Effect of ethanol on splanchnic hemodynamics in awake and unrestrained rats with portal hypertension

Alcoholic liver disease is frequently accompanied by portal hypertension. We have previously shown that alcohol intake in awake, unrestrained rats is followed by an increase in portal tributary blood flow. In this study, the effect of ethanol on splanchnic hemodynamics in rats with portal hypertension was analyzed. Portal hypertension was induced by partial ligation of the portal vein. This procedure resulted in an increase in portal tributary and hepatic arterial blood flows compared to sham-operated animals. Ethanol (2 gm per kg, oral) increased portal tributary blood flow in both sham-operated and portal vein-ligated rats (sham + water = 37.6 +/- 1.4; sham + ethanol = 63.1 +/- 1.9; p less than 0.01; partial portal vein stenosis + water = 53.2 +/- 3.3; partial portal vein stenosis + ethanol = 69.5 +/- 2.2 ml.kg-1.min-1; p less than 0.01). In sham-operated rats, hepatic artery blood flow was unchanged following ethanol (sham + water = 6.6 +/- 0.7; sham + ethanol = 7.1 +/- 1.0 ml.kg-1.min-1), whereas in portal vein-ligated rats, flow was increased (partial portal vein stenosis + water = 13.7 +/- 1.4; partial portal vein stenosis + ethanol = 19.8 +/- 1.1 ml.kg-1.min-1; p less than 0.025). The adenosine receptor blocker 8-phenyltheophylline suppressed only the ethanol-induced increase in both portal tributary and hepatic artery blood flows in portal vein-ligated rats. The increases in hepatic artery and portal tributary blood flows observed in portal vein-ligated rats without ethanol were not influenced by 8-phenyltheophylline.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of ethanol and wine on hepatic arterial and portal venous flows in conscious dogs.

The effects of ethanol and wine on hepatic arterial and portal venous flows were examined in conscious dogs. Ethanol was given intravenously or intragastrically, and red wine (ethanol: 14%) was given intragastrically over 30 min. Intravenous ethanol (0.8 g/kg) and intragastric ethanol (14% vol/vol) increased hepatic arterial flow, which remained elevated for 60 min after the cessation of ethanol administration. Ethanol also increased portal venous flow. Portal venous flow returned gradually toward basal levels after the cessation of intravenous ethanol infusion, whereas it remained elevated even after the cessation of intragastric ethanol. Intragastric wine increased hepatic arterial and portal venous flows. In contrast to intragastric ethanol, hepatic arterial flow continued to rise after the cessation of intragastric wine infusion, while portal venous flow returned toward basal levels. We conclude that, though both ethanol and wine increase hepatic blood flow, the responses of hepatic arterial and portal venous flows differ substantially among intravenous ethanol, intragastric ethanol and intragastric wine.     

The intrahepatic biliary epithelium in the guinea pig: is hepatic artery blood flow essential in maintaining its function and structure?

To determine whether hepatic artery blood flow is essential in maintaining the function and structure of bile ductules/ducts, the acute effects of hepatic artery ligation on bile secretion and hepatic ultrastructure were examined in anesthetized, bile duct-cannulated guinea pigs. Sixty minutes after hepatic artery ligation, spontaneous bile flow (5.08 +/- 0.4 microliter per min per gm liver) was virtually the same as that before hepatic artery ligation (5.31 +/- 0.3 microliter per min per gm), as were the choleretic effects of 10 CU per kg per 30 min secretin (7.14 +/- 0.9 vs. 7.21 +/- 0.9 microliter per min per gm), 300 micrograms per kg per 30 min glucagon (6.72 +/- 0.9 vs. 6.59 +/- 0.8 microliter per min per gm) and 60 mumoles per kg per 30 min glycochenodeoxycholate (6.43 +/- 0.6 vs. 6.45 +/- 0.6 microliter per min per gm). The failure of hepatic artery ligation to affect bile secretory function could not be attributed to the existence of collateral arterial blood flow to the liver. First of all, hepatic artery ligation resulted in diminishing significantly hepatic venous, but not portal, oxygen content. More importantly, in isolated guinea pig livers, perfused through the portal vein alone, secretin, glucagon and glycochenodeoxycholate produced changes in bile flow and composition similar to those seen in vivo. Electron microscopy showed no major ultrastructural changes of hepatic parenchyma and biliary epithelium 2 hr after hepatic artery ligation, or 2 hr after perfusing the liver through the portal vein alone save for some portal edema in the latter instance.(ABSTRACT TRUNCATED AT 250 WORDS)     

Alterations in Splanchnic Blood Flow After Low and High Doses of Ethanol

The purpose of this investigation was to determine the effect of various acute doses of ethanol (1.0, 3.0, 4.0 g/kg) on the distribution of cardiac output (%CO) and blood flow to the splanchnic vascular bed in conscious male Wistar rats. Regional blood flow and cardiac output (CO) were measured by the reference microsphere technique. Mean arterial pressure and CO were significantly reduced 60 min after 3.0 g/kg and 4.0 g/kg of ethanol, while no changes occurred over time in total peripheral vascular resistance or heart rate. Acute ethanol administration produced an early non-sustained increase in portal vein blood flow, that was most pronounced after a low dose of ethanol, and was attenuated after the 3.0 g/kg and 4.0 g/kg doses of ethanol. The early increase in portal vein blood flow produced a corresponding increase in total liver blood flow. Additionally, we found increases in hepatic arterial blood flow after the higher doses. The combined increase in portal vein and hepatic arterial supply to the liver may serve to increase oxygen delivery, more than the singular increase in portal vein blood flow. This early increase in total liver blood flow after high doses of ethanol may be important for protecting hepatocyte function in the presence of high blood ethanol levels.     

Acetate-Mediated Effects of Ethanol

Ethanol has been shown to increase markedly portal blood flow, primarily by increasing intestinal blood flow. This effect of ethanol is reproduced by acetate, infused at rates equivalent to those leading to endogenous acetate production following ethanol administration. The physiological mediator, adenosine, is also known to increase markedly intestinal and portal tributary blood flow. We have shown that adenosine receptor blockade with 8-phenyltheophylline completely abolishes the effects of ethanol, acetate, and adenosine on intestinal and portal blood flow, suggesting that increases in adenosine tone may constitute a common mechanism mediating the actions of both ethanol and acetate on the splanchnic vasculature.
Studies are also presented that show that acetate administration has marked effects on central nervous system function. On two tests, motor coordination and anesthetic potency, both ethanol and acetate showed similar effects. The effects of acetate were fully abolished by 8-phenyltheophylline. The effects of ethanol were partially blocked by 8-phenyltheophylline, with a greater effect of this blocker being seen at low doses of alcohol.
Whereas ethanol at low doses increased locomotor activity in mice, acetate markedly reduced it. The effect of acetate on locomotion was fully reversed by the adenosine receptor blocker 8-phenyltheophylline, whereas the activating effect of ethanol on locomotion was markedly enhanced by this blocker. These data suggest that the actions of ethanol on locomotor activity normally result from the combination of a direct stimulatory effect of ethanol per se and an inhibitory effect of acetate, produced endogenously from ethanol. When the latter effect of acetate is abolished by adenosine receptor blockade, the activating effect of ethanol is fully expressed.
These data demonstrate that acetate is not an inert molecule and that some actions of ethanol may be partially or fully mediated by acetate.     

Effects of intravenous ethanol on hepatic and pancreatic blood flow in dogs

Changes in hepatic and pancreatic blood flow in response to ethanol infusion were determined simultaneously and continuously in anesthetized dogs, using a transit-time ultrasonic flowmeter and a laser-Doppler flowmeter. In addition, the effect of intravenous ethanol on exocrine pancreatic secretion was investigated. With a background infusion of secretin, ethanol (1.3 g/kg body wt) was infused intravenously over a 40-min period. Ethanol infusion significantly increased blood flow in the common hepatic artery (by 49%, at the time of the cessation of ethanol infusion), and this increased flow was maintained for 60 min after the cessation of ethanol infusion. In contrast, blood flow in the portal vein was not altered significantly by ethanol. Pancreatic blood flow and secretion showed no significant difference from those seen in the controls. Our data suggest that intravenous ethanol induces a redistribution of the splanchnic blood flow. The increased hepatic arterial flow seen in response to ethanol may play an important role in preventing ethanol-induced hypoxic liver damage.     

Effect of propranolol on hepatic and systemic hemodynamics in dogs with chronic bile duct ligation

Propranolol has been reported to reduce portal and wedged hepatic vein pressures in man and may be useful for the prevention of variceal bleeding. However, its mechanism of action remains unclear. We have examined the effect of propranolol on the systemic and hepatic circulations in dogs with chronic bile duct ligation and secondary biliary cirrhosis. Under anesthesia, eight dogs received four increasing doses of propranolol as an i.v. bolus followed by continuous infusion. Systemic and hepatic hemodynamic parameters were measured in basal conditions and after a 30 min infusion for each dose. Portal vein and hepatic artery blood flows were measured with electromagnetic flow meters. All dogs had portal hypertension (portal venous pressure 15.3 +/- 0.8 mm Hg), a hyperdynamic circulation and severe liver disease resulting in a marked decrease of propranolol systemic clearance (8.75 ml per min per kg) and extraction (40%). The first dose of propranolol induced a decrease in heart rate (-27%) and in cardiac index (-21%), and an increase in systemic vascular resistance (+20%). With increasing doses, the systemic vascular resistance decreased with an increase in the cardiac index. Propranolol was not associated with significant modifications of hepatic hemodynamics: portal, wedged and free hepatic venous pressures and hepatic artery blood flow were stable, and portal blood flow decreased slightly at very high propranolol levels. In seven dogs studied without dissection of the hepatic vessels, there was a small decrease in portal pressure, but not in wedged and free hepatic venous pressures with increasing doses of propranolol. Thus, in dogs with intrahepatic portal hypertension, propranolol has significant effects on systemic hemodynamics, but only minimal effects on the hepatic circulation.     

Mechanisms of Hepatic Microcirculatory Disturbances Induced by Acute Ethanol Administration in Rats, With Special Reference to Alterations of Sinusoidal Endothelial Fenestrae

Elucidation of the hepatic hemodynamics in acute ethanol administration is an issue of clinical importance for better understanding of alcoholic liver diseases. The purpose of this study is to clarify the mechanism of hepatic microcirculatory disturbances after acute ethanol administration, especially regarding the effects of ethanol on alterations of sinusoidal endothelial fenestrae (SEF) and the involvement of endothelin-l (ET-1) in the mechanism of portal hypertension induced by ethanol. Ethanol was administrated into the portal vein via the mesenteric vein branch of rats as a continuous infusion (4 and 8 mg/min of ethanol) for 60 min. Hepatic tissue blood flow measured with a laser Doppler blood flowmeter was found to be remarkably decreased with time, whereas portal pressure began to increase at 10 min and showed a significant increase by ˜1.5 cm H₂O at 60 min. Ethanol concentrations in blood at 60 min after 4 and 8 mg/min of ethanol infusion were 0.75 mg/ml and 1.77 mg/ml, respectively. At this point, scanning electron microscopy revealed significant decreases in number and diameter of SEF both in zone 1 and zone 3, with the increase in ethanol level. These findings suggested that decreases in number and diameter of SEF, whether primary or secondary, may lead to the impairment of the transport of plasma substances from sinusoids to hepatocytes in acute ethanol administration. Furthermore, the pretreatment of BQ-123 inhibited a decrease in hepatic tissue blood flow and an increase in portal pressure caused by ethanol, indicating that ET-1 may be involved in the mechanism of hepatic circulatory disturbances in acute ethanol administration.     

Ethanol elimination in males and females: relationship to menstrual cycle and body composition

Ethanol pharmacokinetics were determined following oral ethanol, 0.5 gm per kg, in nine normal women and 10 normal men, and related to total body water measured by 3H-water dilution and body fat determined anthropometrically. Ethanol pharmacokinetics were similar in the females throughout the menstrual cycle. No variation was seen in mean peak blood ethanol concentration or elimination rate in the midfollicular (Days 8 to 10) and midluteal (Days 22 to 24) phases. Mean peak blood ethanol values were significantly higher in females (88 +/- 3 mg per 100 ml) than in males (75 +/- 4 mg per 100 ml) (p less than 0.05), and the mean area under the ethanol concentration-time curve was significantly greater in females (241 +/- 12 mg X hr per 100 ml) than in males (177 +/- 11 mg X hr per 100 ml) (p less than 0.001). There was no significant sex difference in mean ethanol elimination rates. The mean apparent volume of distribution of ethanol in female (0.59 +/- 0.02 liter per kg) was less than in males (0.73 +/- 0.02 liter per kg) (p less than 0.001). Both apparent volume of distribution of ethanol and area under curve were significantly correlated with total body water suggesting that the sex differences in ethanol pharmacokinetics were due to sex differences in body water content. The sex differences in ethanol pharmacokinetics may partly explain reports of male-female differences in the natural history of certain ethanol-related disorders.     

Effects of propylthiouracil and methimazole on splanchnic hemodynamics in awake and unrestrained rats

The treatment of alcoholic liver disease with propylthiouracil is based on its effect of suppressing the ethanol-induced increase in hepatic oxygen consumption. It has been postulated that liver necrosis ensues when the increase in oxygen demand by the liver exceeds oxygen delivery to this organ. Data are now presented which show that propylthiouracil also increases portal blood flow in awake, unrestrained rats. Liver blood flow was determined using the labeled microsphere technique in rats at various intervals (0.25, 0.5, 1.0, 3.0, 6.0 and 24 hr) after oral propylthiouracil (50 mg per kg). Administration of propylthiouracil (dose range: 6.25 to 100.0 mg per kg) produced a dose-dependent increase in portal blood flow when given either orally or intraarterially. Maximal flows were obtained with 50 mg per kg (controls = 37.8 +/- 1.5, oral propylthiouracil = 50.7 +/- 2.2 ml.kg-1.min-1). This increase in portal blood flow was accompanied by a decrease in preportal vascular resistance (controls = 2.61 +/- 0.16; propylthiouracil, 50 mg per kg = 1.79 +/- 0.09 mmHg per ml.kg-1.min-1). These effects were correlated with the plasma concentrations of propylthiouracil (r = 0.67, n = 68, p less than or equal to 0.001). The effect of oral propylthiouracil (50 mg per kg) on portal blood flow started at 0.5 hr and lasted for 6 hr after administration, whereas total liver blood flow was increased for 3 hr. Oral propylthiouracil (50 mg per kg) for 5 days resulted in a 53% increase in thyroid weight, an 85% reduction in 125I thyroid uptake and a 74% decrease in serum thyroxine concentration.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of acetaldehyde in the ethanol-induced impairment of hepatic glycoprotein secretion in the rat in vivo

Ethanol administration inhibits hepatic protein and glycoprotein secretion. Previous studies have shown that the metabolism of ethanol is required for this effect. Experiments were designed to determine whether acetaldehyde, the first metabolite of ethanol oxidation, mediated the ethanol-induced secretory defect in rats with normal and stimulated (inflammation-induced) rates of hepatic protein secretion. This study used cyanamide, an aldehyde dehydrogenase inhibitor, to correlate enhanced acetaldehyde levels with an increased ethanol-induced inhibition of hepatic protein secretion. Inflammation was induced by turpentine 24 hr prior to cyanamide (5 mg per kg body weight) or saline pretreatment. Nonfasted rats were intragastrically gavaged with ethanol (4 to 6 gm per kg body weight) or isocaloric glucose 1 hr following pretreatment. [3H]Fucose and/or [14C]leucine were injected intravenously 2 hr following intubation. With elevated levels of acetaldehyde, the ethanol-induced impairment of secretion of labeled proteins and their parallel retention in the liver were markedly potentiated. During inflammation, this inhibition of secretion by ethanol was maintained and further increased with cyanamide pretreatment. These results indicate that the ethanol-induced impairment of hepatic glycoprotein secretion is mediated by acetaldehyde in both normal and inflammation-stimulated animals.     

Estimation of total hepatic blood flow by duplex ultrasound.

The volume flow rate of blood in the portal vein and the hepatic artery was measured using a duplex ultrasound system. Two sections of the hepatic artery were studied; the common hepatic artery where measurements were made just after the bifurcation of the coeliac axis to splenic and hepatic arteries and the hepatic artery itself, where measurements were made just proximal to the porta hepatis in a straight stretch of artery overlying the portal vein. Total hepatic blood flow was taken as the sum of hepatic artery and portal vein flows. A group of 10 normal healthy volunteers in the fasting state was studied. The mean (SD) volume blood flow in the vessels was measured to be: hepatic artery 3.5 (45%) ml/min/kg, common hepatic artery 6.9 (30%) ml/min+/kg, portal vein 13.5 (21%) ml/min/kg, total hepatic flow 17.0 (16%) ml/min/kg.     

The effect of consecutively larger doses of l-arginine on hepatic microcirculation and tissue oxygenation in hepatic steatosis

Background: Impairment of hepatic microcirculation in fatty liver is thought to render it more susceptible to the effects of ischaemia–reperfusion injury as compared to non-fatty liver grafts. The present study aimed to investigate the effect of consecutively larger doses of l-arginine on the hepatic microcirculation and tissue oxygenation of fatty liver.Methods: Sprague–Dawley rats (200–250 g) were fed a liquid ethanol diet to induce hepatic steatosis or a normal diet for 6 weeks. Hepatic blood flow, microcirculation, tissue oxyhaemoglobin (HBO₂) in response to consecutive intravenous bolus administrations of l-arginine (50 mg/kg, 100 mg/kg, 300 mg/kg and 500 mg/kg) or normal saline, were assessed.Results: Baseline hepatic arterial flows and hepatic microcirculation values were significantly lower in steatotic livers vs. control livers. l-arginine significantly improved hepatic arterial, portal venous blood flow, hepatic microcirculation and tissue oxygenation in both fatty and control livers.Conclusions: The administration of NO in cumulatively larger doses is effective at improving hepatic blood flow, microcirculation and hepatic tissue oxygenation in steatotic liver and these results could form the basis of further work into using NO as a therapeutic tool to reclaim moderately steatotic grafts for use in liver transplantation.     

Role of the liver in endotoxin-induced hyperinsulinemia and hyperglucagonemia in rats

The intravenous administration of bacterial endotoxin to fasted rats elicited basal portal and systemic venous hyperinsulinemia and hyperglucagonemia. Enhanced pancreatic secretion of insulin and glucagon was implied by the elevated portal venous hormonal levels. Elevated insulin and glucagon levels were present at 4 hr after a 33 micrograms/100 gm intravenous endotoxin dose despite no fluctuation of the plasma glucose concentration. The role of the liver in the pancreatic hormonal response to endotoxin was investigated by infusing lipopolysaccharide slowly into the portal vein or systemic inferior vena cava. At doses of 33 and 100 micrograms per 100 gm, endotoxin administered via the systemic route stimulated significantly greater insulin and glucagon responses than did portal administration. Furthermore, rats with acute liver injury induced by partial (67%) hepatectomy, which depressed Kupffer cell phagocytosis, did respond to the 33 micrograms per 100 gm intraportal endotoxin dose with significantly greater hyperinsulinemia and hyperglucagonemia. These data suggest that hepatic Kupffer cells normally function to remove lipopolysaccharide from the portal venous blood and that at least at low pharmacological doses the pancreatic hormonal response to endotoxin is mediated by an unknown systemic mechanism.     

Regional differences of effects of ethanol on canine blood vessels

In vitro effects of ethanol (0.1-2.0%,v/v) on canine vasculer smooth muscle were studied. Ethanol dose-dependently produced inhibition in both the amplitude and frequency of the spontaneous rhythmic activity of the canine hepatic portal vein, and at concentration of 1.0 +/- 0.2% completely abolished the spontaneous activity. Ethanol evoked dose-dependent constriction, rather than dilatation, in all vascular smooth muscles tested, including femoral, renal, common carotid, and pulmonary arteries, and external jugular, splenic, pulmonary, femoral, renal, and hepatic portal veins. The vasoconstriction effect of ethanol was much stronger on arteries than on the corresponding veins. Based on the contractile tension developed by ethanol, the femoral artery or the external jugular vein appeared to be most sensitive to ethanol among the arteries or veins preparations tested. The present results suggested that ethanol, depending on concentration, may either enhance or decrease excitability of vascular smooth muscles. There were also regional differences of effects of ethanol on canine blood vessels.     

In vivo interactions between H2-receptor antagonists and ethanol metabolism in man and in rats

The influence of a 7-day medication of either cimetidine (1,000 mg per day) or ranitidine (300 mg per day) on serum ethanol concentrations after a single oral dose of ethanol (0.8 gm per kg body weight) was investigated in a randomized placebo-controlled study in eight male volunteers. Compared with the placebo, cimetidine but not ranitidine produced a significant increase in both the peak serum ethanol concentration (85.9 +/- 3.5 vs. 73.0 +/- 3.2 mg dl-1, p less than 0.02) and in the area under the serum ethanol concentration time curve (350 +/- 19 vs. 304 +/- 25 mg dl-1 hr-1, p less than 0.05). However, the ethanol elimination rate was not affected by cimetidine. When ethanol (1.0 gm per kg body weight) was administered intravenously, cimetidine failed to induce a change in ethanol metabolism. Furthermore, the effect of H2-receptor antagonists was studied in animal experiments. Female Sprague-Dawley rats received a single dose of ethanol (7 or 3 gm per kg body weight) together with an intraperitoneal injection of either cimetidine (120 mg per kg body weight), ranitidine (120 mg per kg body weight) or isotonic saline. After alcohol absorption, ethanol elimination was significantly inhibited by both cimetidine (3.99 +/- 0.39 vs. 5.68 +/- 0.23 mmoles kg-1 hr-1, p less than 0.02) and ranitidine (4.21 +/- 0.14 vs. 5.68 +/- 0.23 mmoles kg-1 hr-1, p less than 0.02) at high ethanol concentrations (60 to 20 mM) but not at blood ethanol concentrations below 20 mM.(ABSTRACT TRUNCATED AT 250 WORDS)     

Beneficial effects of low doses of ethanol on reoxygenation injury following anoxia in rat hearts

Summary We investigated the effect of ethanol on adverse effects of anoxia and reoxygenation in isolated rat hearts. Perfusion of the anoxic Krebs-Henseleit medium for 40 min followed by 30 min of perfusion with aerobic medium produced considerable myocardial cell injury. Incorporation of ethanol (21.7 mM), in both anoxic and aerobic perfusion media resulted in a significant reduction of cell injury and inhibition of creatine phosphokinase release. The contraction bands were reduced to 0.24 as compared to 1.14 per field in the non-treated hearts. The tissue CA⁺⁺ was decreased to 8.72 μmol/gm/dry wt as compared to 20.17 μmol/gm/dry weight in the non-treated hearts and tissue ATP was increased by 50 % in the treated tissue (8.14 μmol/gm/dry wt), as compared to the nontreated anoxic tissue (4.41 μmol/gm/dry wt). However, the inclusion of only ethanol in the anoxic medium did not decrease the damage, suggesting that maximal injury occurred during reoxygenation. Ethanol appears to inhibit myofibril contractures and preserve the structural integrity of plasma membrane during anoxia and reoxygenation. This study suggests a beneficial effect of ethanol in low doses on the post anoxic reperfusion injury in the myocardium.     

Discrepancy between portal pressure and systemic hemodynamic changes after incremental doses of propranolol in awake portal hypertensive rats

The effects of increasing doses of propranolol were studied in awake portal hypertensive rats in order to elucidate the relative effects of the beta-blocker on systemic and splanchnic circulation. Hemodynamic responses to 0.1, 0.2 and 0.4 mg per min infusions of propranolol were compared with placebo in awake rats with portal hypertension due to portal vein stenosis. Heart rate significantly and progressively decreased from 356 +/- 13 to 293 +/- 10 beats per min (mean +/- S.E.). Cardiac output significantly decreased from 54 +/- 3 to 42 +/- 3 ml per min per 100 gm body weight at the highest dose. Significant decrease in portal tributary blood flow from 27 +/- 1 to 18 +/- 1 ml per min, at 0.4 mg per min dose, was due not only to the decrease in cardiac output but also to a significant increase in portal tributary vascular resistance from 269 +/- 17 to 368 +/- 31 dyne per sec per cm5 x 10(3). However, portal pressure showed only an insignificant decrease from 14.9 +/- 1.1 to 14.1 +/- 1.4 mmHg. The reduction in portal pressure being minimal, in spite of a significant decrease in portal tributary blood flow, is explained by an increase in combined hepatic and collateral resistance from 44 +/- 2 to 66 +/- 4 dyne per sec per cm5 x 10(3), p less than 0.05, at 0.4 mg per min dose. We conclude that the systemic and splanchnic effects of propranolol show discrepancy at two levels.(ABSTRACT TRUNCATED AT 250 WORDS)     

Acute Effects of Ethanol on Liver Blood Circulation in the Anesthetized Dog

A single, intraportal injection of ethanol (0.01 g/kg body weight) in the pentobarbital anesthetized dog elicited an immediate rise in the hepatic resistance to both portal and hepatic blood flows. Similar effects were produced by norepinephrine and these, as well as those of ethanol, were significantly reduced by yohimbine. Increased levels of noradrenaline were found in hepatic venous effluent during the vasoconstriction period induced by ehtanol. We postulate that noradrenaline liberated from sympathetic nervous endings of the liver may be involved in vascular response to ethanol.     

Quantitation of the hepatic arterial buffer response to graded changes in portal blood flow

Hepatic arterial blood flow changes inversely in response to altered portal blood flow. The hepatic arterial capacity to buffer portal flow changes was studied over a wide range of portal flow with arterial pressure held steady (the active buffer response) or uncontrolled. The active component of the buffer response led to nearly full dilation of the hepatic artery at low portal flows as shown by inability to dilate further in response to adenosine infusion; at high portal flows the hepatic artery was nearly fully constricted as shown by lack of further constriction to norepinephrine. With pressure uncontrolled, active and passive effects combined to produce an increased compensation with similar efficiency (44% +/- 4%) over the full range of portal blood flows. Thus, although the active component of the hepatic arterial buffer response becomes less efficient at very high and low portal flows, the combination of active and passive effects leads to a larger buffer capacity which is equally efficient over a wide range of portal blood flow changes.