Effect of blockade of angiotensin II on blood pressure, renin and aldosterone in cirrhosis

1-Sar-8-ala angiotensin II (saralasin) was infused intravenously in graded doses of from 0.1 to 10 mug/kg/min to five patients with cirrhosis and ascites after three days of restricted sodium intake. In each patient blockade of AII by saralasin produced a marked fall in blood pressure, a rise in plasma renin activity (PRA) and plasma renin concentration (PRC) and, in four of the five, a fall in plasma aldosterone (PA). The rise in PRA and PRC correlated poorly with changes in blood pressure. The effects of saralasin rapidly reversed after cessation of the infusion. Plasma volume was normal or high in each case. Three patients were mildly hypotensive in the control state, and all five were resistant to the pressor effect of infused AII. After three days of salt loading, the above effects of saralasin were diminished but not abolished. In four normal subjects, after salt depletion, saralasin infusion induced qualitatively similar but much smaller changes in blood pressure, PRA and PRC. In two cirrhotic patients without ascites, after salt depletion, saralasin infusion caused a rise in blood pressure with no significant changes in PRA, PRC or PA. These results provide evidence that in patients with cirrhosis and ascites circulating AII is active in support of blood pressure, in direct suppression of renal renin release, and in stimulation of aldosterone release.     

Effect of sodium restriction and angiotensin II infusion in Bartter's syndrome

Five patients with Bartter's syndrome were investigated. Sodium restriction (less than 10 mEq/day for at least 5 days) showed a renal sodium wastage in only two patients (I and II) in spite of increased aldosterone secretion rate (from 151-427 to 680-842 mug/day). The effect of angiotensin II (A II) 80ng/kg/min for 30-180 min, on plasma renin activity (PRA), plasma aldosterone, and urinary sodium excretion was compared with the effect of a previous infusion of 5% dextrose given at the same rate, 0.5 ml/min for 1 hr. A II infusion resulted in increased plasma aldosterone levels: from 236-330 pg/ml to 800-881 pg/ml in 30 min. This increase was also observed in patient II (from 139 to 600 pg/ml). PRA was decreased by A II infusion (from 1,142-2,462 to 121-1,625 ng/liter/min). In patient IV, this decrease in PRA was also observed when he was on a salt-restricted diet (from 1,934 to 370 ng/liter/min); but the minimal PRA was still higher (370 ng/liter/min) than with a normal diet (121 ng/liter/min). In no case could normal PRA level be obtained. A II infusion induced an increase in urinary sodium excretion only in the two patients with renal sodium wastage (from 80-90 to 265-230 muEq/min in 30 min). Urinary sodium excretion decreased in the other patients from (37.5-213 to 4.30-46 muEq/min) and fractional sodium excretion was reduced in patient V (from 0.56% to 0.45% at 30 min and to 0.29% at 120 min). No significant change with A II infusion was observed in patient IV when he was on a sodium-restricted diet (from 1 to 2.5 muEq/min in 30 min). Urinary potassium excretion was similar to sodium excretion. No change was observed in plasma potassium and sodium.     

Renin, aldosterone and arterial pressure responses to acute beta-adrenergic receptor blockage in hypertensive patients

The effect of acute (intravenous) beta-adrenergic blockade with propranolol or pindolol on arterial pressure (BP), plasma renin activity (PRA), and plasma concentration of aldosterone (PA) was evaluated in 20 essential hypertensive men. BP, PRA and PA were determined during continuous recumbency over-night (8 p.m. to 6 a.m.) every 30 min. Two groups of patients were observed. Patients of group 1 exhibited a characteristic day-night rhythm of PRA with low values before midnight and large increases early in the morning. Conversely, no rhythm and very low PRA values were observed in patients of group II. BP was higher in group II than in group I. In group I following intravenous propranolol or pindolol, BP fell within minutes and levels as well as rhythms of PRA were converted to those of group II without treatment. In group II day-night profiles of PRA and BP remained unchanged. Rhythm and concentration of PA in the two groups were not influenced by either drug. In 4 patients of group I infusion of angiotensin II inhibitor did not lower BP. The observations suggest that in the two groups dissimilarities in rhythms of PRA as well as in BP responses to beta-blockade may reflect differences in neuro-adrenergic tone.     

Agonist and antagonist effects of Sar1-ala8--angiotensin II in salt-loaded and salt-depleted normal man

1 Three normal subjects were infused with Sar1-ala8-angiotensin II (Saralasin, P113) whilst on a high sodium (200 mEq + normal diet) and a low sodium (10 mEq diet) intake. 2 On the high sodium intake when angiotensin II and plasma renin activity (PRA) were suppressed, P113 infusion (5-10 mug kg-1 min-1) caused a slight rise in BP and a marked drop in urine flow and sodium excretion, with a fall in glomerular filtration rate, and effective renal plasma flow. 3 On the low sodium intake, when angiotensin II and PRA were increased, P113 infusion (5-10 mugkg-1 min-1) caused no change in blood pressure, urine flow or sodium excretion. However, when P113 was infused at an incremental rate starting at 0.25 mug kg-1 min-1 there was a fall in standing BP, which was maximal at an infusion rate of 1 mug kg-1 min-1, and this fall in standing BP was largely abolished as the rate of infusion was increased to 10 mug kg-1 min -1. 4 These results show firstly that angiotension II is involved in maintaning standing blood pressure during dietary sodium depletion in normal man and secondly that P113 does have agonist as well as antagonist activity in normal man, the effect depending on the level of angiotension II and sodium intake. When looking for angiotensin II mediated hypertension it may ne important to use an incremental rate of infusion of P113 as the agonist activity of larger doses may mask its hypotensive action.     

Disparity between blood pressure and PRA inhibition after administration of a renin inhibitor to anesthetized dogs: methodological considerations

A dissociation between changes in blood pressure (BP) and plasma renin activity (PRA) has been noted after administration of renin inhibitors. In the present study, the renin inhibitor PD 132002 was given to salt-deplete, anesthetized dogs. PRA was measured at pH 6.0 by a conventional angiotensin I (ANG I) RIA method (PRA-C) and by an ANG I antibody-trapping RIA method (PRA-AT) performed at pH 7.4. PD 132002 at 0.01, 0.1, 1, and 10 mg/kg IV, reduced BP by 3 +/- 2, 9 +/- 2, 24 +/- 4, and 39 +/- 4 mm Hg, respectively, (baseline of 136 +/- 8 mm Hg, N = 5), when infused IV over 30 minutes with a 30 minute recovery between doses. The BP response at 10 mg/kg equaled that of saralasin (20 micrograms/kg/min IV). PRA-AT (baseline of 20 +/- 6 ng ANG l/ml/hr, N = 4) was inhibited by 0%, 28% +/- 12%, 75% +/- 10%, and 97% +/- 1% at 0.01, 0.1, 1, and 10 mg/kg, respectively. Plasma concentrations of immunoreactive ANG II were also reduced dose-dependently and paralleled changes in BP. In contrast, PRA-C (baseline of 13 +/- 4 ng ANG l/ml/hr, N = 4) was inhibited by 82% +/- 8% at 0.01 mg/kg and by > 98% at higher doses. After a single dose of PD 132002 at 10 mg/kg infused over 30 minutes, BP recovery paralleled changes in immunoreactive ANG II and PRA-AT, yet PRA-C inhibition showed no recovery over the same time course. Our data support the conclusion that BP relates better to PRA-AT than PRA-C. Thus the dissociation sometimes observed in studies with renin inhibitors between changes in BP and PRA may be attributed to the assay used to determine PRA.     

A delayed suppression of the renin-aldosterone axis following saline infusion in human hypertension

The purpose of this study was to compare the acute suppressibility of the renin-angiotensin-aldosterone (RAA) axis in normotensive (n = 23) and essential hypertensive (n = 62) subjects. Only those hypertensive subjects with normal plasma renin activity (PRA) levels (sodium restricted, upright) were included in the study. Acute suppression of the RAA axis was determined by measuring PRA, plasma angiotensin II (A II), and plasma aldosterone (PA) at frequent intervals during the infusion of isotonic saline (500 ml/hour for 6 hours). Although all parameters fell significantly from control levels by 20-30 minutes in the normotensive subjects, we found that 60% of the hypertensive subjects showed no significant decline in PRA or PA until 120-240 minutes after beginning the infusion. The other hypertensive subjects showed normal RAA suppression. In addition, while there were no significant differences between the three groups in control PRA or PA levels, we found that the PA levels from 30 to 240 minutes during the saline were significantly higher (P less than 0.01) in the hypertensive subjects with delayed suppression. That there were two distinct populations in the hypertensive group was suggested by the bimodality of the frequency response curve, with peaks occurring at 30 and 240 minutes. These studies indicate an abnormality in the acute suppression of the RAA axis in a substantial proportion of subjects with normal renin essential hypertension. Since previous studies in normal subjects have reported that the early phase of response to saline infusion is related to the sodium ion per se and not to intravascular volume expansion, we have come to the conclusion that the present data are consistent with the hypothesis that the delayed suppression hypertensive group has a diminished ability to respond to the sodium ion.     

An evaluation of antiseptics used for hand disinfection in wards

The diurnal rhythm of plasma aldosterone concentration (PA), plasma renin activity (PRA), plasma cortisol (PC) and serum growth hormone (GH) were examined in 5 cases of normotensive acromegaly and the results were compared with the observations in normal subjects. Moreover, the response of PA to angiotensin-II infusion was studied in 6 cases of normotensive acromegaly. A normal diurnal rhythm with the lowest values in the evening or midnight and the highest values in the morning was observed in 3 of 5 cases in PA and 3 of 4 cases in PC. On the other hand, no apparent rhythm of GH was observed in any cases and that of PRA in 4 of 5 cases. Although there was a significant positive correlation between PA and PC, no significant correlation was demonstrated between PA and PRA. The response of PA to angiotensin-II fusion was significantly suppressed in normotensive acromegaly as compared to the normal subjects in spite of normal levels of PRA except for 1 case. The above observations were interpreted to suggest that the aldosterone regulation system is slightly altered in a certain number of patients with normotensive acromegaly in contrast to the normal subjects in which PRA is the main contributing factor. The low PA and suppressed response of PA toangiotensin-II infusion may suggest the defective action of angiotensin-II infusion on the adrenal gland.     

The effects of dietary sodium on the diurnal activity of the renin-angiotensin-aldosterone system and the excretion of urinary electrolytes

Diurnal variations of five normal men were tested over three 24 h consecutive periods. The first experiment began at 0900 h after the subjects had fasted for 12 h and a normal sodium diet of about 70-80 mEq was given at 0900 h, 1200h, and 1630 h (total of about 220 mEq of Na). Significant variations in the plasma renin activity (PRA), in the plasma aldosterone (PA), and in the urinary Na and K outputs were found. The second experiment began at 1200 h with the first feeding time at 2100 h after fasting about 24 h and the subjects were given a normal sodium diet as in the first experiment, but with the meals given at 2100 h, 2400 h, and 0430 h. The diurnal variations in PRA, plasma aldosterone, and urinary electrolytes disappeared. From this study, it appears that the diurnal variation in urinary electrolyte excretion is a factor of the diurnal variation in PRA and plasma aldosterone. The diurnal variation in PRA and plasma aldosterone are related to the timing of sodium ingestion.     

Platelet-activating factor mediates angiotensin II-induced proteinuria in isolated perfused rat kidney

Isolated kidney preparations (IPK) from male Sprague Dawley rats perfused at constant pressure were used to evaluate the effect of angiotensin II (AII) and platelet-activating factor (PAF) on renal function and urinary protein excretion. Compared with basal, intrarenal infusion of AII at 8 ng/min caused a progressive increase in protein excretion (11 +/- 6 versus 73 +/- 21 micrograms/min) in parallel with a decline in renal perfusate flow (RPF) (29 +/- 3 versus 18 +/- 3 ml/min). Addition to the perfusate of PAF at 50 nM final concentration also induced proteinuria (9 +/- 4 versus 55 +/- 14 micrograms/min) but did not change RPF (29 +/- 3 versus 30 +/- 3 ml/min). Preexposure of isolated kidneys to the PAF receptor antagonist WEB 2086 prevented the increase in urinary protein excretion induced by AII infusion (basal: 13 +/- 6; post-AII: 12 +/- 7 micrograms/min) but failed to prevent the vasoactive effect of AII (RPF, basal: 30 +/- 2; post-AII: 21 +/- 3 ml/min). In additional experiments, dexamethasone reduced the proteinuric effect of PAF remarkably. These results indicate that in isolated kidney preparation: (1) AII infusion induced proteinuria and decreased RPF; and (2) the effect of AII in enhancing urinary protein excretion was completely prevented by a specific PAF receptor antagonist, which, however, did not influence the AII-induced fall in RPF. It is suggested that PAF plays a major role in AII-induced changes in the permselective function of the glomerular capillary barrier.     

Inhibition of the reoxidation of the secondary electron acceptor of photosystem II by bicarbonate depletion

Intravenous infusion of 600 ng/kg/min of 1-sarcosine, 8-isoleucine-angiotensin II, an angiotensin II antagonist, caused a marked blood pressure fall and a decrease in plasma aldosterone in 3 patients with Bartter's syndrome. These results indicate that proximal cause of Bartter's syndrome is an arteriolar hyporesponsiveness to angiotensin II and that this angiotensin II analogue has an antagonist activity on peripheral arterioles as well as adrenal cortex.     

Conversion disorder presenting in a patient with an implantable morphine pump and an epidural abscess resulting in paraplegia

The purpose of this study was to determine long-term role of nitric oxide in modulating the chronic renal and arterial pressure responses to angiotensin II (AII). In normal dogs, intrarenal AII infusion (1.0 ng/KG/min) decreased renal plasma flow (RPF) by 31% and glomerular filtration rate (GFR) by 17% and increased mean arterial pressure (MAP) by 22%. In dogs with chronic intrarenal NO synthesis blockade with N(omega)-nitro-L-arginine methyl ester (3 micrograms/kg/min), AII decreased RPF by 25% and GFR by 19%, and increased MAP by 7%. These data indicate that chronic inhibition of NO synthesis within the kidney attenuated the long-term renal and arterial pressure responses by AII in dogs.     

AT1 receptor subtype mediates the inhibitory effect of central angiotensin II on cerebrospinal fluid formation in the rat

The effect of central administration of angiotensin II (AII) on cerebrospinal fluid (CSF) formation was studied in pentobarbital-anesthetized, artificially-ventilated rats. CSF production was measured by the ventriculocisternal perfusion method with Blue Dextran 2000 as the indicator. Baseline value of CSF production was 3.35 +/- 0.08 microliters/min. Intracerebroventricular (i.c.v.) infusion of AII at rates of 0.5 and 5 pg/min significantly lowered (P < 0.01) CSF formation by 23% and 16%, respectively. In comparison, high peptide doses (50 and 500 pg/min) did not alter this parameter. The inhibitory effect of low AII doses on CSF formation was blocked by the i.c.v. AT1 receptor subtype antagonists, losartan and SK&F 108566 (2.4 and 2.7 ng/min, respectively), but not by the AT2 receptor subtype-specific agent, PD 123319 (3.8 ng/min). Peptide AII antagonists, [Sar1,Ile8]AII (5 ng/min), which binds to both AT1 and AT2 receptors, had a similar effect to those of AT1-specific blockers. It is concluded that AII, by controlling CSF formation, may influence the water and electrolyte balance in the brain.     

Characterization of the hemodynamic response to intravenous diaspirin crosslinked hemoglobin solution in rats

Diaspirin crosslinked hemoglobin solution (DCLHB) has potential for clinical use as an oxygen-carrying solution because of its excellent oxygen transport properties and biochemical stability. The present study characterizes the effects of intravenous infusions of 0.625-40 mL/kg (62.5-4000 mg/kg) DCLHb on mean blood pressure (MAP) and heart rate (HR) in conscious rats. DCLHb at all doses tested except 62.5 mg/kg was associated with an immediate increase in MAP (25-30% above baseline) that peaked between 20-30 minutes after infusion and returned to baseline within 120-300 minutes in a dose-dependent manner. Maximum MAP achieved was in the range of 129 +/- 7 to 140 +/- 7 mm Hg and there was no statistically significant difference in the response between doses. HR responded in a reciprocal manner to changes in MAP. Volume- and oncotic-matched infusions of LR and albumin did not alter MAP or HR. Slow infusion (0.34 mL/min) of DCLHb appeared to blunt the magnitude of the pressor response when compared to bolus injection (< 10 sec). DCLHb administration is associated with a pressor response that is not due to volume load, oncotic pressure, or rate of infusion, suggesting that it is intrinsic to the modified hemoglobin molecule and pharmacologic in nature.     

Organ specificity of angiotensin II and Des-aspartyl angiotensin II in the conscious rat

Des-Asp angiotensin II (des-Asp AII) is a naturally occurring heptapeptide metabolite of angiotensin II (AII) which is formed by the enzymatic action of aminopeptidase A. Angiotensin II and des-Asp AII were infused into unanesthetized rats while direct mean arterial pressure, serum aldosterone and serum corticosterone were measured. Both AII and des-Asp AII caused a dose-related increase in serum aldosterone with a significant increase occurring with a dose as low as 1 ng/min. This effect was blocked by pretreatment with 1-Sar-8-Ala-angiotensin II, a competitive inhibitor of AII; however, the inhibitor was more effective in blocking the effects of AII (101%) than of des-Asp AII (82%). Both angiotensins induced a dose-related increase in serum corticosterone and mean arterial pressure. Des-Asp AII was however only 1/10 as potent as AII in elevating mean arterial pressure. 1-Sar-8-Ala-AII was also effective in inhibiting the pressor effects of AII and des-Asp AII. These data illustrate a high degree of organ specificity or selectivity for des-Asp AII and a low specificity for AII. Aminopeptidase A and leucine aminopeptidase were identified in the adrenal cortex and medulla in large amounts. Des-Asp AII may thus be formed from AII locally in the adrenal gland prior to exerting its action at that site.     

Influence of physiologic hyperglucagonemia on basal and insulin-inhibited splanchnic glucose output in normal man

To evaluate the effects of physiologic hyperglucagonemia on splanchnic glucose output, glucagon was infused in a dose of 3 ng/kg per min to healthy subjects in the basal state and after splanchnic glucose output had been inhibited by an infusion of glucose (2 mg/kg per min). In the basal state, infusion of glucagon causing a 309 +/- 25 pg/ml rise in plasma concentration was accompanied by a rapid increase in splanchnic glucose output to values two to three times basal by 7-15 min. The rise in arterial blood glucose (0.5-1.5 mM) correlated directly with the increment in splanchnic glucose output. Despite continued glucagon infusion, and in the face of stable insulin levels, splanchnic glucose output declined after 22 min, returning to basal levels by 30-45 min. In the subjects initially receiving the glucose infusion, arterial insulin concentration rose by 5-12 muU/ml, while splanchnic glucose output fell by 85-100%. Infusion of glucagon causing an increment in plasma glucagon concentration of 272 +/- 30 pg/ml reversed the inhibition in splanchnic glucose production within 5 min. Splanchnic glucose output reached a peak increment 60% above basal levels at 10 min, and subsequently declined to levels 20-25% below basal at 30-45 min. These findings provide direct evidence that physiologic increments in plasma glucagon stimulate splanchnic glucose output in the basal state and reverse insulin-mediated inhibition of splanchnic glucose production in normal man. The transient nature of the stimulatory effect of glucagon on splanchnic glucose output suggests the rapid development of inhibition or reversal of glucagon action. This inhibition does not appear to depend on increased insulin secretio.     

Renal hemodynamics during norepinephrine and low-dose dopamine infusions in man

OBJECTIVE: To characterize the effects of pressor doses of norepinephrine and low-dose dopamine (3 micrograms/kg/min) on renal hemodynamics in man, as well as to determine the clinical relevance of combining dopamine with norepinephrine. DESIGN: Prospective, single-blind, randomized study. SETTING: Clinical research unit of a tertiary care hospital. SUBJECTS. Six healthy male volunteers ranging in age between 20 and 28 yrs. INTERVENTIONS: The subjects were assigned randomly to four treatments (1 wk apart) in which renal hemodynamics and electrolyte excretion were assessed. Treatments consisted of 180-min infusions of the following: a) 0.9% sodium chloride (control); b) pressor doses of norepinephrine; c) dopamine at 3 micrograms/kg/min; and d) pressor doses of norepinephrine and dopamine at 3 micrograms/kg/min. Pressor doses of norepinephrine was defined as doses required to increase mean arterial pressure (MAP) by 20 mm Hg. MEASUREMENTS AND MAIN RESULTS: Glomerular filtration rate and renal blood flow were derived from inulin and para-aminohippurate clearances, respectively. Urine output and urine solute excretion were also determined. The mean norepinephrine dose required to increase MAP by 22 +/- 2 mm Hg was 118 +/- 30 ng/kg/min (range 76 to 164). After the addition of dopamine, similar doses of norepinephrine resulted in an MAP increase of 15 +/- 4 mm Hg. Glomerular filtration rate and urine output were comparable under all conditions. The infusion of norepinephrine decreased renal blood flow from 1241 +/- 208 to 922 +/- 143 mL/min/1.73 m2 (p = .03). The addition of dopamine returned renal blood flow to baseline values. The clearance of urine sodium increased significantly with the infusion of dopamine alone (p = .03). All subjects completed the four treatment periods. Adverse events, manifested mostly as palpitations and flushing, were rare and self-limiting. CONCLUSIONS: The addition of dopamine (3 micrograms/kg/min) to pressor doses of norepinephrine normalized renal blood flow in healthy volunteers. These hemodynamic changes were not reflected in urine output and glomerular filtration rate; hence, these monitoring parameters may be unreliable indicators of renal function in the setting of vasopressor therapy. In addition, systemic effects were observed with dopamine (3 micrograms/kg/min), as indicated by a decrease in MAP.     

Differential effects of endotoxaemia on pressor and vasoconstrictor actions of angiotensin II and arginine vasopressin in conscious rats

1. Regional haemodynamic responses to arginine vasopressin (AVP; 0.5, 1.0, 5.0 pmol i.v.) and angiotensin II (AII; 5.0, 10.0, 50.0 pmol i.v.) were measured in conscious Long Evans rats at various times (0, 2, 6 and 24 h) during infusion of lipopolysaccharide (LPS, 150 microg kg(-1) h(-1), i.v., n=9) or saline (n=9). Additional experiments were performed in vasopressin-deficient (Brattleboro) rats infused with LPS (n=7) or saline (n=8) to determine whether or not, in the absence of circulating vasopressin, responses to the exogenous peptides differed from those in Long Evans rats. 2. In the Long Evans rats, during the 24 h infusion of LPS, there was a changing haemodynamic profile with renal vasodilatation from 2 h onwards, additional mesenteric vasodilatation at 6 h, and a modest hypotension (reduction in mean arterial blood pressure (MAP) from 103+/-1 to 98+/-2 mmHg) associated with renal and hindquarters vasodilatation at 24 h. 3. In the Brattleboro rats, the changes in regional haemodynamics during LPS infusion were more profound than in the Long Evans rats. At 2 h and 6 h, there was a marked fall in MAP (from 103+/-3 mmHg; to 65+/-3 mmHg at 2 h, and to 82+/-4 mmHg at 6 h) associated with vasodilatation in all three vascular beds. After 24 h infusion of LPS, the hypotension was less although still significant (from 103+/-3 mmHg; to 93+/-4 mmHg, a change of 10+/-4 mmHg), and there was renal and hindquarters vasodilatation, but mesenteric vasoconstriction. 4. During infusion of LPS, at each time point studied, and in both strains of rat, pressor responses to AII and AVP were reduced, but the changes were less marked at 6 h than at 2 h or 24 h. The reduced pressor responses were not accompanied by generalized reductions in the regional vasoconstrictor responses. Thus, in the Long Evans rats, the renal vasoconstrictor responses to both peptides were enhanced (at 6 h and 24 h for AVP; at all times for AII), whereas the mesenteric vasoconstrictor response to AVP was unchanged at 2 h, enhanced at 6 h and reduced at 24 h. The mesenteric vasoconstrictor response to AII was reduced at 2 h, normal at 6 h and reduced at 24 h. The small hindquarters vasoconstrictor responses to both peptides were reduced at 2 h and 6 h, but normal at 24 h. 5. In the Brattleboro rats, the renal vasoconstrictor responses to both peptides were reduced at 2 h and enhanced at 6 h and 24 h, whereas the mesenteric vasoconstrictor response to AVP was normal at 2 h and 6 h, and reduced at 24 h. The response to AII was reduced at 2 h, normal at 6 h and reduced again at 24 h. There were no reproducible hindquarters vasoconstrictions to AVP in the Brattleboro rats. The small hindquarters vasoconstrictor responses to AII were unchanged at 2 h and enhanced at 6 h and 24 h. 6. In isolated perfused mesenteric vascular beds, removed after 24 h of LPS infusion in vivo, there was an increase in the potency of AVP in both strains (Long Evans, ED50 saline: 56.9+/-15.0 pmol, ED50 LPS: 20.4+/-4.8 pmol, Brattleboro, ED50 saline: 38.6+/-4.2, ED50 LPS: 19.6+/-2.9 pmol), but no change in the responses to AII. 7. These findings indicate that a reduced pressor response to a vasoconstrictor challenge during LPS infusion is not necessarily associated with a reduced regional vasoconstriction. The data obtained in the Brattleboro rats indicate a potentially important role for vasopressin in maintaining haemodynamic status during LPS infusion in Long Evans rats. However, it is unlikely that the responses to exogenous AVP (or AII) are influenced by changes in the background level of endogenous vasopressin, since the patterns of change were similar in Long Evans and Brattleboro rats. 8. The results obtained in isolated perfused mesenteric vascular beds differed from those in vivo, possibly due to the conditions pertaining with in vitro perfusion.     

Atypical strains of verocytotoxin-producing Escherichia coli O157 in beef cattle at slaughter in Veneto region, Italy

A population-based study was performed in order to study the interrelationships of the circulating components of the renin-angiotensin system during basal conditions and their relations to blood pressure (BP), age and gender. One hundred and four women and 95 men, 16-70 years old, evenly age distributed and randomly selected from the population of Link?ping, Sweden, participated. Venous blood was drawn at 08.00 hours and ambulatory BP recording was then performed. Serum angiotensin-converting enzyme (ACE) activity correlated with plasma angiotensin II (r = 0.20, P = 0.004), but when calculated separately according to gender, the correlation remained significant only in men (r = 0.33, P = 0.001). Plasma renin activity (PRA) correlated negatively with age (r = -0.30, P < 0.0001), but immunoreactive active renin (IRR) and angiotensin II did not. PRA and IRR correlated negatively with BP in women but correlations disappeared after age adjustment. The 23 women on oestrogen medication did not differ from the remaining 81 with respect to age (P = 0.5), IRR (P = 0.96) or angiotensin II (P = 0.4) levels, but PRA was higher (2.2 +/- 1.4 ng Ang l/ml/h and 1.5 +/- 0.9 ng Ang l/ml/h, respectively, P = 0.004). PRA (r = 0.38, P < 0.0001) and IRR (r = 0.49, P < 0.0001) correlated positively with the levels of angiotensin II. In conclusion the fact that PRA, but not IRR, declined with age and was higher among oestrogen-treated women, although angiotensin II was unaffected suggests IRR to be a more robust marker of angiotensin II levels than is PRA in a population-based setting. ACE correlates positively with angiotensin II in men.     

Vasoactive intestinal peptide, but not pituitary adenylate cyclase-activating peptide, modulates the responsiveness of the gonadotroph to LHRH in man

Vasoactive intestinal peptide (VIP) and pituitary adenylate cyclase-activating peptide (PACAP) are hypothalamic peptides sharing considerable sequence homology which are postulated to be hypophysiotrophic releasing factors. When infused into man, PACAP has no effect on anterior pituitary hormone levels, while VIP causes a significant increase in circulating prolactin concentrations. However, PACAP has recently been shown to augment the release of LH and FSH in response to LHRH in rat anterior pituitary cell culture. In order to ascertain if either peptide has a similar effect in man, PACAP and VIP were infused at 3.6 pmol/kg per min into six healthy male volunteers, and an LHRH test was performed 30 min after the infusion was commenced. Infusion of PACAP did not alter the gonadotrophin response to LHRH significantly. However, VIP augmented the release of LH significantly, both during the infusion and for 30 min thereafter, although there was no effect on FSH release. Thus VIP, but not PACAP, potentiates the release of LH after LHRH injection in man.