Brain tissue deforms similarly to filled elastomers and follows consolidation theory

Franceschini, G.; Bigonia, D.; Regitnig, P.; Holzapfel, G. A.

Affiliations

¹Dipartimento di Ingegneria Meccanica e Strutturale, Università di Trento, Via Mesiano 77 – 38050 Povo, Trento, Italia

²Institute of Pathology, Medical University of Graz, Auenbruggerplatz 25, A-8036 Graz, Austria

³School of Engineering Sciences, Royal Institute of Technology, Osquars backe 1, SE-100 44 Stockholm, Sweden

⁴Computational Biomechanics, Graz University of Technology, Schiesstattgasse 14-B, A-8010 Graz, Austria

Abstract and keywords

Slow, large deformations of human brain tissue—accompanying cranial vault deformation induced by positional plagiocephaly, occurring during hydrocephalus, and in the convolutional development—has surprisingly received scarce mechanical investigation. Since the effects of these deformations may be important, we performed a systematic series of in vitro experiments on human brain tissue, revealing the following features. (i) Under uniaxial (quasi-static), cyclic loading, brain tissue exhibits a peculiar nonlinear mechanical behaviour, exhibiting hysteresis, Mullins effect and residual strain, qualitatively similar to that observed in filled elastomers. As a consequence, the loading and unloading uniaxial curves have been found to follow the Ogden nonlinear elastic theory of rubber (and its variants to include Mullins effect and permanent strain). (ii) Loaded up to failure, the “shape” of the stress/strain curve qualitatively changes, evidencing softening related to local failure. (iii) Uniaxial (quasi-static) strain experiments under controlled drainage conditions provide the first direct evidence that the tissue obeys consolidation theory involving fluid migration, with properties similar to fine soils, but having much smaller volumetric compressibility. (iv) Our experimental findings also support the existence of a viscous component of the solid phase deformation.

Brain tissue should, therefore, be modelled as a porous, fluid-saturated, nonlinear solid with very small volumetric (drained) compressibility.

Keywords: Soft tissue; Biphasic material; Human brain; Elasticity; Terzaghi consolidation

Links

DOI: 10.1016/j.jmps.2006.05.004

WoS: 000242749100005

History

Received: 2005-10-20

Revised: 2006-05-02

Accepted: 2006-05-03

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2007	Hrapko M, Gervaise H, van Dommelen JAW, Peters GWM, Wismans JSHM. Identifying the mechanical behaviour of brain tissue in both shear and compression. In: Proceedings of the 2007 International IRCOBI Conference on the Biomechanics of Impact. September 19-21, 2007; Maastricht, The Netherlands.143-159.
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2020	Sebastian KM. Defining the Mechanical Characteristics of Porcine Brain Tissue Subject to Cyclic, Compressive Loading [Master's thesis]. Mississippi State University; May 2020.
2023	Li Y. Toward a Biofidelic and Repeatable Physical Head-Brain Model for Application in Blunt Impact [PhD thesis]. Edmonton, AB: University of Alberta; 2023.
2014	Patton DA. The Biomechanical Determinants of Sports-Related Concussion: Finite Element Simulations of Unhelmeted Head Impacts to Evaluate Kinematic and Tissue-Level Predictors of Injury and Investigate the Design Implications for Soft-Shell Headgear [PhD thesis]. University of New South Wales; March 2014.
2020	Giudice JS. Personalized Finite Element Modeling of the Brain: Understanding Subject-Specific Deformation Patterns [PhD thesis]. Charlottesville, VA: University of Virginia; December 2020.
2023	Lyu D. Investigation of Biomechanical Thresholds of Mild to Severe Brain Injury Using an Anisotropic Visco-Hyperelastic Finite Element Head Model: Model Development and Simulation of Impact Injury and Blast Injury [PhD thesis]. Detroit, MI: Wayne State University; August 2023.