Dynamic material characterization of the human heel pad based on in vivo experimental tests and numerical analysis

• Published in: Medical engineering & physics Vol. 38; no. 9; pp. 940 - 945
• Main Authors: Kardeh, M., Vogl, T.J., Huebner, F., Nelson, K., Stief, F., Silber, G.
• Format: Journal Article
• Language: English
• Published: England Elsevier Ltd 01.09.2016
• Subjects: Adult; Biomechanical Phenomena; Elasticity; Female; Finite Element Analysis; Heel - diagnostic imaging; Heel pad; Humans; Impact test; In vivo material parameter; Magnetic Resonance Imaging; Materials Testing - instrumentation; Materials Testing - methods; Mechanical Phenomena; Radiology; In vivo material parameter; Heel pad; Finite element analysis; Impact test
• ISSN: 1350-4533; 1873-4030
• DOI: 10.1016/j.medengphy.2016.06.003

•Dynamic material properties of the heel pad under impact conditions are established.•Impact conditions are similar to a heel strike during running.•Quasi-static and dynamic tests separate elastic from inelastic material properties. A numerical-experimental, proof-of-concept approach is described to characterize the mechanical material behavior of the human heel pad under impact conditions similar to a heel strike while running. A 3D finite-element model of the right foot of a healthy female subject was generated using magnetic resonance imaging. Based on quasi-static experimental testing of the subject's heel pad, force-displacement data was obtained. Using this experimental data as well as a numerical optimization algorithm, an inverse finite-element analysis and the 3D model, heel pad hyperelastic (long-term) material parameters were determined. Applying the same methodology, based on the dynamic experimental data from the impact test and obtained long-term parameters, linear viscoelastic parameters were established with a Prony series. Model validation was performed employing quasi-static and dynamic force-displacement data. Coefficients of determination when comparing model to experimental data during quasi-static and dynamic (initial velocity: 1480mm/s) procedure were R2 = 0.999 and R2 = 0.990, respectively. Knowledge of these heel pad material parameters enables realistic numerical analysis to evaluate internal stress and strain in the heel pad during different quasi-static or dynamic load conditions.