Angiotensin II, aldosterone and arginine vasopressin in plasma in congestive heart failure

Pedersen, E. B.; Danielsen, H.; Jensen, Troy; Madsen, M.; Sørensen, Søren Schwartz; Thomsen, Ole Østergaard

doi:10.1111/j.1365-2362.1986.tb01308.x

Cited by 42 publications

(29 citation statements)

References 26 publications

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“…27 Previous human studies performed under similar experimental conditions have shown that plasma Ang II may increase from 15 to 57 pmol/L after a 2-hour infusion of 1.5 ng/kg per minute 29 or from 20 to 25 to 50 to 70 pmol/L with stepwise increasing doses of Ang II from 0.3 to 3.0 ng/kg per minute each for 30 minutes. 28 Such levels of plasma Ang II were roughly the same observed in human pathophysiological conditions such as CHF 31 and renovascular hypertension. 32 Thus, although we could not measure plasma Ang II, our infusion protocol was designed in the assumption that a stepwise increasing rate of 0.625 to 2.5 ng/kg per minute Ang II would have produced a progressive elevation in plasma Ang II from low baseline levels toward physiological and, later, pathophysiological concentrations.…”

Section: Discussionmentioning

confidence: 63%

Endothelin-A Receptors Mediate Renal Hemodynamic Effects of Exogenous Angiotensin II in Humans

Montanari

Carra

et al. 2003

Hypertension

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Abstract-To investigate whether endothelin-A receptors mediate hemodynamic changes caused by exogenous Angiotensin II in humans, 7 healthy volunteers on a 250-mmol sodium diet underwent 3 separate p-aminohippurate and inulin-based renal hemodynamic studies. In 2 studies, Angiotensin II (increasing rates of 0.625, 1.25, and 2.5 ng/kg per minute, each for 30 minutes) was infused either alone or combined with endothelin-A blocker, BQ123, 0.4 nmol/kg per minute. A third infusion of BQ123 alone was not followed by any change. Key Words: receptors, endothelin Ⅲ angiotensin II Ⅲ kidney Ⅲ hemodynamics Ⅲ human A ngiotensin II (Ang II), a potent endogenous vasoconstricting and sodium-retaining peptide, plays a key role in the regulation of renal function and arterial pressure, 1,2 mostly by activating Ang II-type 1 (AT1) receptors, which leads to elevation in blood pressure, renal vasoconstriction, and sodium retention. Several of such actions are similar to those of endothelin-1 (ET-1), which is the predominant isoform of the endothelin family in human vasculature. 3,4 Vasoactive properties of ET-1 are mediated by two receptor subtypes, ET A and ET B , both leading to vasoconstriction in vascular smooth cells, whereas activation of ET B in endothelial cells causes vasodilation as the result of release of prostacyclin and nitric oxide (NO). 3,4 In humans, however, the ET A receptor is the main mediator of ET-1 renal vasoconstriction. 5-8 ET-1, although it is the most potent endogenous vasoconstrictor, assumes a major hemodynamic role and contributes to the end-organ damage, mainly under experimental pathophysiological conditions. 3,4,9 -11 In most of these, interactions between Ang II and ET-1 may contribute largely to the observed changes. For instance, salt-sensitive hypertension, renal vasoconstriction, and cardiovascular and renal fibrotic damage, produced by chronic administration of exogenous Ang II, can be prevented by inhibition of endogenous ET-1, indicating that ET-1 mediates much of the vasoconstriction caused by chronic Ang II. 9 -11 Furthermore, ET-1 participates in the acute pressor effects of exogenous Ang II 12,13 and partly mediates the vasoconstriction from exogenous Ang II in different vascular beds, including kidney. 14,15 Interestingly, studies in rats have shown that such Ang II-ET-1 interaction may be sodium-dependent, because under elevated sodium intake, ET A blockade inhibited Ang II hypertension much more than under sodium restriction. 16 Ang II also stimulates both ET-1 synthesis and release, 3,4,17 whereas ET-1 enhances the pressor action of Ang II. 18 Finally, ET-1 and Ang II share the same intracellular signaling pathways. 3,17 Thus, ET-1 is generally considered as a powerful mediator of Ang II-dependent vasoconstriction and organ damage under experimental conditions. Conversely, little is known on the role of ET-1 and of its potential interactions with Ang II on systemic and renal hemodynamics in humans. In normal humans, systemic ET A blockade markedly blunts systemic and renal vasoconstr...

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Section: Discussionmentioning

confidence: 63%

Endothelin-A Receptors Mediate Renal Hemodynamic Effects of Exogenous Angiotensin II in Humans

Montanari

Carra

et al. 2003

Hypertension

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“…Thus, the sensitivity to AI within the splanchnic vascular bed, as indicated by SVR increase, was diminished to a value of 0.2 ± 0.1 after cilazapril, indicating that at AII plasma concentrations comparable with those in congestive heart failure (Staroukine et al, 1984;Pedersen et al, 1986) the splanchnic vasoconstriction was strongly suppressed. It therefore appears that the ACE inhibition may be beneficial in avoiding splanchnic (mesenterial) vasoconstriction and that this may be of clinical importance in haemodynamic conditions accompanying congestive heart failure (Staroukine et al, 1984;Menge, 1986;Bailey et al, 1987).…”

Section: Discussionmentioning

confidence: 94%

“…Thus, RAS-dependent vasoconstriction reaches greatest importance in patients with congestive heart failure and other low cardiac output states (McNeill et al, 1970(McNeill et al, , 1982Staroukine et al, 1984;Bailey et al, 1987). It was demonstrated that in most patients with myocardial pump failure not only were increased catecholamine plasma levels found (Vignerat et al, 1985), but also plasma renin activity and AII plasma concentrations were elevated (Pedersen et al, 1986), AII being positively correlated with PCWP and negatively correlated with CO, thus, reflecting the severity of myocardial failure (Staroukine et al, 1984).…”

Section: Discussionmentioning

confidence: 99%

“…As a controlled study in severely ill patients with established pronounced mesenterial vasoconstriction was not feasible we investigated in a clinical pharmacological model the influence of cilazapril on AI-dependent changes in splanchnic haemodynamics by raising AII plasma concentrations to levels comparable with those in patients with severe heart failure (Staroukine et al, 1984;Pedersen et al, 1986). In our experimental model the splanchnic circulation was, rather simplistically, treated as a single hypothetical vascular bed; the blood flow control mechanisms to individual splanchnic organs being ignored.…”

Section: Discussionmentioning

confidence: 99%

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Effects of ACE inhibition with cilazapril on splanchnic and systemic haemodynamics in man.

Gasić

Gisslinger

Kleinbloesem

et al. 1989

Brit J Clinical Pharma

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1 There is recent experimental evidence that the renin-angiotensin-system may play an essential role in producing splanchnic vasoconstriction. However, controversy exists as to the influence of ACE inhibition on splanchnic haemodynamics in man.We therefore investigated whether cilazapril, a structurally new and long-acting ACE inhibitor, interacts with angiotensin I-dependent changes in splanchnic haemodynamics in man, using an experimental model. 2 The effects of cilazapril on angiotensin I-induced splanchnic and systemic haemodynamics were studied in seven normotensive men using the hepatic venous catheter technique (indocyanine-green dye), right-heart catheterisation (thermodilution method),.intra-arterial blood pressure monitoring and systolic time-intervals. Dose-responses to angiotensin I were determined under ccrntrol conditions and 60 min after ACE inhibition with 5 mg oral cilazapril. Angiotensin I was infused intravenously at constant rates in an increasing dose-sequence until systolic blood pressure was greater than 30 mm Hg. 3 ACE inhibition with cilazapril did not change basal splanchnic or systemic haemodynamics to any relevant extent. The angiotensin I dependent increase in systemic and pulmonary resistance and pulmonary capillary wedge pressure was attenuated by cilazapril, as indicated by the shift of the dose-response curves to the right. In the splanchnic vascular bed angiotensin I dose-dependently increased splanchnic vascular resistance and also wedge hepatic venous pressure and decreased splanchnic blood flow. These angiotensin I induced haemodynamic changes were clearly suppressed by cilazapril. The angiotensin I dose needed to produce a 30% increase in splanchnic vascular resistance, given as mean and s.e.mean, was 1.7 ± 0.3 ,ug min-' during control-trials vs 7.3 ± 1.3 ,ug min-1 after ACE inhibition with cilazapril (P < 0.001). 4 We conclude that, in man, the influence of cilazapril on acute angiotensin I-mediated haemodynamic responses is present in the splanchnic vascular bed, and that the overall effects of cilazapril are consistent with both arterial and venous effects of the ACE inhibitor. Cilazapril effectively counteracts angiotensin I-induced splanchnic vasoconstriction.

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“…Neurohumoral factors including RAAS factors increase fluid retention [17]. Angiotensin-II, in particular, increases vasopressin, which weakens the effect of TLV somewhat, and aldosterone, which is the final product of the RAAS, increases retention of sodium and water in the renal tubules and is thus thought to act against the effects of TLV [18][19][20]. Neither carperitide nor any inotropic agent that would enhance RAAS activity in patients with ADHF was used in this study.…”

Section: Raas Activity and The Clinical Effect Of Tlv During Early Phmentioning

confidence: 99%

Association between plasma concentration of tolvaptan and urine volume in acute decompensated heart failure patients with fluid overload

et al. 2013

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3 and 7 (r = 0.392, p < 0.01; r = 0.639, p < 0.001, respectively) but not on day 1. The urine volume correlated inversely with p < 0.05; p < 0.05, respectively). Conclusions: Plasma TLV concentrations correlated with the urine volume in late phase of treatment but not in early phase, which suggests that the effect of TLV may possibly be inhibited by renin-angiotensin-aldosterone system activity. (Cardiol J 2016; 23, 5: 497-504)

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Angiotensin II, aldosterone and arginine vasopressin in plasma in congestive heart failure

Cited by 42 publications

References 26 publications

Endothelin-A Receptors Mediate Renal Hemodynamic Effects of Exogenous Angiotensin II in Humans

Endothelin-A Receptors Mediate Renal Hemodynamic Effects of Exogenous Angiotensin II in Humans

Effects of ACE inhibition with cilazapril on splanchnic and systemic haemodynamics in man.

Association between plasma concentration of tolvaptan and urine volume in acute decompensated heart failure patients with fluid overload

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