PEER-REVIEWED PUBLICATION

2023

The Impact of Thickness Heterogeneity on Soft Tissue Biomechanics: A Novel Measurement Technique and a Demonstration on Heart Valve Tissue

Lin C, Mathur M, et al.

Biomechanics and Modeling in Mechanobiology

University of Texas at Austin, Spectrum Health, Medical University of Silesia

RESEARCH SUMMARY

This study developed a rapid, non-destructive optical profilometry technique to map soft tissue thickness heterogeneity and demonstrated its biomechanical significance using ovine mitral valve leaflets. The authors compared tissue mechanics under biaxial tension, bending, and buckling, both with and without accounting for spatial thickness variation. Using computational modeling validated by mechanical testing, they showed that assuming uniform thickness can introduce errors up to 60% in stress and deformation predictions. The method revealed that native valve leaflets exhibit thinner regions at sites of folding, demonstrating that local thickness heterogeneity directly influences mechanical behavior, anisotropy, and buckling patterns. This framework highlights the need to incorporate true thickness maps into soft tissue models for accurate biomechanical interpretation.

Biaxial tensile tests were performed on ovine anterior mitral valve leaflets using a CellScale BioTester under equibiaxial loading (500 mN) in 37 °C PBS. Six samples were tested before and after application of a talc-based optical contrast protocol to confirm that profilometry imaging did not affect mechanical response. The BioTester recorded radial and circumferential forces with 1.5 N load cells (±1.5 mN precision) at 5 Hz sampling, while fiduciary markers tracked deformation fields. Force and displacement data were used to compute stretch ratios and stress–strain curves, quantifying toe stiffness, calf stiffness, transition stretch, and anisotropy. The BioTester data confirmed consistent J-shaped tension–stretch behavior before and after imaging, validating the non-destructive measurement protocol.

AUTHORS

Chien-Yu Lin, Mrudang Mathur, Marcin Malinowski, Tomasz A. Timek, Manuel K. Rausch.

PUBLICATION DETAILS

JOURNAL

Biomechanics and Modeling in Mechanobiology

YEAR

2023

INSTITUTIONS

University of Texas at Austin, Spectrum Health, Medical University of Silesia

COUNTRIES

Poland, United States

INSTRUMENT USED

BioTester

TESTING METHODS

Biaxial TestingHydrated and Temperature Controlled TestingTensile Testing

RESEARCH APPLICATIONS

Cardiac Tissue Engineering & MechanicsECM & Decellularized Matrix MechanicsFibrosis & Tissue RemodelingHeart Valve Tissue Engineering & MechanicsMechanotransductionVascular Tissue Engineering & Mechanics

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