Your search keyword '"Petit, Yvan"' showing total 10 results

1. Tensile mechanical properties of the cervical, thoracic and lumbar porcine spinal meninges.

Author

Sudres P, Evin M, Wagnac E, Bailly N, Diotalevi L, Melot A, Arnoux PJ, and Petit Y

Subjects

Animals, Dura Mater, Elastic Modulus, Pia Mater, Stress, Mechanical, Swine, Meninges, Spinal Cord

Abstract

Background: The spinal meninges play a mechanical protective role for the spinal cord. Better knowledge of the mechanical behavior of these tissues wrapping the cord is required to accurately model the stress and strain fields of the spinal cord during physiological or traumatic motions. Then, the mechanical properties of meninges along the spinal canal are not well documented. The aim of this study was to quantify the elastic meningeal mechanical properties along the porcine spinal cord in both the longitudinal direction and in the circumferential directions for the dura-arachnoid maters complex (DAC) and solely in the longitudinal direction for the pia mater. This analysis was completed in providing a range of isotropic hyperelastic coefficients to take into account the toe region., Methods: Six complete spines (C0 - L5) were harvested from pigs (2-3 months) weighing 43±13 kg. The mechanical tests were performed within 12 h post mortem. A preload of 0.5 N was applied to the pia mater and of 2 N to the DAC samples, followed by 30 preconditioning cycles. Specimens were then loaded to failure at the same strain rate 0.2 mm/s (approximately 0.02/s, traction velocity/length of the sample) up to 12 mm of displacement., Results: The following mean values were proposed for the elastic moduli of the spinal meninges. Longitudinal DAC elastic moduli: 22.4 MPa in cervical, 38.1 MPa in thoracic and 36.6 MPa in lumbar spinal levels; circumferential DAC elastic moduli: 20.6 MPa in cervical, 21.2 MPa in thoracic and 12.2 MPa in lumbar spinal levels; and longitudinal pia mater elastic moduli: 18.4 MPa in cervical, 17.2 MPa in thoracic and 19.6 MPa in lumbar spinal levels., Discussion: The variety of mechanical properties of the spinal meninges suggests that it cannot be regarded as a homogenous structure along the whole length of the spinal cord., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2021

2. Impact of spinal rod stiffness on porcine lumbar biomechanics: Finite element model validation and parametric study.

Author

Brummund M, Brailovski V, Petit Y, Facchinello Y, and Mac-Thiong JM

Subjects

Animals, Biomechanical Phenomena, Models, Anatomic, Pressure, Swine, Weight-Bearing, Finite Element Analysis, Lumbar Vertebrae anatomy & histology, Lumbar Vertebrae physiology, Mechanical Phenomena, Spinal Cord anatomy & histology, Spinal Cord physiology

Abstract

A three-dimensional finite element model of the porcine lumbar spine (L1-L6) was used to assess the effect of spinal rod stiffness on lumbar biomechanics. The model was validated through a comparison with in vitro measurements performed on six porcine spine specimens. The validation metrics employed included intervertebral rotations and the nucleus pressure in the first instrumented intervertebral disc. The numerical results obtained suggest that rod stiffness values as low as 0.1 GPa are required to reduce the mobility gradient between the adjacent and instrumented segments and the nucleus pressures across the porcine lumbar spine significantly. Stiffness variations above this threshold value have no significant effect on spine biomechanics. For such low-stiffness rods, intervertebral rotations in the instrumented zone must be monitored closely in order to guarantee solid fusion. Looking ahead, the proposed model will serve to examine the transverse process hooks and variable stiffness rods in order to further smooth the transition between the adjacent and instrumented segments, while preserving the stability of the instrumented zone, which is needed for fusion.

Published

2017

3. Development of an instrumented spinal cord surrogate using optical fibers: A feasibility study.

Author

Facchinello Y, Wagnac É, Ung B, Petit Y, Pradhan P, Peyrache LM, and Mac-Thiong JM

Subjects

Compressive Strength, Feasibility Studies, Models, Anatomic, Printing, Three-Dimensional, Optical Fibers, Spinal Cord

Abstract

In vitro replication of traumatic spinal cord injury is necessary to understand its biomechanics and to improve animal models. During a traumatic spinal cord injury, the spinal cord withstands an impaction at high velocity. In order to fully assess the impaction, the use of spinal canal occlusion sensor is necessary. A physical spinal cord surrogate is also often used to simulate the presence of the spinal cord and its surrounding structures. In this study, an instrumented physical spinal cord surrogate is presented and validated. The sensing is based on light transmission loss observed in embedded bare optical fibers subjected to bending. The instrumented surrogate exhibits similar mechanical properties under static compression compared to fresh porcine spinal cords. The instrumented surrogate has a compression sensing threshold of 40% that matches the smallest compression values leading to neurological injuries. The signal obtained from the sensor allows calculating the compression of the spinal cord surrogate with a maximum of 5% deviation. Excellent repeatability was also observed under repetitive loading. The proposed instrumented spinal cord surrogate is promising with satisfying mechanical properties and good sensing capability. It is the first attempt at proposing a method to assess the internal loads sustained by the spinal cord during a traumatic injury., (Copyright © 2017 IPEM. Published by Elsevier Ltd. All rights reserved.)

Published

2017

4. Morphometrics of the entire human spinal cord and spinal canal measured from in vivo high-resolution anatomical magnetic resonance imaging.

Author

Fradet L, Arnoux PJ, Ranjeva JP, Petit Y, and Callot V

Subjects

Adult, Aged, Cross-Sectional Studies, Female, Humans, Magnetic Resonance Imaging, Male, Middle Aged, Reference Values, Young Adult, Spinal Canal anatomy & histology, Spinal Cord anatomy & histology

Abstract

Study Design: Measurements of cervical and thoracolumbar human spinal cord (SC) geometry based on in vivo magnetic resonance imaging and investigation of morphological "invariants.", Objective: The current work aims at providing morphological features of the complete in vivo human normal SC and at investigating possible "invariant" parameters that may serve as normative data for individualized study of SC injuries., Summary of Background Data: Few in vivo magnetic resonance image-based studies have described human SC morphology at the cervical level, and similar description of the entire SC only relies on postmortem studies, which may be prone to atrophy biases. Moreover, large interindividual variations currently limit the use of morphological metrics as reference for clinical applications or as modeling inputs., Methods: Absolute metrics of SC (transverse and anteroposterior diameters, width of anterior and posterior horns, cross-sectional SC area, and white matter percentage) were measured using semiautomatic segmentation of high resolution in vivo T2*-weighted transverse images acquired at 3 T, at each SC level, on healthy young (N = 15) and older (N = 8) volunteers. Robustness of measurements, effects of subject, age, or sex, as well as comparison with previously published postmortem data were investigated using statistical analyses (separate analysis of variance, Tukey-HSD, Bland-Altman). Normalized-to-C3 parameters were evaluated as invariants using a leave-one-out analysis. Spinal canal parameters were measured and occupation ratio border values were determined., Results: Metrics of SC morphology showed large intra- and interindividual variations, up to 30% and 13%, respectively, on average. Sex had no influence except on posterior horn width (P < 0.01). Age-related differences were observed for anteroposterior diameter and white matter percentage (P < 0.05) and all postmortem metrics were significantly lower than in vivo values (P < 0.001). In vivo normalized SC area and diameters seemed to be invariants (R > 0.74, root-mean-square deviation < 10%). Finally, minimal and maximal occupation ratio were 0.2 and 0.6, respectively., Conclusion: This study presented morphological characteristics of the complete in vivo human SC. Significant differences linked to age and postmortem state have been identified. Morphological "invariants" that could be used to calculate the normally expected morphology accurately, were also identified. These observations should benefit to biomechanical and SC pathology studies., Level of Evidence: N/A.

Published

2014

5. Effect of experimental, morphological and mechanical factors on the murine spinal cord subjected to transverse contusion: A finite element study

Author

Fournely, Marion, Petit, Yvan, Wagnac, Eric, Evin, Morgane, Arnoux, Pierre-Jean, Laboratoire de Biomécanique Appliquée (LBA UMR T24), Aix Marseille Université (AMU)-Université Gustave Eiffel, and International Laboratory on Spine Imaging and Biomechanics (iLab-Spine)

Subjects

Critical Care and Emergency Medicine, Science, Materials Science, Finite Element Analysis, Models, Neurological, Nervous System, SPINAL CORD INJURY, Mice, BIOMECANIQUE, Imaging, Three-Dimensional, DEFORMATION, Medicine and Health Sciences, Animals, Humans, Computer Simulation, BLESSURE, Gray Matter, MOELLE EPINIERE, Musculoskeletal System, Trauma Medicine, Spinal Cord Injuries, Damage Mechanics, Physics, TRAUMATIC INJURY, Biology and Life Sciences, Classical Mechanics, CENTRAL NERVOUS SYSTEM, SYSTEME NERVEUX, White Matter, BIOMECHANICS, Spine, MATERIAL PROPERTIES, Biomechanical Phenomena, Neuroanatomy, Disease Models, Animal, Neurology, METHODE DES ELEMENTS FINIS, Physical Sciences, Medicine, COMPRESSION, [SDV.IB]Life Sciences [q-bio]/Bioengineering, Anatomy, Neurotrauma, SPINAL CORD, Research Article, Neuroscience, TRAUMATISME

Abstract

Finite element models combined with animal experimental models of spinal cord injury provides the opportunity for investigating the effects of the injury mechanism on the neural tissue deformation and the resulting tissue damage. Thus, we developed a finite element model of the mouse cervical spinal cord in order to investigate the effect of morphological, experimental and mechanical factors on the spinal cord mechanical behavior subjected to transverse contusion. The overall mechanical behavior of the model was validated with experimental data of unilateral cervical contusion in mice. The effects of the spinal cord material properties, diameter and curvature, and of the impactor position and inclination on the strain distribution were investigated in 8 spinal cord anatomical regions of interest for 98 configurations of the model. Pareto analysis revealed that the material properties had a significant effect (p

Published

2020

6. Morphological features of thoracolumbar burst fractures associated with neurological outcome in thoracolumbar traumatic spinal cord injury.

Author

Goulet, Julien, Richard-Denis, Andréane, Petit, Yvan, Diotalevi, Lucien, and Mac-Thiong, Jean-Marc

Subjects

SPINAL cord injuries, SPINAL canal, SPINAL injuries, TRAUMA centers, SPINAL cord, ENERGY transfer

Abstract

Purpose: To identify specific morphological characteristics in thoracolumbar burst fractures associated with neurological outcome after severe traumatic spinal cord injury (TSCI). Methods: We retrospectively analyzed the clinical and radiological (CT scan morphological characteristics) data of 25 consecutive patients admitted for TSCI secondary to a burst fracture at levels from T11 to L2 between 2010 and 2017 in single level-1 trauma center. We included severe TSCI, defined as American Spinal Injury Association Impairment Scale (AIS) grade A, B or C. Results: Among the 25 patients with severe TSCI, 14 were AIS A, 5 were AIS B, and 6 were AIS C upon initial preoperative neurological evaluation. The AIS grade and the burden of associated injuries (Injury Severity Score, ISS) were the only clinical factors significantly associated with poor neurological recovery. The trauma level of energy was not associated with neurological outcome. Several fractures parameters were independently related to neurological recovery: the postero-inferior corner translation, presence of retropulsed fragment comminution and complete lamina fracture. The magnitude of sagittal kyphosis angle, vertebral kyphosis index and vertebral body comminution were not associated with the neurological outcome. Conclusions: Morphological features of the bony structures involving the spinal canal in thoracolumbar burst fractures with severe TSCI are associated with the chronic neurological outcome and could provide more insight than the AIS clinical grading. The fracture pattern may better reflect the actual level of energy transferred to the spinal cord than distinguishing between low- and high-energy trauma. [ABSTRACT FROM AUTHOR]

Published

2020

7. Strain rate dependent behavior of the porcine spinal cord under transverse dynamic compression.

Author

Fradet, Léo, Cliche, Francis, Petit, Yvan, Mac-Thiong, Jean-Marc, and Arnoux, Pierre-Jean

Subjects

SPINAL cord compression, STRAIN rate, CYCLIC loads

Abstract

The accurate description of the mechanical properties of spinal cord tissue benefits to clinical evaluation of spinal cord injuries and is a required input for analysis tools such as finite element models. Unfortunately, available data in the literature generally relate mechanical properties of the spinal cord under quasi-static loading conditions, which is not adapted to the study of traumatic behavior, as neurological tissue adopts a viscoelastic behavior. Thus, the objective of this study is to describe mechanical properties of the spinal cord up to mechanical damage, under dynamic loading conditions. A total of 192 porcine cervical to lumbar spinal cord samples were compressed in a transverse direction. Loading conditions included ramp tests at 0.5, 5 or 50 s-1 and cyclic loading at 1, 10 or 20 Hz. Results showed that spinal cord behavior was significantly influenced by strain rate. Mechanical damage occurred at 0.64, 0.68 and 0.73 strains for 0.5, 5 or 50 s-1 loadings, respectively. Variations of behavior between the tested strain rates were explained by cyclic loading results, which revealed behavior more or less viscous depending on strain rate. Also, a parameter (stress multiplication factor) was introduced to allow transcription of a stress-strain behavior curve to different strain rates. This factor was described and was significantly different for cervical, thoracic and lumbar vertebral heights, and for the strain rates evaluated in this study. [ABSTRACT FROM AUTHOR]

Published

2016

8. Three-Dimensional (3 - D) Reconstruction of the Spine From a Single X-Ray Image and Prior Vertebra Models.

Author

Novosad, Justin, Cheriet, Farida, Petit, Yvan, and Labelle, Hubert

Subjects

ALGORITHMS, STANDARDIZATION, QUALITATIVE research, SPINAL cord, CENTRAL nervous system, SPINE, RADIOSCOPIC diagnosis

Abstract

The lateral bending test is routinely used by clinicians for the preoperative assessment of spinal mobility. The evaluation of bending motion is usually based on the qualitative analysis of a two-dimensional (2-D) antero-posterior X-ray image. The aim of this paper is to introduce a novel three-dimensional (3-D) reconstruction technique that is a prerequisite for the quantitative 3-D analysis of lateral bending motion. An algorithm was developed for the 3-D reconstruction of the spine from a single X-ray image. The X-ray is calibrate using a small calibration object and an explicit calibration algorithm. The information contained in the single X-ray is completed by registering a priori 3LD geometric models of individual vertebrae. Part of the error yielded by the 3-D12-D registration is corrected by a vertebral alignment constraint that aims to minimize intervertebral dislocations. Three-di- mensional models of 15 different scoliosis patients, obtained from a standard stereo-radiographic 3-D reconstruction, were used in simulation and validation experiments. Experimental results show that the new method is robust and accurate. With pessimistic levels of simulated noise, the average root mean square reconstruction error is 2.89 mm, which is appropriate for common clinical applications. [ABSTRACT FROM AUTHOR]

Published

2004

9. A Sensitive and Fast Fiber Bragg Grating-Based Investigation of the Biomechanical Dynamics of In Vitro Spinal Cord Injuries.

Author

Mishra, Satyendra Kumar, Mac-Thiong, Jean-Marc, Wagnac, Éric, Petit, Yvan, Ung, Bora, and Kinet, Damien

Subjects

SPINAL cord injuries, FIBER Bragg gratings, SPINAL cord compression, SPINAL cord, TISSUE mechanics

Abstract

To better understand the real-time biomechanics of soft tissues under sudden mechanical loads such as traumatic spinal cord injury (SCI), it is important to improve in vitro models. During a traumatic SCI, the spinal cord suffers high-velocity compression. The evaluation of spinal canal occlusion with a sensor is required in order to investigate the degree of spinal compression and the fast biomechanical processes involved. Unfortunately, available techniques suffer with drawbacks such as the inability to measure transverse compression and impractically large response times. In this work, an optical pressure sensing scheme based on a fiber Bragg grating and a narrow-band filter was designed to detect and demonstrate the transverse compression inside a spinal cord surrogate in real-time. The response time of the proposed scheme was 20 microseconds; a five orders of magnitude enhancement over comparable schemes that depend on costly and slower optical spectral analyzers. We further showed that this improvement in speed comes with a negligible loss in sensitivity. This study is another step towards better understanding the complex biomechanics involved during a traumatic SCI, using a method capable of probing the related internal strains with high-spatiotemporal resolution. [ABSTRACT FROM AUTHOR]

Published

2021

10. Numerical investigation of the relative effect of disc bulging and ligamentum flavum hypertrophy on the mechanism of central cord syndrome.

Author

Bailly, Nicolas, Diotalevi, Lucien, Beauséjour, Marie-Hélène, Wagnac, Éric, Mac-Thiong, Jean-Marc, and Petit, Yvan

Subjects

*CERVICAL vertebrae, *HISTOLOGY, *HYPERTROPHY, *INTERVERTEBRAL disk, *INTERVERTEBRAL disk displacement, *JOINT hypermobility, *SPINAL canal, *SPINAL cord, *SPINAL cord compression, *SPRAINS, *PHYSIOLOGICAL stress, *STRUCTURAL models, *ARTICULAR ligaments, *STENOSIS, *CENTRAL cord syndrome, *DESCRIPTIVE statistics, *SPONDYLOSIS, *DISEASE complications

Abstract

The pathogenesis of the central cord syndrome is still unclear. While there is a consensus on hyperextension as the main traumatic mechanism leading to this condition, there is yet to be consensus in studies regarding the pathological features of the spine (intervertebral disc bulging or ligamentum flavum hypertrophy) that could contribute to clinical manifestations. A comprehensive finite element model of the cervical spine segment and spinal cord was used to simulate high-speed hyperextension. Four stenotic cases were modelled to study the effect of ligamentum flavum hypertrophy and intervertebral disc bulging on the von Mises stress and strain. During hyperextension, the downward displacement of the ligamentum flavum and a reduction of the spinal canal diameter (up to 17%) led to a dynamic compression of the cord. Ligamentum flavum hypertrophy was associated with stress and strain (peak of 0.011 Mpa and 0.24, respectively) in the lateral corticospinal tracts, which is consistent with the histologic pattern of the central cord syndrome. Linear intervertebral disc bulging alone led to a higher stress in the anterior and posterior funiculi (peak 0.029 Mpa). Combined with hypertrophic ligamentum flavum, it further increased the stress and strain in the corticospinal tracts and in the posterior horn (peak of 0.023 Mpa and 0.35, respectively). The stenotic typology and geometry greatly influence stress and strain distribution resulting from hyperextension. Ligamentum flavum hypertrophy is a main feature leading to central cord syndrome. Unlabelled Image • Spinal canal narrowing, hypertrophic ligamentum flavum and disc bulging, were modelled. • Hyperextension led to a small reduction of the spinal canal diameter. • Each spondylotic feature leads to a specific stress and strain distribution pattern. • Simulated ligamentum flavum hypertrophy corroborates histological findings. [ABSTRACT FROM AUTHOR]

Published

2020