For more than , the replacement of diseased natural heart valves with prosthetic devices has dramatically extended the quality and length of the lives of millions of patients worldwide. However, bioprosthetic heart valves (BHV) continue to fail due to structural failure resulting from poor tissue durability and faulty design. Clearly, an in-depth understanding of the biomechanical behavior of BHV at both the tissue and functional prosthesis levels is essential to improving BHV design and to reduce rates of failure. In this study, we simulated quasi-static BHV leaflet deformation under 40, 80, and quasi-static transvalvular pressures. A Fung-elastic material model was used that incorporated material parameters and axes derived from actual leaflet biaxial tests and measured leaflet collagen fiber structure. Rigorous experimental validation of predicted leaflet strain field was used to validate the model results. An overall maximum discrepancy of 2.36% strain between the finite element (FE) results and experiment measurements was obtained, indicating good agreement between computed and measured major principal strains. Parametric studies utilizing the material parameter set from one leaflet for all three leaflets resulted in substantial variations in leaflet stress and strain distributions. This result suggests that utilization of actual leaflet material properties is essential for accurate BHV FE simulations. The present study also underscores the need for rigorous experimentation and accurate constitutive models in simulating BHV function and design.
Skip Nav Destination
e-mail: msacks@pitt.edu
Article navigation
November 2005
Technical Papers
Simulated Bioprosthetic Heart Valve Deformation under Quasi-Static Loading
Wei Sun,
Wei Sun
Engineered Tissue Mechanics Laboratory, Department of Bioengineering,
University of Pittsburgh
, Pittsburgh, PA 15219
Search for other works by this author on:
Ajay Abad,
Ajay Abad
Engineered Tissue Mechanics Laboratory, Department of Bioengineering,
University of Pittsburgh
, Pittsburgh, PA 15219
Search for other works by this author on:
Michael S. Sacks
Michael S. Sacks
Engineered Tissue Mechanics Laboratory, Department of Bioengineering,
e-mail: msacks@pitt.edu
University of Pittsburgh
, Pittsburgh, PA 15219
Search for other works by this author on:
Wei Sun
Engineered Tissue Mechanics Laboratory, Department of Bioengineering,
University of Pittsburgh
, Pittsburgh, PA 15219
Ajay Abad
Engineered Tissue Mechanics Laboratory, Department of Bioengineering,
University of Pittsburgh
, Pittsburgh, PA 15219
Michael S. Sacks
Engineered Tissue Mechanics Laboratory, Department of Bioengineering,
University of Pittsburgh
, Pittsburgh, PA 15219e-mail: msacks@pitt.edu
J Biomech Eng. Nov 2005, 127(6): 905-914 (10 pages)
Published Online: July 14, 2005
Article history
Received:
May 5, 2005
Revised:
July 14, 2005
Citation
Sun, W., Abad, A., and Sacks, M. S. (July 14, 2005). "Simulated Bioprosthetic Heart Valve Deformation under Quasi-Static Loading." ASME. J Biomech Eng. November 2005; 127(6): 905–914. https://doi.org/10.1115/1.2049337
Download citation file:
Get Email Alerts
Simulating the Growth of TATA-Box Binding Protein-Associated Factor 15 Inclusions in Neuron Soma
J Biomech Eng (December 2024)
Evaluation of an Inverse Method for Quantifying Spatially Variable Mechanics
J Biomech Eng (December 2024)
Effect of Structure and Wearing Modes on the Protective Performance of Industrial Safety Helmet
J Biomech Eng (December 2024)
Sex-Based Differences and Asymmetry in Hip Kinematics During Unilateral Extension From Deep Hip Flexion
J Biomech Eng (December 2024)
Related Articles
Dynamic Simulation Pericardial Bioprosthetic Heart Valve Function
J Biomech Eng (October,2006)
The Structure and Mechanical Properties of the Mitral Valve Leaflet-Strut Chordae Transition Zone
J Biomech Eng (April,2004)
Simulation of Physiological Loading in Total Hip Replacements
J Biomech Eng (August,2006)
A Theoretical Framework to Analyze Bend Testing of Soft Tissue
J Biomech Eng (February,2007)
Related Proceedings Papers
Related Chapters
Experimental Studies
Nanoparticles and Brain Tumor Treatment
Data Tabulations
Structural Shear Joints: Analyses, Properties and Design for Repeat Loading
Microstructure Evolution and Physics-Based Modeling
Ultrasonic Welding of Lithium-Ion Batteries