Rheology of brain tissue and hydrogels: A novel hyperelastic and viscoelastic model for forensic applications

Yarin, A. L.; Kosmerl, V.

doi:10.1063/5.0173127

Physics of Fluids

2023

DOI: 10.1063/5.0173127

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Rheology of brain tissue and hydrogels: A novel hyperelastic and viscoelastic model for forensic applications

A. L. Yarin,

V. Kosmerl

Abstract: A new strain-energy function W, which possesses the strain energy expressible as a rational function of the principal invariants of the Cauchy tensor C, is proposed. It generates a hyperelastic constitutive equation with characteristics of brain tissues: a much stronger resistance to compression than to stretching and strongly nonlinear response in simple shear, including non-zero first and second normal differences. This model exponent α resembles the Ogden model in uniaxial stretching/compression and reveals… Show more

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Cited by 5 publications

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“…Wave dynamics is also in focus in the two inter-related works of Yarin and Kosmerl (2023) and Kosmerl and Yarin (2023). These works are motivated by a short-range gunshot wound to the head, where a bullet penetrates brain tissue and can cause backspatter of brain tissue fragments.…”

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Applications of fluid dynamics and mechanics of continua in forensics

Yarin

2023

Physics of Fluids

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Here, an overview is given of a collection of works published by Physics of Fluids under an umbrella-title Flow and Forensics. These works span the two fields, which currently coexist without too much interaction, namely, fluid mechanics and forensic science. Nevertheless, both fields reveal mutual interest for quite some time. The present work demonstrates that not only a tangential interaction, but a wide mutual polymer-like reptation might be beneficial for both fields. The present set of works already demonstrates that sub-fields of fluid mechanics, such as multi-phase flows, gas dynamics, and rheology, fluid mechanical topics, such as drops and vortices, and tools, such as de Laval nozzle, are not alien at all to forensic science subjects and could be beneficial for them. In its turn, forensic science can enrich fluid mechanics by such subjects as blood pattern analysis, blood and brain spatter analysis, prediction of the blood spatter origin, and delineation of a staged suicide (a homicide) from a real one.

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confidence: 99%

Applications of fluid dynamics and mechanics of continua in forensics

Yarin

2023

Physics of Fluids

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Flow control and imbibition dynamics studies in paper membranes using inert additives

Das,

Gupta

2024

Chemical Engineering Science

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Penetrating gunshots to the head after close-range shooting: Dynamics of waves and the effect of brain tissue rheology

Kosmerl,

Yarin

2023

Physics of Fluids

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Formation of the brain tissue backspatter after penetrating gunshots to the head is preceded and driven by formation and evolution of the bullet channel, which is filling with air and/or muzzle gases or issuing them with tissue fragments or without them. This process is explored here in a model situation in the framework of the dynamics of waves in brain tissue affected by its realistic rheological behavior, fragmentation, and gas dynamics in the evolving bullet channel. As a rheological model of the brain tissue, a new strain-energy function W, introduced in the accompanying work, is employed, which expresses the strain energy as a rational function of the principal invariants of the Cauchy tensor C. This strain-energy function W generates a hyperelastic constitutive equation, which resembles the behavior of brain tissues, i.e., reveals a much stronger resistance to compression than to stretching and strongly nonlinear response in simple shear. This new rheological model belongs to the class of hyperelastic models used for description of hydrogels. The equations of motion supplemented by this rheological model reveal the dynamics of the compression and rarefaction waves propagating through the brain tissue following the formation of the bullet channel. These waves are reflected from the skull and the bullet channel. In parallel, gas dynamics of air and/or muzzle gases flowing into or issued outward of the bullet channel, and stretching-driven fragmentation of the brain tissue are evolving in concert with the wave dynamics in the brain tissue. This allows for prediction of backspatter of the brain tissue resulting from a short-range shooting.

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Rheology of brain tissue and hydrogels: A novel hyperelastic and viscoelastic model for forensic applications

Cited by 5 publications

References 35 publications

Applications of fluid dynamics and mechanics of continua in forensics

Applications of fluid dynamics and mechanics of continua in forensics

Flow control and imbibition dynamics studies in paper membranes using inert additives

Penetrating gunshots to the head after close-range shooting: Dynamics of waves and the effect of brain tissue rheology

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