Prostaglandin E1 enhances hepatic portal venous flow by dilating the portal vascular bed in 70% hepatectomized dog.

The effects of portal, hepatic arterial and femoral venous administration of prostaglandin E1 (PGE) on portal venous flow (PVF) and hepatic arterial flow HAF were examined before and after 70% hepatectomy in anesthetized dogs. In the hepatectomized condition, portal venous administration of PGE (0.5 microgram/kg/min) caused an increase in PVF without any change in systemic arterial pressure (SAP). HAF was unchanged following the injection. The portal effect of PGE on PVF was dose-dependent, and a reduction in portal venous resistance was seen. However, the same dose of PGE failed to change PVF under intact liver conditions. Hepatic arterial administration of PGE (0.5 microgram/kg/min) brought no significant change in PVF or HAF, with or without hepatectomy. Femoral venous administration of PGE (0.5 micrograms/kg/min) produced an increase in PVF concomitant with a significant decrease in SAP. HAF showed no change after the injection. A decrease in PVR was seen only in the hepatectomized condition. It is concluded that PGE is potent in increasing PVF in the hepatectomized condition, and the portal vasculature is involved as the site of action.     

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.     

An attempt to decrease ammonia levels after portacaval anastomosis in dogs: hepatic periarterial neurectomy

Hepatic encephalopathy and elevated serum ammonia levels occur commonly after portacaval shunt and are hypothesized to be, in part, due to decreased hepatic blood flow. Prior work has demonstrated increased blood flow to the liver following hepatic periarterial neurectomy. In this experimental study, we investigated the functional, hemodynamic, and histopathological changes in the liver and kidney occurring after the addition of hepatic periarterial neurectomy to side-to-side portacaval shunt in dogs. It is our hypothesis that the addition of hepatic periarterial neurectomy to portacaval shunt will decrease postshunt ammonia levels. Side-to-side portacaval shunt was performed in 12 dogs (group I). Hepatic periarterial neurectomy was added to portacaval shunt in 9 dogs (group II). Serum levels of ammonia, urea, creatinine, alanine aminotransferase, aspartate aminotransferase, alkaline phosphatase, albumin, and bilirubin together with hepatic blood flow were determined in both groups preoperatively and on postoperative day 21. The pre- and postoperative histopathologic changes of the liver and kidney were evaluated. There was significantly less postoperative elevation of serum ammonia and aspartate aminotransferase when hepatic periarterial neurectomy was added to the portacaval shunt procedure. Hemodynamic studies of hepatic artery and hepatic tissue indicated better blood flow in group II. The histopathologic evaluation of group II showed expansion of sinusoids, portal vessels, and portal areas and increased portal fibrosis as compared to group I. The results of this experimental study show that adding hepatic periarterial neurectomy to the portacaval shunt procedure improves postoperative serum levels of ammonia and aspartate aminotransferase and hepatic artery and tissue blood flow.     

Should temporary extracorporeal continuous portal diversion replace meso/porta-caval shunts in “small-for-size” syndrome in porcine hepatectomy?

AIM:To investigate the feasibility of temporary extracorporeal continuous porta-caval diversion(ECPD) to relieve portal hyperperfusion in "small-for-size" syndrome following massive hepatectomy in pigs.METHODS:Fourteen pigs underwent 85%-90% liver resection and were then randomly divided into thecontrol group(n = 7) and diversion group(n = 7).In the diversion group,portal venous blood was aspirated through the portal catheter and into a tube connected to a centrifugal pump.After filtration,the blood was returned to the pig through a double-lumen catheter inserted into the internal jugular or subclavian vein.With the conversion pump,portal venous inflow was partially diverted to the inferior vena cava through a catheter inserted via the gastroduodenal vein at 100-130 m L/min.Portal hemodynamics,injury,and regeneration in the liver remnant were compared between the two groups.RESULTS:Compared to the control group,porta-caval diversion via ECPD significantly mitigated excessive portal venous flow and portal vein pressure(PVP); the portal vein flow(PVF),hepatic artery flow(HAF),and PVP in the two groups were not significantly different at baseline; however,the PVF(431.8 ± 36.6 vs 238.8 ± 29.3,P 0.01; 210.3 ± 23.4 vs 122.3 ± 20.6,P 0.01) and PVP(13.8 ± 2.6 vs 8.7 ± 1.4,P 0.01; 15.6 ± 2.1 vs 10.1 ± 1.3,P 0.05) in the control group were significantly higher than those in the diversion group,respectively.The HAF in the control group was significantly lower than that in the diversion group at 2 h and 48 h post hepatectomy,and ECPD significantly attenuated injury to the sinusoidal lining and hepatocytes,increased the regeneration index of the liver remnant,and relieved damage that the liver remnant suffered due to endotoxin and bacterial translocation.CONCLUSION:ECPD,which can dynamically modulate portal inflow,can reduce injury to the liver remnant and facilitate liver regeneration,and therefore should replace permanent meso/porta-caval shunts in "smallfor-size" syndrome.     

The effect of duodenal acidification on gastric circulation and function in the dog.

The effect of acidification of duodenal contents on splanchnic bloodflow and gastric circulation was investigated in anaesthetized dogs by measuring electromagnetically portal venous and left gastric artery bloodflow and gastric mucosa bloodflow with pertechnetate clearance. Duodenal acidification increased portal venous bloodflow and reduced mesenteric inflow resistance. At the same time bloodflow in the gastric artery and (not significantly) in the mucosa were reduced in consequence of increased inflow resistances.     

Hepatic arterial and portal flow in cardiogenic and hemorrhagic shock in awake dogs

The changes in liver blood flow produced by experimental cardiogenic and hemorrhagic shock are relatively unexplored. Fifteen unanesthetized dogs in which electromagnetic blood flow transducers had been implanted on the common hepatic artery and portal vein were subjected to acute myocardial infarction by mercury embolization of the circumflex coronary artery. Another group of ten dogs were bled to an arterial pressure of 40 mmHg and maintained at that level for 2 hours before reinfusion. Six additional dogs in which blood flow transducers had been implanted on the superior mesenteric artery and portal vein also were subjected to hemorrhage. In three of the six, phenoxybenzamine was infused directly into the superior mesenteric artery 45 minutes prior to bleed-out. During cardiogenic shock, both hepatic arterial and protal venous flow fell. However, whereas protal flow continued to fall, eventually stabilizing at values 36 +/- 3% of control, hepatic arterial flow subsequently rose, reaching values 93 +/- 9% above control. Total liver blood flow, after an initial decline to 53 +/- 4% of control levels rose as a result of the increased hepatic arterial flow to 73 +/- 4% of control values. During hemorrhage, both hepatic arterial and protal venous flows decreased as aortic pressure fell. Within 5 minutes of reinfusion, hepatic arterial flow surpassed its control values. Portal flow also increased but, on a percentage basis, not to so great an extent. Flow in hepatic artery remained high for 40 minutes after reinfusion, whereas portal flow rapidly decreased to levels seen at the end of hemorrhage. In hemorrhage without alpha-adrenergic receptor blockade the superior mesenteric bed constricted, thereby supporting systemic pressure. With alpha-adrenergic blockade, however, mesenteric flow became pressure-dependent and no longer acted as a homeostatic mechanism.     

Extracorporeal continuous portal diversion plus temporal plasmapheresis for “small-for-size” syndrome

AIM:To investigate the effect of plasmapheresis via the portal vein for"small-for-size"syndrome(SFSS)aided by extracorporeal continuous portal diversion(ECPD).METHODS:Extensive or total hepatectomy in the pig is usually adopted as a postoperative liver failure(PLF)or SFSS model.In this study,animals which underwent85%-90%hepatectomy were randomized into either the Systemic group(n=7)or the Portal group(n=7).In the Systemic group,all pigs received temporal plasmapheresis(PP)via the extracorporeal catheter circuit(systemic to systemic circulation)from 24 to 30 h posthepatectomy(PH);in the Portal group,all pigs received ECPD to divert partial portal vein flow(PVF)to the systemic circulation after hepatectomy,then converted to temporal PP from 24 to 30 h PH,and subsequently converted to ECPD again until 48 h PH.In the Portal group,the PVF was preserved at 3.0-3.3 times that of the baseline value,similar to that following 70%hepatectomy,which was regarded as the optimal PVF to the hypertrophic liver remnant.At 48 h PH,all pigs were re-opened and the portal vein pressure(PVP),PVF,and HAF(hepatic artery flow)were measured,and then diversion of the portal venous flow was terminated.After1 h the PVP,PVF,and HAF were re-measured.The portal hemodynamic changes,liver injury,liver regeneration and bacterial/lipopolysaccharide(LPS)translocation were evaluated in the two groups.RESULTS:The PVP in the Portal group was significantly lower than that in the Systemic group during the time period from 2 to 49 h PH(P<0.05).Serum alanine aminotransferase(ALT),total bilirubin(TB)and ammonia were significantly reduced in the Portal group compared with the Systemic group from 24 to 48 h PH(P<0.05).The Portal group may have attenuated sinusoidal endothelial injury and decreased the level of HA compared with the Systemic group.In the Systemic group,there was significant sinusoidal dilation,hydropic changes in hepatocytes and hemorrhage into the hepatic parenchyma,and the sinusoidal endothelial lining was partially destroyed and detac     

Role of glucagon in hyperglycemic response during a short period of hemorrhage in anesthetized dogs

A role of pancreatic glucagon in hemorrhage induced hyperglycemia was studied in anesthetized dogs with or without functional adrenalectomy (ADRX), surgical hepatic denervation (HNX), and surgical pancreatectomy (PCX). Plasma epinephrine, norepinephrine, and glucose concentrations were determined in both hepatic venous and aortic blood. Plasma glucagon (IRG) and insulin (IRI) levels were determined in aortic blood. All dogs were bled until aortic systolic pressure dropped to approximately 50% (64.8 +/- 1.6 mmHg, n = 25) of its control value (136.7 +/- 4.4 mmHg, n = 25), and the hypotension was maintained for 5 min. In control dogs (n = 10), hemorrhage markedly increased aortic epinephrine and hepatic venous norepinephrine. Similarly, aortic IRG, hepatic venous glucose and aortic glucose rose significantly during hemorrhage. In dogs with HNX combined with ADRX (n = 10), aortic epinephrine and hepatic venous norepinephrine remained unchanged during hemorrhage. Aortic IRG concentration, however, increased to a level similar to that observed in the control group. Aortic glucose increased significantly along with significant increases in hepatic venous glucose. In dogs with PCX combined with HNX and ADRX (n = 5), the increases in aortic IRG, hepatic venous glucose and aortic glucose observed in the first two groups in response to hemorrhage were virtually abolished. The results indicate that the increase in aortic IRG during hemorrhage is of pancreatic origin. We conclude that the pancreatic glucagon may be involved in the hyperglycemic response to hemorrhage, most likely through glucose mobilization by the liver during the early phase of hemorrhagic hypotension.     

Acute hemodynamic effects of octreotide and terlipressin in patients with cirrhosis: a randomized comparison

BACKGROUND: Octreotide and terlipressin are widely used in acute variceal hemorrhage to reduce the bleeding rate. They purportedly act by mesenteric arterial vasoconstriction, thus reducing portal venous flow (PVF) and portal pressure. Little is known about the immediate-early hemodynamic effects of these drugs. AIM: To compare the acute hemodynamic effects of octreotide and terlipressin in patients with cirrhosis. PATIENTS: Forty-two cirrhotic patients with a history of variceal bleeding were randomized to receive either octreotide 100 microg intravenous bolus followed by a continuous infusion at 250 microg/h (n = 21), or terlipressin 2 mg intravenous bolus (n = 21). METHODS: Mean arterial pressure (MAP), heart rate (HR), hepatic venous pressure gradient (HVPG), and PVF, assessed by duplex Doppler ultrasonography, were measured before and at 1, 5, 10, 15, 20, and 25 min after the start of drug administration. RESULTS: Octreotide markedly decreased HVPG (-44.5 +/- 17.8%) and PVF (-30.6 +/- 13.6%) compared to the baseline at 1 min (p < 0.05). Thereafter, both variables rapidly returned toward the baseline, and by 5 min, no significant differences in HVPG (-7.1 +/- 28.9%) and PVF (10.2 +/- 26.2%) were noted. A similar transient effect on MAP and HR was observed. Terlipressin significantly decreased HVPG (-18.3 +/- 11.9%) and PVF (-32.6 +/- 10.5%) at 1 min (p < 0.05) and sustained these effects at all time points. The effects on arterial pressure and HR were also sustained. CONCLUSIONS: Octreotide only transiently reduced portal pressure and flow, whereas the effects of terlipressin were sustained. These results suggest that terlipressin may have more sustained hemodynamic effects in patients with bleeding varices.     

Intrahepatic circulation in liver disease

Using the multiple indicator dilution approach, events occurring in the microvascular bed can be characterized in experimental animals with different types of cirrhosis and in man. Intrahepatic shunts can be found shunting blood away from sinusoids in both cirrhotic patients and cirrhotic animals. Such shunts were present in about one-third of cirrhotic patients with portal hypertension, and occurred mainly between the portal vein and hepatic veins. In cirrhotics, portohepatic anastomoses are usually large in diameter (more than 20 micron in diameter). Collagenization of the space of Disse and the progressive transformation of sinusoids into capillary-like channels decrease the extravascular space accessible to albumin and probably to other large molecules and protein-bound substances. However, unlike findings obtained in well-capillarized organs, these sinusoidal changes do not appear to limit the diffusion of sucrose, water, and lipophilic substances, such as lidocaine in the extravascular and intracellular spaces. The pattern observed for labeled sucrose curves following hepatic artery injection in cirrhotic patients could be secondary to the passage through the dense peribiliary capillary plexus originating from the enlarged arterial bed in cirrhosis. The difference in the perfusion of cirrhotic nodules with regard to the portal venous and hepatic artery routes introduces important new concepts in the overall mechanism of the elimination of endogenous and exogenous substances by the cirrhotic liver: blood entering the liver by the two afferent vessels will not flow through the same vascular bed before reaching the efferent hepatic veins.     

Increase in renal magnesium overflow following aortotomy-induced hemorrhage in pigs.

Hemorrhage causes an increase in plasma Mg++ levels. This article identifies some of the tissues contributing to the hemorrhage induced increase in plasma Mg++. Anesthetized, splenectomized pigs were subjected to a 5 mm aortotomy. Blood samples from the abdominal aorta, inferior vena cava, pulmonary artery, hepatic portal vein, and renal vein were sampled for Mg++ changes caused by this uncontrolled hemorrhage. Aortotomy produced a rapid drop in arterial pressure and cardiac output, both of which remained depressed for the following 120 minutes (P less than 0.05). By 120 minutes, 6 of the 8 pigs survived, but three of the six survivors showed signs of cardiovascular decompensation. A significant increase in arterial plasma Mg++ was indicated by a paired t-test (P less than 0.05). Analysis of the venous samples also revealed a significant increase during the post-aortotomy period. Renal venous and hepatic portal venous plasmas both showed increases greater than that in the arterial plasma. The renal and splanchnic tissues, then, were partly responsible for the increase in the arterial Mg++ which follows hemorrhage.     

Performance of Doppler ultrasound in the prediction of severe portal hypertension in hepatitis C virus-related chronic liver disease.

PURPOSE: To evaluate the correlation between hepatic vein pressure gradient measurement and Doppler ultrasonography (DUS) in patients with chronic liver disease (CLD). PATIENTS AND METHODS: Sixty-six patients with fibrotic to cirrhotic hepatitis C virus-related CLD, were consecutively included upon referral to our haemodynamic laboratory. Superior mesenteric artery pulsatility index (SMA-PI), right interlobar renal and intraparenchymal splenic artery resistance indices, were determined, followed by hepatic venous pressure gradient (HVPG) measurement. RESULTS: A correlation was found between HVPG and intraparenchymal splenic artery resistance index (SA-RI) (r=0.50, P<0.0001), SMA-PI (r=-0,48, P<0.0001), right interlobar renal artery resistance index (RRA-RI) (r=0.51, P<0.0001) in the whole patient population. However, dividing patients according to the presence/absence of severe portal hypertension (i.e. HVPG > or =12 mmHg), a correlation between HVPG and intraparenchymal SA-RI (r=0.70, P<0.0001), SMA-PI (r=-0.49, P=0.02), RRA-RI (r=0.66, P=0.0002) was observed only for HVPG values <12 mmHg. HVPG but not DUS correlated with the presence of esophageal varices (P<0.0001). CONCLUSIONS: Superior mesenteric artery pulsatility index, intraparenchymal splenic and right interlobar renal artery resistance indices do not adequately predict severe portal hypertension.     

Impact of mesocaval shunt on safe minimal liver remnant:Porcine model

AIM: To investigate the capacity of shunts to relieve portal hypertension and decrease the safe minimal liver remnant in pigs.METHODS: A subtotal hepatectomy with < 60 mL blood loss and without hepatic pedicle occlusion was performed.The mesenteric venous inflow was diverted through a mesocaval shunt(MCS) constructed using the prepared left renal vein with an end-to-side running suture of 5-0 proline.All 21 animals that underwent subtotal hepatectomy and/or MCS were divided into three groups.In the 15% group,the residual volume was 14%-19% of total liver volume(TLV);in the 15%+ S group,the residual volume was also 14%-19% of TLV with a mesocaval shunt(MCS);and in the 10%+ S group,the residual volume was 8%-13% of TLV with an MCS.In the three groups,the intraoperative portal vein pressure(PVP) and portal vein flow(PVF) were monitored and compared at laparotomy and 1 h posthepatectomy.The survival rate,sinusoidal endothelial damage,tissue analysis,and serum analysis were investigated among the three groups.RESULTS: The percentage residual liver volume was 15.9%,16.1% and 11.8% in the 15%,15%+ S,10%+ S groups,respectively.After hepatectomy,PVF and portal-to-arterial flow ratio in the 15%+ S group significantly decreased and hepatic artery flow(HAF) per unit volume significantly increased,compared to those in the 15% group.The PVP in the 15%+ S group and 10%+ S group increased slightly from that measured at laparotomy;however,in the 15% group,the PVP increased immediately and significantly above that observed in the other two groups.The 14-d survival rates were 28.5%,85.6%,and 14.2% in the 15%,15%+ S,and 10%+ S groups,respectively.In the 15%+ S group,the shunts effectively attenuated injury to the sinusoidal endothelium,and the changes in the serum and tissue analysis results were significantly reduced compared to those in the 15% and 10%+ S groups.CONCLUSION: MCS can decompress the portal vein and so attenuate liver injury from hyperperfusion,and make extreme or marginal hepatectomy safer.     

Blockade of ATP-sensitive K+ channels by glibenclamide reduces portal pressure and hyperkinetic circulation in portal hypertensive rats.

Certain results of in vitro studies raise the possibility that blockade of ATP-sensitive K+ channels by glibenclamide may induce vasoconstriction. Therefore, this substance might decrease portal pressure and hyperkinetic circulation in animals with portal hypertension. Thus, systemic and regional hemodynamics (radioactive microspheres) were measured before and 20 min after a bolus intravenous injection of glibenclamide (20 mg/kg) in conscious rats with portal vein stenosis. Blood pressure decreased significantly from 14.5 +/- 1.5 to 12.2 +/- 1.2 (mean +/- SE). Cardiac index significantly decreased by 24%, portal tributary blood flow by 31%, and hepatic artery blood flow by 35%. Systemic vascular resistance significantly increased by 38%, portal territory vascular resistance and hepatic artery vascular resistance by 61%, each, and renal vascular resistance by 17%. Arterial pressure, heart rate, and renal blood flow were unchanged. Moreover, glibenclamide blunted the vasodilating action of diazoxide (an ATP-sensitive K+ channel opener). These results show that in rats with extrahepatic portal hypertension the blockade of ATP-sensitive K+ channels by glibenclamide reduces portal pressure and hyperkinetic circulation.     

Nitroglycerin improves the hemodynamic response to vasopressin in portal hypertension

This study was designed to investigate whether the addition of nitroglycerin to vasopressin infusion could avoid the deleterious systemic effects of vasopressin while maintaining or enhancing the therapeutic benefits of portal pressure reduction. The effect of nitroglycerin on splanchnic and systemic hemodynamics was studied in cirrhotic patients and portal hypertensive dogs receiving i.v. vasopressin. During i.v vasopressin infusion (0.4 units per min), the cardiac output decreased in patients by 14% from 7.6 +/- 0.9 (mean +/- S.E.) to 6.5 +/- 0.7 liters per min, p less than 0.01, the mean arterial pressure increased 21% from 87 +/- 2 to 105 +/- 4, p less than 0.01, and the heart rate decreased 11% from 79 +/- 3 to 71 +/- 3, p less than 0.01. The administration of sublingual nitroglycerin (0.4 mg) returned all the systemic hemodynamic parameters to baseline values. In dogs, vasopressin infusion significantly reduced portal pressure and flow while increasing portal venous resistance. Nitroglycerin when added to the vasopressin infusion reduced portal venous resistance and further decreased portal pressure in dogs. In patients, vasopressin reduced the hepatic blood flow (44%), wedged hepatic venous pressure (11%), and the gradient between wedged and free hepatic venous pressures (23%). Nitroglycerin administration caused a further reduction of the wedged hepatic venous pressure (23.6 +/- 2.3 to 21.1 +/- 2.0, 11%, p less than 0.01). There was a small but not significant further decline (7%) in the hepatic venous pressure gradient. These results provide evidence that the addition of nitroglycerin to an i.v. infusion of vasopressin reversed the detrimental effects of vasopressin while preserving the beneficial effects.     

Hepatic insulin resistance during canine sepsis

Glucose dyshomeostasis and insulin resistance are well-documented characteristics of sepsis. The insulin resistance could be manifested in a decreased peripheral glucose uptake and/or an increased hepatic glucose output. To investigate the hepatic and peripheral responses to insulin in a three-day model of sepsis, 14 mongrel dogs were studied. Animals were randomly assigned to a SEPTIC (n = 5), SHAM (n = 4), or CONTROL (n = 5) group. Sepsis was induced in anesthetized dogs via a midline laparotomy with subsequent placement of a fecal-soaked gauze sponge around intestines. SHAM and CONTROL dogs were pair-fed with the SEPTIC dogs. On the third day, animals were anesthetized, intubated, and ventilated. Via a left-side laparotomy, electromagnetic flow probes were placed to measure hepatic arterial and portal venous blood flows. Cannulas were placed in femoral, portal, and hepatic veins and femoral artery to measure hepatic outputs of glucose, lactate, and oxygen during hyperinsulinemic-euglycemic clamps ranging from 0.4 to 4,000 mU insulin/min. Portal venous insulin concentrations in SEPTIC animals were significantly increased compared to CONTROL animals during 0.4 and 4 mU insulin/min infusions. An insulin infusion rate of 40 mU/min significantly decreased net hepatic glucose output (NHGO) in CONTROL animals but did not affect NHGO in SHAM or SEPTIC animals. An insulin infusion rate of 4,000 mU/min significantly decreased NHGO in all groups. An attempt to analyze the ED50 of the three dose-response curves was inconclusive. Glucose infusion rates (GIR) increased during insulin infusion but the GIR were not different between groups at any insulin infusion rate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of hepatic nerves, norepinephrine, angiotensin, and elevated central venous pressure on postsinusoidal resistance sites and intrahepatic pressures in cats

Portal venous pressure was controlled by resistance localized to specific sites in hepatic lobar veins in cats. All of the pressure drop from the portal vein to the vena cava occurred across postsinusoidal vessels; portal pressure, lobar venous pressure, and, therefore, sinusoidal pressure were not significantly different. Norepinephrine and angiotensin infusions (intraportal) caused elevation in portal pressure due to constriction of hepatic venous resistance sites as well as some constriction of presinusoidal (portal or sinusoidal) resistance sites. At low doses of norepinephrine presinusoidal constriction dominated whereas at higher doses the postsinusoidal constriction increased proportionately more. Hepatic nerve stimulation produced a similar response measured at an early time (1 min), but by 3 min the presinusoidal constriction showed complete escape so that elevated portal pressure was entirely due to hepatic venous constriction. The same site that provided basal vascular resistance also provided the increased hepatic venous resistance with nerve stimulation and infusion of angiotensin and norepinephrine. Rapid elevation of central venous pressure (CVP) caused elevated sinusoidal pressure. At high CVP (16 mm Hg), 75% of a rise in CVP was transmitted whereas at normal CVP (less than 4.5 mm Hg) less than 20% transmission occurred. The presence of a high resistance in the hepatic veins protected intrahepatic pressure from the effects of normal fluctuation of CVP.     

Hepatic insulin resistance during chronic hyperdynamic sepsis.

Disturbances in normal glucose metabolism and homeostasis which manifest as hyperglycemia and glucose intolerance are often observed during clinical sepsis. Skeletal and myocardial muscle as well as whole body insulin resistance have been demonstrated in this laboratory and others during experimental and clinical sepsis. The existence of hepatic insulin resistance in sepsis has yet to be fully elucidated. This study was undertaken to assess hepatic insulin resistance during chronic hyperdynamic sepsis. Animals were randomly assigned to a septic (n = 7), sham (n = 7), or control (n = 7) group. Sepsis was induced in anesthetized dogs via a midline laparotomy whereby a fecal-soaked gauze sponge was placed amid the intestines. Sham animals underwent a laparotomy with mechanical manipulation of the intestines but no fecal implant. Control animals had no previous surgery. Sham and control dogs were pair-fed with the septic dogs. On postoperative day 7, after an overnight fast, animals were anesthetized, intubated, and ventilated. Via a left subcostal laparotomy, electromagnetic flow probes were placed to measure hepatic arterial and portal venous blood flows. Cannulae were placed in femoral, portal, and hepatic veins and femoral artery and used to calculate hepatic outputs of glucose, lactate, and oxygen during a basal period and hyperinsulinemic-euglycemic clamps which used intravenous insulin infusions which ranged from 0.4 to 4,000 mU/min. Mean arterial blood pressure decreased with increasing insulin concentrations in septic animals while no change was seen in control or sham animals. In control and sham animals, net hepatic glucose output (NHGO) decreased in response to increasing insulin levels. Septic animals showed no such inverse relationship and, moreover, showed no change in glucose output response to any insulin infusion, i.e., hepatic insulin unresponsiveness during sepsis. Net hepatic lactate output during basal pre-insulin period during sepsis was negative. This was in contrast to the positive outputs in control and sham animals. Glucose infusion rates (GIR) increased during insulin infusion but were not different between groups at any insulin infusion rate. These data demonstrated a hepatic insulin resistance (unresponsiveness) during chronic hyperdynamic, hypermetabolic sepsis.     

肝前性门静脉高压大鼠NO、CO与高动力循环的关系

目的 观察肝前性门静脉高压大鼠血中一氧化氮（NO）、碳氧血红蛋白（COHb)与血液循环动力指标的关系。方法 制作门静脉高压大鼠模型和假手术组模型。分别检测血中NO、COHb浓度，测定门静脉压力。血流和平均动脉压。结果 门静脉高压组大鼠血中NO、COHb浓度均较假手术组高，门静脉高压组大鼠门静脉压增高，门静脉血流减少及平均动脉压降低，血中NO、CO-Hb水平分别与门静脉压力呈正相关，与门静脉血流和平均动脉压呈负相关。结论 NO、一氧化碳（CO）的过度形成和释放对门静脉高压的形成和维持起重要作用。     

Deleterious effects of splanchnic congestion on hepatic energy metabolism following repeated portal triad cross-clamping in dogs

Thirty minutes of warm hepatic ischemia produced by portal triad cross-clamping was repeated five times at 30-minute intervals in three groups of five dogs each: Group A was subjected only to portal triad cross-clamping; Group B received simultaneous clamping of the celiac axis and the superior mesenteric artery; and Group C had a simultaneous splenojugular shunt. The arterial blood ketone body ratio (acetoacetate/beta-hydroxybutyrate: KBR), reflecting the NAD+/NADH ratio in liver mitochondria, decreased significantly after each cross-clamping in all groups. After the first declamping, there was no significant difference in the recovery rate of the KBR among the three groups. After the second declamping, the recovery rate in Group A decreased significantly compared with the rates of Groups B and C (P less than 0.05). After the fourth declamping, the recovery rate in Group B was significantly lower than that of Group C (P less than 0.05). The hepatic energy charge [(ATP + 1/2ADP)/(ATP + ADP + AMP)] 30 minutes after the fifth declamping decreased significantly to 0.75 +/- 0.01 in Group A, compared with 0.84 +/- 0.01 in Group C (P less than 0.01). The lactate and total free plasma amino acid levels in the arterial blood increased significantly in the order of Groups A, B, and C. It is suggested that the inflow of stagnant portal venous blood to ischemic liver impairs hepatic energy metabolism.