Litcius/Paper detail

Modelling the rate-dependent mechanical behaviour of the brain tissue

Afshin Anssari-Benam, Giuseppe Saccomandi

2024Journal of the mechanical behavior of biomedical materials/Journal of mechanical behavior of biomedical materials10 citationsDOIOpen Access PDF

Abstract

A new modelling approach is employed in this work for application to the rate-dependent mechanical behaviour of the brain tissue, as an incompressible isotropic material. Extant datasets encompassing single- and multi-mode compression, tension and simple shear deformation(s) are considered, across a wide range of deformation rates from quasi-static to rates akin to blast loading conditions, in the order of 1000 s−1 . With a simple functional form and a reduced number of parameters, the model is shown to capture the considered rate-dependent behaviours favourably, including in both single- and multi-mode deformation fits, and over all range of deformation rates. The provided modelling results here are obtained from either first fitting the model to the quasi-static data, or/and predicting the behaviour at a different rate than those used for calibrating the model parameters. Given its simplicity, versatility, predictive capability and accuracy, the application of the utilised modelling framework in this work to the rate-dependent mechanical behaviour of the brain tissue is proposed.

Topics & Concepts

Deformation (meteorology)IsotropyCompressibilityExtant taxonWork (physics)Range (aeronautics)Simple shearMechanicsCompression (physics)Materials scienceComputer scienceShear (geology)Composite materialPhysicsThermodynamicsOpticsEvolutionary biologyBiologyAutomotive and Human Injury BiomechanicsElasticity and Material ModelingCellular and Composite Structures