PEER-REVIEWED PUBLICATION

2020

Mechanics of Porcine Heart Valves’ Strut Chordae Tendineae Investigated as a Leaflet–Chordae–Papillary Muscle Entity

Ross CJ, Laurence DW, et al.

Annals of Biomedical Engineering

University of Oklahoma, Iowa State University, Oklahoma State University, Graz University of Technology, Norwegian University of Science and Technology

Austria, Norway, United States

RESEARCH SUMMARY

Porcine atrioventricular valve strut chordae tendineae were tested using a configuration that retained leaflet, chordae, and papillary muscle attachments during loading. This setup was used to preserve native anatomical interactions during mechanical loading and to better reflect cardiovascular tissue biomechanics. Mechanical testing was performed primarily under uniaxial loading, with results considered in the context of heart valve biaxial testing approaches used for soft cardiac tissues. Nonlinear and direction-dependent stress–stretch responses were observed, along with regional differences between mitral and tricuspid valves. Mitral strut chordae showed greater thickness and extensibility than tricuspid samples. Experimental data were fit using an Ogden hyperelastic model to obtain constitutive parameters for computational modeling. Comparisons indicated that retaining leaflet and papillary muscle attachments influenced measured chordal mechanics and altered the resulting material properties used in heart valve simulations.

A CellScale BioTester mechanical testing system was used to perform force-controlled uniaxial tensile testing on porcine strut chordae tendineae while preserving their attachments to valve leaflets and papillary muscles. The system enabled precise low-force loading under hydrated conditions and supported integration with Digital Image Correlation to quantify local tissue stretch along the chordae. These CellScale measurements were essential for capturing physiologically relevant stress–stretch behavior, identifying regional mechanical differences between mitral and tricuspid valves, and deriving constitutive model parameters for heart valve biomechanics and surgical repair modeling.

AUTHORS

Colton J. Ross, Devin W. Laurence, Ming-Chen Hsu, Ryan Baumwart, Yan D. Zhao, Arshid Mir, Harold M. Burkhart, Gerhard A. Holzapfel, Yi Wu, Chung-Hao Lee.

PUBLICATION DETAILS

JOURNAL

Annals of Biomedical Engineering

YEAR

2020

INSTITUTIONS

University of Oklahoma, Iowa State University, Oklahoma State University, Graz University of Technology, Norwegian University of Science and Technology

COUNTRIES

Austria, Norway, United States

INSTRUMENT USED

BioTester

TESTING METHODS

Digital Image Correlation (DIC)Hydrated and Temperature Controlled TestingMicro-Mechanical TestingTensile Testing

RESEARCH APPLICATIONS

Heart Valve Tissue Engineering & Mechanics

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