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Literature DB >> 31543547

Mechanobiological Stability of Biological Soft Tissues.

Abstract

Like all other materials, biological soft tissues are subject to general laws of physics, including those governing mechanical equilibrium and stability. In addition, however, these tissues are able to respond actively to changes in their mechanical and chemical environment. There is, therefore, a pressing need to understand such processes theoretically. In this paper, we present a new rate-based constrained mixture formulation suitable for studying mechanobiological equilibrium and stability of soft tissues exposed to transient or sustained changes in material composition or applied loading. These concepts are illustrated for canonical problems in arterial mechanics, which distinguish possible stable versus unstable mechanobiological responses. Such analyses promise to yield insight into biological processes that govern both health and disease progression.

Entities: Chemical Disease Gene Species

Keywords: adaptation; extracellular matrix; matrix turnover; mechanical homeostasis; tissue growth

Year: 2018 PMID： 31543547 PMCID： PMC6754118 DOI： 10.1016/j.jmps.2018.12.013

Source DB: PubMed Journal: J Mech Phys Solids ISSN： 0022-5096 Impact factor: 5.471

43 in total

Mechanobiological Stability of Biological Soft Tissues.

1. A model for aortic growth based on fluid shear and fiber stresses.

2. Biaxial biomechanical adaptations of mouse carotid arteries cultured at altered axial extension.

3. Complementary vasoactivity and matrix remodelling in arterial adaptations to altered flow and pressure.

4. The micromechanics of fluid-solid interactions during growth in porous soft biological tissue.

5. A theoretical model of enlarging intracranial fusiform aneurysms.

6. Nonlinear simulations of solid tumor growth using a mixture model: invasion and branching.

7. Biochemomechanics of cerebral vasospasm and its resolution: II. Constitutive relations and model simulations.

8. A mathematical model for the growth of the abdominal aortic aneurysm.

9. A growth mixture theory for cartilage with application to growth-related experiments on cartilage explants.

10. Mathematical modelling of engineered tissue growth using a multiphase porous flow mixture theory.

1. Optimization of Tissue-Engineered Vascular Graft Design Using Computational Modeling.

2. The role of topology and mechanics in uniaxially growing cell networks.

3. Constrained Mixture Models of Soft Tissue Growth and Remodeling - Twenty Years After.

4. Complementary roles of mechanotransduction and inflammation in vascular homeostasis.

5. Developmental origins of mechanical homeostasis in the aorta.

Review 6. Vascular Mechanobiology: Homeostasis, Adaptation, and Disease.

7. Numerical knockouts-In silico assessment of factors predisposing to thoracic aortic aneurysms.