A Method for Planar Biaxial Mechanical Testing That Includes In-plane Shear

Overview

Journal J Biomech Eng

Publisher American Society of Mechanical Engineers

Date 1999 Oct 26

PMID 10529924

Citations 35

Authors

M S Sacks

Affiliations

Soon will be listed here.

Abstract

A limitation in virtually all planar biaxial studies of soft tissues has been the inability to include the effects of in-plane shear. This is due to the inability of current mechanical testing devices to induce a state of in-plane shear, due to the added cost and complexity. In the current study, a straightforward method is presented for planar biaxial testing that induces a combined state of in-plane shear and normal strains. The method relies on rotation of the test specimen's material axes with respect to the device axes and on rotating carriages to allow the specimen to undergo in-plane shear freely. To demonstrate the method, five glutaraldehyde treated bovine pericardium specimens were prepared with their preferred fiber directions (defining the material axes) oriented at 45 deg to the device axes to induce a maximum shear state. The test protocol included a wide range of biaxial strain states, and the resulting biaxial data re-expressed in material axes coordinate system. The resulting biaxial data was then fit to the following strain energy function W: [equation: see text] where E'ij is the Green's strain tensor in the material axes coordinate system and c and Ai are constants. While W was able to fit the data very well, the constants A5 and A6 were found not to contribute significantly to the fit and were considered unnecessary to model the shear strain response. In conclusion, while not able to control the amount of shear strain independently or induce a state of pure shear, the method presented readily produces a state of simultaneous in-plane shear and normal strains. Further, the method is very general and can be applied to any anisotropic planar tissue that has identifiable material axes.

Citing Articles

Backscatter tensor imaging and 3D speckle tracking for simultaneous ex vivo structure and deformation measurement of myocardium.

Cormack J, Simon M, Kim K Ultrasound Med Biol. 2023; 49(5):1238-1247.

PMID: 36858914 PMC: 10050135. DOI: 10.1016/j.ultrasmedbio.2023.01.009.

A Bayesian constitutive model selection framework for biaxial mechanical testing of planar soft tissues: Application to porcine aortic valves.

Aggarwal A, Hudson L, Laurence D, Lee C, Pant S J Mech Behav Biomed Mater. 2023; 138:105657.

PMID: 36634438 PMC: 10226148. DOI: 10.1016/j.jmbbm.2023.105657.

The Effects of Healthy Aging on Right Ventricular Structure and Biomechanical Properties: A Pilot Study.

Kia D, Shen Y, Bachman T, Goncharova E, Kim K, Simon M Front Med (Lausanne). 2022; 8:751338.

PMID: 35083230 PMC: 8784691. DOI: 10.3389/fmed.2021.751338.

A generic physics-informed neural network-based constitutive model for soft biological tissues.

Liu M, Liang L, Sun W Comput Methods Appl Mech Eng. 2021; 372.

PMID: 34012180 PMC: 8130895. DOI: 10.1016/j.cma.2020.113402.

Paired Pressure-Volume Loop Analysis and Biaxial Mechanical Testing Characterize Differences in Left Ventricular Tissue Stiffness of Volume Overload and Angiotensin-Induced Pressure Overload Hearts.

Childers R, Trask A, Liu J, Lucchesi P, Gooch K J Biomech Eng. 2021; 143(8).

PMID: 33729495 PMC: 10782875. DOI: 10.1115/1.4050541.