Intravenous urocortin II decreases blood pressure through CRF(2) receptor in rats

Urocortin II (Ucn II) is a new member of the corticotropin-releasing factor (CRF) family that binds selectively to the CRF subtype 2 receptor (CRF(2)). CRF or urocortin injected intravenously (i.v.) induced hypotension. We investigated the influence of iv human Ucn II (hUcn II) on basal mean blood pressure (MAP) and on the sympathetic mediated hypertensive response to TRH analog, RX-77368 injected intracisternally (i.c.) 20 min after hUcn II in urethane-anesthetized rats. Ucn II (3, 10, and 30 microg/kg, i.v.) significantly decreased basal MAP from baseline by -20.9+/-6.5, -21.3+/-5.4 and -46.8+/-6.5 mm Hg, respectively, after 10 min. RX-77368 (30 ng, i.c.) elevated MAP for over 90 min with a maximal hypertensive response at 20 min. Ucn II (3, 10, and 30 microg/kg, i.v.) did not alter the 20 min net rise in MAP induced by RX-77368 (35.7+/-7.1, 32.6+/-3.3 and 24.6+/-6.9 mm Hg, respectively) compared with vehicle (33.6+/-4.3 mm Hg). The selective CRF(2) antagonist, astressin(2)-B (60 microg/kg, i.v.) abolished hUcn II hypotensive action while having no effect on basal MAP. These data show that iv hUcn II induces hypotension through peripheral CRF(2) receptor while not altering the responsiveness to sympathetic nervous system-mediated rise in MAP.     

Cardiac and hemodynamic responses to synthetic atrial natriuretic factor in rats

To determine the hemodynamic effects of a hypotensive dose of atrial natriuretic factor (ANF), a synthetic peptide containing 26 amino acids of endogenous rat ANF (Arg-Arg-Ser-Ser-Cys-Phe-Gly-Gly-Arg-Ile-Asp-Arg-Ile-Gly-Ala-Gln-Ser-Gly -Leu-Gly-Cys-Asn-Ser-Phe-Arg-Tyr-COOH) was studied in two groups of barbiturate anesthetized rats. In the first experiment, a 20-minute infusion of a hypotensive dose, 95 pmole/min i.v., of the synthetic ANF decreased mean arterial pressure (MAP) by 40 +/- 3 mm Hg from a baseline of 128 +/- 5 mm Hg, and cardiac output (CO) (microsphere method) by 7.8 +/- 1.8 ml/min/100 gm from a baseline of 23.5 +/- 1.3 ml/min/100 gm. Synthetic ANF did not significantly affect the total peripheral resistance (TPR) measured at the end of the 20-minute infusion. Sodium nitroprusside (SNP), infused at an equihypotensive dose of 20 micrograms/kg/min i.v., produced the same hemodynamic profile in seven other animals; in contrast, 0.3 mg/kg i.v. of hydralazine (n = 7) lowered MAP by 56 +/- 6 mm Hg and reduced TPR index by 3.0 +/- 0.6 mm Hg/ml/min/100 gm, but did not change CO. Other than an increase in coronary blood during SNF infusion, there were no significant changes in the distribution of cardiac output. Infusion of the saline vehicle had no significant effects on any of these parameters. The results of the second experiment in anesthetized rats confirmed that hypotensive doses of 40 and 100 pmole/kg/min i.v. lowered CO (dye dilution method) from a baseline of 33 +/- 6 to a minimum of 24 +/- 2 ml/min/100 gm (p less than 0.05) without affecting TPR. In addition, synthetic ANF did not significantly affect heart rate (HR) but it slightly reduced cardiac contractility (dp/dt50). These results suggest that the hypotensive dose of synthetic ANF reduced cardiac output, partially by diminishing stroke volume, and perhaps contractility.     

A potent hypotensive factor in chicken left ventricle

Chicken artria and ventricles both have membrane-bound granules which resemble those containing atriopeptin (ANP) in mammals. However, nothing is known about the contents of the avian granules. A previous study in chickens showed that although extracts of whole chicken heart or synthetic rat ANP both caused profound hypotension, ANP caused both natriuresis and diuresis, while chicken heart extract did not. The present study sought to locate the region(s) of chicken heart containing the hypotensive activity, and to observe the effect on sodium and water excretion and blood pressure in rats. Acid extracts of either atrium, either ventricle, ventricular septum, skeletal muscle, and liver were identically prepared from chickens and rats. Extracts were adjusted to the same protein concentration and injected (0.15 ml/kg) into anesthetized Single Comb White Leghorn roosters. Mean arterial pressure (MAP) and the time for recovery were measured. The most potent extract from chicken hearts was from the left ventricle (-38 +/- 1 mm Hg, 149 +/- 9 sec to recover). All other extracts (including right ventricle) produced only small (10-20 mm Hg), short-lived (20-30 sec) decreases in MAP. In contrast, only rat atrial extracts evoked long-lasting hypotension (greater than 40 mm Hg, recovery time greater than 200 sec). A 30-min infusion of the most potent chicken extract (left ventricle, CLV) into rats produced a small but significant natriuresis and diuresis compared to the vehicle time control (P less than 0.05) and the hypotensive response to bolus injection was about one-third that seen in the chicken. The location of potent spasmolytic activity primarily in chicken left ventricle, the different avian renal responses to chicken heart extract and synthetic rat ANP (5), and the weak diuretic, natriuretic, and hypotensive effects of CLV extract in rats all suggest that the chicken heart substance may be different from mammalian ANP.     

Altered cardiovascular responses to chronic angiotensin II infusion in aged rats

In this work we determined by telemetry the cardiovascular effects produced by Ang II infusion on blood pressure (BP) and heart rate (HR) in aged rats. Male Wistar aged (48-52 weeks) and young (12 weeks) rats were used. Ang II (6 microg/h, young, n=6; aged, n=6) or vehicle (0.9% NaCl 1 microl/h, young, n=4; aged, n=5) were infused subcutaneously for 7 days, using osmotic mini-pump. The basal diurnal and nocturnal BP values were higher in aged rats (day: 98+/-0.3 mm Hg, night: 104+/-0.4 mm Hg) than in the young rats (day: 92+/-0.2 mm Hg, night: 99+/-0.2 mm Hg). In contrast, the basal diurnal and nocturnal HR values were significantly smaller in the aged rats. Ang II infusion produced a greater increase in the diurnal BP in the aged rats (Delta MAP=37+/-1.8 mm Hg) compared to the young ones (Delta MAP=30+/-3.5 mm Hg). In contrast, the nocturnal MAP increase was similar in both groups (young rats; Delta MAP=22+/-3.0 mm Hg, aged rats; Delta MAP=24+/-2.6 mm Hg). During Ang II infusion HR decreased transiently in the young rats. An opposite trend was observed in the aged rats. Ang II infusion also inverted the BP circadian rhythm, in both groups. No changes in HR circadian rhythm were observed. These differences suggest that the aging process alters in a different way Ang II-sensitive neural pathways involved in the control of autonomic activity.     

Mechanism of vasorelaxant activity of a fraction of root extract of Sesamum indicum Linn

The petroleum ether soluble fraction (SIPE) of the root extract of S. indicum was evaluated for the vasorelaxant activity using isolated rat aorta. SIPE up to 180 microg/ml concentration significantly inhibited phenylephrine- and KCl-induced contraction to the extent of 98.13 +/- 6.37 and 70.19 +/- 3.43% respectively in isolated rat aorta in a concentration dependent manner. The vasorelaxant activity was not blocked by propranolol (10 microM), atropine (1 microM) indomethacin (10 microM) and glibenclamide (10 microM). Influence of SIPE on phenylephrine-induced contractions in aortic preparations in absence of functional endothelium and on pre-incubating the tissue with L-NAME (300 microM) or methylene blue (10 microM) was also studied. SIPE at 180 microg/ml concentration could elicit partial relaxation in presence of L-NAME or methylene blue to the extent of 34.26 +/- 6.13 and 25.66 +/- 10.95% respectively. However, in absence of functional endothelium, SIPE exhibited little relaxation to the extent of 6.70 +/- 4.87%. These studies revealed that the vasorelaxant activity of SIPE was chiefly mediated through endothelium-dependent pathway.     

Integrative pattern of vasomotor efficiency in SHR during ontogenesis

Numerous studies concerning the cardiovascular system in SHR often yield controversial data. The background of this diversity has various roots, ranging from different vascular segments or areas studied up to the different age of experimental animals. Our study aimed to follow the BP as an integrated response of vascular system. This approach was justified since stabilized cardiac output in SHR was proved till 1 year of age. The groups of male SHR (aged 3, 5, 9, 17 and 52 weeks) and age-matched Wistar rats were used. Significant basal BP difference between SHR and Wistar rats was found at 9 weeks of age and continued till the age of 52 weeks, reaching 189.6+/-11.9 mm Hg in SHR and 117.3+/-6.9 mm Hg in Wistar rats P<0.01 . The significant difference in BP increase to two doses of noradrenaline 0.1 microg and 1 microg between SHR and control rats was also found at the age of 9 weeks. At 52 weeks the BP increment to two doses of noradrenaline was in SHR 19.7+/-2.0 mm Hg and 60.5+/-3.9 mm Hg and in Wistar rats 7.4+/-1.9 mm Hg and 40.5+/-3.2 mm Hg P<0.01 . The hypotensive response to acetylcholine 0.1 microg, 1 microg and 10 microg in SHR was enhanced at 17 weeks of age only and this amplification persisted till the age of 52 weeks. In 52-week-old SHR the hypotensive response to three doses was 69.9+/-10.2 mm Hg, 87.5+/-11.8 mm Hg and 103.4+/-10.6 mm Hg, while in Wistar rats it was 37.4+/-4.2 mm Hg P<0.01 , 62.3+/-3.5 mm Hg P<0.01 and 73.5+/-2.8 mm Hg P<0.05 . In conclusion, the efficiency of cardiovascular system of SHR to respond to noradrenaline was already enhanced from 9 weeks of age, whereas the response to acetylcholine was not augmented before the age of 17 weeks.     

Fluid extravasation from spleen reduces blood volume in endotoxemia

We recently demonstrated that fluid is filtered out of the splenic circulation and into the lymphatic system. The current experiments were designed to investigate the importance of this route of fluid extravasation in endotoxemia. Lipopolysaccharide (LPS) was infused into conscious intact and splenectomized rats (150 microg x kg(-1). h(-1) i.v. for 18 h). In the intact rats, mean arterial pressure (MAP) fell from 101+/-2.4 to 88+/-3.9 mm Hg (n = 7) and then stabilized at about 90 mm Hg. Hematocrit rose from 41+/-0.9 to 45+/-0.4% at 40 min, at which time plasma volume had fallen from 4.7+/-0.12 to 4.0+/-0.05 ml/100 g body wt. In the splenectomized rats MAP did not fall and hematocrit did not rise. There also was no change in plasma volume, i.e., splenectomy prevented the hypotension and hemoconcentration customarily induced by LPS. In a second series of experiments, splenic arterial and venous blood flows were simultaneously measured in anesthetized rats infused with LPS (150 microg x kg(-1) x h(-1)). LPS increased splenic fluid efflux. We conclude that during endotoxemia the initial fall in circulating blood volume may be attributed to fluid extravasation from the splenic vasculature.     

Endothelium-dependent hypotensive and vasorelaxant effects of the essential oil from aerial parts of Mentha x villosa in rats.

Cardiovascular effects of an essential oil from the aerial parts of Mentha x villosa (OEMV) were tested in rats using a combined in vivo and in vitro approach. In non-anesthetized normotensive rats, OEMV (1, 5, 10, 20, 30 mg kg(-1) body wt., i.v.) induced a significant and dose-dependent hypotension (-3 +/- 1.8%; -6 +/- 0.7%; -40 +/- 6.7%; -58 +/- 3.8%; -57 +/- 2.1%, respectively) associated with decreases in heart rate (-1 +/- 0.3%; -9 +/- 0.9%; -17 +/- 3.2%; -72 +/- 3.1%; -82 +/- 1.4%, respectively). The hypotensive and bradycardic responses evoked by OEMV were attenuated and blocke by pre-treatment of the animals with atropine (2 mg kg(-1) body wt., i.v.). In isolated rat atrial preparations, OEMV (10, 100, 300, 500 microg ml(-1)) produced concentration-related negative chronotropic and inotropic effects (IC50 value = 229 +/- 17 and 120 +/- 13 microg ml(-1), respectively). In isolated rat aortic rings, increasing concentrations of OEM (10, 100, 300, 500 microg ml(-1)) were able to antagonize the effects of phenylephrine (1 microM), prostaglandin F2alpha (10 microM) and KCl (80 mM)-induced contractions (IC50 value = 255 +/- 9, 174 +/- 4 and 165 +/- 14 microg ml(-1), respectively). The vasorelaxant activity induced by OEMV was attenuated significantly by either endothelium removal (IC50 value = 304 +/- 9 microg ml(-1)), NG-nitro L-arginine methyl ester (L-NAME) 100 microM (IC50 value=359 +/- 18 microg ml(-1)), L-NAME 300 microM (IC50 value = 488 +/- 20 microg ml(-1)) or indomethacin 10 microM (IC50 value = 334 +/- 18 microg ml(-1)). However, it was not affected by atropine 1 microM (IC50 value = 247 +/- 12 microg ml(-1)). Furthermore, the hypotensive response induced by OEMV was attenuated significantly after nitric oxide (NO) synthase blockade (L-NAME, 20 mg kg(-1) body wt., i.v.), while bradycardia was not altered. The results suggest that the hypotensive effect induced by OEMV is probably due to its direct cardiodepressant action and peripheral vasodilation, which can be attributed to both endothelium-dependent (via EDRFs, at least NO and prostacyclin) and endothelium-independent mechanisms (such as Ca2+ channel blockade).     

Involvement of angiotensin-(1-7) in the hypothalamic hypotensive effect of captopril in sinoaortic denervated rats

The role of anterior hypothalamic angiotensin-(1-7) (Ang-(1-7)) on blood pressure regulation was studied in sinoaortic denervated (SAD) rats. Since angiotensin-converting enzyme inhibitors increase endogenous levels of Ang-(1-7), we addressed the involvement of Ang-(1-7) in the hypotensive effect induced by captopril in SAD rats. Wistar rats 7 days after SAD or sham operation (SO) were anaesthetized and the carotid artery was cannulated for monitoring mean arterial pressure (MAP). A needle was inserted into the anterior hypothalamus for drug administration. Intrahypothalamic administration of Ang-(1-7) (5 pmol) was without effect in SO rats but reduced MAP in SAD rats by 15.5+/-3.2 mm Hg and this effect was blocked by 250 pmol [D-Ala(7)]-Ang-(1-7), a Mas receptor antagonist. Angiotensin II (Ang II) induced an increase in MAP in both groups being the effect greater in SAD rats (DeltaMAP=15.8+/-1.4 mm Hg) than in SO rats (DeltaMAP=9.6+/-1.0 mm Hg). Ang-(1-7) partially abolished the pressor response caused by Ang II in SAD rats. Whilst the captopril intrahypothalamic injection did not affect MAP in SO animals, it significantly reduced MAP in SAD rats (DeltaMAP=-13.3+/-1.9 mm Hg). Either [D-Ala(7)]-Ang-(1-7) or an anti-Ang-(1-7) polyclonal antibody partially blocked the MAP reduction caused by captopril. In conclusion, whilst Ang-(1-7) does not contribute to hypothalamic blood pressure regulation in SO normotensive animals, in SAD rats the heptapeptide induces a reduction of blood pressure mediated by Mas receptor activation. Although Ang-(1-7) is not formed in enough amount in the AHA of SAD animals to exert cardiovascular effects in normal conditions, our results suggest that enhancement of hypothalamic Ang-(1-7) levels by administration of captopril is partially involved in the hypotensive effect of the ACE inhibitor.     

Methysergide delays the decompensatory responses to severe hemorrhage by activating 5-HT(1A) receptors

Central administration of the serotonin receptor ligand methysergide delays the decompensatory response to hypotensive hemorrhage. This study was performed to determine the receptor subtype that mediates this effect. Lateral ventricular (LV) injection of methysergide (40 microg) delayed the hypotensive, bradycardic, and sympathoinhibitory responses to blood withdrawal (1.26 ml/min) in conscious rats. The response was quantified, in part, as the blood volume withdrawal that produced a 40-mmHg fall in blood pressure. The delayed hypotensive response produced by methysergide (8.2 +/- 0.2 vs. 5.6 +/- 0.2 ml, P < 0.01) was reversed by the 5-hydroxytryptamine (HT)(1A) antagonist WAY-100635 (30 microg iv: 6.7 +/- 0.4 ml, P < 0. 01; 100 microg iv: 5.6 +/- 0.1 ml, P < 0.01). LV injection of the 5-HT(1A) agonist (+)-8-hydroxy-2-(di-n-propylamino)tetralin (8-OH-DPAT) also delayed the hypotensive (10 microg: 8.6 +/- 0.3, P < 0.01; 20 microg: 9.2 +/- 0.3 ml, P < 0.01), bradycardic, and sympathoinhibitory responses to hemorrhage. WAY-100635 (10 microg iv) completely reversed the effects of 8-OH-DPAT (20 microg: 5.4 +/- 0.3 ml). Neither selective blockade of 5-HT(2) receptors nor stimulation of 5-HT(1B/1D) receptors had any effect on hemorrhage responses. These data indicate that methysergide stimulates 5-HT(1A) receptors to delay the decompensatory responses to hemorrhage.     

Bimodal effects of chronically administered neurokinin B (NKB) on in vivo and in vitro cardiovascular responses in female rats

The in vivo cardiovascular effects of acutely administered neurokinin B (NKB) have been attributed both to direct effects on vascular tone and to indirect effects on central neuroendocrine control of the circulation. We proposed: 1) that a modest long-term increase in plasma NKB levels would decrease mean arterial pressure (MAP) due to attenuated peripheral vascular tone, and 2) that chronic high-dose NKB would increase MAP, due to increased sympathetic outflow which would override the peripheral vasodilation. We examined the in vivo and in vitro cardiovascular effects of chronic peripheral NKB. Low- (1.8 nmol/h) or high- (20 nmol/h) dose NKB was infused into conscious female rats bearing telemetric pressure transducers. MAP, heart rate (HR) and the pressor responses to I.V. phenylephrine (PE, 8 microg) and angiotensin II (Ang II, 150 ng) were measured. Concentration-response curves of small mesenteric arteries were constructed to PE using wire myography. Low-dose NKB reduced basal MAP (88+/-2 mm Hg to 83+/-2 mm Hg), did not affect resting HR, reduced the pressor responses to PE, and attenuated the maximal constriction of mesenteric arteries to PE and KCl. By contrast, high-dose NKB increased basal MAP (86+/-1 mm Hg to 89+/-1 mm Hg), increased HR (350+/-3 beats/min to 371+/-3 beats/min), increased the pressor responses to Ang II and, contrary to our hypothesis, increased the maximum contractile responses of mesenteric arteries to PE and KCl. The cardiovascular effects of NKB are thus dose-dependent: whereas chronic low-dose NKB directly modulates vascular tone to reduce blood pressure, chronic high-dose NKB induces an increase in blood pressure through both central (indirect) and peripheral (direct) pathways.     

Endothelium-derived nitric oxide is involved in the hypotensive and vasorelaxant responses induced by the aqueous fraction of the ethanolic extract of the leaves of Albizia inopinata (Harms) G. P. Lewis in rats.

The acute cardiovascular effects of an aqueous fraction of the ethanolic extract of the leaves (AFL) of Albizia inopinata (Harms) G. P. Lewis (Leguminosae) were studied in rats using a combined in vivo and in vitro approach. In conscious, unrestrained rats, AFL (5, 10 and 20 mg/kg(-1) body wt. i.v., randomly) produced a significant and dose-dependent hypotension associated with increases in heart rate and cardiac output, and with a strong reduction in total peripheral resistances. The hypotensive response to AFL (20 mg/kg(-1) body wt.) was attenuated significantly after nitric oxide (NO) synthase blockade (L-NAME, 20 mg/kg(-1) body wt. i.v.). Furthermore, under these conditions, the associated tachycardia was inhibited completely. In isolated rat aortic rings, increasing concentrations of AFL (10, 20, 40 and 80 microg/ml(-1)) were able to antagonize the effects of phenylephrine- (1 microM) and KCl- (80 mM) induced contractions (IC50 value 65 +/- 4 and 54 +/- 6 microg/ml(-1), respectively). The smooth muscle-relaxant activity of AFL was inhibited similarly either removal of the vascular endothelium or by L-NAME (10 and 100 microM), but was not affected significantly by atropine (1 microM) or indomethacin (10 microM). In isolated rat atrial preparations, AFL (30, 100, 300 and 500 microg/ml(-1)) produced concentration-related negative inotropic and chronotropic effects (IC50 value = 274 +/- 53 and 335 +/- 23 microg/ml(-1), respectively). These results suggest that in rats, the hypotensive effect of AFL is due to a peripheral vasodilation, at least partly secondary to the release of NO by the vascular endothelium. The direct cardio-depressant actions of AFL are of little importance in the systemic effects of the extract.     

Cardiovascular responses to an isosterically modified prostaglandin analog in conscious dogs

The cardiovascular effects of oral and intravenous administration of 0.05 and 0.1 mg/kg of the isosterically modified prostaglandin (PG) analog, (+)- 4-(3-[3-[2-(1-hydroxycyclohexyl)ethyl]-4-oxo-thiazolidinyl] propyl) benzoic acid were ascertained in conscious mongrels. After 0.05 mg/kg p.o., mean arterial pressure (MAP), obtained from indwelling catheters, fell from 105 +/- 1 to 100 +/- 4 mm Hg and total peripheral resistance (TPR) decreased from 0.062 +/- 0.006 to 0.039 +/- 0.002 mm Hg/ml/min. Cardiac output (CO), measured via electromagnetic flow probes, rose from 1.8 +/- 0.2 to 2.6 +/- 0.1 l/min and heart rate from 109 +/- 13 to 128 +/- 8 beats/min. The 0.1 mg/kg p.o. dose produced similar results. Intravenous injection of 0.1 mg/kg immediately dropped MAP from 103 +/- 6 to 58 +/- 3 mm Hg and TPR from 0.049 +/- .006 to .014 +/- .002 mm Hg/ml/min. CO climbed from 2.3 +/- 0.2 to 5.3 +/- 0.5 l/min and HR increased from 126 +/- 9 to 254 +/- 14 beats/min. Stroke volume was not affected by either oral or intravenous administration of the PG analog. Pretreatment with 100 micrograms/kg timolol blunted the CO and HR responses to 0.1 mg/kg iv of the PG analog without affecting the depressor response. Metaraminol infused during injection of 0.1 mg/kg iv of the PG analog diminished all responses. When compared to the cardiovascular effects of hydralazine and nitroprusside, the profile of the PG analog activity closely resembled that produced by the arterial vasodilator, hydralazine; in contrast, nitroprusside (which also dilates veins) reduced stroke volume, but did not significantly affect HR. In conclusion, dilation of the resistance vessels by the PG analog decreased MAP and TPR and reflexly elevated CO and HR in conscious dogs.     

Hypothalamic angiotensinergic-noradrenergic systems interaction in fructose induced hypertension

OBJECTIVE: Several studies suggest the importance of the interaction between the renin angiotensin and sympathetic nervous systems in blood pressure control, especially in clinical situations such as the metabolic syndrome. Previously, we have demonstrated changes in noradrenergic hypothalamic control of blood pressure in an animal model of insulin resistance and hypertension. The aim of the present study was to evaluate the effects of the interaction between the noradrenergic and angiotensinergic systems on hypothalamic blood pressure regulation in fructose hypertensive rats. METHODS: In control (C) and fructose-fed hypertensive (F) rats, we studied: 1) the effects of hypothalamic perfusion of irbesartan (AT(1) angiotensin receptor antagonist, 50 and 500 microg ml(-1)) and metoprolol (beta(1) adrenergic receptor antagonist, 10 and 100 microg ml(-1)) on blood pressure, heart rate and noradrenaline intrahypothalamic levels, by means of the microdialysis technique; and 2) the effects of intrahypothalamic microinjection of angiotensin II alone or after metoprolol pre-administration, on blood pressure and heart rate. RESULTS: Meanwhile irbesartan perfusion did not modify neither mean arterial pressure (MAP) nor heart rate or noradrenaline hypothalamic levels in the C group, its highest dose diminished MAP (DeltaMAP: F: - 16.3+/-1 mm Hg, p<0.05) and noradrenaline levels (% of basal levels: 58+/-7%, p<0.05) in the F group, without affecting heart rate. Intrahypothalamic perfusion of metoprolol diminished MAP only in the F group (DeltaMAP: F: -12.1+/-1.1 mm Hg, p<0.05), but did not modify heart rate in both groups. On the other hand, it diminished noradrenaline hypothalamic levels in C (% of basal levels: 53+/-6%, p<0.05) but not in the F group. The pressor response to angiotensin II microinjection was increased in F rats (DeltaMAP: F: 13.3+/-1.5 mm Hg vs. C: 6.9+/-1.8 mm Hg; p<0.05). Previous administration of metoprolol markedly abolished this increment. CONCLUSIONS: Our results suggest the existence of an increase in AT(1) and beta(1) adrenergic receptors tone in the hypothalamus of F rats, which could be related to the increase in blood pressure present in this experimental model. On the other hand, considering that the enhanced pressor response to angiotensin II intrahypothalamic injection in F rats was abolished by previous administration of a beta(1) adrenergic receptor antagonist, these results would indicate that beta(1) adrenergic receptors activation participates in the pressor response to angiotensin II in this experimental model of insulin resistance and hypertension.     

Effect of splenic extract on plasma volume and renal function in the rat

A hypotensive and natriuretic factor has recently been extracted from the rat spleen. Experiments were designed to investigate the mechanisms underlying the increase in urine output caused by splenic extract. Rat spleens were homogenized in phosphate buffered saline (PBS), centrifuged, subjected to ultrafiltration (mol. wt. cutoff 10,000), extracted on C18 affinity columns and dried. After reconstitution in isotonic saline, the extract was injected IV into conscious rats. Splenic extract caused a decrease in plasma volume (17.4+/-1.1 to 15.8+/-1.0 ml at 1 hr), and a delayed increase in urine output (1.8+/-0.2 to 4.0+/-0.4 ml/hr at 2 hr). There were no such changes in the muscle-injected control group. The increase in urine output was accompanied by an increase in glomerular filtration rate (splenic extract, 2.2+/-0.2 to 5.9+/-1.6 ml/min; muscle extract, 2.9+/-0.4 to 3.1+/-0.6 ml/min). Renal blood flow in the splenic extract-injected group fell during the course of the experiment so that, at 120 min., it was significantly lower both with respect to its baseline value and the muscle control group (splenic extract 22.1+/-0.2 to 17.5+/-2.2 ml/min; muscle extract 24.4+/-4.1 to 23.3+/-3.8 ml/min). During this same period, mean arterial pressure in the splenic extract group also fell from 98+/-2 to 91+/-4 mmHg. Renal vascular conductance therefore did not change. In conclusion, splenic extract causes a primary decrease in plasma volume and a delayed increase in urine output that is mediated, at least in part, by an increase in glomerular filtration rate. It is suggested that the splenic factor(s) probably achieves this by differential vasodilatation of the afferent glomerular arteriole and constriction of the efferent glomerular arteriole.     

Systemic blood pressure response to the inhibition of two hyperpolarizing pathways: a comparison to NO-synthase inhibition

The impact on blood pressure of two vasodilating mechanisms, underlied by vascular smooth muscle hyperpolarization, was studied and compared to that induced by nitric oxide NO mechanism. Systemic blood pressure, after inhibitory intervention in arachidonic acid metabolism cytochrome P-450 inhibition by miconazole 0.5 mg/100 g b.w. , one of the hyperpolarizing pathways, did not change. After the inhibition of the action voltage-dependent K(+) channels operator by 4-aminopyridine 0.1 mg/100 g b.w. , the other hyperpolarizing pathway, blood pressure declined slightly from 132.3+/-3.2 mm Hg to 116.5+/-5.0 mm Hg, P<0.05 . Inhibition of nitric oxide production L-NAME 5 mg/100 g b.w. increased blood pressure considerably 123.5+/-2.7 mm Hg to 155.4+/-3.1 mm Hg, P<0.001 . After inhibition of the hyperpolarizing pathway by miconazole, hypotension induced by acetylcholine (Ach, 10 microg represented 63.0+/-1.9 mm Hg vs control value 78.6+/-5.2 mm Hg P<0.001 , by bradykinin (BK) 100 microg 59.4+/-3.9 mm Hg vs control value 71.2+/-6.1 mm Hg P<0.05 . After inhibition of the hyperpolarizing pathway by 4-aminopyridine, hypotension induced by ACh 10 microg achieved 64.6+/-2.5 mm Hg vs control value 78.4+/-2.8 mm Hg P<0.001 and that induced by BK 100 microg 56.6+/-5.3 mm Hg vs control value 72.3+/-2.5 mm Hg P<0.001 . ACh or BK hypotension after the inhibition of the above hyperpolarizing pathways was significantly attenuated. On the contrary, after NO-synthase inhibition the hypotension to ACh was significantly enhanced. Blood pressure decrease after ACh 10 microg hypotension was 91.8+/-4.1 mm Hg vs control value 79.3+/-3.3 mm Hg P<0.01 , and after BK 100 microg it was 78.4+/-7.1 mm Hg vs control value 68.3+/-5.2 mm Hg. A different basal BP response, but equally attenuated hypotension to Ach and BK, was detected after the inhibition of two selected hyperpolarizing pathways. In cotrast, the inhibition of NO production elicited an increase in systemic BP and augmentation of ACh and BK hypotension. The effectiveness of further hyperpolarizing mechanisms in relation to systemic BP regulation and nitric oxide level remains open.     

Aminopropionic acid receptors in paraventricular nucleus mediate pressor and vasopressin responses to endothelin-1 in subfornical organ

Endothelin-1 (ET-1) acts at selected brain loci to elicit a pressor response and secretion of vasopressin (AVP). Glutamatergic receptors of the N-methyl-D-aspartate (NMDA) subtype mediate ET-1-induced AVP secretion in vitro, but the role of glutamatergic receptors in the pressor response and the secretion of AVP in vivo has not been studied. We hypothesized that both the pressor response and AVP secretion in response to ET-1 microinjection into subfornical organ (SFO) would be suppressed by ionotropic glutamatergic receptor antagonists in the paraventricular nucleus (PVN). Sinoaortic denervated male Long Evans rats were equipped with intracerebral cannulae directed into the SFO and the magnocellular region of the PVN bilaterally. Experiments were performed 5 days later in conscious rats. Direct injection of 5 pmol ET-1 into the SFO resulted in a 20 +/- 3 mm Hg increase in mean arterial pressure (MAP) (+/- SE) and a 14.1 +/- 0.3 pg/ml increase in the mean plasma AVP level (+/- SE) (P < 0.001 vs. artificial CSF) that was blocked by selective ET(A) inhibition. Neither the pressor response nor the increase in plasma AVP in response to ET-1 was altered despite prior injection of the NMDA blocker diclozipine (5 microg, MK801) into PVN bilaterally. In contrast, bilateral PVN injection with 6-cyano-7-nitroquinoxaline-2,3-dione (40 nmol, CNQX) prevented the pressor response (MAP +/- SE, - 4 +/- 4 mm Hg) and also inhibited AVP secretion (mean AVP level +/- SE, 0.16 +/- 0.50 pg/ml) (P < 0.001 vs. vehicle in PVN after injection of ET-1 into SFO). These findings support the conclusion that both the pressor response and AVP secretion in response to ET-1 acting at the SFO are mediated by a non-NMDA, most likely an aminopropionic acid glutamatergic receptor within the PVN.     

Evidence for a dual action of converting enzyme inhibitor on blood pressure in normal man

We studied the effect of a converting enzyme inhibitor (CEI), Captopril SQ 14,225 50 mg p.o. in eight supine normal subjects under a high sodium (150 mEq/d) and low sodium (25 mEq/d) diet. On high sodium, plasma renin (PRA) and aldosterone were basal and Saralasin did not lower mean blood pressure. However, CEI induced an 11.4 +/- 3.2 mm fall in blood pressure (p less than 0.02) and either indomethacin 50 mg or ibuprofen 800 mg (PI), when given simultaneously on another day abolished the blood pressure response (2.5 +/- 0.9 mm Hg, p greater than 0.5). In contrast, on a low salt diet where renin was increased, CEI induced a drop in blood pressure which was not significantly altered by PI (12.8 +/- 1.1 vs. 10.0 +/- 3.1 mm Hg, p greater than 0.5). CEI increased plasma renin on both diets (1.7 +/- 0.5 to 3.5 +/- 0.8 and 2.8 +/- 0.6 to 12.5 +/- 3.1 ng/ml/hr respectively both p less than 0.05). Aldosterone did not change (high Na+) or fell (low Na+). Inhibition of Prostaglandin synthesis did not significantly block the renin rise from CEI suggesting that the direct angiotensin II negative feedback is relatively independent of acute prostaglandin release. Our studies suggest that CEI has a dual hypotensive action. In a low renin state, the hypotensive action appears to be mediated through vascular prostaglandins.     

Endothelin-a receptor blockade does not debilitate the cardiovascular and hormonal adaptation to xenon or isoflurane anesthesia in dogs

The objective of this study was to investigate whether circulatory and hormonal changes during xenon plus remifentanil or isoflurane plus remifentanil anesthesia are altered by endothelin-A (ET(A)) receptor blockade. Eight beagle dogs were studied in four protocols (n = 7 each). After a 30-min awake period, anesthesia was induced with 8 mg/kg propofol, administered intravenously (iv), and maintained with either 0.8% +/- 0.01% (vol/vol) isoflurane plus 0.5 microg/kg/min remifentanil (Protocol 1) or 63% +/- 1% (vol/vol) xenon plus 0.5 microg/kg/min remifentanil (Protocol 2) for 1 hr. Protocols 3 and 4 were preceded by ET(A) blockade with ABT-627 (Atrasentan; iv bolus of 1 mg/kg, then 100 microg/kg/h continuously). Irrespective of Atrasentan administration, the mean arterial blood pressure (MAP) ranged between 92 and 96 mm Hg in the awake state and fell to 67 +/- 3 mm Hg in controls (mean +/- SEM) and to 64 +/- 2 mm Hg in the Atrasentan group during isoflurane plus remifentanil anesthesia, whereas MAP remained constant during xenon plus remifentanil anesthesia. A decrease in heart rate was observed during either kind of anesthesia, but bradycardia was most prominent during xenon plus remifentanil anesthesia. In the control groups, and in the Atrasentan-treated dogs, a decrease in cardiac output and an increase in systemic vascular resistance were more prominent during xenon plus remifentanil than during isoflurane plus remifentanil anesthesia. Hormonal alterations during anesthesia remained unaffected by ET(A) receptor blockade. Angiotensin II and vasopressin increased in all protocols, and adrenaline and noradrenaline concentrations rose only during xenon plus remifentanil anesthesia. We conclude that the hemodynamic and hormonal adaptation after xenon plus remifentanil and isoflurane plus remifentanil anesthesia does not depend on the endothelin system, because it is unaffected by ET(A) receptor inhibition. Therefore, the use of Atrasentan does not impair cardiovascular stability during xenon- or isoflurane-based anesthesia in our dog model. However, the way anesthesia is performed is of crucial importance for hemodynamic and hormonal reactions observed during research in animals because the release of vasopressin and catecholamines may be intensified by xenon plus remifentanil anesthesia.     

A new inorganic vasodilator, trans-[Ru(NO)(NH(3))(4)(POEt)(3)](PF(6))(3): hypotensive effect of endothelium-dependent and -independent vasodilators in different hypertensive animals models.

The hypotensive effect of RuNO was investigated in acute and chronic hypertensive rats, as well as in normotensive rats. Acute hypertension rats were used with 30% increase on basal BP (phenylephrine, angiotensin II (Ang II), N(G)-nitro-L-arginine methyl ester (L-NAME), and adult spontaneously hypertensive rats (SHR) (basal BP 168 +/- 3 mm Hg) were used as models for chronic hypertension. Rats were implanted with catheters (iv/ia) for BP measurements and for in bolus administration of RuNO, sodium nitroprusside (SNP), and acetylcholine (Ach) (10, 20, 40 nmol/kg, iv). The principal findings of this study were: (i) The hypotensive response to RuNO was 150% higher in acutely (phenylephrine and Ang II) and chronically (SHR) hypertensive rats than in normotensive rats, except in the case of L-NAME-induced hypertension (deltaMAP = 10 +/- 1.4 mm Hg). Chronic SHR showed 60% increase (deltaMAP = 19 +/- 0.8 mm Hg) in the effect compared to normotensive rats. (ii) The hypotensive response to SNP was lower (60%) in hypertensive rats than in normotensive rats, when compared to RuNO. However, the responses were similar in L-NAME-induced hypertension (deltaMAP = 30 +/- 2 mm Hg). (iii) The vasodilator response to Ach was increased in rats with Ang II-induced hypertension (deltaMAP = 53 +/- 1 mm Hg) and in SHR (deltaMAP = 67 +/- 3 mm Hg). RuNO response was more potent than SNP in hypertensive models and the increment in relation to normotensive was observed in the phenylephrine- and L-NAME-treated rats. This response could be correlated to the different endothelial dysfunction present in each model.