A computational model coupling mechanics and electrophysiology in spinal cord injury

Jérusalem, Antoine; García-Grajales, Julián A.; Merchán-Pérez, Ángel; Peña, José M.

doi:10.1007/s10237-013-0543-7

Cited by 49 publications

(185 citation statements)

References 36 publications

(73 reference statements)

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“…[19,28], see Table 1. An explicit scheme was used for solving the electrophysiological ion channel dynamics variables of the HH boundary condition equations.…”

Section: Materials Law and Numerical Solvermentioning

confidence: 99%

“…This model follows the approach proposed by Jérusalem et al [19] to model the ion channel left shift related damage. In this model, Equation (30) is also used but the reversal potentials of the ion channels are modified to reflect such damage, see Equation (31).…”

Section: Boundary Conditionsmentioning

confidence: 99%

“…In order to validate the electrophysiological implementation of the CT and HH boundary conditions, both were modelled separately and, in the absence of deformation, validated against the results of two other numerical codes: Neurite, a 1D finite difference framework for mechanical electrophysiological coupling [19,28], and a Matlab 1D FE code with CT and HH applied as boundary conditions in a similar fashion, and solved using the Newton-Raphson iterative scheme, see Appendix B for the full study and Appendix C for the Matlab 1D code.…”

Section: Electrophysiological Validationmentioning

confidence: 99%

“…To this end, Jérusalem et al [19] proposed a 1D finite difference model to capture the longitudinal strain and strain rate dependence of electrophysiological alteration by relating the N a V and voltage gated potassium (K V ) ion channels dynamics to the strain in the membrane. This model aimed at capturing the recovery of CAP amplitude up to 30 minutes post white matter stretch in experiments conducted by Shi and Whitebone [7].…”

Section: Introductionmentioning

confidence: 99%

“…Their model considers the extracellular matrix, membrane and intracellular matrix as separate element types. The strain based electrophysiology damage model proposed by Jérusalem et al [19] was adopted in this model but the ion channel dynamics damage was not directly linked to the deformation. While the 3D FE approach allows for multiple loading modes, the required spatial discretisation of the axonal membrane (approximately a thousandth of the axon diameter) for a fully geometrically conserving model remains computationally expensive.…”

Section: Introductionmentioning

confidence: 99%

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3D finite element formulation for mechanical–electrophysiological coupling in axonopathy

Kwong

Bianchi

Malboubi

et al. 2019

Computer Methods in Applied Mechanics and Engineering

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Traumatic injuries to the central nervous system (brain and spinal cord) have recently been put under the spotlight because of their devastating socioeconomical cost. At the cellular scale, recent research efforts have focussed on primary injuries by making use of models aimed at simulating mechanical deformation induced axonal electrophysiological functional deficits. The overwhelming majority of these models only consider axonal stretching as a loading mode, while other modes of deformation such as crushing or mixed modes-highly relevant in spinal cord injury-are left unmodelled. To this end, we propose here a novel 3D finite element framework coupling mechanics and electrophysiology by considering the electrophysiological HodgkinHuxley and Cable Theory models as surface boundary conditions introduced directly in the weak form, hence eliminating the need to geometrically account for the membrane in its electrophysiological contribution. After validation against numerical and experimental results, the approach is leveraged to model an idealised axonal dislocation injury. The results show that the sole consideration of induced longitudinal stretch following transverse loading of a node of Ranvier is not necessarily enough to capture the extent of axonal electrophysiological deficit and that the non-axisymmetric loading of the node participates to a larger extent to the subsequent damage. On the contrary, * Corresponding authors Email addresses: man.kwong@eng.ox.ac.uk (Man Ting Kwong ), antoine.jerusalem@eng.ox.ac.uk (Antoine Jérusalem ) Preprint submitted to Computer Methods In Applied Mechanics And EngineeringJune 6, 2018 a similar transverse loading of internodal regions was not shown to significantly worsen with the additional consideration of the non-axisymmetric loading mode.

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“…[19,28], see Table 1. An explicit scheme was used for solving the electrophysiological ion channel dynamics variables of the HH boundary condition equations.…”

Section: Materials Law and Numerical Solvermentioning

confidence: 99%

Section: Boundary Conditionsmentioning

confidence: 99%

Section: Electrophysiological Validationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

3D finite element formulation for mechanical–electrophysiological coupling in axonopathy

Kwong

Bianchi

Malboubi

et al. 2019

Computer Methods in Applied Mechanics and Engineering

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Electro‐mechanical response of a 3D nerve bundle model to mechanical loads leading to axonal injury

Cinelli

Destrade

Duffy

et al. 2018

Numer Methods Biomed Eng

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Traumatic brain injuries and damage are major causes of death and disability. We propose a 3D fully coupled electro-mechanical model of a nerve bundle to investigate the electrophysiological impairments due to trauma at the cellular level. The coupling is based on a thermal analogy of the neural electrical activity by using the finite element software Abaqus CAE 6.13-3. The model includes a real-time coupling, modulated threshold for spiking activation, and independent alteration of the electrical properties for each 3-layer fibre within a nerve bundle as a function of strain. Results of the coupled electro-mechanical model are validated with previously published experimental results of damaged axons. Here, the cases of compression and tension are simulated to induce (mild, moderate, and severe) damage at the nerve membrane of a nerve bundle, made of 4 fibres. Changes in strain, stress distribution, and neural activity are investigated for myelinated and unmyelinated nerve fibres, by considering the cases of an intact and of a traumatised nerve membrane. A fully coupled electro-mechanical modelling approach is established to provide insights into crucial aspects of neural activity at the cellular level due to traumatic brain injury. One of the key findings is the 3D distribution of residual stresses and strains at the membrane of each fibre due to mechanically induced electrophysiological impairments, and its impact on signal transmission.

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Effects of nerve bundle geometry on neurotrauma evaluation

Cinelli

Destrade

McHugh

et al. 2018

Numer Methods Biomed Eng

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A computational model coupling mechanics and electrophysiology in spinal cord injury

Cited by 49 publications

References 36 publications

3D finite element formulation for mechanical–electrophysiological coupling in axonopathy

3D finite element formulation for mechanical–electrophysiological coupling in axonopathy

Electro‐mechanical response of a 3D nerve bundle model to mechanical loads leading to axonal injury

Effects of nerve bundle geometry on neurotrauma evaluation

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