Hemodynamic effects of vasopressin, alone and in combination with nitroprusside, in patients with liver cirrhosis and portal hypertension

Pulmonary Hypertension in Intensive Care Units: An Updated Review

Pulmonary hypertension (PH) is a condition associated with high morbidity and mortality. Patients with PH who require critical care usually have severe right ventricular (RV) dysfunction. Although different groups of PH have different etiologies, pulmonary vascular dysfunction is common in these groups. PH can lead to increased pulmonary artery pressure, which can ultimately cause RV failure. Clinicians should be familiar with the presentations of this disease and diagnostic tools. The contributing factors, if present (e.g., sepsis), and coexisting conditions (e.g., arrhythmias) should be identified and addressed accordingly. The preload should be optimized by fluid administration, diuretics, and dialysis, if necessary. On the other hand, the RV afterload should be reduced to improve the RV function with pulmonary vasodilators, such as prostacyclins, inhaled nitric oxide, and phosphodiesterase type 5 inhibitors, especially in group 1 PH. Inotropes are also used to improve RV contractility, and if inadequate, use of ventricular assist devices and extracorporeal life support should be considered in suitable candidates. Moreover, vasopressors should be used to maintain systemic blood pressure, albeit cautiously, as they increase the RV afterload. Measures should be also taken to ensure adequate oxygenation. However, mechanical ventilation is avoided in RV failure. In this study, we reviewed the pathophysiology, manifestations, diagnosis, monitoring, and management strategies of PH, especially in intensive care units.

Effects of vasopressin during a pulmonary hypertensive crisis induced by acute hypoxia in a rat model of pulmonary hypertension

BACKGROUND

A pulmonary hypertensive crisis (PHC) can be a life-threatening condition. We established a PHC model by exposing rats with monocrotaline (MCT)-induced pulmonary hypertension to acute hypoxia, and investigated the effects of vasopressin, phenylephrine, and norepinephrine on the PHC.

METHODS

Four weeks after MCT 60 mg kg^-1 administration i.v., right ventricular systolic pressure (RVSP), systolic BP (SBP), mean BP (MBP), cardiac index (CI), and pulmonary vascular resistance index (PVRI) were measured. PHC defined as an RVSP exceeding or equal to SBP was induced by changing the fraction of inspiratory oxygen to 0.1. Rats were subsequently treated by vasopressin, phenylephrine, or norepinephrine, followed by assessment of systemic haemodynamics, isometric tension of femoral and pulmonary arteries, cardiac function, blood gas composition, and survival.

RESULTS

PHC was associated with increased RV dilatation and paradoxical septal motion. Vasopressin increased MBP [mean (standard error)] from 52.6 (3.8) to 125.0 (8.9) mm Hg and CI from 25.4 (2.3) to 40.6 (1.8) ml min^-1 100 g^-1 while decreasing PVRI. Vasopressin also improved RV dilatation, oxygenation, and survival in PHC. In contrast, phenylephrine increased MBP from 54.8 (2.3) to 96.8 (3.2) mm Hg without improving cardiac pump function. Norepinephrine did not alter MBP. Vasopressin contracted femoral but not pulmonary arteries, whereas phenylephrine contracted both arterial beds. Hence, improvements with vasopressin in PHC might be associated with decreased PVRI and selective systemic vasoconstriction.

CONCLUSIONS

In this rat model of a PHC, vasopressin, but not phenylephrine or norepinephrine, resulted in better haemodynamic and vascular recovery.

The differential effects of systemic vasoconstrictors on human pulmonary artery tension

OBJECTIVES

Acute pulmonary hypertension following cardiac surgery can have a significant effect on postoperative morbidity and mortality. However, limited data are available on the efficacy and potency of clinically used systemic vasopressors on the pulmonary vasculature. The aim of this study was to use human pulmonary artery to characterize the pharmacological effects of clinically used vasopressors on the human pulmonary vasculature.

METHODS

Fifty-seven pulmonary artery rings of internal diameter 2-4 mm and 2 mm long, mounted in a multiwire myograph system, were used to measure changes in isometric tension. We constructed concentration response curves by cumulative addition to the myograph chambers of KCl, noradrenaline (NA), adrenaline (AD), vasopressin, endothelin-1 (ET-1) and prostaglandin F2a (PGF2a).

RESULTS

AD, NA, ET-1, PGF2a and KCl caused dose-dependent vasoconstriction in the pulmonary artery samples (EC50 246 nM [95% confidence interval, CI, 153-394 nM], 150 nM [95% CI 51-447 nM], 1.46 nM [95% CI 0.69-3.1 nM], 6.35 µM [95% CI 3.58-11.2 µM] and 17.24 mM [95% CI 12.43-24.07 mM], respectively), whereas vasopressin had no significant effect. The order of efficacy was KCl = PGF2a > AD > NA > ET-1 and the order of potency was ET-1 T-AD = NA > PGF2a > KCl.

CONCLUSIONS

This study demonstrated the efficacy and potency of clinically used vasopressors and endogenous vasopressors on human pulmonary vascular tone. PGF2a and KCl equally caused maximal amounts of constriction, whereas ET-1 had less effect and vasopressin had no effect. These effects may need to be taken into account in the clinical setting because they might result in the development of pulmonary hypertension.

Hospital and intensive care unit management of decompensated pulmonary hypertension and right ventricular failure

Pulmonary hypertension and concomitant right ventricular failure present a diagnostic and therapeutic challenge in the intensive care unit and have been associated with a high mortality. Significant co-morbidities and hemodynamic instability are often present, and routine critical care unit resuscitation may worsen hemodynamics and limit the chances of survival in patients with an already underlying poor prognosis. Right ventricular failure results from structural or functional processes that limit the right ventricle’s ability to maintain adequate cardiac output. It is commonly seen as the result of left heart failure, acute pulmonary embolism, progression or decompensation of pulmonary hypertension, sepsis, acute lung injury, or in the perioperative setting. Prompt recognition of the underlying cause and institution of treatment with a thorough understanding of the elements necessary to optimize preload, cardiac contractility, enhance systemic arterial perfusion, and reduce right ventricular afterload are of paramount importance. Moreover, the emergence of previously uncommon entities in patients with pulmonary hypertension (pregnancy, sepsis, liver disease, etc.) and the availability of modern devices to provide support pose additional challenges that must be addressed with an in-depth knowledge of this disease.

Vasoconstrictor responses to vasopressor agents in human pulmonary and radial arteries: an in vitro study

BACKGROUND

Vasopressor drugs, commonly used to treat systemic hypotension and maintain organ perfusion, may also induce regional vasoconstriction in specialized vascular beds such as the lung. An increase in pulmonary vascular tone may adversely affect patients with pulmonary hypertension or right heart failure. While sympathomimetics constrict pulmonary vessels, and vasopressin does not, a direct comparison between these drugs has not been made. This study investigated the effects of clinically used vasopressor agents on human isolated pulmonary and radial arteries.

METHODS

Isolated pulmonary and radial artery ring segments, mounted in organ baths, were used to study the contractile responses of each vasopressor agent. Concentration-response curves to norepinephrine, phenylephrine, metaraminol, and vasopressin were constructed.

RESULTS

The sympathomimetics norepinephrine, phenylephrine, and metaraminol caused concentration-dependent vasoconstriction in the radial (pEC50: 6.99 ± 0.06, 6.14 ± 0.09, and 5.56 ± 0.07, respectively, n = 4 to 5) and pulmonary arteries (pEC50: 6.86 ± 0.11, 5.94 ± 0.05 and 5.56 ± 0.09, respectively, n = 3 to 4). Vasopressin was a potent vasoconstrictor of the radial artery (pEC50 9.13 ± 0.20, n = 3), whereas in the pulmonary artery, it had no significant effect.

CONCLUSIONS

Sympathomimetic-based vasopressor agents constrict both human radial and pulmonary arteries with similar potency in each. In contrast, vasopressin, although a potent vasoconstrictor of radial vessels, had no effect on pulmonary vascular tone. These findings provide some support for the use of vasopressin in patients with pulmonary hypertension.

Pulmonary vascular and right ventricular dysfunction in adult critical care: current and emerging options for management: a systematic literature review

INTRODUCTION

Pulmonary vascular dysfunction, pulmonary hypertension (PH), and resulting right ventricular (RV) failure occur in many critical illnesses and may be associated with a worse prognosis. PH and RV failure may be difficult to manage: principles include maintenance of appropriate RV preload, augmentation of RV function, and reduction of RV afterload by lowering pulmonary vascular resistance (PVR). We therefore provide a detailed update on the management of PH and RV failure in adult critical care.

METHODS

A systematic review was performed, based on a search of the literature from 1980 to 2010, by using prespecified search terms. Relevant studies were subjected to analysis based on the GRADE method.

RESULTS

Clinical studies of intensive care management of pulmonary vascular dysfunction were identified, describing volume therapy, vasopressors, sympathetic inotropes, inodilators, levosimendan, pulmonary vasodilators, and mechanical devices. The following GRADE recommendations (evidence level) are made in patients with pulmonary vascular dysfunction: 1) A weak recommendation (very-low-quality evidence) is made that close monitoring of the RV is advised as volume loading may worsen RV performance; 2) A weak recommendation (low-quality evidence) is made that low-dose norepinephrine is an effective pressor in these patients; and that 3) low-dose vasopressin may be useful to manage patients with resistant vasodilatory shock. 4) A weak recommendation (low-moderate quality evidence) is made that low-dose dobutamine improves RV function in pulmonary vascular dysfunction. 5) A strong recommendation (moderate-quality evidence) is made that phosphodiesterase type III inhibitors reduce PVR and improve RV function, although hypotension is frequent. 6) A weak recommendation (low-quality evidence) is made that levosimendan may be useful for short-term improvements in RV performance. 7) A strong recommendation (moderate-quality evidence) is made that pulmonary vasodilators reduce PVR and improve RV function, notably in pulmonary vascular dysfunction after cardiac surgery, and that the side-effect profile is reduced by using inhaled rather than systemic agents. 8) A weak recommendation (very-low-quality evidence) is made that mechanical therapies may be useful rescue therapies in some settings of pulmonary vascular dysfunction awaiting definitive therapy.

CONCLUSIONS

This systematic review highlights that although some recommendations can be made to guide the critical care management of pulmonary vascular and right ventricular dysfunction, within the limitations of this review and the GRADE methodology, the quality of the evidence base is generally low, and further high-quality research is needed.

Use of vasopressin after Caesarean section in idiopathic pulmonary arterial hypertension

We report the successful use of vasopressin in the management of hypotension in association with severe right ventricular (RV) failure in two patients with advanced idiopathic pulmonary arterial hypertension. Both patients were pregnant and developed systemic hypotension after delivery by Caesarean section. Placental autotransfusion and possibly oxytocin use were thought to be the major contributing factors in worsening RV function. After the use of vasopressin in both patients, cardiovascular variables improved without untoward effect on RV function, and provided rescue therapy for systemic hypotension in this setting. Vasopressin, a direct vasopressor acting via V1 receptors on the vascular endothelium, has been shown to cause pulmonary vasodilatation experimentally and in animal models of pulmonary hypertension. Its synthetic analogue, terlipressin, has been shown to reduce pulmonary vascular resistance in humans with cirrhosis. Vasopressin may therefore have differential effects on the pulmonary and systemic circulations, allowing systemic pressure to be supported without detrimental effects on the pulmonary circulation.

The future treatment of portal hypertension

Increased understanding of the hyperdynamic circulation syndrome has resulted in novel therapeutic approaches, some of which have already reached clinical practice. Central to the hyperdynamic circulation syndrome is an imbalance between the increase in different vasodilators (foremost among which is nitric oxide) and the compensatory increase in vasoconstrictors--usually accompanied by a blunted response. This chapter discusses the role of endothelin in the pathogenesis of the syndrome and in future treatment approaches. A relatively new area of research in this field is the role of infection and inflammation in the initiation and maintenance of the hyperdynamic circulation syndrome. The use of antibiotics in the setting of acute variceal bleeding is standard practice. Studies have suggested that chronic manipulation of the intestinal flora could have beneficial effects in the treatment of portal hypertension. The bile salts are another novel and interesting target. Although their vasoactive properties have been known for some time, recent data demonstrate that their effects could be central in the pathogenesis of the hyperdynamic circulation syndrome, and that manipulation of the composition of the bile acid pool could be a therapeutic approach to portal hypertension. Finally, hypoxia and angiogenesis play a role in the development of portal hypertension and the formation of collaterals. This role needs to be further defined but it appears likely that this phenomenon is yet another target for therapeutic intervention.

Haemodynamic effects of combined treatment with molsidomine and propranolol on portal hypertension in conscious and unrestrained cirrhotic rats

We investigated the systemic and splanchnic haemodynamic effects of combined treatment with molsidomine and propranolol on cirrhotic rats. Liver cirrhosis was produced by repeated intraperitoneal injections of thioacetamide. The blood flow of each organ was measured serially using the radioactive microsphere method in the awake state before and after the administration of each agent. Cirrhotic rats received molsidomine (0-.5 mg/kg), propranolol (0.1 or 0.2 mg/min), both agents or placebo. Combination treatment with molsidomine and 0.1 mg/min propranolol significantly reduced portal pressure compared with molsidomine or propranolol alone (21 +/- 4 vs 15 +/- 3 or 11 +/- 2% P < 0.05). Systemic haemodynamic changes with this combined treatment were mild. This combined treatment slightly inhibited the molsidomine-induced decrease in portal vascular resistance (27 +/- 9 vs 31 +/- 6; NS) and markedly inhibited the molsidomine-induced decrease in splanchnic arterial resistance (7 +/- 6 vs 27 +/- 5% P < 0.05). Compared with low-dose propranolol administration, the combined treatment was associated with a significant decrease in portal vascular resistance (27 +/- 9% decrease vs 2 +/- 2% increase; P < 0.001) and a significant decrease in splanchnic arterial resistance (7 +/- 6% decrease vs 5 +/- 4% increase P < 0.05). The combination of molsidomine and high-dose propranolol (0.2 mg/min) caused a marked reduction in portal venous inflow, mean arterial pressure and cardiac index. We conclude that propranolol enhances the molsidomine-induced decrease in portal pressure by splanchnic vasoconstriction in association with a slight decrease in portal vascular resistance. The combination therapy with molsidomine and low-dose propranolol combination had more beneficial and less harmful effects on systemic and splanchnic haemodynamics and thus appears to be a superior method for treating portal hypertension.

Response of blood flow to vasopressin in the collateral left gastric vein in patients with portal hypertension

BACKGROUND/AIMS

A problem in pharmacotherapy for bleeding varices in portal hypertension is non-responders. The aim of this study was to elucidate the features of hemodynamic response to vasopressin in the gastroesophageal collateral vein in patients with esophageal varices.

METHODS

Flow velocity in the portal and the collateral left gastric vein was measured with an echo-Doppler flowmeter before and during infusion of vasopressin, 0.2 U/min, in 41 patients with cirrhosis and esophageal varices.

RESULTS

The decrease in flow velocity in the left gastric vein with vasopressin (-29 +/- 25%) was significantly smaller than that in the portal vein (-56 +/- 20%). There was no or only minimal change in flow velocity in the left gastric vein in 39% of the patients, especially in those with large-size varices. In 28 patients examined by portal catheterization, changes in flow velocity in the left gastric vein were correlated with portal pressure, and portal pressure in non-responders was significantly higher than that in responders (non-responders: 363 +/- 49, responders: 312 +/- 41 mmH2O, p < 0.05).

CONCLUSIONS

It was concluded that hepatofugal blood flow in the gastroesophageal collateral is not readily reduced by vasopressin. However, as the study was performed in a stable condition without variceal bleeding, whether these hemodynamic features will apply during acute variceal bleeding in patients who are known to have a poor hemodynamic response to vasopressin remains to be elucidated.

Hemodynamic effects of combined treatment with somatostatin analogue (SMS 201-995) and low-dose isosorbide dinitrate on portal hypertension in conscious cirrhotic rats

The authors investigated whether combined treatment with the somatostatin analogue, SMS 201-995, and low-dose isosorbide dinitrate enhanced the hemodynamic effects of the individual agents on rats with thioacetamide-induced cirrhosis. Four groups of cirrhotic rats received SMS 201-995 (0.1 microgram.min-1.kg-1), isosorbide dinitrate (10 micrograms.min-1.kg-1), both agents, or placebo, respectively. Hemodynamics were measured serially in conscious rats, using a radioactive microsphere method. SMS 201-995 reduced portal venous inflow 21 +/- 4% and portal pressure 17 +/- 3%. Isosorbide dinitrate decreased portal venous inflow 20 +/- 4%, by inducing splanchnic vasoconstriction mediated by low pressure baroreflexes, and this agent also decreased portal pressure, by 14 +/- 2%. Portal venous resistance rose 7.6 +/- 3% with isosorbide dinitrate alone, but decreased 18 +/- 4% with combination therapy. This effect may have been induced by the pronounced vasodilatory effect of isosorbide dinitrate on the venous vasculature, since the reflex splanchnic vasoconstriction that occurs with low-dose isosorbide dinitrate disappears when this agent is combined with SMS 201-995. The decrease in portal pressure was more marked (22 +/- 4%) and changes in systemic hemodynamics were milder with the combined treatment. It was concluded that combination therapy with SMS 201-995 and low-dose isosorbide dinitrate may be beneficial for portal hypertension in liver cirrhosis.

Balloon tamponade and vasoactive drugs in the control of acute variceal haemorrhage

Successful pharmacological arrest of haemorrhage might avoid the risk of aspiration associated with tamponade and early studies have suggested that the vasoactive agent somatostatin may be as effective and perhaps safer than tamponade in controlling variceal haemorrhage. In our view, vasopressin has not established a role in management but we retain an open mind regarding the potential use of terlipressin in combination with nitroglycerin. It is unlikely that any of these agents can improve significantly our ability to control variceal haemorrhage when compared to balloon tamponade but they may reduce the incidence of pulmonary complications and thereby reduce subsequent mortality. Tamponade has proved successful in controlling acute haemorrhage from oesophageal varices in our hands. Late complications continue to give cause for concern but until effective safe alternatives to tamponade are developed, we continue to advocate its use for emergency control of acute variceal haemorrhage. Our own studies have shown that the high mortality seen in this patient population may reflect the severity of the underlying liver disease rather than failure of a management policy employing oesophageal tamponade for the initial control of acute variceal haemorrhage.

Long-term haemodynamic effects of a 4-week regimen of nipradilol, a new beta-blocker with nitrovasodilating properties, in patients with portal hypertension due to cirrhosis. A comparative study with propranolol

To study the long-term effects of pharmacological combination therapy, a comparison was made of the haemodynamic changes in patients with cirrhosis and portal hypertension following a 4-week treatment of propranolol or nipradilol, a new nonselective beta-blocker with nitrovasodilating effect. Nipradilol (12 mg/dag, n = 12) significantly diminished wedged hepatic venous pressure (WHVP, 25 +/- 16%), the hepatic venous pressure gradient (HVPG, 20 +/- 12%), and estimated hepatic blood flow (EHBF, 18 +/- 16%). Propranolol (30 mg/day, n = 11) also caused a significant reduction in WHVP (22 +/- 21%) and HVPG (24 +/- 21%), but not in EHBF. The percentage of portal pressure reduction and the frequency of nonresponders did not differ between the nipradilol and propranolol groups. Both agents reduced heart rate by approx. 20%. Nipradilol, however, did not cause a significant reduction in cardiac index (CI) versus a 14% reduction by propranolol. Pulmonary capillary wedge pressure and central venous pressure, an index of preload, were decreased slightly in the nipradilol group. When nonresponders were excluded, there was a significant correlation of the percentage of reduction between WHVP and CI or systemic vascular resistance, in the nipradilol group. These results indicate that nipradilol may have potent hypotensive effects on portal hypertension, similar but not superior to propranolol. Nipradilol, at the dosage used in the present study, did not appear to exert a nitrovasodilating effect to enhance the portal pressure reduction induced by beta-blocking action.

Effects of vaso-active agents on hepatic function and blood gases in patients with cirrhosis: a study of vasopressin and nitroglycerin

The effects of vaso-active agents on hepatic function and splanchnic oxygenation were studied in 17 patients with cirrhosis and portal hypertension. Eight patients received vasopressin (0.3 iu/min) and nine patients received nitroglycerin (50 micrograms/min). Both drugs caused a significant reduction in the portal venous pressure gradient. Vasopressin infusion significantly decreased intrinsic clearance of indocyanine green (-23%, P less than 0.01). This may be due to a decreased hepatic perfusion (-28%, P less than 0.01) and portal venous oxygenation (-15% in portal venous oxygen tension, P less than 0.05). In contrast, no changes in hepatic perfusion and portal venous oxygenation were observed after nitroglycerin infusion. Nitroglycerin did not decrease intrinsic clearance of indocyanine green. These results suggest that vasodilators, rather than vasoconstrictors, might be welcome in the treatment of patients with cirrhosis and portal hypertension.

The use of vasopressin in the treatment of upper gastrointestinal haemorrhage

Vasopressin is a potent vasoconstrictor which greatly reduces mesenteric blood flow. In patients with portal hypertension this results in decreased portal venous flow and portal pressure. Because of this property, vasopressin has been used for years in the therapy of variceal haemorrhage. A few controlled trials show that vasopressin causes a decrease in bleeding but has no effect on survival. It has been shown that intravenous vasopressin is just as effective as intra-arterial, and is associated with fewer complications. The inability to influence the outcome of variceal haemorrhage significantly may be related to suboptimal dosing due to the occurrence of systemic complications at higher doses. The combination of vasopressin with either sodium nitroprusside or nitroglycerin (glyceryl trinitrate) has resulted in a further decline of portal pressure, along with amelioration of most of the adverse haemodynamic effects of vasopressin. Whether or not clinical efficacy is increased when vasopressin is combined with sodium nitroprusside or nitroglycerin remains to be proven. Analogues of vasopressin, such as terlipressin, held early promise as agents which would be as effective as vasopressin, without the cardiac adverse effects. Recent data have not supported this and at present there is little to suggest any advantage of terlipressin over vasopressin. Virtually no adequate studies have yet been performed to support the use of vasopressin in the treatment of non-variceal haemorrhages. There is reason to suspect that vasopressin can effectively control bleeding from haemorrhagic gastritis, but the subsequent results of inducing gastric ischaemia in an already damaged gastric mucosa are unknown. In summary, vasopressin appears to have little effect on the mortality of patients with variceal haemorrhage. It may, however, help control the haemorrhage in some patients by lowering the portal pressure. Cardiovascular complications limit the dose that can be used but it is hoped that by combining vasopressin with nitroglycerin, a more effective and safe therapy will be available for variceal haemorrhages.

Vasopressin lowers pulmonary artery pressure in hypoxic rats by releasing atrial natriuretic peptide

The authors previously demonstrated that arginine vasopressin (AVP) lowers pulmonary artery pressure in rats with hypoxic pulmonary hypertension by activation of the V1 receptor. The pulmonary depressor effect of AVP in hypoxia-adapted rats is not due to its effect on cardiac output. The current study tested two alternative hypotheses: that AVP lowers pulmonary artery pressure in the hypoxia-adapted lung by (1) dilating pulmonary vasculature directly, or (2) releasing atrial natriuretic peptide (ANP) from the heart. The first hypothesis was tested by injecting AVP into the pulmonary arteries of isolated, buffer perfused lungs and monitoring pulmonary artery pressure, and by exposing preconstricted pulmonary artery rings to graded doses of AVP and monitoring the tension generated. AVP caused minimal vasodilation in perfused lungs and only a small vasodilator effect in pulmonary artery rings. The second hypothesis was tested by injecting AVP (160 ng/kg) or vehicle intravenously in conscious hypoxia-adapted (4 weeks) or air control rats and measuring ANP in arterial blood and atria, and by testing pretreatment with the V1 receptor antagonist d(CH2)5 Tyr(Me)AVP (130 micrograms/kg) on the AVP-induced increase in plasma ANP. AVP produced a 7-fold increase in plasma ANP (209 +/- 33 to 1346 +/- 233 pg/ml; p less than 0.05) in hypoxia-adapted rats and a 5-fold increase in ANP (122 +/- 22 to 573 +/- 174 pg/ml; p less than 0.05) in air controls. ANP release was abolished by pretreatment of both groups with d(CH2)5 Tyr(Me)AVP. The AVP-induced ANP release came mainly from left atrium. These data strongly suggest that the pulmonary depressor effects of AVP in hypoxia-adapted rats is due to augmented V1 receptor-induced release of ANP from left atrium.

Review: the pharmacological control of variceal bleeding

The haemodynamic effects and clinical uses of drugs used in the management of patients with oesophageal variceal bleeding are reviewed. Vasoconstrictor agents (vasopressin, teripressin) alone or in combination with nitrates continue to be used for acute bleeding episodes, while somatostatin is an alternative. Alpha- and beta-adrenergic blocking drugs and vasodilators which lead to a sustained decrease in portal pressure can be used for the prevention of bleeding episodes, but despite numerous studies the pharmacological treatment of variceal bleeding remains controversial.

Haemodynamic responses to 1.25 and 2 mg of terlipressin intravenously in man

The systemic and hepatic haemodynamic effects following terlipressin (Glypressin) administration were studied. Bolus intravenous injections of 1.25 and 2 mg significantly decreased wedged hepatic vein pressure gradient by 29% and 31%, respectively. With each dose there was a small increase in mean arterial blood pressure but after 1.25 mg of terlipressin, estimated hepatic blood flow fell by only 11% (not significant) compared to 24% after 2 mg, while the cardiac index fell by 12% compared to 29%. The adverse haemodynamic effects of terlipressin were diminished by a decrease in dosage, without any alteration in the beneficial effect of the drug upon portal pressure. Whether the smaller dose will be effective in arresting variceal haemorrhage remains to be determined.

Lack of vasopressin action on splanchnic hemodynamics during bleeding: a study in conscious, portal hypertensive rats

Due to the marked effects of hemorrhage on cardiac output and splanchnic hemodynamics, the circulatory actions of vasopressin may differ during bleeding as opposed to stable conditions. We evaluated this hypothesis in conscious rats with portal hypertension due to chronic portal vein stenosis, by comparing the effects of a vasopressin infusion (0.02 IU per kg per min) to those of a control saline infusion, during and after a hypotensive hemorrhage (25 ml per kg). We also studied unbled portal hypertensive rats receiving an identical infusion of vasopressin or saline. During and after hemorrhage, vasopressin induced significant changes in systemic hemodynamics but had no effect on portal pressure, portal tributary blood flow and nonhepatic splanchnic arteriolar resistance. In unbled animals, by contrast, vasopressin decreased portal pressure and portal tributary blood flow and increased nonhepatic splanchnic arteriolar resistance. Our data further indicate that hemorrhage alone caused an early vasoconstriction in the portal tributaries and a delayed vasoconstriction in the nonsplanchnic vascular bed while vasopressin during hemorrhage induced an early and sustained vasoconstriction in the nonsplanchnic vascular bed as well as in the portal tributaries. The results show that, during and after severe bleeding, vasopressin exerts little influence on portal hemodynamics. Although these data do not allow firm conclusions concerning the therapeutic efficacy of vasopressin in bleeding esophageal varices, they demonstrate that the splanchnic actions of vasoactive substances cannot be readily extrapolated from stable conditions to hemorrhage.

Direct portacaval anastomoses are safe and effective in patients with previous abdominal operations

Direct side-to-side portacaval anastomosis is employed exclusively in our institution to control variceal hemorrhage regardless of previous operative history. A consecutive, unselected group of 152 such patients was reviewed to ascertain the effect of previous major abdominal operation on operative difficulty and outcome. Fifty patients, with previous operations ranging from biliary and gastric procedures to thrombosed distal splenorenal shunts, were compared with 102 previously unoperated patients. This comparison led to the conclusions that side-to-side direct portacaval anastomosis may be carried out in patients with a previous major abdominal operation without an increased risk in mortality or morbidity, and that although intraoperative blood loss and transfusion requirements were increased in previously operated patients, these factors (along with operative time) could be minimized by use of intraoperative vasopressin and electrocautery. Thus, alternative shunting procedures, with their increased thrombosis and rebleeding rates, need not be considered in such patients.

Verapamil favorably influences hepatic microvascular exchange and function in rats with cirrhosis of the liver

The effect of the calcium channel blocking agent, verapamil, on microcirculatory patterns and hepatic function was investigated in the perfused liver of cirrhotic rats. Compared with controls, cirrhotic livers had higher vascular resistance, increased intrahepatic shunting, and smaller extravascular albumin space and larger extravascular sucrose space, as determined by a multiple-indicator dilution technique. Hepatic function, estimated by determining propranolol and antipyrine extraction, was markedly reduced in cirrhotic livers. Portal pressure was then reduced 25% either pharmacologically by verapamil or hydrodynamically by lowering inflow. Verapamil decreased vascular resistance by 22%. This was associated with a 38% reduction in intrahepatic shunting and a 62% increase in extravascular albumin space. Hydrodynamically lowering pressure had no or adverse effects. The verapamil-induced improvement in microcirculatory characteristics was associated with a significant improvement in oxygen consumption (+21%) and antipyrine clearance (+20%). We conclude that the microvascular distortions of liver cirrhosis in the rat are partially reversible by vasodilators like verapamil.