NO, but not CO, attenuates anaphylaxis-induced postsinusoidal contraction and congestion in guinea pig liver

The pathophysiology of the hepatic vascular response to anaphylaxis in guinea pig is not known. We studied effects of anaphylaxis on hepatic vascular resistances and liver weight in isolated perfused livers derived from guinea pigs sensitized with ovalbumin. We also determined whether nitric oxide (NO) or carbon monoxide (CO) modulates the hepatic anaphylaxis. The livers were perfused portally and recirculatingly at constant flow with diluted blood. With the use of the double-occlusion technique to estimate the hepatic sinusoidal pressure (Pdo), portal venous resistance (Rpv) and hepatic venous resistance (Rhv) were calculated. An antigen injection caused venoconstriction characterized by an increase in Rpv greater than Rhv and was accompanied by a large liver weight gain. Pretreatment with the NO synthase inhibitor NG-nitro-l-arginine methyl ester, but not the heme oxygenase inhibitor zinc protoporphyrin IX, potentiated the antigen-induced venoconstriction by increasing both Rpv and Rhv (2.2- and 1.2-fold increase, respectively). In conclusion, anaphylaxis causes both pre- and postsinusoidal constriction in isolated guinea pig livers. However, the increases in postsinusoidal resistance and Pdo cause hepatic congestion. Endogenously produced NO, but not CO, modulates these responses.     

Effects of Hct and norepinephrine on segmental vascular resistance distribution in isolated perfused rat livers

We studied the effects of blood hematocrit (Hct), blood flow, or norepinephrine on segmental vascular resistances in isolated portally perfused rat livers. Total portal hepatic venous resistance (Rt) was assigned to the portal (Rpv), sinusoidal (Rsinus), and hepatic venous (Rhv) resistances using the portal occlusion (Ppo) and the hepatic venous occlusion (Phvo) pressures that were obtained during occlusion of the respective line. Four levels of Hct (30%, 20%, 10%, and 0%) were studied. Rpv comprises 44% of Rt, 37% of Rsinus, and 19% of Rhv in livers perfused at 30% Hct and portal venous pressure of 9.1 cmH2O. As Hct increased at a given blood flow, all three segmental vascular resistances of Rpv, Rsinus, and Rhv increased at flow >15 ml/min. As blood flow increased at a given Hct, only Rsinus increased without changes in Rpv or Rhv. Norepinephrine increased predominantly Rpv, and, to a smaller extent, Rsinus, but it did not affect Rhv. Finally, we estimated Ppo and Phvo from the double occlusion maneuver, which occluded simultaneously both the portal and hepatic venous lines. The regression line analysis revealed that Ppo and Phvo were identical with those measured by double occlusion. In conclusion, changes in blood Hct affect all three segmental vascular resistances, whereas changes in blood flow affect Rsinus, but not Rpv or Rhv. Norepinephrine increases mainly presinusoidal resistance. Ppo and Phvo can be obtained by the double occlusion method in isolated perfused rat livers.     

Hepatic venoconstriction is involved in anaphylactic hypotension in rats

We determined the roles of liver and splanchnic vascular bed in anaphylactic hypotension in anesthetized rats and the effects of anaphylaxis on hepatic vascular resistances and liver weight in isolated perfused rat livers. In anesthetized rats sensitized with ovalbumin (1 mg), an intravenous injection of 0.6 mg ovalbumin caused not only a decrease in systemic arterial pressure from 120 +/- 9 to 43 +/- 10 mmHg but also an increase in portal venous pressure that persisted for 20 min after the antigen injection (the portal hypertension phase). The elimination of the splanchnic vascular beds, by the occlusions of the celiac and mesenteric arteries, combined with total hepatectomy attenuated anaphylactic hypotension during the portal hypertension phase. For the isolated perfused rat liver experiment, the livers derived from sensitized rats were hemoperfused via the portal vein at a constant flow. Using the double-occlusion technique to estimate the hepatic sinusoidal pressure, presinusoidal (R(pre)) and postsinusoidal (R(post)) resistances were calculated. An injection of antigen (0.015 mg) caused venoconstriction characterized by an almost selective increase in R(pre) rather than R(post) and liver weight loss. Taken together, these results suggest that liver and splanchnic vascular beds are involved in anaphylactic hypotension presumably because of anaphylactic presinusoidal contraction-induced portal hypertension, which induced splanchnic congestion resulting in a decrease in circulating blood volume and thus systemic arterial hypotension.     

Thromboxane A2 analogue contracts predominantly the hepatic veins in isolated canine liver

Thromboxane A₂ (TxA₂) is a potent vasoconstrictor and has been implicated as a mediator of liver diseases such as ischemic-reperfusion injury. We determined the effects of TxA₂ and the well-known hepatic venoconstrictor histamine, on the vascular resistance distribution and liver weight in isolated canine livers perfused with blood via the portal vein. The stable TxA₂ (STA₂; 20 μg, n=5) and histamine (5 μg, n=6) similarly increased the hepatic total vascular resistance, 2.5- and 2.4-fold, respectively. The increase in the hepatic venous resistance was significantly greater than that of the portal resistance (threefold vs. 1.9-fold for STA2; threefold vs. 1.8-fold for histamine). Predominant hepatic venoconstriction induced by both agents was confirmed in livers perfused in a reverse direction from the hepatic vein to the portal vein, as shown by marked precapillary vasoconstriction. STA2 transiently increased liver weight loss (−3.6 g/100g liver weight), followed by a gradual weight gain (9.0 g/100 g). Histamine caused a progressive weight gain (9.1 g/100 g). In conclusion, similar to histamine, TxA₂ constricts predominantly the hepatic vein in isolated canine livers.     

Involvement of platelet-activating factor and leukotrienes in anaphylactic segmental venoconstriction in ovalbumin sensitized guinea pig livers

The hepatic anaphylactic venoconstriction is partly involved in anaphylactic hypotension, and is characterized by significant post-sinusoidal constriction and liver congestion in guinea pigs. We determined what chemical mediators are involved in anaphylaxis-induced segmental venoconstriction and liver congestion in perfused livers isolated from ovalbumin sensitized guinea pigs. Livers were perfused portally and recirculatingly at constant flow with diluted blood. The sinusoidal pressure was measured by the double occlusion pressure (Pdo), and was used to determine the pre-sinusoidal (Rpre) and post-sinusoidal (Rpost) resistances. An antigen injection increased both the portal vein pressure and Pdo, resulting in 4.1- and 2.3-fold increases in Rpre and Rpost, respectively. Hepatic congestion was observed as reflected by liver weight gain. Pretreatment with TCV-309 (10microM, platelet-activating factor (PAF) receptor antagonist) or ONO-1078 (100microM, human cysteinyl-leukotriene (Cys-LT) receptor 1 antagonist), but not indomethacin (10microM, cyclooxygenase inhibitor), ketanserin (10microM, serotonin receptor antagonist), or diphenhydramine (100microM, histamine H1 antagonist), significantly attenuated this anaphylactic hepatic venoconstriction. Anaphylaxis-induced increases in Rpre and Rpost were significantly inhibited by TCV-309 (by 48%) and ONO-1078 (by 36%), respectively. Combined TCV-309 and ONO-1078 pretreatment exerted additive inhibitory effects on anaphylactic hepatic venoconstriction. Anaphylactic hepatic weight gain was converted to weight loss when post-sinusoidal constriction was attenuated. It is concluded that anaphylaxis-induced pre-sinusoidal constriction is mainly caused by PAF and the post-sinusoidal constriction by Cys-LTs in guinea pig livers.     

Hepatic venous resistance site in the dog: localization and validation of intrahepatic pressure measurements

Intrahepatic pressure (9.4 +/- 0.3 mmHg; 1 mmHg = 133.32 Pa), measured proximal to a hepatic venous resistance site, was insignificantly different from portal venous pressure (9.6 +/- 0.4 mmHg). This lobar venous pressure is not wedged hepatic venous pressure as it is measured from side holes in a catheter with a sealed tip. Validation of the lobar venous pressure measurement was done in a variety of ways and using different sizes and configurations of catheters. The site of hepatic venous resistance in the dog is localized to a narrow sphincterlike region about 0.5 cm in length and within 1-2 cm (usually within 1 cm) of the junction of the vena cava and hepatic veins. Sinusoidal and portal venous resistance appears insignificant in the basal state and large increases in liver blood volume (histamine infusion or passive vena caval occlusion) or large decreases in liver blood volume (passive vascular occlusion) do not alter the insignificant pressure gradient between portal and lobar venous pressures. Norepinephrine infusion (1.25 microgram X kg-1 X min-1 intraportal) and hepatic sympathetic nerve stimulation (10 Hz) led to a significantly greater rise in portal venous pressure than in lobar venous pressure, indicating some presinusoidal (and (or) sinusoidal) constriction and this indicates that lobar venous pressure cannot be assumed under all conditions to accurately reflect portal pressure. However, most of the rise in portal venous pressure induced by intraportal infusion of norepinephrine or nerve stimulation and virtually all of the pressure rise induced by histamine could be attributed to the postsinusoidal resistance site.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of hepatic venous sphincter contraction on transmission of central venous pressure to lobar and portal pressure

In dogs anesthetized with pentobarbital, central vena caval pressure (CVP), portal venous pressure (PVP), and intrahepatic lobar venous pressure (proximal to the hepatic venous sphincters) were measured. The objective was to determine some characteristics of the intrahepatic vascular resistance sites (proximal and distal to the hepatic venous sphincters) including testing predictions made using a recent mathematical model of distensible hepatic venous resistance. The stimulus used was a brief rise in CVP produced by transient occlusion of the thoracic vena cava in control state and when vascular resistance was elevated by infusions of norepinephrine or histamine, or by nerve stimulation. The percent transmission of the downstream pressure rise to upstream sites past areas of vascular resistance was elevated. Even small increments in CVP are partially transmitted upstream. The data are incompatible with the vascular waterfall phenomenon which predicts that venous pressure increments are not transmitted upstream until a critical pressure is overcome and then further increments would be 100% transmitted. The hepatic sphincters show the following characteristics. First, small rises in CVP are transmitted less than large elevations; as the CVP rises, the sphincters passively distend and allow a greater percent transmission upstream, thus a large rise in CVP is more fully transmitted than a small rise in CVP. Second, the amount of pressure transmission upstream is determined by the vascular resistance across which the pressure is transmitted. As nerves, norepinephrine, or histamine cause the hepatic sphincters to contract, the percent transmission becomes less and the distensibility of the sphincters is reduced. Similar characteristics are shown for the "presinusoidal" vascular resistance and the hepatic venous sphincter resistance.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of leukotrienes B4, C4, and D4 on segmental pulmonary vascular pressures

Leukotrienes (LTs) C4 and D4 are vasoconstrictors and are thought to increase both systemic and pulmonary vascular permeability. However, we and others have observed that LTC4 and LTD4 cause pulmonary vasoconstriction but do not increase the fluid filtration coefficient of excised guinea pig lungs perfused with a cell-depleted perfusate. To determine what vascular segments were exposed to an LT-induced increase in intravascular hydrostatic pressure we measured pulmonary arterial (Ppa), pulmonary arterial occlusion (Po,a), venous (Po,v) and double occlusion (Pdo) pressures in isolated guinea pig lungs perfused with a cell-depleted buffered salt solution before and after injecting 4 micrograms of LTB4, LTC4, or LTD4 into the pulmonary artery. All three LTs increased airway pressures and also increased Ppa, Po,a, and Pdo. Histamine (15 micrograms) as well as serotonin (20 or 200 micrograms) had the same effect. In excised rabbit lungs, histamine and serotonin increased only Ppa, and Po,a. LTC4 had no vasoactivity. There are marked species variations with regard to the activity and site of action of histamine, serotonin, and LTC4 on the pulmonary circulation.     

Segmental vascular resistances and compliances in dog lung

The segmental distribution of vascular resistances and compliances were evaluated in isolated blood perfused lung lobes using arterial, venous, and double-occlusion pressures and were compared with filtration midpoint capillary pressures (Pc,f). We separated total vascular resistance (RT) and compliance (CT) into large artery (Ra, Ca), large vein (Rv, Cv), and microvascular compartments (Rmc, Cmc) at base-line and increased vascular pressures and during infusions of histamine, serotonin, and norepinephrine. In control lobes, double-occlusion pressure (Pdo) closely approximated Pc,f at all vascular pressures. Pre- and postcapillary resistance were approximately equal when referenced to either Pc,f or Pdo. Although Rmc comprised 42% of RT and Cmc constituted 76% of CT, a twofold increase in base-line Pc,f caused RT to decrease to 67% and Rmc/RT to 29% of control values, whereas CT decreased to 87% and Cmc/CT decreased to 88% of control values over the same Pc,f range. Mean static CT was 2.25 +/- 0.09 ml X cmH2O-1. 100 g-1, whereas dynamic CT was 1.54 +/- 0.08 ml X cmH2O-1. 100 g-1, or only 68% of static vascular compliance. Drug infusions increased mean RT from 4.2- to 5.3-fold and significantly decreased both static and dynamic CT. Although all vascular segments were constricted, histamine affected primarily large veins, serotonin increased Ra greater than Rv, and norepinephrine constricted upstream and downstream vessels about equally. Increased Pc,f in the presence of these drugs decreased RT significantly in every case primarily through attenuation of the drug vasoconstrictor effect on Rmc and decreased CT primarily due to a decrease in Cmc, but increased Cmc/(Ca + Cv). Thus the microvascular compartment appears to be the major site of both fluid filtration and vascular compliance and contributes significantly to total vascular resistance. Drug infusions constricted large and small vessel compartments as defined here, but increased Pc,f attenuated microvascular vasoconstriction and to a lesser extent large vessel vasoconstriction resulting in a reduced microvascular resistance in both drug-treated and control lobes. This effect can be attributed to recruitment and/or distension of microvessels and distension of larger vessels.     

Role of beta-adrenergic agonists in the control of vascular capacitance

The role of beta-adrenergic agonists, such as isoproterenol, on vascular capacitance is unclear. Some investigators have suggested that isoproterenol causes a net transfer of blood to the chest from the splanchnic bed. We tested this hypothesis in dogs by measuring liver thickness, cardiac output, cardiopulmonary blood volume, mean circulatory filling pressure, portal venous, central venous, pulmonary arterial, and systemic arterial pressures while infusing norepinephrine (2.6 micrograms.min-1.kg-1), or isoproterenol (2.0 micrograms.min-1.kg-1), or histamine (4 micrograms.min-1.kg-1), or a combination of histamine and isoproterenol. Norepinephrine (an alpha- and beta 1-adrenergic agonist) decreased hepatic thickness and increased mean circulatory filling pressure, cardiac output, cardiopulmonary blood volume, total peripheral resistance, and systemic arterial and portal pressures. Isoproterenol increased cardiac output and decreased total peripheral resistance, but it had little effect on liver thickness or mean circulatory filling pressure and did not increase the cardiopulmonary blood volume or central venous pressure. Histamine caused a marked increase in portal pressure and liver thickness and decreased cardiac output, but it had little effect on the estimated mean circulatory filling pressure. Isoproterenol during histamine infusions reduced histamine-induced portal hypertension, reduced liver size, and increased cardiac output. We conclude that the beta-adrenergic agonist, isoproterenol, has little influence on vascular capacitance or liver volume of dogs, unless the hepatic outflow resistance is elevated by agents such as histamine.     

Active and passive liver microvascular responses from angiotensin, endothelin, norepinephrine, and vasopressin

Vasoconstrictor agents may induce a decrease in hepatic vascular volume passively, by decreasing distending pressure, or actively, by stimulating contractile elements of capacitance vessels. Hepatic venular resistance was estimated in anesthetized rabbits from hepatic venular pressure (P(mu hv); by servo-null micropipette), inferior vena cava pressure, and total hepatic blood flow (F(hv); by ultrasound flow probe). Changes in liver volume were estimated from measures of liver lobe thickness. Angiotensin (ANG) II, endothelin (ET)-1, norepinephrine (NE), and vasopressin (VP) were infused into the portal vein at a constant rate for 5 min. We conclude that ANG II and NE induced active constriction of hepatic capacitance vessels, because the liver lobe thickness decreased significantly even though P(mu hv) and portal venous distending pressure (P(pv)) increased. All four agents increased splanchnic and hepatic venous resistances in similar proportions. With VP, P(mu hv) and P(pv) decreased, but with ET-1, P(mu hv) and P(pv) increased. However, lobe thickness was not significantly changed by either drug during the infusion compared with the 2-min control period. Thus VP and ET-1 have only minor effects on hepatic capacitance vessels. ET-1, at 0.04 microg. min(-1). kg body wt(-1), caused an increase in systemic arterial blood pressure, but erythrocyte movement through the sinusoids in some animals stopped.     

Effects of chronic hypoxia on pulmonary vascular responses to biogenic amines

The effects of chronic hypoxia on pulmonary vascular resistance changes (% delta Rpv) to histamine, 5-hydroxytryptamine (5-HT), norepinephrine (NE), and KCl were studied in isolated perfused lungs from control rats and rats exposed to 7, 14, and 28 days of hypoxia. Histamine, which produced linear increases in % delta Rpv with increasing doses in the control, was reversed to vasodilation by chronic hypoxia of 7 and 14 days and at 28 days, vasodilation to this amine still predominated (7 out of 10). Control responses to 5-HT were unaltered by 7 days of hypoxia but enhanced at 14 and 28 days. Control responses to NE showed either vasoconstriction or vasodilation; at 7 days of hypoxia, NE had no significant vasoactivity; however, at 14 days, vasoconstriction and vasodilation were both observed, with vasodilation being more effective. Lastly, the pressor responses to KCl were not affected by chronic hypoxia of any duration. These results suggest that chronic hypoxia: 1) does not alter pulmonary vascular contractility (KCl); 2) reduces H1 and alpha-receptor activity while enhancing H2- and beta-receptor activity; and 3) enhances the pressor responses to 5-HT by increasing either the efficacy of this amine or the number of 5-HT vasoconstrictor receptors.     

A computational model of the hepatic circulation applied to analyze the sensitivity of hepatic venous pressure gradient (HVPG) in liver cirrhosis

Measurement of hepatic venous pressure gradient (HVPG) is currently widely adopted to provide an estimate of portal pressure gradient (PPG) in the diagnosis and treatment of portal hypertension associated with liver cirrhosis. Despite the well-documented clinical utility of HVPG, it remains poorly understood how the relationship between HVPG and PPG is affected by factors involved in the pathogenesis and progression of cirrhosis. In the study, a computational model of the hepatic circulation calibrated to in vivo data was developed to simulate the procedure of HVPG measurement and quantitatively investigate the error of HVPG relative to PPG under various pathophysiological conditions. Obtained results confirmed the clinical consensus that HVPG is applicable to the assessment of portal hypertension caused by increased vascular resistance located primarily at the sinusoidal and postsinusoidal sites rather than at the presinusoidal site. On the other hand, our study demonstrated that the accuracy of HVPG measurement was influenced by many factors related to hepatic hemodynamics even in the case of sinusoidal portal hypertension. For instance, varying presinusoidal portal vascular resistance significantly altered the difference between HVPG and PPG, while an enhancement in portosystemic collateral flow tended to improve the accuracy of HVPG measurement. Moreover, it was found that presinusoidal and postsinusoidal vascular resistances interfered with each other with respect to their influence on HVPG measurement. These findings suggest that one should take into account patient-specific pathological conditions in order to achieve a better understanding and utilization of HVPG in the clinical practice.     

Different accessibility from the artery and the portal vein of alpha- and beta-receptors involved in the sympathetic nerve action on glycogenolysis and hemodynamics in perfused rat liver

In perfused rat liver perivascular nerve stimulation (7.5 Hz, 20 V, 2 ms, 5 min) at the liver hilus caused an increase in glucose and lactate output and a decrease in flow. The influence of the alpha 1-receptor blocker prazosine and the beta-blocker propranolol on these nerve effects was studied in the isolated rat liver perfused classically via the portal vein only and, as developed recently, via both the hepatic artery and the portal vein. 1) In livers perfused via the portal vein only the nerve stimulation-dependent metabolic alterations were nearly completely inhibited by prazosine (5 microM), but not influenced by propranolol (10 microM). The hemodynamic changes were lowered to only 33% by prazosine and not altered by propranolol either. 2) In livers perfused via the hepatic artery (100 mm Hg, 20-40% of flow) and the portal vein (10 mm Hg, 80-60% of flow)--similar to portal perfusions--the nerve stimulation--dependent metabolic alterations were almost completely blocked by arterial, portal or simultaneously applied arterial and portal prazosine. However--in contrast to portal perfusions--the metabolic alterations were reduced to about 20% (glucose) and 50% (lactate) also by propranolol independently of its site of application. The decrease in flow was reduced by prazosine to about 60%, 50% and 30% when applied via the artery, the portal vein or via both vessels, respectively. The hemodynamic alterations were not influenced by propranolol. These results allow the following conclusions: A subpopulation of beta-receptors can play a permissive role in the alpha 1-receptor-mediated sympathetic nerve action on glucose and lactate metabolism.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of endothelin and vasopressin on portal pressure of rats

Endothelin is a vasoconstrictor peptide which has recently been isolated and sequenced from the vascular endothelial cells. It was reported to increase blood pressure in vivo and produce a prolonged contraction with a slow onset in vitro. The purpose of this study was to investigate whether endothelin can lower the portal pressure as another endogenous vasoconstriction peptidevasopressin (AVP) can. Heart rate, systemic blood pressure, portal pressure, and portal vein blood flow were measured. Effects of endothelin on these parameters were compared with those of AVP. Endothelin 10(-10) mol/Kg significantly decreased all of the parameters mentioned. At the higher dose (5 x 10(-10) mol/Kg), however, the portal pressure and blood pressure were increased and portal vein blood flow was unchanged. On the other hand, AVP decreased the portal pressure and portal vein blood flow but elevated the systemic blood pressure. In vitro experiments revealed that endothelin contracted both tail artery and portal vein of rat and vasopressin contracted only tail artery. We concluded that although both are endogenous vasoconstricting peptides, endothelin and AVP affect differently on arterial and venous vascular beds as well as on portal pressure.     

Validation of double vascular occlusion method for Pc,i in lung and skeletal muscle

Capillary pressures in isogravimetric lung and skeletal muscle measured with the double vascular occlusion technique (Pdo) were compared to those measured using the traditional gravimetric technique (Pc,i). Pressures were measured using both techniques in isolated blood-perfused canine lungs (n = 18), blood-perfused rat hindquarters before (n = 8) and after (n = 6) maximal dilatation with papaverine and in rat hindquarters perfused with an artificial plasma (n = 6). In both organs, regardless of vascular tone, the double vascular occlusion isogravimetric pressure was the same as the gravimetric Pc,i, and the two measurements were highly correlated. Lung: Pdo = -0.22 + 1.06 Pc,i (r = 0.85, P less than 0.01); hindquarter: Pdo = -1.03 + 0.99 Pc,i (r = 0.91, P less than 0.01). In addition, Pdo was the same at every combination of isogravimetric arterial and venous pressures tested. The results indicate that the more rapidly applied double vascular occlusion pressure yields an accurate measure of isogravimetric capillary pressure in isolated organs over a wide range of isogravimetric pressures.     

Hypoxia-induced alterations of norepinephrine vascular reactivity in isolated perfused cat lung

Past work in the isolated perfused cat lung has shown that acute hypoxia (H) changes the response to norepinephrine (NE) from vasoconstriction to vasodilation but has no effect on the response to serotonin (S). These results could be related to the increase in pulmonary arterial pressure or vascular resistance during the hypoxic pressor response or a direct effect of H. We addressed this question, in the same preparation, by comparing responses to NE under four conditions in each experimental animal (n = 12): 1) NE infused during normoxia; 2) NE infused after vascular resistance (Rpv) was increased with serotonin; 3) NE infused after Rpv was increased by H; 4) NE infused after lobar pressure was raised by an increase in flow (P/F). PO2 values during H were varied (27-56 Torr). S and H produced a 137 +/- 35 and 43 +/- 8% delta Rpv increase in lobar vascular resistance, respectively. P/F increased lobar pressure 91 +/- 10%. Only NE infusion during H demonstrated significant differences in lobar pressure and Rpv compared with control normoxic periods. There was no correlation between responses to NE during S, H, and P/F and degree to which each stimulus increased Rpv or lobar pressure (r = 0.003, 0.28, 0.24). A significant relationship between response to NE during H vs. PO2 during H was observed (r = 0.78; P less than 0.001). In a subset of animals, we repeated the infusion of NE during H and P/F post-beta-blockade. The decrease in vascular response to NE during H and the correlation of PO2 with NE response were abolished (n = 7).(ABSTRACT TRUNCATED AT 250 WORDS)     

The roles of mast cells and Kupffer cells in rat systemic anaphylaxis

Mast cells and other cells such as macrophages have been shown to mediate systemic anaphylaxis. We determined the roles of mast cells and Kupffer cells in hepatic and systemic anaphylaxis of rats. Roles of mast cells were examined by using the mast cell-deficient white spotting (Ws/Ws) rat; the Ws/Ws and wild type (+/+) rats were sensitized with ovalbumin (1 mg). Roles of Kupffer cells were examined by depleting Kupffer cells using gadolinium chloride or liposome-encapsulated dichloromethylene diphosphonate in the Ws/Ws and Sprague-Dawley rats. An intravenous injection of 0.6 mg ovalbumin caused substantial anaphylactic hypotension in both the Ws/Ws and +/+ rats; however, the occurrence was delayed in the Ws/Ws rats. After antigen, portal venous pressure increased by 13.1 cmH2O in the +/+ rats, while it increased only by 5.7 cmH2O in the Ws/Ws rats. In response to antigen, the isolated perfused liver of the Ws/Ws rats also showed weak venoconstriction, the magnitude of which was one tenth as large as that of the +/+ rats, indicating that hepatic anaphylaxis was primarily due to mast cells. In contrast, Kupffer cell depletion did not attenuate anaphylactic hepatic venoconstriction in isolated perfused livers. In conclusion, mast cells are involved mainly in anaphylactic hepatic presinusoidal portal venoconstriction but only in the early stage of anaphylactic systemic hypotension in rats. Macrophages, including Kupffer cells, do not participate in rat hepatic anaphylactic venoconstriction.     

Deficit in nitric oxide production in cirrhotic rat livers is located in the sinusoidal and postsinusoidal areas

Intrahepatic nitric oxide (NO) production is decreased in cirrhotic livers. Our objective was to identify, in cirrhotic rat livers, intrahepatic vascular segments where the deficit of NO facilitates the effect of vasoconstrictors. By using a modified rat liver perfusion system with measurement of both the perfusion and sinusoidal (wedged hepatic vein) pressures, we studied the effect of the NO synthase blocker N(omega)-nitro-l-arginine (l-NNA) on the response to methoxamine (alpha(1)-adrenoreceptor agonist) in different segments of the intrahepatic circulation of normal and cirrhotic rat livers. l-NNA enhanced the presinusoidal, sinusoidal, and postsinusoidal responses to methoxamine in normal livers as well as the presinusoidal response in cirrhotic livers. However, l-NNA did not change the already enhanced sinusoidal/postsinusoidal response to methoxamine in cirrhotic livers. The postsinusoidal response to methoxamine was higher in cirrhotic rats with ascites than in those without ascites. We concluded that NO modulates the presinusoidal, sinusoidal, and postsinusoidal vascular tone in normal livers. NO production in cirrhotic rat livers is severely impaired in the sinusoidal and postsinusoidal areas but is preserved in the presinusoidal area, as evidenced by its normal response to l-NNA. We speculate that an increased postsinusoidal response to catecholamines may participate in the genesis of ascites in cirrhosis.