PEDIATRIC CARDIOVASCULAR INTENSIVE-CARE - MYOCARDIAL PERFUSION

被引：6

作者：

HOFFMAN, JIE

机构：

[1] Department of Pediatrics, Cardiovascular Research Institute, University of California, San Francisco, CA 94143

来源：

PROGRESS IN PEDIATRIC CARDIOLOGY | 1995年 / 4卷 / 03期

关键词：

SUBENDOCARDIAL ISCHEMIA; CORONARY FLOW RESERVE; AUTOREGULATION; MYOCARDIAL OXYGEN CONSUMPTION;

D O I：

10.1016/1058-9813(95)00120-R

中图分类号：

R5 [内科学];

学科分类号：

1002 ; 100201 ;

摘要：

The heart in a person at rest has a high oxygen consumption that must be met by a high blood flow; during exercise or stress, oxygen consumption rises and flow must increase in proportion to avoid myocardial ischemia. At normal perfusing pressures, basal left ventricular flows can increase about 4-fold with maximal vasodilatation, that is, there is a large coronary flow reserve. This reserve can be reduced if basal flow is increased, for example, by tachycardia, anemia, catecholamines, hypoxemia and abnormal hemoglobins. It can also be decreased if maximal flow is reduced by disease of large or small coronary arteries, tachycardia, hypertrophy, or polycythemia. With abolition of coronary flow reserve, myocardial ischemia occurs. These changes occur predominantly in the subendocardium, and are usually patchy unless there is acute near total prolonged ischemia. Other causes of reduced subendocardial perfusion are a raised ventricular end-diastolic pressure and increased contractility. The immature heart may be at a particular disadvantage in terms of coronary reserve because of its high basal coronary flows.

引用

页码：117 / 123

页数：7

共 54 条

[1]

Grossman, Jones, McLaurin, Wall stress and patterns of hypertrophy in human left ventricle, J Clin Invest, 56, pp. 56-64, (1975)

[2]

Weber, Janicki, Myocardial oxygen consumption: the role of wall force and shortening, Am J Physiol, 233, pp. H421-H430, (1977)

[3]

Weber, Janicki, Interdependence of cardiac function, coronary flow, and oxygen extraction, Am J Physiol, 235, pp. H784-H793, (1978)

[4]

Suga, Hisano, Hirata, Hayashi, Ninomiya, Mechanism of higher oxygen consumption rate: pressure-loaded vs. volume loaded heart, Am J Physiol, 242, pp. H942-H948, (1982)

[5]

Suga, Hisano, Goto, Yamada, Igarashi, Effect of positive inotropic agents on the relation between oxygen consumption and systolic pressure-volume area in the canine left ventricle, Circ Res, 53, pp. 306-318, (1983)

[6]

Rooke, Feigl, Work as a correlate of canine left ventricular oxygen consumption, and the problem of catecholamine oxygen wasting, Circ Res, 50, pp. 273-286, (1982)

[7]

Hoffman, Coronary physiology, Current Concepts in Cardiovascular Physiology, pp. 289-349, (1990)

[8]

Canty, Coronary pressure-function and steady-state pressure-flow relations during autoregulation in the unanesthetized dog, Circ Res, 63, pp. 821-836, (1988)

[9]

Drake-Holland, Laird, Noble, Spaan, Vergroesen, Oxygen and coronary vascular resistance during autoregulation and metabolic vasodilatation in the dog, J Physiol (Lond), 348, pp. 285-299, (1984)

[10]

Mosher, Ross, McFate, Shaw, Control of coronary blood flow by an autoregulatory mechanism, Circ Res, 14, pp. 250-259, (1964)

← 1 2 3 4 5 6 →