Active changes in hepatic capacitance were studied in pump-perfused dog livers during hepatic nerve stimulation or during intrahepatic arterial infusion of histamine (0.01-1 mg/l) or epinephrine (0.05 mg/l). Hepatic nerve stimulation at 5 pulses/s (pps) reduced hepatic blood volume by 76 +/- 39 (SD) ml/kg tissue and decreased the apparent hepatic compliance 36% from a control value of 25.6 +/- 9.3 ml.kg-1.mmHg-1, with constant flow perfusion. With a constant hepatic arterial pressure, 5 pps stimulation decreased hepatic arterial flow to 16% of control; the volume expelled was 91 +/- 33 ml/kg. Epinephrine caused hepatic artery constriction, the active expulsion of 71 ml/kg of blood, and a decrease of about 30% in hepatic compliance. Histamine dramatically reduced the hepatic vascular compliance, decreased the portal venous conductance, increased hepatic arterial conductance, and caused the apparent hepatic blood volume to double. Increased hepatic venous pressure, hepatic nerve stimulation, epinephrine, and, especially, histamine caused a significant filtration of fluid from the hepatic vasculature. We conclude that significant active capacitance changes and transsinusoidal fluid filtration can be induced in the canine liver by neural and hormonal stimuli.
SUMMARY To quantify the relative contribution of blood flow redistribution and active changes in vascular capacity in the regulation of cardiac output, blood flow and volumes in two parallel vascular beds were measured in response to varying carotid sinus pressures. In nine dogs, carotid sinuses were isolated and intrasinus pressure was controlled. Two external reservoirs were placed between the caval veins and the right heart to measure changes in vascular capacity in splanchnic and extrasplanchnic vascular beds. At intrasinus pressures of SO and 200 nun Hg, we have simultaneously measured arterial resistances, compliances, changes in flows, and "unstressed vascular volume," and time constants of venous drainage in the splanchnic and extrasplanchnic vascular beds. Compliances and time constants of venous drainage were found to be nearly equal in the two beds. A decrease in intrasinus pressure from 200 to 50 mm Hg resulted in a small redistribution of blood flow (about 5% of cardiac output) from the extraplanchnic compartment to the splanchnic vascular bed. Changes in reservoir volumes were found to be around 7.0 ml/kg. The splanchnic vascular bed was responsible for a greater change in reservoir volume for a given change in intrasinus pressure. With any change in intrasinus pressure, the change in arterial resistance in the extrasplanchnic vascular bed was greater than that of the splanchnic vascular bed. Blood flow redistribution was not found to be a significant factor contributing to changes in reservoir volume. The changes in reservoir volume seen, must have been due to active changes in vascular capacity in the two channels chosen. Circ Res 48: 274-285, 1981 THE importance of changes in the capacitive property of the systemic vascular bed has been recognized for some time. For example, a decrease in capacity can increase the filling presure of the right heart which, in turn, can increase cardiac output. Evidence that the carotid sinus baroreceptor reflex controls the systemic vascular capacity has been presented from several laboratories (Drees and Rothe, 1974;Rashkind et al., 1953;Salzman, 1957;Shoukas and Sagawa 1973). The amount of blood which can be mobilized from the entire systemic vascular bed by the reflex has also been quantified (Drees and Rothe, 1974;Rashkind et al., 1953;Shoukas and Sagawa, 1973). However, the exact mechanism and source of blood mobilization remains somewhat controversial (Caldini et al., 1974;Coleman et al., 1974;Green, 1975;Mitzner and Goldberg, 1975).Using a dog preparation in which venous return was diverted into a reservoir while cardiac output was kept constant, Shoukas and Sagawa (1973) showed that significant shifts of blood between the dog and a reservoir occurred when carotid sinus pressure was changed. They hypothesized that the reflex altered the "unstressed" vascular volume of the systemic veins based on the finding that the total systemic vascular compliance did not change significantly. A more recent work by Shoukas and Brunner (1980) indicated that the reflex...
The magnitude of vascular capacitance change induced by hypercapnia, hypoxia, or hypoxic hypercapnia was estimated during the administration of experimental gas mixtures to anesthetized dogs for 25 min. Mean circulatory filling pressure (Pcf) was determined by fibrillating the heart and equilibrating arterial and venous pressures with a pump. We assumed that the total blood volume remained constant and that the magnitude of change in peripheral venous volume equaled the sum of the changes in blood volume in the cardiopulmonary and arterial beds. We further assumed that active (reflex) peripheral venoconstriction occurred if the cardiopulmonary and arterial bed blood volumes, as well as the Pcf, increased. Within 3 min, severe hypercapnia and hypoxic hypercapnia induced a 5.2 and 7.3 ml/kg reduction in systemic vascular capacity, and, by 19 min of experimental gas presentation, increased Pcf by 5.5 and 7.0 mmHg, respectively. Severe hypoxia had less effect (0.7 ml/ kg and 2.5 mmHg, respectively) at 19 min. Severe hypercapnia also increased the central venous, systemic arterial, and pulmonary arterial pressures and decreased heart rate. Hypoxic hypercapnia additionally increased cardiac output. We conclude that severe systemic hypercapnia, whether alone or in combination with hypoxia, causes a significant active reduction in vascular capacitance, but severe hypoxia is less effective.
Hypercapnic stimulation of the brain may account for some of the decrease in vascular capacitance (venoconstriction) seen with whole-body hypercapnia. Six mongrel dogs were anesthetized with alpha-chloralose and paralyzed with pancuronium bromide. The vagi were cut and the carotid bodies and sinuses were denervated. The head circulation was isolated and perfused with normoxic [arterial partial pressure of O2 (Pao2) = 112 mmHg], normocapnic (PaCO2 = 40 mmHg) blood, or one of three levels of normoxic, hypercapnic (PaCO2 = 56, 68, or 84 mmHg) blood. A membrane oxygenator was used to change gas tensions in the perfusate blood. The systemic circulation received normoxic, normocapnic blood (Pao2 = 107 mmHg; PaCO2 = 32 mmHg). Systemic arterial pressure increased from 111 to 134 mmHg, and heart rate decreased from 174 to 150 beats/min with a head blood PaCO2 of 84 mmHg. Central blood volume was not affected by head hypercapnia. Cardiac output significantly decreased only with a head blood PaCO2 of 84 mmHg. Mean circulatory filling pressure increased by 0.014 mmHg/1 mmHg increase in head PaCO2. The sensitivity of the total peripheral resistance to cephalic blood hypercapnia was 0.88%/mmHg, whereas that for the mean circulatory filling pressure was only 0.19%/mmHg. We conclude that stimulation of the brain, via perfusion of the head with hypercapnic blood, causes a small but significant increase in mean circulatory filling pressure, due to systemic venoconstriction.
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