to the sacrum around the sacroiliac joint and on the superior ramus, both on the side of the weight-bearing leg. Softening of the pubic symphysis redirects the load backward, decreases the stresses at the anterior pelvis, and increases them at the posterior pelvis. A stiffening of the pubic symphysis redirects the load forward, increases the load on the posterior pelvis, and decreases them at the anterior pelvis. This investigation highlights the significance of the pubic symphysis on the load distribution of the pelvis and in maintaining the integrity of the structures. Its role should not be neglected when analyzing the pelvis.

Published

2020

2. Finite element analysis of the pelvis including gait muscle forces: an investigation into the effect of rami fractures on load transmission

Author

T. Gerich, Pierre-Louis Ricci, Stefan Maas, and Jens Kelm

Subjects

Inverse dynamics, 03 medical and health sciences, Ingénierie mécanique [C10] [Ingénierie, informatique & technologie], 0302 clinical medicine, Gait (human), lcsh:Orthopedic surgery, medicine, Orthopedics and Sports Medicine, Joint (geology), Pelvic ring fracture, Pelvis, 030222 orthopedics, Physiological loadings of the gait, Research, Mechanical engineering [C10] [Engineering, computing & technology], Biomechanics, Finite element analysis, Anatomy, Finite element method, lcsh:RD701-811, medicine.anatomical_structure, Transmission (telecommunications), Fracture (geology), Muscle forces, Biomechanics of the pelvis, 030217 neurology & neurosurgery, Geology

Abstract

Background The objective of the study is to investigate the load transmission within the pelvic ring under physiological loading during gait and to correlate these results with clinical findings. In a second approach, we analysed how load distribution is altered by fractures of the anterior pelvic ring. Methods Muscle forces and joint reaction forces are calculated by inverse dynamics and implemented in a finite element pelvis model including the joints. Results With the intact configuration and according to the moment of the gait, left and right superior and inferior rami show the highest stresses of the model, corresponding to the typical location of an anterior pelvic ring fracture. A superior ramus fracture induces larger stresses to the lower ramus and a slight increase of stresses on the posterior structures. A total disruption of anterior rami redirects the loads to the back of the pelvis and introduces significantly higher stresses on the posterior structures. Conclusions This investigation enhances the understanding of the biomechanics of the pelvis and highlights the important role of the rami in load carrying and in maintaining integrity of the pelvic ring.

Published

2018

3. Use of a Computed Tomography Based Approach to Validate Noninvasive Devices to Measure Rotational Knee Laxity

Author

Pierre-Louis Ricci, Pierre-Jean Arnoux, Arno Zürbes, Stefan Maas, Frédéric Walter, Jens Kelm, Simon Neumann, Danièle Waldmann, Fonds National de la Recherche - FnR [sponsor], and University of Luxembourg: Research Unit of Engineering Sciences (RUES) [research center]

Subjects

musculoskeletal diseases, medicine.medical_specialty, Flexibility (anatomy), Article Subject, Computer science, Mechanical engineering [C10] [Engineering, computing & technology], computed tomography, Thigh, Rotation, musculoskeletal system, noninvasive measurement device, Ingénierie mécanique [C10] [Ingénierie, informatique & technologie], medicine.anatomical_structure, rotational knee laxity, medicine, Ligament, Rotameter, Femur, Displacement (orthopedic surgery), Radiology, Biomedical engineering, Fixation (histology), Research Article

Abstract

The purpose of this study is to validate a noninvasive rotational knee laxity measuring device called “Rotameter P2” with an approach based on Computed Tomography (CT). This CT-approach using X-rays is hence invasive and can be regarded as a precise reference method that may also be applied to similar devices. An error due to imperfect femur fixation was observed but can be neglected for small torques. The most significant estimation error is due to the unavoidable soft tissues rotation and hence flexibility in the measurement chain. The error increases with the applied torque. The assessment showed that the rotational knee angle measured with the Rotameter is still overestimated because of thigh and femur displacement, soft tissues deformation, and measurement artefacts adding up to a maximum of 285% error at +15 Nm for the Internal Rotation of female volunteers. This may be questioned if such noninvasive devices for measuring the Tibia-Femoral Rotation (TFR) can help diagnosing knee pathologies and investigate ligament reconstructive surgery.

Published

2015