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The primary purpose of the vascular system is to serve as a nonthrombogenic conduit for blood flow, which is necessary for the delivery of oxygen, nutrients, hormonal signals, and cellular components throughout the body. The cellular elements of blood vessels, (endothelial cells, smooth muscle cells, fibroblasts, and niche progenitor cells) are similar throughout the vasculature. However, structure and function varies throughout the vascular tree to allow for the dynamic regulation of blood flow, primarily regulated by changes in arteriolar resistance and venous capacitance. In addition, the vasculature regulates the cellular and molecular trafficking between the intravascular and extravascular space, as well as into and out of the vessel wall. As discussed later in this chapter, the normal adaptive responses of the endothelium and smooth muscle cells to inflammation and injury account for some of the atherosclerotic changes or vessel wall thickening after transplantation.
The organization of the cellular elements and extracellular matrix components varies dramatically throughout the vasculature, accounting for its distinctive anatomic and physiologic features at various sites. Vessels larger than capillaries possess three distinct layers or tunics, called the intima, media, and adventitia . These layers are generally thicker and better defined in arteries than in veins. In arteries, the intima is composed of a sheet of endothelial cells lining the luminal surface and a subendothelial extracellular matrix basement membrane. It is divided from the media by an internal elastic lamina. Rare inflammatory cells and smooth muscle cells may be found within the normal intima, although larger populations are seen as a reaction to injury or as a result of atherosclerotic disease. The media contains circular smooth muscle fibers embedded in a matrix of collagen, elastin, and proteoglycans and is divided from the adventitia by an external elastic lamina. Although the media is composed mostly of smooth muscle cells, there is increasing evidence that smooth muscle cell progenitors reside in niche populations within the media. Both the internal and external elastic laminae are visualized as bright white lines using B-mode ultrasonography, allowing a measurement of intima-media thickness, which can be used as a surrogate marker for atherosclerosis. The adventitia, which serves as the strength layer after endarterectomy, is composed primarily of loose connective tissue and fibroblasts. Inflammatory cells, nerve fibers, niche progenitor cells, a nutrient microcirculation (known as the vasa vasorum ), and a lymphatic network also reside within the adventitia.
The arterial tree can be divided into three separate categories: large elastic arteries, medium muscular arteries, and small arteries. The aorta and its major branches are classified as large elastic arteries, while the distributing arteries to major organs comprise the muscular arteries, and the arteries within organs comprise the small arteries. From small arteries, blood flow travels through arterioles to capillary beds, then to postcapillary venules and small veins, and blood flow then returns to the heart via larger veins. Collateral arteries are a special class of muscular arteries that traverse from one artery to another, rather than feeding into arterioles. Normally there is little flow through collateral arteries and they have low shear stress. However, when the main conduit artery is obstructed, collateral artery flow and shear stress increase substantially, as a compensatory mechanism, which after adaption eventually can restore up to one-third of the normal conduit artery blood flow ( Fig. 3.1 ).
The aortic media is composed of well-defined lamellar units; each unit consists of a concentric plate of elastin and a circumferentially oriented layer of smooth muscle cells, surrounded by a network of type III collagen fibrils embedded in a matrix of basal lamina. Finer elastin fibers compose a network between lamellae, as do bundles of interstitial type I collagen. As the aorta becomes more distant from the heart, the percentage of collagen increases and the elastin decreases, so that the thoracic aorta and its major branches have more elastin than collagen and the abdominal aorta has more collagen than elastin.
The tangential tension on an artery wall can be approximately estimated with Laplace's law (tension is proportional to the product of the radius and the pressure). Because blood pressure is similar in animals of all sizes, the average wall tangential tension per lamellar unit is remarkably constant across different species. The upper two-thirds of the thoracic aorta, which is thicker than 28 lamellar units, also contains a medial vasa vasorum. The dependence of the abdominal aortic wall on luminal nutrition, because of the lack of a medial vasa vasorum, may explain its increased propensity to aneurysm formation.
In contrast to elastic arteries, where collagen and elastin comprise approximately 60% of the dry weight of the media, muscular arteries contain proportionally more smooth muscle cells and less collagen and elastin, allowing them to alter their diameter rapidly through vasodilation or vasoconstriction. In addition, their ratio of media to lumen is higher, contributing to their function as resistive arteries ( Fig. 3.2 ). Elastin is diminished as arteries become smaller, and the internal and external elastic lamellae become discontinuous and fragmented. The smallest arteries (arterioles) consist of only an endothelium, a layer of smooth muscle cells, and a filamentous collagenous adventitia. At the capillary level, only the endothelium remains, supported by an occasional contractile connective tissue cell known as a pericyte .
The differentiation of these three types of arteries has significance because each class of vessel is subject to different pathology and diseases. Atherosclerosis affects the elastic and muscular arteries, whereas medial calcific sclerosis is limited to muscular arteries, and small arteries are subject to diffuse fibromuscular thickening and hyalinization.
Veins, as befitting their role as capacitance vessels under low-pressure conditions, are larger and thinner walled than arteries. Despite this, the vasa vasorum in veins is denser than in arteries and has increased medial wall flow, suggesting that luminal blood flow is less capable of providing nutritional support to the vein wall. Disruption of the vasa vasorum in veins, during vein graft harvest, may lead to wall damage and worse patency rates. The subendothelial layer of the intima is missing entirely in veins, and an internal elastic lamina is present only in larger veins. The medial layer contains few smooth muscle cells, collagen, and elastin. Thin bicuspid valves, consisting of two layers of endothelium sandwiched around a layer of connective tissue, support unidirectional flow to the heart. They are present in larger numbers in peripheral extremity veins and are rarely present in central veins. The contractile state of both venules and veins is largely controlled by sympathetic adrenergic activity.
Veins can be divided into three systems: deep (located below the muscular fascia, paralleling arteries and providing approximately 90% to 95% of the extremity drainage), superficial (providing the remaining 5% to 10% of drainage), and perforating (connecting the deep and superficial systems). The usual direction of flow is from the superficial to the deep system. There is substantially more variation in venous anatomy than arterial anatomy. The function of venous valves is to decrease the hydrostatic pressure from the weight of blood within each segment of the venous system when standing and to prevent retrograde flow. Entrapment of venous valves from fibrotic scarring resulting from incomplete resolution of deep venous thrombosis can cause venous obstruction, estimated to contribute to approximately 80% of chronic venous insufficiency. The other 20% results from primary valvular incompetence. Evidence suggests that the increased collagen with decreased smooth muscle and elastin found in varicose veins may occur prior to the development of incompetent valves, leading to reflux.
The basic structural components described previously combine to allow the vasculature to dynamically regulate blood flow by changing luminal area and wall thickness, both in an acute reaction (e.g., increased blood flow induced by exercise, vascular injury, temperature, and pain) and in chronic structural changes to the structural wall, induced by ongoing stimuli (hypertension, increased or decreased inflow or outflow, and pathologic inflammation). These alterations require changes within the individual cellular elements, as well as cell-cell interactions, which allow the fully formed vessel to function as an integrated organ.
Blood flow within the vasculature creates unique biomechanical forces on the vessel walls at different levels throughout the vascular tree—these biomechanical forces are pressure and shear stress. Pressure is created by the hydrostatic force of cardiac contraction, with the addition of the hydrostatic pressure created by gravity. Gravity is a compressive force that also creates wall tension. The greatest wall tension occurs in the large elastic vessels. Wall tension is distributed across all three layers of the vessel wall and determines wall thickness. Shear stress primarily affects the endothelium and is a result of drag caused by the tangential flow of viscous blood over the intimal surface. This force causes endothelial cells to align with the direction of flow. In laminar conditions, the magnitude of shear stress is directly proportional to blood flow and fluid viscosity and inversely related to the cube of the radius. Shear stress is normally maintained in mammals at a constant between 10 and 20 dynes/cm 2 at all levels of the arterial tree. Both developing and mature vessels respond to changes in hemodynamic forces by adjusting their diameters to maintain a constant level of shear stress. Acutely, this occurs by altering vasomotor tone. The reaction of arteries and arterioles to vasoactive substances is dependent on the stage in development, the species, and the particular vascular bed.
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