Abstract
Arteries are exposed to relentless pulsatile haemodynamic loads, but via mechanical homeostasis they tend to maintain near optimal structure, properties and function over long periods in maturity in health. Numerous insults can compromise such homeostatic tendencies, however, resulting in maladaptations or disease. Chronic inflammation can be counted among the detrimental insults experienced by arteries, yet inflammation can also play important homeostatic roles. In this paper, we present a new theoretical model of complementary mechanobiological and immunobiological control of vascular geometry and composition, and thus properties and function. We motivate and illustrate the model using data for aortic remodelling in a common mouse model of induced hypertension. Predictions match the available data well, noting a need for increased data for further parameter refinement. The overall approach and conclusions are general, however, and help to unify two previously disparate literatures, thus leading to deeper insight into the separate and overlapping roles of mechanobiology and immunobiology in vascular health and disease.
Highlights
The concept of homeostasis was introduced by Walter Cannon in the 1920s, extending the notion of a stable c The Authors
Arteries are exposed to relentless pulsatile hemodynamic loads, but via mechanical homeostasis they tend to maintain near optimal structure, properties, and function over long periods in maturity in health
We recently showed that a computational model of arterial growth and remodeling (G&R) that includes mechano- and immuno-stimulated matrix turnover can capture salient biomechanical features of the time-course of maladaptive remodeling of the thoracic aorta in both C57BL/6 and Apoe-/- mice infused with angiotensin II (AngII) for a period of weeks [20,21]
Summary
The concept of homeostasis was introduced by Walter Cannon in the 1920s, extending the notion of a stable c The Authors.
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