Title :
Evaluation of material model parameters of vaginal tissue with different fiber orientation
Author :
Martins, Rita ; Martins, Pedro ; Mascarenhas, Teresa ; Jorge, Renato Natal
Author_Institution :
INEGI (Inst. de Cienc. e Inovacao em Eng. Mec. e Eng. Ind.), Porto, Portugal
Abstract :
Vaginal tissue is known to be stiffer when load is applied in the longitudinal direction of its fibers rather than the transverse direction. However, little attention has been paid to the differences in the material parameters that characterize these tissues´ behavior. The goal of this study was to evaluate the differences of vaginal tissue´s material parameters for constitutive modeling. For this purpose, experimental data from previous uniaxial tensile tests, in the longitudinal and transverse directions, of anterior and posterior vaginal wall samples were used. The material parameters were determined for Weiss modified and Mooney-Rivlin material models using an analytical method. As expected, different mechanical properties reflected different material parameters. Weiss modified material model confirmed to be suitable for modeling the longitudinal direction but inaccurate in the transverse direction, whereas Mooney-Rivlin´s revealed to be more adequate on modeling the transverse direction.
Keywords :
bending strength; biological tissues; biomechanics; elasticity; obstetrics; physiological models; tensile testing; Mooney-Rivlin material model; Weiss modified material model; analytical method-based material model; anterior vaginal wall longitudinal direction; anterior vaginal wall samples; anterior vaginal wall transverse direction; longitudinal direction modeling; longitudinal fiber direction; material model parameters; material parameter determination; model parameter evaluation; parameter-characterized tissue behavior; posterior vaginal wall longitudinal direction; posterior vaginal wall samples; posterior vaginal wall transverse direction; stiff vaginal tissue; tensile test-derived experimental data; tissue behavior characterization; transverse direction modeling; uniaxial tensile test; vaginal tissue behavior; vaginal tissue fiber direction; vaginal tissue fiber orientation; vaginal tissue load application; vaginal tissue material model; vaginal tissue material parameters; vaginal tissue mechanical properties; vaginal tissue transverse direction; vaginal tissue-applied load; vaginal tissue-based constitutive modeling; Adaptation models; Analytical models; Biological tissues; Biomechanics; Load modeling; Mathematical model; Strain; constitutive modeling; transverse isotropy; vaginal tissue parameters;
Conference_Titel :
Bioengineering (ENBENG), 2015 IEEE 4th Portuguese Meeting on
Conference_Location :
Porto
DOI :
10.1109/ENBENG.2015.7088847
