Mechanisms of portal hypertension-induced alterations in renal hemodynamics, renal water excretion, and renin secretion

Congestive renal failure: the pathophysiology and treatment of renal venous hypertension

Longstanding experimental evidence supports the role of renal venous hypertension in causing kidney dysfunction and "congestive renal failure." A focus has been heart failure, in which the cardiorenal syndrome may partly be due to high venous pressure, rather than traditional mechanisms involving low cardiac output. Analogous diseases are intra-abdominal hypertension and renal vein thrombosis. Proposed pathophysiologic mechanisms include reduced transglomerular pressure, elevated renal interstitial pressure, myogenic and neural reflexes, baroreceptor stimulation, activation of sympathetic nervous and renin angiotensin aldosterone systems, and enhanced proinflammatory pathways. Most clinical trials have addressed the underlying condition rather than venous hypertension per se. Interpreting the effects of therapeutic interventions on renal venous congestion are therefore problematic because of such confounders as changes in left ventricular function, cardiac output, and blood pressure. Nevertheless, there is preliminary evidence from small studies of intense medical therapy or extracorporeal ultrafiltration for heart failure that there can be changes to central venous pressure that correlate inversely with renal function, independently from the cardiac index. Larger more rigorous trials are needed to definitively establish under what circumstances conventional pharmacologic or ultrafiltration goals might best be directed toward central venous pressures rather than left ventricular or cardiac output parameters.

Therapeutic effect of captopril, pentoxifylline, and cordyceps sinensis in pre-hepatic portal hypertensive rats

BACKGROUND/AIM

Portal hypertension is an important and potentially fatal complication of liver disease whereby cellular and fibrotic alterations manifest to increase portal venous pressure. The aim of this study is to investigate the effect of captopril, pentoxifylline (PTX), and cordyceps sinensis in pre-hepatic portal hypertensive rats.

SETTINGS AND DESIGN

Wistar male rats were divided at random into 3 main groups: the first group: control rats. The second group: sham-operated rats and the third group: prehepatic portal hypertensive rats (PHPHT) induced by regulated pre-hepatic portal vein ligation. After 14 days, Group 3 was subdivided into 5 subgroups. Subgroup (1): portal vein-ligated (PVL) was killed at once; Subgroup (2): received distilled water for 30 days (untreated PVL group); subgroups 3-5 were treated with captopril (60 mg/kg, orally); PTX (100 mg/kg, orally); and C. sinensis (200 mg/kg, orally), respectively, as a single daily dose for 30 days.

PATIENTS AND METHODS

Portal pressure, nitric oxide (NO), antioxidant enzymes, Liver enzymes, and creatinine levels were measured to evaluate the status of the liver state.

RESULTS

Portal vein ligation produced significant increments in liver enzymes, NO, creatinine and portal pressure concomitant with significant decrements in glutathione content and superoxide dismutase activity. Treatment with captopril, PTX, and C. sinensis resulted in a significant reduction in liver enzymes, NO, creatinine and portal pressure and observable increase in antioxidant enzymes.

CONCLUSIONS

captopril, PTX, and C. sinensis have promising effect in controlling PHPHT and reducing hyperdynamic circulatory state through reduction of portal pressure and NO level.

Negative feedforward control of body fluid homeostasis by hepatorenal reflex

The liver, well known for its role in metabolism, clearance and storage can also be regarded as a sensory organ. The liver is an ideal place to monitor the quality and quantity of absorbed substances, because portal blood delivers substances absorbed from the intestine to the liver and these substances circulate in the hepatic vasculature before substances enter the systemic circulation. Sodium (Na(+))-sensitive mechanism exists in the liver; it is stimulated by the increase in Na(+) concentration in the portal vein, and then hepatorenal reflex is triggered. Renal sympathetic nerve activity is reflexively decreased and urinary Na(+) excretion is increased. This Na(+)-sensitive hepatorenal reflex has a significant role in post-prandial natriuresis. However, the long-term role of this reflex in Na(+) homeostasis may be less important, probably because of the desensitization of Na(+)-sensitive mechanisms. Na(+)-K(+)-2Cl(-) cotransporter (NKCC1) is involved in the hepatoportal Na(+)-sensitive mechanism, and NKCC1 expression is reduced if the hepatoportal region is exposed to high Na(+) concentrations for a long time. This situation occurs when animals intake a high-sodium chloride diet for a long time. Liver cirrhosis also impairs the Na(+)-sensitive hepatorenal reflex. Hepatoportal baroreceptor-induced renal sympathetic excitation and the impaired Na(+)-sensitive hepatorenal reflex may partially explain the Na(+) retention in liver cirrhosis.

Immediate neuroendocrine signaling after partial hepatectomy through acute portal hyperpressure and cholestasis

BACKGROUND & AIMS

Early neuroendocrine pathways contribute to liver regeneration after partial hepatectomy (PH). We investigated one of these pathways involving acute cholestasis, immediate portal hyperpressure, and arginine vasopressin (AVP) secretion.

METHODS

Surgical procedure (PH, Portal vein stenosis (PVS), bile duct ligation (BDL), spinal cord lesion (SCL)) and treatments (capsaicin, bile acids (BA), oleanolic acid (OA)) were performed on rats and/or wild type or TGR5 (GPBAR1) knock-out mice. In these models, the activation of AVP-secreting supraoptic nuclei (SON) was analyzed, as well as plasma BA, AVP, and portal vein pressure (PVP). Plasma BA, AVP, and PVP were also determined in human living donors for liver transplantation.

RESULTS

Acute cholestasis (mimicked by BDL or BA injection) as well as portal hyperpressure (mimicked by PVS) independently activated SON and AVP secretion. BA accumulated in the brain after PH or BDL, and TGR5 was expressed in SON. SON activation was mimicked by the TGR5 agonist OA and inhibited in TGR5 KO mice after BDL. An afferent nerve pathway also contributed to post-PH AVP secretion, as capsaicin treatment or SCL resulted in a weaker SON activation after PH.

CONCLUSIONS

After PH in rodents, acute cholestasis and portal hypertension, via the nervous and endocrine routes, stimulate the secretion of AVP that may protect the liver against shear stress and bile acids overload. Data in living donors suggest that this pathway may also operate in humans.

Liver-kidney pathophysiological interrelationships in liver diseases

On the basis of several clinical and experimental researches, it is possible today to deepen the different mechanisms regarding kidney and liver relationships. However, the most studied field remains the renal function during liver disease. These alterations can be divided into: 1. Renal functional impairment is mainly considered due to hemodynamic derangement with a progressive decrease in peripheral vascular resistance (PVR) and an increase in cardiac output and rate, characteristic of hyperdynamic circulation, and outer cortex renal ischemia. Two principal forms of RFI characterize the hepatorenal syndrome (HRS) while in the first stage is based on the simple decrease in renal clearances with avid sodium retention. 2. Metabolic renal damage is principally due to abnormal serum levels of bile acids, bilirubin and perhaps toxic hepatic molecules which induce tubular dysfunction leading to RTA, of which type I, in the incomplete form, is the most common, varying between 30% and 50% of cases. It is mainly studied during cholestatic disease. 3. Organic renal impairment is principally based on immunological response to viral antigens and abnormal hepatic products which lead to the presence of immunocomplexes and cryoglobulins on the blood which tend to be deposited in the subendothelial and subepithelial glomerular areas, inducing complement activation, mesangial cell proliferation and monocyte-macrophage cell infiltration.

Splenorenal reflex modulates renal blood flow in the rat

We have previously shown that the splenorenal reflex controls renin release through splenic afferent and renal sympathetic nerves. We proposed that this reflex would also affect renal blood flow (RBF). RBF was measured in male Long Evans rats using transit-time flow probes. There were no significant differences between any of the experimental groups with respect to baseline values of RBF (8.9 +/- 0.4 ml min(-1), n= 25) or mean arterial pressure (MAP, 98.7 +/- 2.5 mmHg, n= 25). Splenic venous pressure was selectively raised (from 7.9 +/- 0.6 to 21.6 +/- 0.3 mmHg, n= 25) in anaesthetized rats by partial ligation of the splenic vein. This caused an immediate fall in RBF (-2.1 +/- 0.2 ml min(-1), n= 7) and in MAP (-12.4 +/- 2.8 mmHg, n= 7). The fall in RBF, but not the fall in blood pressure, was attenuated by renal denervation (DeltaRBF: - 0.7 +/- 0.1 ml min(-1), n= 6), splenic denervation (DeltaRBF: -0.8 +/- 0.1 ml min(-1), n= 6) and close renal arterial injection of the alpha1-adrenergic blocker phenoxybenzamine (12.5 microg; DeltaRBF: -0.8 +/- 0.1 ml min(-1), n= 6). Renal conductance fell only in the intact control group, i.e. the residual fall in RBF in the denervated and phenoxybenzamine-treated animals could be attributed to the fall in MAP. We also showed that splenic vein occlusion increased both splenic afferent (from 3.0 +/- 0.3 to 6.6 +/- 0.6 spikes s(-1), n= 5) and renal efferent (from 24.8 +/- 2.0 to 50.2 +/- 4.9 spikes s(-1), n= 9) nerve activity. We conclude that obstruction to splenic venous outflow, such as would occur in portal hypertension, initiates increased splenic afferent nerve activity and renal vasoconstriction through the splenorenal reflex, as well as a fall in blood pressure. We propose that this contributes to the renal and cardiovascular dysfunction observed in portal hypertension.

Update on ascites and hepatorenal syndrome

Ascites is the most common complication occurring during liver cirrhosis. Even if a significant decrease in renal clearance may be observed in the first step of chronic active liver disease, renal impairment, at times complicated by the typical signs of hepatorenal syndrome, occurs only in patients with ascites, especially when tense and refractory. Experimental and clinical data seem to suggest a primary sodium and water retention in the pathogenesis of ascites, in the presence of an intrahepatic increase of hydrostatic pressure, which, by itself, physiologically occurs during digestion. Abnormal sodium and water handling leads to plasma volume expansion, followed by decreased peripheral vascular resistance and increased cardiac output. This second step is in agreement with the peripheral arterial vasodilation hypothesis, depicted by an increase in total blood volume, but with a decreased effective arterial blood volume. This discrepancy leads to the activation of the sympathetic nervous and renin-angiotensin-aldosterone systems associated with the progressive activation of the renal autacoid systems, especially, that of the arachidonic acid. During advanced cirrhosis, renal impairment becomes more sustained and renal autacoid vasodilating substances are less available, possibly due to a progressive exhaustion of these systems. At the same time ascites becomes refractory inasmuch as it is no longer responsive to diuretic treatment. Various pathogenetic mechanisms leading to refractory ascites are mentioned. Finally, several treatment approaches to overcome the reduced effectiveness of diuretic therapy are cited. Paracentesis, together with simultaneous administration of human albumin or other plasma expanders is the main common approach to treat refractory ascites and to avoid a further decrease in renal failure. Other effective tools are: administration of terlipressin together with albumin, implantation of the Le Veen shunt, surgical porto-systemic shunting or transjugular intrahepatic portosystemic stent-shunt, or orthotopic liver transplantation, according to the conditions of the individual patient.

Effect of insufflation gas and intraabdominal pressure on portal venous flow during pneumoperitoneum in the rat

BACKGROUND

Carbon dioxide, the primary gas used to establish a pneumoperitoneum, causes numerous systemic effects related to cardiovascular function and acid-base balance. Therefore, the use of other gases, such as helium, has been proposed. Furthermore, the pneumoperitoneum itself, with the concomitant elevation of intraabdominal pressure, causes local and systemic effects that have been only partly elucidated. Portal blood flow, which plays an important role in hepatic function and cell-conveyed immune response, is one of the affected parameters.

METHODS

An established animal model (rat) of laparoscopic surgery was extended by implanting a periportal flow probe. Hemodynamics in the portal vein were then measured by transit-time ultrasonic flowmetry during increasing intraabdominal pressure (2-12 mmHg) caused by gas insufflation (carbon dioxide vs helium).

RESULTS

The installation of the pneumoperitoneum with increasing intraperitoneal pressure led to a significant linear decrease in portal venous flow for both carbon dioxide and helium. At higher pressure levels (8-12 mmHg), portal blood flow was significantly lower (1.5-2.5-fold) during carbon dioxide pneumoperitoneum. An intraabdominal pressure of 8 mmHg caused a decrease to 38.2% of the initial flow (helium, 59.7%); whereas at 12 mmHg, portal flow was decreased to 16% (helium, 40.5%).

CONCLUSION

Elevated intraabdominal pressure generated by the pneumoperitoneum results in a reduction of portal venous flow. This effect is significantly stronger during carbon dioxide insufflation. Portal flow reduction may compromise hepatic function and cell-conveyed immune response during laparoscopic surgery.

Hepatosplanchnic haemodynamics and renal blood flow and function in rats with liver failure

BACKGROUND

Massive liver necrosis, characteristic of acute liver failure, may affect hepatosplanchnic haemodynamics, and contribute to the alterations in renal haemodynamics and function.

AIMS

To investigate the relation between hepatosplanchnic haemodynamics, including portal systemic shunting, and renal blood flow and function in rats with acute liver failure.

METHODS

Liver failure was induced in male Wistar rats by intraperitoneal injection of 1.1 g/kg of D(+)-galactosamine hydrochloride. The parameters assessed included; systemic, hepatosplanchnic, and renal blood flow (57Co microsphere method); portal-systemic shunting and intrarenal shunting (consecutive intrasplenic, intraportal, or renal arterial injections of 99mTc methylene diphosphonate and 99mTc albumin microspheres); arterial blood pressure and portal pressure; renal function; and liver function (liver function tests and 14C aminopyrine breath test).

RESULTS

Progressive liver dysfunction was accompanied by the development of a hyperdynamic circulation, a highly significant decrease in renal blood flow and function, and an increase in intrarenal shunting 36, 42, and 48 hours after administration of D-galactosamine. The alterations in renal blood flow and function were accompanied by significant increases in portal pressure, portal venous inflow, and intrahepatic portal systemic shunting in galactosamine treated rats compared with controls. There was a significant correlation between changes in renal blood flow and changes in portal pressure, intrahepatic portal systemic shunting, and deterioration in liver function (r = 0.8, p < 0.0001).

CONCLUSIONS

The results of this study suggest that both increased intrahepatic portal systemic shunting and hepatocyte impairment may contribute to alterations in renal haemodynamics and function.

Therapeutic efficacy of the non-peptide AVP antagonist OPC-31260 in cirrhotic rats

The present study was undertaken to determine whether a non-peptide arginine vasopressin (AVP) antagonist [5-dimethylamino-1-(4-(2-methylbenzoylamino)benzoyl]-2,3,4,5-tetra hydro-1H- benzazepine] (OPC-31260) improves the impaired water excretion in rats with experimental liver cirrhosis. Male Wistar rats weighing 200 to 250 g were injected in an equal volume (4 ml/kg) of carbon tetrachloride and olive oil at an interval of seven days for three months, causing liver cirrhosis with ascites. Control rats were injected with only olive oil. Body weight (body wt) and hematocrit (Hct) were lower in the cirrhotic rats than the control rats (body wt 360.7 vs. 238.5 g, P < 0.01; Hct 46.3 vs. 39.2%, P < 0.01). A water loading test (30 ml/kg) was carried out and 20-minute urine collections were made for three hours. The percent of water load excreted was 62.5% in the cirrhotic rats, a value significantly less than that of 102.1% in the control rats. However, its percent increased to 215.1% after the oral administration of 5 mg/kg OPC-31260 (P < 0.01). Minimal urinary osmolality (UOsm) was 185.5 mOsm/kg H2O in the cirrhotic rats receiving the vehicle, a value greater than the control rats of 125.5 mOsm/kg H2O (P < 0.01). The oral administration of 5 mg/kg OPC-31260 reduced minimal UOsm to 85.2 mOsm/kg H2O in the cirrhotic rats (P < 0.01). Urinary excretion of sodium was lower in the cirrhotic rats than the control rats (87.1 vs. 312.4 microEq/3 hr, P < 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)

Arterial underfilling does not cause sodium retention in cirrhosis

PURPOSE

To test the peripheral arterial vasodilation hypothesis of sodium retention in cirrhosis. This states that sodium retention is triggered by arterial underfilling and predicts that development of sodium retention will be associated with significant and related declines in indices of arterial filling that reverse when sodium retention resolves.

DESIGN

Longitudinal evaluation of a cohort of patients with alcoholic liver disease.

PATIENTS AND METHODS

Eighteen men, 8 of whom were studied twice, 3 three times, 2 four times, and 5 five times (40 between-study comparisons). Between 23 studies, the patients were ascites-free (Group NN). Ascites spontaneously disappeared between seven studies (Group YN), appeared between six studies (Group NY), and remained present between four studies (Group YY). Between-study changes in blood volume, arterial blood pressure, cardiac output, systemic vascular resistance, left atrial volume, left ventricular diastolic diameter, aortic root diameter, aortic blood velocity, plasma norepinephrine and atrial natriuretic factor concentrations, plasma renin activity, and urinary sodium excretion were evaluated by paired t-tests. These changes were also compared among groups by analysis of variance. In addition, correlations among the changes were sought.

RESULTS

Systolic, diastolic, and mean arterial pressures, left ventricular diastolic diameter, aortic root diameter, stroke volume, cardiac output, plasma norepinephrine concentration, and systemic vascular resistance were unchanged between studies. Left atrial volume increased between studies in Group NY. Pulse pressure fell more in Group NY than in Groups NN and YN, principally as a result of a decline in systolic blood pressure. Plasma norepinephrine concentration, plasma renin activity, and blood volume rose more in Group NY than in Groups NN, YN, and YY. Changes in both systolic and pulse pressures were directly correlated with the change in sodium excretion but unrelated to the change in plasma norepinephrine concentration. Changes in plasma norepinephrine concentration and plasma renin activity were unrelated to changes in blood pressure, systemic vascular resistance, and urinary sodium excretion.

CONCLUSIONS

None of the indices of arterial filling tested except pulse pressure were related to sodium retention. Reduced pulse pressure is inconsistent with arterial underfilling, as peripheral vasodilation instead increases pulse pressure by increasing diastolic run-off. These data do not support the hypothesis that arterial underfilling is the stimulus for sodium retention in alcoholic cirrhosis.

Changes in splanchnic blood flow and cardiovascular effects following peritoneal insufflation of carbon dioxide

Laparoscopic surgery has rapidly become a popular and widely used technique. Although this procedure has been shown to be generally safe, cardiovascular derangement related to carbon dioxide pneumoperitoneum has been reported. There are few data available on the relationship between systemic and regional hemodynamics in cases of pneumoperitoneum. Changes in splanchnic blood flow and cardiovascular effects following a moderate increase of intraabdominal pressure (IAP) to 16 mmHg during a 3-h period were analyzed in six anesthetized dogs. After insufflation, cardiac output and blood flow in the superior mesenteric artery and portal vein decreased progressively and returned to the preinsufflation values following deflation. Hepatic arterial blood flow did not change significantly, perhaps due to compensatory mechanisms for maintenance of hepatic blood flow. Mechanical compression of the splanchnic capillary beds due to the elevated IAP may possibly reflect the increase in systemic vascular resistance causing the decrease in cardiac output. To prevent this impairment, intermittent decompression of gas during surgical laparoscopy is recommended.

Changes of the fibrinolytic system in liver dysfunction: role of portal hypertension

The contribution of hemodynamic changes to the pathogenesis of accelerated fibrinolysis in liver disease was investigated in rats. In animals with hepatic lesions induced by a 7-week inhalation of carbon tetrachloride there was a significant increase in blood t-PA activity and PAI activity, with no significant change in portal pressure. Following a 10-min portal vein occlusion there was a marked increase in portal pressure and t-PA activity and a significant decrease in PAI activity. Following ligation of both portal vein and hepatic artery, t-PA activity increased to a higher extent and PAI activity was reduced to a lesser extent than changes found in portal-stenosed rats. Our data suggest that high t-PA circulating levels in liver disease could be related not only to the reduced t-PA clearance as a consequence of liver injury but also to hemodynamic changes.

The location of the receptors involved in the human diuretic response to drinking an isotonic electrolyte solution

1. This study aimed to shed light on the receptors involved in the diuretic response to drinking isotonic fluids in man by employing a polyethylene glycol-based bowel lavage solution (Golytely) which is reported to cause no net movement of fluid across the gut. 2. Drinking Golytely resulted in a transient hypotonic diuresis. Mean urine flow rose from control values of 0.9 ml min-1 to 10.1 ml min-1 70 min after the start of drinking. The increase in urine output was accompanied by a fall in urine osmolality from control values of 879 mosM kg-1 to 105 mosM kg-1. The diuresis is similar to that produced by ingestion of an equal volume of an absorbable electrolyte-based solution (Tyrode). 3. Neither solution produced changes in plasma osmolality or electrolytes, but Golytely provoked a 6.8% contraction of plasma volume, whereas drinking Tyrode resulted in plasma expansion. Copious diarrhoea was experienced by all subjects who drank Golytely solution and by none on drinking Tyrode solution. 4. The infusion of Golytely into the stomach resulted in a hypotonic diuresis similar in magnitude to that elicited by drinking. Drinking with simultaneous aspiration of gastric contents ('sham-drinking') did not produce a significant diuresis. 5. Plasma arginine vasopressin (AVP) levels did not fall following the drinking of Golytely. The assay used was sufficiently sensitive to measure changes of 0.6 pg AVP (ml plasma)-1. 6. The findings show that signals from the oropharynx do not mediate the diuretic response to drinking Golytely in man and that a mechanism other than inhibition of AVP release appears to be involved. The receptors mediating this response may lie in the stomach and/or small bowel since Golytely is not absorbed, as evidenced by the contraction of plasma volume and diarrhoea.

The endocrinology and pathophysiology of alcoholic cirrhosis and functional renal failure--a review

The pathophysiology and characteristics of decompensated alcoholic cirrhosis and functional renal failure are reviewed. The review will be restricted to alcoholic cirrhosis, because most cases of functional renal failure in the United States occur in the setting of alcoholic cirrhosis, which is also the most common cause of ascites in North America and Europe. Moreover, hepatorenal syndrome may complicate other forms of liver disease besides alcoholic cirrhosis, but the pathogenesis in such circumstances may not be the same as in the cirrhotic state.

Blunted natriuretic response and low blood pressure after atrial natriuretic factor in early cirrhosis

We compared the natriuretic response to a standard dose of atrial natriuretic factor in nine patients with early cirrhosis (no ascites or edema) with the response in normal subjects displaying a range of baseline sodium excretions due to different sodium intakes (20 mmoles per day, n = 9; 100 mmoles per day, n = 9, and 200 mmoles per day, n = 9). In these normal subjects, sodium output rose, in the same order, from 49 +/- 12 to 177 +/- 26, from 116 +/- 21 to 365 +/- 106 and from 228 +/- 29 to 901 +/- 85 mumoles per min in the first 20 min after 100 micrograms atrial natriuretic factor (human atrial natriuretic factor 99-126). Thus, irrespective of basal excretion, natriuresis rose by at least 2-fold. In the cirrhotic patients, natriuresis rose from 173 +/- 42 to 305 +/- 77 mumoles per min, that is by hardly 1-fold, significantly less than in the normal subjects (p less than 0.01). Renal function studies indicated that atrial natriuretic factor caused less rise in glomerular filtration rate and in fractional sodium excretion. Atrial natriuretic factor induced a fall in blood pressure only in the cirrhotic group, from 130 +/- 4/81 +/- 2 to 108 +/- 4/68 +/- 3 mmHg (p less than 0.001). Plasma atrial natriuretic factor was not low in the cirrhotic patients. Although these data are compatible with a primary disturbance of sodium excretion in early cirrhosis without ascites, such an explanation is complicated by the concomitant drop in blood pressure after atrial natriuretic factor.(ABSTRACT TRUNCATED AT 250 WORDS)

Pathogenesis of sodium and water retention in high-output and low-output cardiac failure, nephrotic syndrome, cirrhosis, and pregnancy (2)

This article has analyzed the pathogenesis of sodium and water retention in several circumstances. The initiator of retention has been proposed to be either a fall in cardiac output (e.g., low-output cardiac failure and vasoconstrictor hypovolemic nephrotic syndrome) or peripheral arterial vasodilatation (e.g., high-output cardiac failure, cirrhosis, arteriovenous fistula, and pregnancy). In the only state discussed, in which the kidney is diseased and not merely responding to extrarenal reflexes--i.e., nephrotic syndrome--intrarenal mechanisms may predominate and lead to expansion of the arterial vascular tree and suppression of the renin-angiotensin-aldosterone system (i.e., hypervolemic nephrotic syndrome). Otherwise, when kidneys are healthy, either a fall in cardiac output or peripheral arterial vasodilatation may diminish arterial vascular filling and thereby initiate a series of hemodynamic and hormonal events that result in renal sodium and water retention (Fig. 7). Finally, the approach presented in this article should be considered to be a vantage point from which to evaluate states of sodium and water retention, but not to be an exclusive position.

Role of diuretics, hormonal derangements, and clinical setting of hyponatremia in medical patients

Because hyponatremia is frequently associated with preceding diuretic treatment and unrestricted fluid intake--conditions which have not been addressed sufficiently in published literature--we studied the pathophysiology and the clinical setting of such hyponatremia in a large group of internal medicine patients. We observed: a) Of an initial 310 patients with chemical hyponatremia only 204 (64%) had an associated plasma hypoosmolality. Since a normal plasma osmolality excludes a disturbance of water metabolism only the 204 patients with hypoosmolar hyponatremia were included in the study. This data shows that plasma osmolality is an essential measurement in any evaluation of hyponatremia. b) In 204 consecutive patients with hypoosmolar hyponatremia the electrolyte disturbance was related to advanced congestive cardiac failure in 25%, decompensated liver cirrhosis in 18%, volume contraction in 28%, syndrome of inappropriate antidiuretic hormone secretion in 19% and renal insufficiency in 4%. c) Plasma vasopressin was measurable in 90% of the 204 patients. It is known that radioimmunoassays to measure vasopressin fail to reliably detect low concentrations of circulating vasopressin (less than 0.5 pg/ml). It may therefore be stated that hypoosmolar hyponatremia was generally characterized by a failure of antidiuretic hormone suppression. d) Mean daily fluid intake of hyponatremic patients was 2.35 +/- 0.15 l. In the presence of stimulated vasopressin this large a fluid intake is bound to worsen the severity of hyponatremia. e) Of 204 patients 126 were treated with diuretics at the time of study. In these patients hyponatremia worsened during such treatments and was associated with evidence of prerenal azotemia. However there were no significant differences between diuretic-treated and -untreated patients with respect to plasma vasopressin stimulation and amount of fluid intake.(ABSTRACT TRUNCATED AT 250 WORDS)

Reflex increase in renal nerve activity during acutely altered portal venous pressure

This study was designed to determine the reflex effects of renal nerve activity during acutely altered portal venous pressure in anesthetized dogs. Following inflation of a balloon in the main portal vein of animals with the neuraxis intact, mean blood pressure (MBP) fell significantly from 127 +/- 8 mm Hg to 101 +/- 7 mm Hg, while renal nerve activity (RNA) increased to 189 +/- 11%. This significant increase in RNA during inflation of the balloon was not entirely eliminated by either carotid sinus nerve (CSN) denervation (163 +/- 9% of the control level) or vagotomy (161 +/- 11% of the control level). The reflex increase in RNA observed with the combined denervation of the carotid sinus and vagal nerves (CSN + Va denervation) was 138 +/- 2% of the control level, and this level of RNA increase was significantly smaller compared to those in the other 3 groups (intact, CSN or Va denervated). Even when the portal venous pressure below caudal to the balloon was controlled at a pre-distension level by means of opening an artificial bypass constructed between the mesenteric vein and the femoral vein in the CSN + Va denervated group, the increased RNA response during inflation of the balloon remained. After hepatic denervation in the CSN + Va denervated group with the opening of the bypass, however, inflation of a balloon caused no significant changes in RNA, even when more profound hypotension existed during inflation of the balloon.(ABSTRACT TRUNCATED AT 250 WORDS)

Systemic haemodynamics, renal and platelet function during chronic propranolol administration in patients with compensated cirrhosis

Chronic propranolol administration is followed by some haemodynamic alterations, which may impair renal function. It has also been suggested that it may reduce platelet production of proaggregatory thromboxane (TX) A2. We therefore evaluated cardiac index (CI), systemic vascular resistance (SVR), creatinine clearance, daily sodium excretion under controlled sodium intake, platelet aggregation and platelet TXA2 production during whole blood clotting in eight patients with cirrhosis, portal hypertension and no ascites, before and after 3 months of propranolol administration. Liver function was also assessed by evaluating the galactose elimination capacity (GEC) and galactose clearance (Cgal). The expected, significant reduction of CI and increase of SVR was observed. Creatinine clearance and sodium balance were unchanged throughout the study. Furthermore, the renal prostaglandin system, as reflected by urinary prostaglandin E2 and TXB2 excretion, was also unaffected by the drug. No modification of platelet aggregation, platelet TXA2 production during whole blood clotting, GEC and Cgal was observed. We conclude that chronic propranolol administration is followed by alterations of CI and SVR, but it does not impair renal function and platelet aggregation in patients with cirrhosis, portal hypertension and no ascites. The maintenance of renal function during beta-adrenergic blockade is not due to an increased renal production of vasodilating prostaglandins.

Effect of vasopressin antagonist on water excretion in inferior vena cava constriction

Elevated levels of plasma arginine vasopressin (AVP) have been suggested to impair water excretion in congestive heart failure. In the present study, to determine a role for AVP in the impaired water excretion in rats with the inferior vena cava constriction (IVC), two AVP antagonists were used in the IVC rats at the proximal portion of the hepatic vein under the diaphragm and in sham-operated (control) rats. After surgery, 48 hrs were allowed before the experiments were started. A mean cardiac index of 260.0 +/- 12.3 ml/min/kg in the IVC rats was significantly lower than that in the control rats, 323.6 +/- 13.2 ml/min/kg (P less than 0.01). The rats were given an antidiuretic antagonist, [1-(beta-mercapto-beta, beta-cyclopentamethylenepropionic acid), 2-(O-ethyl)-D-tyrosine, 4-valine] AVP (30 micrograms/kg) or the antagonist vehicle, i.p., and 20 min later they were administered 30 ml/kg of water orally. Minimal urinary osmolality (Uosm) in the IVC rats receiving the vehicle was significantly greater than the control rats (292.7 +/- 53.1 vs. 97.8 +/- 10.6 mOsm/kg H2O, P less than 0.01). The administration of the antidiuretic antagonist in the IVC rats decreased minimal Uosm to 90.0 +/- 3.6 mOsm/kg H2O. This value was significantly lower than the vehicle rats (P less than 0.01), and was a comparable level to minimal Uosm of 82.1 +/- 3.7 mOsm/kg H2O in the control rats receiving the antidiuretic antagonist. The IVC rats excreted 51.4 +/- 5.9% of the water load in three hr, a value significantly less than that excreted by the control rats, 95.1 +/- 6.0% (P less than 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)

Disorders of the serum electrolytes, acid-base balance, and renal function in alcoholism

This chapter reviews the disturbances of the serum sodium and potassium concentrations, acid-base imbalances, and acute renal dysfunction that are seen frequently in alcoholic patients. The hyponatremia common in decompensated cirrhotics is caused by an impairment of renal free water clearance and concomitant water ingestion. Excessive proximal renal tubular sodium reabsorption and nonosmotic vasopressin release underlie the defect in renal water excretion in cirrhosis. Restriction of water intake is the principal therapeutic measure for hyponatremia. Hypokalemia is common in alcoholics but when observed does not always represent true potassium depletion. Although most cirrhotics have a diminished total body potassium content, intracellular potassium concentration is usually normal. In some patients gastrointestinal and renal potassium losses and nutritional potassium deficiency may cause true potassium depletion. Respiratory and metabolic alkalosis are the acid-base disturbances seen most frequently in alcoholics. Acidosis is relatively uncommon and is usually due to renal insufficiency, lactic acid or keto-acid accumulation. Toxin ingestion (methanol, ethylene glycol, or isopropanol) may also cause severe acidosis. Rhabdomyolysis, common in severe alcoholism, may produce various electrolyte disturbances and acute renal failure. The prognosis for recovery is good although temporary dialysis may be necessary.

The pathogenesis of renal sodium retention and ascites formation in Laennec's cirrhosis

This chapter critically reviews our current understanding of the pathogenesis, clinical syndrome, and therapy of the disturbances of renal sodium handling, renal perfusion, and glomerular filtration rate that occur in patients with Laennec's cirrhosis. Avid renal sodium reabsorption, a characteristic feature of cirrhosis, occurs independent of moderate changes in renal function and precedes the onset of ascites. The initiation of sodium retention may be a direct consequence of the hepatic disease process and may also result from defective intravascular filling. In the presence of ascites the most important sodium retaining signal is a defective intravascular volume. The principal effectors of renal sodium retention and vasoconstriction are stimulation of the renin-angiotensin-aldosterone axis and augmentation of renal sympathetic nerve activity. Deficient production of natriuretic hormone(s) and endogenous renal vasodilators, such as prostaglandins and kinins, also contributes to the sodium retention and renal hypoperfusion seen in cirrhosis. The hepatorenal syndrome is an extreme imbalance in these renal vasoconstrictor and vasodilator forces. In the therapy of ascites in Laennec's cirrhosis, abstention from alcohol, sodium restriction, and cautious diuresis are the principal therapeutic measures. A grave prognosis accompanies the diagnosis of the hepatorenal syndrome although recoveries have been reported.

Sympathetic nervous activity in cirrhosis. A survey of plasma catecholamine studies

This review summarizes recent progress in the knowledge of catecholamines in cirrhosis. Compensated patients have normal plasma concentration of noradrenaline. Highly elevated plasma noradrenaline concentration in decompensated patients indicates that the sympathetic nervous system is enhanced in this condition. This may especially apply to the sympathetic tone in the kidney, as evaluated by regional measurements of noradrenaline overflow. Hepatic elimination of catecholamines is only slightly reduced. Activation of the sympathetic nervous system seems to play an important role in the avid sodium-water retention and decreased kidney perfusion observed in decompensated cirrhosis. Volume- en baro-receptors are likely to elicit this overactivity. The decreased systemic arterial blood pressure may be a primary event which is in part counteracted by enhanced sympathetic nervous activity and activated renin-angiotensin system. The role of a non-volume-dependent hepatic baro-receptor, false neurotransmitters, postsynaptic receptors, and autonomous neuropathy are yet unknown issues of further research.

Effect of head-out water immersion on hepatorenal syndrome

A 47-year-old patient with severe decompensated alcoholic liver disease developed a progressive deterioration of her renal function (serum creatinine 4.0 mg/dL) with a renal failure index (RFI: UNa/U/PCr) consistently less than 1.0. In the absence of other causes of renal failure, these values supported the diagnosis of hepatorenal syndrome (HRS). A five-hour head-out water immersion (HWI) in a sitting position was carried out to increase the patient's "effective" blood volume (EBV) in an attempt to reverse the HRS. Hemodynamic monitoring (Swan-Ganz) was performed during the entire HWI procedure. Cardiac index increased by 64% during HWI (2.57 to 4.22 L/min/m2). Stroke volume index doubled (32.9 to 65.0 mL/m2) and systemic vascular resistance decreased by 48% (1426 to 754 dyne sec/cm). Increases in right atrium (RA) pressure (7.5 to 17.5 mm Hg) and pulmonary wedge (PW) capillary pressure (7.5 to 16.3 mm Hg) also occurred. Hemoglobin, hematocrit, and plasma protein concentrations decreased by 18% during HWI. Only a modest improvement in creatinine, urea, inulin, and para-aminohippurate (PAH) clearances was observed during HWI, and the RFI remained below 1.0. Plasma levels of antidiuretic hormone (ADH), aldosterone, and renin activity decreased during HWI. The patient's renal function progressively deteriorated over the next 15 days, but tubular function, as assessed by an RFI less than 1.0, was still intact seven days after our study. Our results indicate that a considerable increase in effective blood volume does not restore renal function in HRS.

Body fluid homeostasis in congestive heart failure and cirrhosis with ascites

The urinary excretion of salt and water in man is regulated by a variety of renal and extrarenal mechanisms that respond to changes in dietary sodium intake as well as to alterations in the holding capacity of the vascular and interstitial compartments. Changes in extracellular fluid volume are detected by volume sensors located in the intrathoracic vascular bed, the kidney and other organs. These sensing mechanisms gauge the adequacy of intravascular volume relative to capacitance at various sites within the circulation. Congestive heart failure and cirrhosis with ascites are two disease states of man in which a hemodynamic disturbance within a given circulatory subcompartment is perceived by these sensing mechanisms and results in renal sodium retention. While the primary disturbance in both of these conditions originates outside the kidney, a variety of renal effector mechanisms respond to the perceived circulatory disturbance and result in enhanced tubule reabsorption of salt and water. These effector mechanisms involve physical adjustments in renal microvascular hemodynamics, tubule fluid composition and flow rate and transtubular ion gradients. These in turn are partially regulated by a variety of neural and humoral pathways including the renin-angiotensin-aldosterone axis, prostaglandins, and kinins.

A comparison of acute reversible pre- and postsinusoidal portal hypertension on salt and water retention in the dog

To define the relationship between portal hypertension and renal excretion of salt and water, two acute animal models of portal hypertension were investigated. In both models, it was necessary for systemic and renal hemodynamics to remain unchanged during the creation of portal hypertension so as to eliminate the effects of change in these parameters on renal excretion. In eight dogs, portal hypertension was induced by controlled tightening of a ligature around the superior hepatic vein and changes in hemodynamics were prevented by controlled i.v. titration with canine plasma. Rises in portal pressure 9.3 +/- 2.6 to 15.6 +/- 2.3 cm H2O were associated with significant decreases in urine volume 1.57 +/- 0.53 to 0.66 +/- 0.21 ml per min (p less than 0.05) and urinary sodium excretion [340 +/- 82 to 145 +/- 75 mEq per min (p less than 0.05)]. In contrast, similar experiments in five dogs in which the portal vein was partially ligated with increases in portal pressure from 8.3 +/- 0.6 to 18.6 +/- 0.5 cm H2O resulted in no change in urinary volume or sodium excretion. Acute reversible portal hypertension induced by hepatic vein constriction is associated with acute reversible retention of water and salt in the absence of changes in renal blood flow and creatinine clearance which only occur when the liver is involved and not with portal vein constriction.

Resistance to diuretics: emphasis on a pharmacological perspective

Resistance to diuretics occurs frequently in clinical settings. Most attention to this phenomenon has been directed toward the pathophysiology of the disease state, with little focus on the pharmacology of the diuretics themselves. This review summarises the pathogenesis and emphasises the pharmacological determinants of response to diuretics, including absorption, delivery to the kidney, and response to amounts of diuretic reaching the site of action. In normal subjects, overall response to organic acid diuretics such as frusemide (furosemide) is determined by the total amount of drug delivered into the urine (reflecting amounts of drug reaching the intraluminal site of action), the time course of delivery, and the relationship between amounts of drug reaching the urine and response (the dynamics of response). The conditions of azotaemia, inhibition of synthesis of prostaglandins, and the oedematous disorders of congestive heart failure, cirrhotic liver disease and nephrotic syndrome are examined in the above context. In azotaemic subjects, delivery of organic acid diuretics to their intraluminal site of action is inhibited by accumulated endogenous organic acids which compete for transport into the nephron at the organic acid secretory site of the proximal tubule. Whether the dynamics of response are changed has not been investigated. During inhibition of synthesis of prostaglandins, and in the oedematous disorders, there appear to be no changes in handling of frusemide; i.e. bioavailability, total drug delivered into the urine and the time course of delivery are comparable with that in normal subjects unless concomitant renal dysfunction exists. Resistance in these conditions is therefore due to a change in the dynamics of response.

Noradrenaline and adrenaline concentrations in various vascular beds in patients with cirrhosis. Relation to haemodynamics

Plasma noradrenaline (NA) and adrenaline (A) concentrations were related to various haemodynamic parameters in fifteen patients with cirrhosis. In supine position at rest plasma NA and A in peripheral venous blood were significantly higher in patients with cirrhosis than in normal subjects. Mean plasma NA averaged 0.66 and 0.21 ng/ml, respectively (P less than 0.01). The corresponding values for plasma A were 0.14 and 0.05 ng/ml (P less than 0.03). Splanchnic arterial-hepatic venous extraction ratio of NA in patients with cirrhosis averaged 0.46 (P less than 0.01). The right kidney released NA into the systemic circulation. Renal venous plasma NA exceeded arterial concentration by 38% (P less than 0.02). NA concentrations in femoral vein and ascitic fluid were not different from that of arterial plasma. Plasma NA was positively correlated to wedged hepatic vein pressure (r = 0.86, P less than 0.001) and to heart rate (r = 0.61, P less than 0.02), but inversely correlated to plasma volume (r = 0.83, P less than 0.01) in cirrhotic patients. Arterial blood pressure was reduced in these patients compared to controls (P less than 0.02), but not significantly correlated to plasma NA. The increased plasma NA indicates that sympathetic nervous activity is enhanced in patients with cirrhosis. Based on the above positive correlation between NA and heart rate and the significant release of NA from the kidney, it may be hypothesized that the increased sympathetic nervous activity especially involves heart and kidney. This response may be mediated by baro- and volume receptors.

The physiology of vasopressin release and the pathogenesis of impaired water excretion in adrenal, thyroid, and edematous disorders

Osmotic control for vasopressin release has been recognized for several years. Further understanding of factors affecting the sensitivity and threshold of ADH release has been advanced by the technological development of a sensitive radioimmunoassay. Evidence suggesting that ADH secretion is also mediated by nonosmotic stimuli involving a separate anatomic pathway from the hypothalamic osmoreceptor has been well documented. Experimental results suggest that the parasympathetic afferent pathways from both "high" and "low" pressure receptors constitute the most important nonosmotic pathways for ADH release. Factors such as hypoxia, altered hemodynamic states, alpha- and beta-adrenergic stimuli, nicotine, adrenal insufficiency, and advanced hypothyroidism are likely examples which activate this nonosmotic pathway. Clarification of the exact interrelationship between the osmotic and nonosmotic release of ADH needs further examination, particularly in the area of central neurotransmitters. However, available information allows for the proposal of a model of this interaction and its clinical implications which may explain many cases of "reset osmostat." Recent available data also provide support for ADH playing a role in the maintenance of blood pressure under certain circumstances. Like other potent vasoconstrictors, preliminary evidence suggests that ADH requires transcellular calcium influx for its vascular effects. Adrenal, thyroid, and edematous disorders have all been shown to be associated with abnormal water excretion. The results of recent studies indicate that these abnormal physiological states have impaired water excretion as a result of both nonosmolar factors stimulating ADH release and intrarenal factors, including diminished glomerular filtration rate or increased proximal tubule reabsorption which lead to decreased distal fluid delivery to the diluting segment of the nephron. Verney's original studies demonstrating the osmoreceptor regulation of ADH release remain a milestone in renal physiology. In the past decade, considerable new information about nonosmotic regulation of ADH has led to further understanding of renal water regulation in health and disease; nevertheless, many of these answers have only stimulated the imagination to ponder even more questions.

Plasma levels and hepatic extraction of renin and aldosterone in alcoholic liver disease

Arterial plasma levels and hepatic extraction of renin and aldosterone (ALDO) were measured in 24 patients with alcoholic liver disease and in 14 normal subjects being evaluated as prospective kidney donors. Patients with liver disease had higher plasma concentrations and lower fractional hepatic extractions of both renin and ALDO than the normal subjects. The quantity of renin extracted by the liver was highly correlated with plasma renin in both normal subjects and patients. Plasma ALDO concentration was positively correlated with plasma renin (p less than 0.001) but not with serum sodium, potassium or albumin concentration, inferior vena cava pressure, corrected hepatic venous wedge pressure, plasma volume or sulfobromophthalein storage or transport. Sixteen patients were restudied after one month. Six had received 40 mg/day of prednisolone, and the remaining 10 had received a placebo. Neither group had a change in plasma volume, corrected hepatic venous wedge pressure, plasma concentration or hepatic extraction of renin or ALDO. Serum albumin concentration increased and inferior vena cava pressure decreased with prednisolone therapy. These studies document high plasma levels and impaired hepatic extraction of renin and ALDO in patients with liver disease that are not corrected by short-term prednisolone therapy.

Mechanism of effect of hypoxia on renal water excretion

The effect of lowering the pressure of oxygen from 80 to 34 mm Hg was examined in anesthetized dogs that were undergoing a water diuresis. This degree of hypoxia was associated with an antidiuresis as urine osmolality (Uosm) increased from 107 to 316 mosmol/kg H(2)O (P < 0.001) and plasma arginine vasopressin increased from 0.06 to 7.5 muU/ml, (P < 0.05). However, hypoxia was not associated with significant changes in cardiac output (CO, from 4.2 to 4.7 liters/ min), mean arterial pressure (MAP, from 143 to 149 mm Hg), glomerular filtration rate (GFR, from 46 to 42 ml/min), solute excretion rate (SV, from 302 to 297 mosmol/min), or filtration fraction (from 0.26 to 0.27, NS). Hypoxia was associated with an increase in renal vascular resistance (from 0.49 to 0.58 mm Hg/ml per min, P < 0.01). The magnitude of hypoxia-induced antidiuresis was the same in innervated kidneys and denervated kidneys. To further examine the role of vasopressin in this antidiuresis, hypoxia was induced in hypophysectomized animals. The effect of hypoxia on CO, MAP, GFR, SV, and renal blood flow in hypophysectomized animals was the same as in intact animals. In contrast to intact animals, however, hypoxia did not induce a significant antidiuresis in hypophysectomized animals (Uosm from 72 to 82 mosmol/kg H(2)O). To delineate the afferent pathway for hypoxia-stimulated vasopressin release, hypoxia was induced in dogs with either chemo- or baroreceptor denervation. The effect of hypoxia on CO, MAP, GFR, SV, and renal blood flow in the denervated animals was the same as in nondenervated animals. Hypoxia resulted in an antidiuresis in chemoreceptor (Uosm from 113 to 357 mosmol/kg H(2)O, P < 0.001) but not in baroreceptor (Uosm from 116 to 138 mosmol/kg H(2)O, NS) denervated animals. To determine if hypoxia alters renal response to vasopressin, exogenous vasopressin was administered to normoxic and hypoxic groups of dogs. The antidiuretic effect of vasopressin was no different in these two groups. These results demonstrate that hypoxia induces an antidiuresis which is independent of alterations in CO, MAP, SV, filtration fraction, renal nerves, or renal response to vasopressin and occurs through baroreceptor-mediated vasopressin release. The nature of the baroreceptor stimulation remains to be elucidated.