Abstract
Cardiovascular disease is cited as the underlying cause of death in one out of every three deaths within the United States; this burden on the health care system percolates down to affect patients on an individual level. In part, the problem arises from the low regenerative capacity of cardiovascular system cells, for example, cardiac myocytes, and from oxidative stressors to the human body.Endothelial progenitor cells (EPCs) are a type of stem cell, and various clinical conditions including hypertension and renal failure underlie their dysfunction. EPCs are classified as either early or late outgrowth endothelial progenitor cells depending on the time they appear in circulation and at the site of injury after an inciting event. Their function is paracrine through the release of cytokines, growth factors and chemokines such as interleukin-6 and vascular endothelial growth factor, and they are involved in transdifferentiation into vascular smooth muscle cells and potentially cardiac myocytes. They are beneficial to the modification of cardiovascular cell apoptosis, fibrosis, and contractility. In times of stress, the normal function of endothelial progenitor cells is altered; this creates a maladaptive cycle where stress and failed coping mechanisms enhance each other toward the culmination of cardiovascular disease.The development of the cardiovascular system follows gastrulation in the embryonic period, and the cells that form the system are derived from the mesoderm; being mesoderm, the vascular cells exhibit heterogeneity in their origin and function. The need to understand the molecular and cellular regulatory pathways during development can amalgamate efforts of endothelial cell and cardiovascular system pathophysiology for the advancement of patient cardiovascular reserve and function.
Highlights
The development of the vascular system is an early process during embryo- and organogenesis; the heart is the first organ that becomes functional in the human embryo
Marked remodeling of the cardiovascular system (CVS) occurs as the embryo develops through the stages of organogenesis and vasculogenesis; the blood vessels branch, degenerate, and canalize among other remodeling processes that underlie angiogenesis
This review revealed that levels of high-density lipoproteins (HDL) above normal do not further reduce the risk of coronary heart disease
Summary
The development of the vascular system is an early process during embryo- and organogenesis; the heart is the first organ that becomes functional in the human embryo. Development of the heart begins in the cardiac bulge of the embryo; this along with the vascular system develop from the mesoderm during the gastrulation stage of embryogenesis. Vasculogenesis, the development of the vascular system within the mesoderm, progresses through the formation of vascular islands that enlarge and coalesce to form the vascular system and hematopoietic cell. Marked remodeling of the cardiovascular system (CVS) occurs as the embryo develops through the stages of organogenesis and vasculogenesis; the blood vessels branch, degenerate, and canalize among other remodeling processes that underlie angiogenesis. The development of the cardiovascular system is both intraembryonic and extra-embryonic (yolk sac and placenta) with development starting primarily in the yolk sac followed by migration of hematopoietic cells to the liver and ending up in the bone marrow
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