Redistribution of cardiac output in anesthetized thermally dehydrated rats

Cardiac output (CO) and its distribution were studied in dehydrated (37 degrees C) anesthetized (Na thiopentone) rats prior to and following heat acclimation (at 34 degrees C), using 57Co 15 micron microspheres. In non-acclimated dehydrated rats, CO decreased while heart rate (HR) increased significantly. Following acclimation CO increased without any change in HR; during dehydration CO remained elevated together with a significant increase in HR. In non-acclimated rats at low dehydration blood perfusion to peripheral thermoregulatory areas increased while perfusion of splanchnic area decreased; at high dehydration level peripheral blood flow decreased whereas splanchnic blood flow was augmented. In acclimated dehydrated rats, CO distribution to thermoregulatory areas did not change while perfusion of the splanchnic area decreased. It is suggested that following acclimation, the increased CO contributes to maintenance of thermoregulatory peripheral blood flow; in non-acclimated rats severe dehydration leads to augmented blood flow in the permeable splanchnic vascular bed, increasing efflux of plasma protein and failure of plasma volume conservation.     

The redistribution of cardiac output in the dog during heat stress

In conscious Greyhound dogs, radioactive microsphere techniques have been used to measure cardiac output, its regional distribution, and proportion of the cardiac output passing through arteriovenous anastomoses (AVA's) in a thermoneutral environment and during severe heat stress. Heat stress resulted in a 74% increase in cardiac output and 4–6% of the cardiac output passed through AVA's. compared with about 1% under thermoneutral conditions: blood flow rate increased in skin of the lower legs and ears, tongue, maxillo turbinals, nasal mucosa, respiratory muscles and spleen, decreased in the thyroids, brain and spinal cord, and did not change significantly in the non-respiratory muscles, heart, pituitary, adrenals, kidneys, liver, stomach and intestines. Thus the circulatory requirements of the heat stressed dogs were met partly by an increase in cardiac output and partly by changes in its distribution. In contrast, the Merino sheep meets such a situation entirely by a redistribution of cardiac output. The present results may be taken as evidence that the Greyhound dog is less heat tolerant than the Merino sheep. The decreased brain blood flow during heat stress is similar to that which occurs in the sheep, but contrast with previous results obtained on anaestherized dogs. The less marked redistribution of cardiac output in the dog compared with the sheep, may explain the apparent difference in energy cost of panting in the two species.     

Hemodynamic and cardiac actions of trazodone and imipramine in the anesthetized dog.

The relative cardiovascular effects of trazodone and imipramine were compared in two open-chest, anesthetized dog models. Trazodone lowered arterial blood pressure (0.3 mg/kg), slowed heart rate (3 mg/kg) and reduced myocardial contractile force (3–10 mg/kg) following i.v. administration. Low i.v. doses (0.05–0.15 mg/kg) of imipramine increased arterial blood pressure and heart rate, presumably as a consequence of its known anticholinergic properties and/or effects on neuronal catecholamine re-uptake mechanisms. Subsequent to administration of 1.5 and 5 mg/kg, however, the vascular and myocardial depressant effects of imipramine were evident. Trazodone (1–10 mg/kg, i.v.), unlike imipramine, effected a substantial level of $\text{alpha}$-adrenergic blockade $\text{vs.}$ a fixed challenge dose of norepinephrine, although less than that associated with phentolamine. Both trazodone and imipramine reduced aortic flow although $\text{via}$ different mechanisms. The reduction following administration of trazodone resulted from a decrease in heart rate whereas imipramine depressed aortic flow by lowering stroke volume.     

Determination of cardiac output and other reference physiology parameters in lightly anesthetized dogs

1. Cardiac output; arterial, pulmonary artery, central venous and pulmonary wedge pressures; heart rate, hematocrit, and plasma sodium and potassium; arterial and mixed venous blood gases; and respiratory rates were measured in 45 mixed sex, non-pregnant, clinically normal mongrel dogs of 8-30 kilograms body weight following light anesthesia with halothane/50% N20-02. 2. Arithmetic means and standard deviations were calculated to develop tables of reference values. 3. Mean measured cardiac outputs were found to be 31-59% higher in these dogs than the values indicated by published standards; cardiac indices were 30-44% higher; heart rates were 16-30% lower; calculated stroke volumes were 60-112% greater; and total peripheral resistances were 35-57% less than the standard published values. 4. All other measured or calculated parameters fell within previously published canine or human reference limits.     

Control of right atrial pressure at constant cardiac output suppresses volume natriuresis in anesthetized rats

The blood volume of anesthetized rats was expanded acutely by 33% with donor blood while a caval snare was gradually tightened so that right atrial pressure (RAP) was prevented from rising (n = 6). In control experiments (n = 5) an aortic snare was used to hold mean arterial blood pressure near the values found in the experimental series. However, RAP was allowed to change freely and increased by 1.6 +/- 0.4 mmHg (1 mmHg = 133.322 Pa) during volume expansion. When the two groups were compared, there were no significant differences between their mean arterial blood pressures (near 110 mmHg) or in their cardiac outputs (near 0.25 mL X min-1 X g body weight-1). There were, however, significant differences between their renal responses to the volume load. When RAP was free to change, the rate of volume excretion (V) increased to 30 +/- 15 (SEM) microL X min-1 X g kidney weight-1 (KW) from its control value of 3.49 +/- 0.31 and the rate of sodium excretion (UNaV) increased to 3.59 +/- 0.20 muequiv X min-1 X g KW-1 from its preinfusion value of 0.42 +/- 0.10. When RAP was not allowed to increase during volume loading, V and UNaV did not change from their respective preinfusion values (2.99 +/- 0.46 microL X min-1 X g KW-1 and 0.35 +/- 0.10 muequiv X min-1 X g KW-1). The results imply that during acute blood volume expansion increased central vascular pressure is a prerequisite for the homeostasis of body water and salt.