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Cardiovascular System

Cardiovascular System. Dr. Sufia Husain. Ischemic Heart Disease (Coronary Heart Disease). A group of closely related syndromes caused by an imbalance between the myocardial oxygen demand and blood supply. Angina pectoris (chest pain). Acute myocardial infarction. Sudden cardiac death.

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Cardiovascular System

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  1. Cardiovascular System Dr. Sufia Husain

  2. Ischemic Heart Disease(Coronary Heart Disease) • A group of closely related syndromes caused by an imbalance between the myocardial oxygen demand and blood supply. • Angina pectoris (chest pain). • Acute myocardial infarction. • Sudden cardiac death. • Chronic ischemic heart disease with congestive heart failure.

  3. Ischemic Heart Disease: Epidemiology-(coronary atherosclerosis) • Peak incidence: 60y for males and 70y for females. • Men are more affected than women until the ninth decade. • Contributing factors: • Hypertension. • Diabetes mellitus. • Smoking. • High levels of LDL. • Genetic factors (direct or indirect). • Lack of exercise.

  4. Pathogenesis of Ischemic Heart Disease • 1) Role of Critical stenosis or obstruction: (>=75% of the lumen of one or more coronary arteries by atherosclerotic plaque).

  5. Pathogenesis of Ischemic Heart Disease 2) Role of Acute Plaque Change: • In most patients the myocardial ischemia underlying unstable angina, acute MI, and (in many cases) sudden cardiac death is precipitated by abrupt plaque change followed by thrombosis .

  6. Pathogenesis of Ischemic Heart Disease • Most often, the initiating event is disruption of previously only partially stenosing plaques with any of the following: • Rupture/fissuring, exposing the highly thrombogenic plaque constituents • Erosion/ulceration, exposing the thrombogenic subendothelial basement membrane to blood • Hemorrhage into the atheroma, expanding its volume.

  7. Pathogenesis of Ischemic Heart Disease 3) Role of Coronary Thrombus: • In acute transmural MI thrombus superimposed on a disrupted but previously only partially stenotic plaque converts it to a total occlusion. In unstable angina, acute subendocardial infarction, or sudden cardiac death, the extent of luminal obstruction by thrombosis is usually incomplete . • Thrombus in coronary artery can also embolize.

  8. Pathogenesis of Ischemic Heart Disease 4) Role of Vasoconstriction: • Vasoconstriction compromises lumen size, and, by increasing the local mechanical forces, can potentiate plaque disruption.

  9. Pathogenesis of Ischemic Heart Disease 5) Role of Inflammation: • Inflammatory processes play important roles at all stages of atherosclerosis. Entry of leukocytes into the wall is a consequence of the release of chemokines by endothelial cells, and the increased expression of adhesion proteins in these cells. At later stages of atherosclerosis, destabilization and rupture of the plaque may involve the secretion of metalloproteinases by macrophages. These enzymes weaken the plaque by digesting collagen at the fibrous cap.

  10. A. Plaque rupture without superimposed thrombus in a patient who died suddenly. B. Acute coronary thrombosis superimposed on an atherosclerotic plaque with focal disruption of the fibrous cap, triggering fatal myocardial infarction. C. Massive plaque rupture with superimposed thrombus, also triggering a fatal myocardial infarction (special stain highlighting fibrin in red). In both

  11. Ischemic Heart Disease: Pathogenesis

  12. Vascular Diseases

  13. Slide 12.1

  14. ENDOTHELIAL CELLS • ECs comprise the single cell-thick, continuous lining of the entire cardiovascular system, collectively called the endothelium. Endothelial structural and functional integrity is fundamental to the maintenance of vessel wall homeostasis and normal circulatory function.

  15. Slide 12.3

  16. Smooth muscle cells • SMCs are predominant cellular element of the vascular media • SMCs are responsible for vasoconstriction and dilation in response to normal or pharmacologic stimuli. • They also synthesize collagen, elastin, and proteoglycans; and elaborate growth factors and cytokines. They migrate to the intima and proliferate following vascular injury. • Thus, SMCs are important elements of both normal vascular repair and pathologic processes such as atherosclerosis.

  17. Smooth muscle cells • Vascular injury ( endothelial injury/dysfunction) stimulates SMC growth. Reconstitution of the damaged vascular wall is a physiologic healing response that includes the formation of a neointima, in which SMCs (1) migrate from the media to the intima, (2) multiply as intimal SMCs, and (3) synthesize and deposit ECM

  18. Smooth muscle cells • During the healing response, SMCs undergo changes that resemble dedifferentiation. In the intima they lose the capacity to contract and gain the capacity to divide. • Intimal SMCs may return to a nonproliferative state when either the overlying endothelial layer is re-established following acute injury or the chronic stimulation ceases.

  19. Arteriosclerosis Arteriosclerosis (literally, "hardening of the arteries") is a generic term for thickening and loss of elasticity of arterial walls. Three patterns of arteriosclerosis are recognized; they vary in pathophysiology and clinical and pathological consequences. 1)Atherosclerosis, the most frequent and important pattern

  20. Arteriosclerosis 2)Mönckeberg medial calcific sclerosis is characterized by calcific deposits in muscular arteries in persons older than age 50. They do not encroach on the vessel lumen. 3)Arteriolosclerosis affects small arteries and arterioles. There are two anatomic variants, hyaline and hyperplastic, both associated with thickening of vessel walls with luminal narrowing that may cause ischemic injury. Most often associated with hypertension and diabetes mellitus.

  21. Atherosclerosis • Atherosclerosis is characterized by intimal lesions called atheromas, or atheromatous or fibrofatty plaques, which protrude into and obstruct vascular lumens and weaken the underlying media. They may lead to serious complications

  22. Atherosclerosis: Morphology • Fatty streaks are the earliest lesion of atherosclerosis. They are composed of lipid-filled foam cells. They are not significantly raised and thus do not cause any disturbance in blood flow. Fatty streaks begin as multiple yellow, flat spots less than 1 mm in diameter that coalesce into elongated streaks, 1 cm long or longer. They contain T lymphocytes and extracellular lipid in smaller amounts than in plaques.

  23. Fatty streak—a collection of foam cells in the intima. A. Aorta with fatty streaks ( arrows), associated largely with the ostia of branch vessels. B. Close-up photograph of fatty streaks from the aorta of an experimental hypercholesterolemic rabbit shown after staining with Sudan red, a lipid-soluble dye, again illustrating the relationship of the lesions to the two-branch vessel ostia. C. Photomicrograph of fatty streak in an experimental hypercholesterolemic rabbit, demonstrating intimal macrophage-derived foam cells ( arrow). Slide 12.9

  24. Morphology • The key processes in atherosclerosis are intimal thickening and lipid accumulation. An atheroma or atheromatous plaque consists of a raised focal lesion initiating within the intima, having a soft, yellow, grumous core of lipid (mainly cholesterol and cholesterol esters), covered by a firm, white fibrous cap.

  25. Morphology • The atheromatous plaques appear white to whitish yellow and impinge on the lumen of the artery. They vary in size from approximately 0.3 to 1.5 cm in diameter but sometimes coalesce to form larger masses. Atherosclerotic lesions usually involve only a partial circumference of the arterial wall ("eccentric" lesions) and are patchy and variable along the vessel length.

  26. Atherosclerosis: Morphology • The most heavily involved vessels are the abdominal aorta then coronary arteries, the popliteal arteries, the internal carotid arteries, and the vessels of the circle of Willis.

  27. Atherosclerosis: Morphology Atherosclerotic plaques have three principal components: • (1) cells, including SMCs, macrophages, and other leukocytes • (2) ECM, including collagen, elastic fibers, and proteoglycans • (3) intracellular and extracellular lipid . These components occur in varying proportions.

  28. Atherosclerosis: Morphology • Typically, the superficial fibrous cap is composed of SMCs and relatively dense ECM. Beneath and to the side of the cap (the "shoulder") is a cellular area consisting of macrophages, SMCs, and T lymphocytes. • Deep to the fibrous cap is a necrotic core, containing a disorganized mass of lipid (primarily cholesterol and cholesterol esters), cholesterol clefts, debris from dead cells, foam cells, fibrin, variably organized thrombus, and other plasma proteins.

  29. Atherosclerosis: Morphology • Foam cells are large, lipid-laden cells that derive predominantly from blood monocytes (tissue macrophages), but SMCs can also imbibe lipid to become foam cells. • Around the periphery of the lesions, there is usually evidence of neovascularization (proliferating small blood vessels). Typical atheromas contain relatively abundant lipid. • Atheromas often undergo calcification.

  30. Major components of well-developed atheromatous plaque: fibrous cap composed of proliferating smooth muscle cells, macrophages, lymphocytes, foam cells, and extracellular matrix. The necrotic core consists of cellular debris, extracellular lipid with cholesterol crystals, and foamy macrophages. Slide 12.6

  31. Gross views of atherosclerosis in the aorta. A. Mild atherosclerosis composed of fibrous plaques, one of which is denoted by the arrow. B. Severe disease with diffuse and complicated lesions. Slide 12.7

  32. Histologic features of atheromatous plaque in the coronary artery. A. Overall architecture demonstrating a fibrous cap (F) and a central lipid core (C) with typical cholesterol clefts. The lumen (L) has been moderately narrowed. Note the plaque-free segment of the wall ( arrow). In this section, collagen has been stained blue (Masson trichrome stain). B. Higher-power photograph of a section of the plaque shown in A, stained for elastin ( black) demonstrating that the internal and external elastic membranes are destroyed and the media of the artery is thinned under the most advanced plaque ( arrow). C. Higher-magnification photomicrograph at the junction of the fibrous cap and core showing scattered inflammatory cells, calcification ( broad arrow), and neovascularization ( small arrows). Slide 12.8

  33. American Heart Association classification of human atherosclerotic lesions from the fatty dot (type I) to the complicated type VI lesion. The diagram also includes growth mechanisms and clinical correlations. Slide 12.11

  34. COMPLICATIONS The advanced lesion of atherosclerosis is at risk for the following pathological changes that have clinical significance: 1) Focal rupture, ulceration, or erosion of the luminal surface of atheromatous plaques may result in exposure of highly thrombogenic substances that induce thrombus formation or discharge of debris into the bloodstream, producing microemboli composed of lesion contents (cholesterol emboli or atheroemboli).

  35. COMPLICATIONS 2) Hemorrhage into a plaque, especially in the coronary arteries, may be initiated by rupture of either the overlying fibrous cap or the thin-walled capillaries that vascularize the plaque. A contained hematoma may expand the plaque or induce plaque rupture.

  36. COMPLICATIONS 3)Superimposed thrombosis, the most feared complication, usually occurs on disrupted lesions (those with rupture, ulceration, erosion, or hemorrhage) and may partially or completely occlude the lumen. Thrombi may heal and become incorporated into and thereby enlarge the intimal plaque.

  37. 4)Aneurysmal dilation may result from ATH-induced atrophy of the underlying media, with loss of elastic tissue, causing weakness and potential rupture 5) Calcifications.

  38. Natural history of atherosclerosis Slide 12.5

  39. Risk Factors for Atherosclerosis Major Nonmodifiable • Increasing age • Male gender • Family history • Genetic abnormalities PotentiallyControllable • Hyperlipidemia • Hypertension • Cigarette smoking • Diabetes

  40. Risk Factors for Atherosclerosis Lesser, Uncertain, or Nonquantitated • Obesity • Physical inactivity • Stress ("type A" personality) • Postmenopausal estrogen deficiency  • High carbohydrate intake • Alcohol • Lipoprotein Lp(a) • Hardened (trans)unsaturated fat intake • Chlamydia pneumoniae

  41. PATHOGENESIS: response to injury hypothesis • This concept, called theresponse to injury hypothesis, considers atherosclerosis to be a chronic inflammatory response of the arterial wall initiated by injury to the endothelium. Moreover, lesion progression is sustained by interaction between modified lipoproteins, monocyte-derived macrophages, T lymphocytes, and the normal cellular constituents of the arterial wall.

  42. Processes in the response to injury hypothesis. 1, Normal. Slide 12.13

  43. 2, Endothelial injury with adhesion of monocytes and platelets (the latter to denuded endothelium). Slide 12.14

  44. 3, Migration of monocytes (from the lumen) and smooth muscle cells (from the media) into the intima. Slide 12.15

  45. 4, Smooth muscle cell proliferation in the intima. Slide 12.16

  46. 5, Well-developed plaque. Slide 12.17

  47. Slide 12.18

  48. PATHOGENESIS: response to injury hypothesis Central to this thesis are the following: • Accumulation of lipoproteins, mainly LDL, with its high cholesterol content, in the vessel wall • Chronic endothelial injury, usually subtle, yielding increased permeability, leukocyte adhesion, and thrombotic potential.

  49. PATHOGENESIS: response to injury hypothesis • Adhesion of blood monocytes (and other leukocytes) to the endothelium, followed by their migration into the intima and their transformation into macrophages and foamcells • Adhesion of platelets • Release of factors from activated platelets, macrophages, or vascular cells that cause migration of SMCs from media into the intima

  50. PATHOGENESIS: response to injury hypothesis • Proliferation of smooth muscle cells in the intima, and elaboration of extracellular matrix, leading to the accumulation of collagen and proteoglycans • Enhanced accumulation of lipids both within cells (macrophages and SMCs) and extracellularly.

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