Patel, B.; Gizzi, A.; Hashemi, J.; Awakeem, Y.; Gregersen, H.; Kassab, G. Biomechanical Constitutive Modeling of the Gastrointestinal Tissues: A Systematic Review. Materials & Design 2022, 217, 110576, doi:10.1016/j.matdes.2022.110576.
Patel, B.; Gizzi, A.; Hashemi, J.; Awakeem, Y.; Gregersen, H.; Kassab, G. Biomechanical Constitutive Modeling of the Gastrointestinal Tissues: A Systematic Review. Materials & Design 2022, 217, 110576, doi:10.1016/j.matdes.2022.110576.
Patel, B.; Gizzi, A.; Hashemi, J.; Awakeem, Y.; Gregersen, H.; Kassab, G. Biomechanical Constitutive Modeling of the Gastrointestinal Tissues: A Systematic Review. Materials & Design 2022, 217, 110576, doi:10.1016/j.matdes.2022.110576.
Patel, B.; Gizzi, A.; Hashemi, J.; Awakeem, Y.; Gregersen, H.; Kassab, G. Biomechanical Constitutive Modeling of the Gastrointestinal Tissues: A Systematic Review. Materials & Design 2022, 217, 110576, doi:10.1016/j.matdes.2022.110576.
Abstract
The gastrointestinal (GI) tract is a continuous channel through the body that consists of the esophagus, the stomach, the small intestine, the large intestine, and the rectum. Its primary functions are to move the intake of food for digestion before storing and ultimately expulsion of feces from the rectum through the anal sphincter. The mechanical behavior of GI tissues thus plays a crucial role for GI function in health and disease. The mechanical properties are typically characterized by a constitutive biomechanical model, which is a mathematical representation of the relation between load and deformation in a tissue. Hence, validated biomechanical constitutive models are essential to characterize and simulate the mechanical behavior of the GI tract under physiological and pathological conditions. Numerous constitutive models have consequently been proposed over the past three decades, mainly inspired by work done in cardiovascular tissues. Here, a comprehensive review of these constitutive models is provided. This review is limited to studies where a model of the strain energy function is proposed to characterize the stress-strain relation of a GI tissue. Several needs are identified for more advanced modeling of GI biomechanics including: 1) Microstructural models that provide actual structure-function relations; 2) Validation of coupled electro-mechanical models accounting for active muscle contractions; 3) Human data under physiological and pathological conditions to develop and validate models. The findings from this review provide guidelines for using existing constitutive models as well as perspective and directions for future studies aimed at establishing new constitutive models for GI tissues.
Digestive tract; Colon; Biomechanics; Mechanical properties; Strain energy function; Hyperelasticity
Subject
Biology and Life Sciences, Anatomy and Physiology
Copyright:
This is an open access article distributed under the Creative Commons Attribution License which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
