Vascular Extracellular Matrix and Arterial Mechanics
TLDR
By correlating vessel mechanics with physiological blood pressure across animal species and in mice with altered vessel compliance, it is shown that cardiac and vascular development are physiologically coupled, and there is evidence for a universal elastic modulus that controls the parameters of ECM deposition in vessel wall development.Abstract:
An important factor in the transition from an open to a closed circulatory system was a change in vessel wall structure and composition that enabled the large arteries to store and release energy during the cardiac cycle. The component of the arterial wall in vertebrates that accounts for these properties is the elastic fiber network organized by medial smooth muscle. Beginning with the onset of pulsatile blood flow in the developing aorta, smooth muscle cells in the vessel wall produce a complex extracellular matrix (ECM) that will ultimately define the mechanical properties that are critical for proper function of the adult vascular system. This review discusses the structural ECM proteins in the vertebrate aortic wall and will explore how the choice of ECM components has changed through evolution as the cardiovascular system became more advanced and pulse pressure increased. By correlating vessel mechanics with physiological blood pressure across animal species and in mice with altered vessel compliance, we show that cardiac and vascular development are physiologically coupled, and we provide evidence for a universal elastic modulus that controls the parameters of ECM deposition in vessel wall development. We also discuss mechanical models that can be used to design better tissue-engineered vessels and to test the efficacy of clinical treatments.read more
Citations
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References
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Molecular Regulation of Vascular Smooth Muscle Cell Differentiation in Development and Disease
TL;DR: The focus of this review is to provide an overview of the current state of knowledge of molecular mechanisms/processes that control differentiation of vascular smooth muscle cells (SMC) during normal development and maturation of the vasculature, as well as how these mechanisms/ processeses are altered in vascular injury or disease.
Journal ArticleDOI
Requisite Role of Angiopoietin-1, a Ligand for the TIE2 Receptor, during Embryonic Angiogenesis
Chitra Suri,Pamela F. Jones,Sybill Patan,Sona Bartunkova,Maisonpierre Peter C,Samuel Davis,Thomas N. Sato,George D. Yancopoulos +7 more
TL;DR: It is shown that mice engineered to lack Angiopoietin-1 display angiogenic deficits reminiscent of those previously seen in mice lacking TIE2, demonstrating that AngiopOietIn-1 is a primary physiologic ligand for TIE1 and that it has critical in vivo angiogenesis actions that are distinct from VEGF and that are not reflected in the classic in vitro assays used to characterize VEGf.
Journal ArticleDOI
Functional arteries grown in vitro.
Laura E. Niklason,Jinming Gao,William M. Abbott,Karen K. Hirschi,S. Houser,Robert P. Marini,Robert Langer +6 more
TL;DR: A tissue engineering approach was developed to produce arbitrary lengths of vascular graft material from smooth muscle and endothelial cells that were derived from a biopsy of vascular tissue, with patency documented up to 24 days by digital angiography.
Journal ArticleDOI
Regulation of differentiation of vascular smooth muscle cells
TL;DR: Current knowledge of the regulation of SMC differentiation is summarized, with a particular emphasis on consideration of how this process is controlled during normal vascular development and how these control processes might be altered in vascular diseases such as atherosclerosis, which are characterized by marked alterations in the differentiated state of the SMC.