Vascular pericytes and smooth muscle cells surround many blood vessels of the body. Their primary roles include vessel stabilization and regulation of the blood flow. The high degree of... Show moreVascular pericytes and smooth muscle cells surround many blood vessels of the body. Their primary roles include vessel stabilization and regulation of the blood flow. The high degree of heterogeneity among these cells is dictated by (1) differences in their developmental origin and (2) their location in the vascular bed. Phenotype switching contributes to this heterogeneity especially following in vitro culture. In the absence of distinguishing molecular markers, functional assays that capture their heterogeneity in vitro are needed. Spatiotemporal changes in intracellular Ca2+ levels and contraction in response to vasoconstrictors reflect the differences between vascular pericyte and smooth muscle cell. In order to capture this heterogeneity in vitro, large ensembles of cells need to be analyzed. Here we developed an automated image processing method to measure intracellular Ca2+ and contraction in large cell groups which in combination with a computational approach for integrative analysis allowed vascular pericytes and smooth muscle cells to be distinguished without knowledge of their anatomical origin. (C) 2019 The Authors. Published by Elsevier Inc. Show less
The presence of calcium deposits in the vessel wall is indicative of advanced atherosclerosis, and the extent of coronary calcification has been found to add prognostic significance to conventional... Show moreThe presence of calcium deposits in the vessel wall is indicative of advanced atherosclerosis, and the extent of coronary calcification has been found to add prognostic significance to conventional risk factors of coronary artery disease. However, the mechanisms underlying vascular calcification are still obscure. The major objective of the work described in the first part of this thesis was to elucidate the mechanisms involved in atherosclerotic calcification. To study the process of VSMC calcification we developed and characterized an in vitro model of neonatal rat VSMC calcification. To investigate whether pharmacotherapy may affect vascular calcifications, we have studied the effect of a calcium antagonist (amlodipine) and a statin (atorvastatin) and their combination on this process. Inflammation is an important mechanism in the atherosclerotic process, and prospective and cross-sectional clinical and epidemiological studies have shown that CRP is consistently associated with CVD. The causality of CRP in atherosclerosis is discussed. To enable the study of the effect of CRP on atherosclerosis development in vivo, ApoE*3-Leiden/hCRP transgenic mice were generated and studied. The effects of a calcium antagonist (amlodipine), administered either alone or in combination with a statin (atorvastatin), on early atherosclerosis development in ApoE*3-Leiden/hCRP was investigated. Show less