Differential effects of reduced cyclic stretch and perturbed shear stress within the arterial wall

Due to the pulsatile nature of blood flow, arteries are constantly exposed to dynamic mechanical forces; the pulsatility continuously stretches the vessel wall and the flow creates a frictional force on the interior surface. These stresses, referred to as cyclic circumferential stretch and shear stress, are known to determine arterial structure and morphology; modulation of which leads to the progression of vascular diseases such as hypertension and atherosclerosis. Yet the individual contributions of cyclic stretch and shear stress, with regards to vascular disease, have yet to be revealed. In this thesis I wish to identify the role of reduced cyclic stretch in the development of endothelial dysfunction and vascular remodeling, develop an experimental model for studying the autonomous effects of shear stress and cyclic stretch and how these two stimuli individually modulate markers of vascular disease in different regions of the vascular wall. I will begin by introducing the different structural and cellular components of the vascular wall and their individual functions. From here I will introduce how hemodynamic forces transmitted to the vascular wall due to the pulsatile nature of blood flow play an essential role maintaining arterial health and function. And as such, how deviations from a physiologic hemodynamic range can have catastrophic implications for the vasculature. Next I will introduce how certain hemodynamic conditions can stimulate cellular dysfunction and how this relates to initiation and progression of vascular disease. In the first paper, we set out to determine if reduction of cyclic stretch could be a factor which induces remodeling of the arterial wall. We found that reducing compliance caused a decrease in vascular smooth muscle function, as well as inducing switch in smooth muscle cell phenotype. Arteries exposed to a reduced cyclic stretch also exhibited increased matrix degradation and cellular proliferation than those allowed to stretch physiologically. These findings accent the importance of cyclic stretch in the maintenance of a differentiated and fully functional phenotype of vascular smooth muscle cells, as well as in the regulation of migratory properties, proliferation and matrix turnover in the vascular wall. In the second paper we investigated how reduction of cyclic stretch influences endothelial dysfunction and modulation of nitric oxide bioavailability. We observed that reduced compliance significantly decreases the activity of the enzyme responsible for producing nitric oxide (eNOS). Overall production of reactive oxygen species were also increased by reducing compliance, which we were able to attribute to stimulation of the superoxide generating NAD(P)H oxidase. We found that experimentally reduced compliance also caused a significant decrease in endothelial function, as assessed with bradykinin dependent vascular relaxation. The results from this study point out how reduced arterial compliance interrupts t