Portal hypertension represents one of the main clinical complications of chronic liver diseases. Its consequences, variceal bleeding, ascites and hepatic encephalopathy are major causes of death and liver transplantation in patients with cirrhosis. The aim of the farmacological treatment in portal hypertension is to achieve a sustained decrease in portal pressure. A reduction in the hepatic venous pressure gradient (HVPG) by more than 20% of baseline values or below 12 mmHg by pharmacological agents has been associated with a marked reduction of the risk of variceal bleeding or rebleeding. However, these targets are achieved only in about 30% of the patients treated with nadolol or propranolol.1-3 The presence of adverse effects or contraindications to β-blockers and the low efficacy of this therapy have stimulated the search of alternative pharmacological treatments for portal hypertension.

The effect of the blockade of the renin-angiotensin system in the treatment of portal hypertension at different levels, with saralasin or angiotensin convertase enzyme inhibitors, has been studied since two decades.4,5 However, severe arterial hypotension was frequently observed. With the development of non-peptide, orally active angiotensin II type 1 receptor (AT1) antagonists, a new chapter in the inhibition of the bioenzimatic cascade was started. In 1999, Schneider et al. reported that the administration of 25 mg per day of losartan caused an important decrease in portal pressure in patients with portal hypertension without clinically significant arterial hypotension.3

Conversely, recent studies were unsuccessful in corroborating this initial results.7,8 For instance, in the study of González-Abraldes et al, the administration of higher doses of losartan caused arterial hypotension without changes in HVPG.7 Hence, the potential use of losartan in the treatment of portal hypertension is still under debate.

The aim of the present randomized controlled study was to evaluate the effects on portal and systemic hemodynamics of long term losartan administration (25 mg/day) versus propranolol in cirrhotic patients with portal hypertension.

The study was a randomized trial of losartan vs. propranolol. Patients were randomized with a ratio 2:1 to receive either losartan or propranolol. Randomization was carried out in blocks of five using random numbers stratified according to the severity of portal hypertension, arbitrary defined as moderate (baseline HVPG less than 16 mmHg) or severe (equal or greater than 16 mmHg). The sample size was calculated in 27 patients for a power to detect an increase of response from an estimated 37% in the propranolol group3 to 95% in the losartan group (Schneider et al. reported 98% of response in their study)6 with an a-error of 0.05 and a P-error of 0.20.9

Splanchnic and systemic hemodynamics and Doppler duplex ultrasound were performed at baseline and after 3 months of continued therapy. Laboratory analysis including hematologic tests (hemoglobin, leukocyte, neutrophil and platelet count) and biochemical tests (alanin ami-notransferase, alkaline-phosphatase, gammaglutamyl-transferase, creatinine, blood urea nitrogen, albumin and prothrombin time), were performed at baseline and every 4 weeks by the local laboratory. Any therapy with vasoactive drugs was withdrawn at least seven days before baseline measurements.

Once the baseline measurements were completed, patients were randomly allocated to one of the two treatment groups. Ten patients (five with moderate and five with severe portal hypertension) received propranolol therapy with an initial dose of 20 mg per day. This dosage was increased stepwise until the heart rate was reduced by 20% or to less than 55 beats/min. Seventeen patients (nine with moderate and eight with severe portal hypertension) received losartan 25 mg/day. The patients were enrolled and assigned to the groups by G.C.

Doppler duplex ultrasound. After an overnight fast, a Doppler duplex ultrasound study was performed according to a previously described procedure10,11 (Aloka SS1700, with color Doppler and a 3.5 MHz sector electronic probe). Briefly, the portal vein was longitudinally scanned and the sample volume was positioned in the middle of the portal trunk; the isoniation angle was equal or lower than 55°. Portal diameter and mean flow velocity were measured and portal blood flow was automatically calculated.12 The final value of all measurements was the mean of at least three determinations. All these studies were performed by the same observer (G.C.).

Splanchnic and systemic hemodynamics. After the ultrasound study was performed, the patients were transferred to hemodynamic Unit. Then, under fluoroscopic guidance, a 7F balloon catheter was advanced into the main right hepatic vein to measure the free and wedged hepatic venous pressures, and a Swan-Ganz catheter was advanced into the pulmonary artery to measure cardiopul-monary pressures, as previously described.10,13 Portal pressure was determined by the HVPG, which is obtained by subtracting the free hepatic venous pressure from the wedged hepatic venous pressure. Systolic, diastolic and mean arterial pressures were measured by using an automatic sphygmomanometer (VR 12, Electronics for Medicine). Systemic vascular resistance was calculated as [(Mean Arterial Pressure-Right Atrial Pressure)/Cardiac Output] X 80. Total arterial compliance was calculated as stroke volume/pulse pressure; where stroke volume = cardiac output/heart rate; and pulse pressure = systolic - diastolic pressure.14,15 Portal resistance was calculated as HVPG/portal blood flow and expressed as mm Hg X minute/liter.16 The final value of all measurements was the mean of at least three determinations. All these studies were performed by the same observer (P.V.), who was blinded to group assignment.

Results were expressed as mean + SD. Shapiro-Wilk’s W of normality was performed. Differences between proportions were analyzed by %2 test and the Fisher’s exact test. Differences between groups were analyzed by paired and unpaired Student’s t test, and by Mann-Whitney U or Wilcoxon matched paired tests, according to the distribution. Significance was established at p > 0.05. Pearson’s r coefficient was utilized for correlations.

A total of 27 patients were randomized to receive losa-rtan (n = 17) or propranolol (n = 10). Recruitment started in September 1999 and ended in October 2001. All the patients completed the study, and none of them was excluded from analysis. Both drugs were well tolerated and no important adverse effect was recorded. There were no differences between the two groups in clinical, laboratory or hemodynamic baseline characteristics (Tables IandII). No significant difference was found in the proportion of responders between the groups. No significant changes were observed in liver or renal function tests after propranolol or losartan administration.

Propranolol induced a statistically significant reduction of cardiac output and heart rate (Table II). Propranolol caused a decrease in HVPG from 16.4 (+ 4.1) to 13.1 (+ 3.6) mmHg (p 0.07), without changes in portal blood flow or portal resistance. Six out of 10 patients showed a reduction equal or greater than 20% in HVPG and were considered responders. The five patients with severe portal hypertension were responders, versus 1/5 patients with moderate portal hypertension (p 0.048)

No significant difference was observed after losartan administration in any parameter of the systemic hemodynamics. After losartan administration, the HVPG decreased from 15.6 (+ 4.2) to 11.8 (+ 3.5) mmHg (p 0.002), with a reduction in portal resistance from 13.7 (+ 5.7) to 10.9 (+ 5.8) mmHg . min/L (p 0.049), without changes in portal blood flow. A significant correlation was found between changes in HVPG and portal resistance (r 0.88; p < 0.0001).

A decrease in HVPG between 10 and 19% from baseline was found in 5/17. Eight patients showed a reduction of 20% or more in HVPG and were considered responders.

Responder patients to losartan had a higher mean arterial pressure (105 + 12 vs 89 + 9 mmHg; p 0.01), pulmonary wedged pressure (16 + 7.2 vs 8.2 + 3.2 mmHg; p 0.01) and wedged hepatic vein pressure (26.9 + 5 vs 21.4 + 3.2 mmHg; p 0.02) than non responders.

Analyzing the variations in hemodynamic parameters according to the severity of portal hypertension, patients with severe portal hypertension showed higher baseline mean arterial pressure, HVPG, wedged hepatic venous pressure and portal resistance (Table III), and showed a significant reduction in HVPG and portal resistance after treatment. Three out of nine patients with moderate portal hypertension were responders to losartan vs. 5/8 patients with severe portal hypertension (NS).

In this study we investigated the effects of twelveweek treatment with losartan 25 mg/d versus propranolol in patients with compensated cirrhosis and portal hypertension. We observed that chronic administration of losartan caused a significant decrease in HVPG without changes in systemic hemodynamics or renal function. Changes in HVPG strongly correlated with variations in portal resistance. Patients with higher portal hypertension and portal resistance showed a better response to losartan.

Large amount of evidence supports the hypothesis that angiotensin II plays a role in the physiopathology of portal hypertension. For instance, the renin-angiotensin system is frequently activated in patients with advanced cirrhosis and it has been observed a direct relationship between plasma renin activity and HVPG. Furthermore, angiotensin II raises portal pressure by an increase in hepatic vascular resistance17 caused by direct contraction of activated stellate cells. Recent studies have shown that this effect is mediated by the interaction between angiotensin II and the AT1 receptor.18

Angiotensin II, the final active product of the renin-angiotensin system, interacts with at least two membrane receptors in humans, type1 and type 2. Physiological effects of angiotensin, such as vasoconstriction, aldosterone stimulation, salt and water homeostasis, and contraction and proliferation of hepatic activated stellate cells seem to be mediated by the stimulation of the G-protein-coupled AT1 receptor. Moreover, several studies have shown the presence of this receptors in human myofibroblast-like hepatic stellate cells.18-20

The variations in HVPG and portal resistance after losartan administration may be explained by the effect of the blockade of AT1 on the contractility of hepatic activated stellate cells, by means of a decrease in intrahepatic vascular resistance assuming an increased activation of the renin-angiotensin system in the hepatic circulation.18

Losartan is a low molecular weight non-peptide, thus orally active, without intrinsic agonist properties. This drug is well absorbed and its bioavailability unaffected by food. In the liver, by a cytochrome P450 mechanism is partially converted into a more active metabolite, EXP3174. This metabolite has about 10-fold higher affinity for the AT1 receptor than losartan and is more slowly cleared. Losartan and EXP3174 are eliminated by both, biliary and urinary excretions.19 Consequently, reports of high losartan and EXP3174 concentrations in patients with cirrhosis suggest that the dose should be lowered in the presence of hepatic impairment.21

Regarding to the systemic and portal effects of losartan, our results are in discrepancy with other authors’ fidings. For instance, González-Abraldes et al found a significant decrease in mean arterial pressure and systemic vascular resistance, with renal function impairment and without changes in HVPG.7 Nonetheless, the doses administered in this study were higher. A possible explanation to this discordance is that higher doses of losartan in patients with cirrhosis may account of marked systemic effects, specifically a reduction in arterial pressure.22 Accordingly, arterial hypotension may enhance the activation of endogenous vasoactive systems and then counterbalance a putative local effect of the AT1 blockade.

With reference to the first study evaluating the effect of 7-day administration of losartan on portal pressure in cirrhotic patients,6 Schneider et al found a more than 40% decrease in HVPG, without clinically important (although significant) changes in arterial blood pressure. The patients had higher baseline portal pressure and a proportion of them suffered from more advanced liver disease than those of our study. Additionally, in our series, patients with higher portal hypertension showed a better response to losartan. These clinical findings are in agreement with the observation that plasmatic angiotensin II concentrations present a two fold increase in preascitic cirrhosis versus controls, but an eight fold increase in advanced cirrhosis with refractary ascites versus controls.23 In conclusion, the administration of losartan in a dose of 25 mg per day was well tolerated and effective in lowering portal pressure in patients with compensated cirrhosis, particularly in those with more severe portal hypertension.

The authors are grateful to Professor Abraham Lemberg for helpful discussions.