Cardiovascular and renal effects of adrenomedullin in rats with heart failure

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Cardiovascular and renal effects of adrenomedullin in rats with heart failure

Noritoshi Nagaya¹, Toshio Nishikimi¹, Takeshi Horio¹, Fumiki Yoshihara², Akio Kanazawa¹, Hisayuki Matsuo², and Kenji Kangawa²

¹ Department of Internal Medicine and ² Research Institute, National Cardiovascular Center, Suita, Osaka 565, Japan

ABSTRACT

Top
Abstract
Introduction
Methods
Results
Discussion
References

Plasma adrenomedullin (AM), a novel hypotensive peptide, has been shown to increase in heart failure (HF). This study soughtto examine the cardiovascular and renal effects of intravenousinfusion of AM in HF rats and sham-operated rats (control) usingtwo doses of AM that would not induce hypotension. Rat AM-(1 $---$ 50)was intravenously administered at rates of 0.01 (low) and 0.05(high) µg · kg body wt¹ · min¹. Low-dose AM increased urine flow (+21% in HF, +29% in control)and urinary sodium excretion (+109% in HF, +123% in control) withoutchanges in any hemodynamic variables. In contrast, high-dose AMslightly decreased mean arterial pressure ( $-$ 3% in HF, $-$ 5% in control)and significantly increased cardiac output (+20% in HF, +12% incontrol). Infusion of high-dose AM resulted in significant decreasesin right ventricular systolic pressure ( $-$ 11%) and right atrialpressure ( $-$ 28%) only in HF rats. High-dose AM significantly increasedglomerular filtration rate (+10% in HF, +16% in control) and effectiverenal plasma flow (+25% in HF, +46% in control) as well as urineflow and urinary sodium excretion. In summary, intravenous infusionof AM exerted diuresis and natriuresis without inducing hypotensionand, in the higher dose, produced beneficial hemodynamic and renalvasodilator effects in rats with compensatedHF.

myocardial infarction

	INTRODUCTION

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ADRENOMEDULLIN (AM) is a novel hypotensive peptide originally isolated from human pheochromocytoma (8). AM peptide andmRNA have been reported to be expressed not only in adrenal medullabut also in the heart, kidney, lung, and endothelium (5, 23).AM has been shown to promote vasodilatation (1), diuresis,and natriuresis (6, 10, 11) and to inhibit aldosteroneproduction in normal animals (27). Recently, AM has been shownto have a positive inotropic action in the perfused rat heart(25, 26). We and others have shown that plasma AM levels areincreased in patients with heart failure (HF) (7, 15). Tissuelevels of AM peptide and mRNA have been shown to be increasedin the heart, kidney, and lungs of HF rats (13). These findingssuggest that AM may play a role in the regulation of volume andpressure homeostasis in HF via its renal, vascular, cardiac, andendocrine effects. However, the potential effects of AM as a therapeuticagent for HF are not fully understood. Recently, Rademaker etal. (22) showed that intravenous infusion of high-dose AM maintainedurine flow despite a marked decrease in arterial pressure in HFsheep induced by rapid pacing. It is still unclear, however, whetherintravenous infusion of AM elicits a beneficial renal effect ata dose that would not induce hypotension. In addition, there hasbeen no report concerning the effects of AM on pulmonary hypertensionsecondary to left ventricularfailure.

The present study was designed to investigate the effects of intravenous infusion of relatively low-dose AM on renal functionand systemic and pulmonary hemodynamics in a rat model of HF producedby left coronaryligation.

	METHODS

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Model of HF. Male Wistar rats weighing 180-220 g were used in this study. Myocardial infarction was produced by a previously describedmethod (16). In brief, after rats were anesthetized by intraperitonealinjection of pentobarbital sodium (30 mg/kg body wt), they wereintubated with a polyethylene tube (PE-240) and artificially ventilatedusing a volume-regulated respirator. The heart was exposed viaa left thoracotomy, and the left coronary artery was ligated 2-3mm from its origin between the pulmonary artery conus and theleft atrium using a 6-0 Prolene suture. To reduce deaths due toarrhythmia, we pretreated the rats with an intraperitoneal injectionof xylocaine (1-2 mg/kg) before coronary artery ligation and observedthe electrocardiogram on the monitor. If ventricular tachycardiaor fibrillation was observed, we injected additional xylocaineintraperitoneally or tapped the heart gently using a cotton applicator(17). These procedures were effective for converting the fatalarrhythmia to sinus rhythm. Finally, the heart was restored toits normal position and the lungs were hyperinflated to help evacuateair from the thoracic cavity before the chest was closed. Thecontrol rats received a sham operation involving thoracotomy andcardiac exposure but without coronary artery ligation. The survivingrats were maintained on standard ratchow.

The HF and control rats were randomly assigned to five groups. Low-dose AM (0.01 µg · kg body wt¹ · min¹; HF, n = 8; control, n = 9), high-dose AM (0.05 µg · kg bodywt¹ · min¹; HF, n = 10; control, n = 9), or saline (HF, n = 10) was intravenouslyadministered in each group. The saline group was prepared to ruleout a time-course effect during the intravenous infusionprotocol.

Study protocol. Approximately 4 wk after surgery, subsequent experimental procedures were performed. Rats were anesthetized by intraperitonealinjection of Inactin (100 mg/kg body wt) and placed on a heatingpad to maintain body temperature at 37-38°C throughout the study.Tracheostomy was performed with a PE-240 tube. A polyethylenecatheter (PE-10) was inserted into the right femoral artery tomeasure the heart rate (HR) and mean arterial pressure (MAP).A polyethylene catheter (PE-50) was inserted into the right jugularvein and was advanced through the right atrium into the rightventricle for measurement of mean right atrial pressure (RAP)and right ventricular systolic pressure (RVSP). These hemodynamicvariables were measured using a pressure transducer (model P23ID; Gould, Glen Burnie, MD) connected to a polygraph and wererecorded by a thermal recorder (7758 B System; Hewlett-Packard,Palo Alto, CA). A thermomicroprobe was advanced into the ascendingaorta via the right carotid artery and connected to a cardiacoutput (CO) computer (Cardiotherm-500; Columbus Instruments).For measurement of CO, 0.1 ml of 0.9% saline at room temperaturewas injected as a bolus via the jugular vein catheter. A secondPE-50 catheter was inserted into the left jugular vein for theinfusion of saline containing 5% inulin and 1.8% p-aminohippuricacid (PAH) at a rate of 0.2 ml · 100 g body wt¹ · h¹. A third PE-50 catheter was inserted into the left femoral veinfor the continuous infusion of AM or saline at a rate of 0.3 ml· 100 g body wt¹ · h¹. Finally, a PE-100 catheter was inserted into the bladder tocollect urine. After an equilibration period of 60 min, we measuredRAP at baseline. Then the catheter was advanced into the rightventricle by monitoring the pressure. Urine was collected overtwo periods of 20 min each, and 150-µl blood samples were drawnat the midpoint of each urine collection for measurement of PAHand inulin. Simultaneously, we recorded hemodynamic variables,including HR, MAP, RVSP, and CO. The averaged values in the twoperiods were used as the values before AM infusion. After thecontrol measurements and samples were obtained, AM (0.01 µg ·kg body wt¹ · min¹ or 0.05 µg · kg body wt¹ · min¹) was intravenously administered. Thirty minutes later, all measurementswere repeated over two periods of 20 min and the averaged valuesin the two periods were used as the values after AMinfusion.

After completion of these measurements, 4 ml of blood were drawn from the femoral artery for measurements of plasma AM andatrial natriuretic peptide (ANP). Then the heart was arrestedby the injection of 2 mmol of KCl through the femoral artery.The ventricles and lungs were excised, dissected free, and weighed.Infarction size was determined as a percentage of left ventriculararea, as previously reported (1). Only rats with infarct size>30% of the left ventricle were enrolled in this study as a modelof HF (21).

Analysis. Urinary concentration of sodium was measured by flame photometry. Inulin was measured by the anthrone method. PAH was measuredby Marshall's method. Glomerular filtration rate (GFR) and effectiverenal plasma flow (ERPF) were determined from inulin and PAH clearance,respectively. Effective renal blood flow (ERBF) was calculatedas ERPF/(1 $-$ hematocrit); renal vascular resistance (RVR) wasdetermined as (MAP $-$ RAP)/ERBF. The filtration fraction was calculatedas GFR/ERPF.

Measurement of AM, ANP, cAMP, and cGMP. The plasma concentrations of AM and ANP were determined by radioimmunoassay after extraction with Sep-Pak C18 cartridges (Millipore;Waters, Milford, MA), as previously reported (12, 23). Theurinary concentrations of cAMP and cGMP were determined with radioimmunoassaykits (cAMP assay kit and cGMP assay kit; Yamasa Shoyu, Chiba,Japan), as previously reported (4). A normal value of plasmaAM in rats was established from nine sham-operatedrats.

Statistical analysis. Numerical values were expressed as means ± SD unless otherwise indicated. Comparisons of variables between two groups weremade by Student's unpaired t-test. Comparisons of values amongthree or more groups were made using one-way ANOVA followed byScheffé's multiple comparison test. Changes in hemodynamic andrenal variables during AM infusion were analyzed with Student'spaired t-test. A P value <0.05 was consideredsignificant.

	RESULTS

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Physiological profiles. The physiological profiles of the five experimental groups are summarized in Table 1. Moderate to large infarcts were observedin three HF groups, and the mean infarct size was similar in thethree groups. HF rats showed significantly increased weights ofthe right ventricle and the lungs compared with control rats.Plasma ANP levels were markedly increased in HF rats comparedwith control rats. MAP and CO at baseline were significantly decreasedin HF rats compared with control rats (Figs. 1 and 2). RVSP andRAP at baseline were significantly increased in HF rats. Theseresults suggest the presence of chronic HF in this experimentalmodel.

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Table 1. Baseline characteristics of control and HF rats

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Fig. 1. Hemodynamic responses to infusion of low-dose adrenomedullin (AM) (0.01 µg · kg body wt¹ · min¹) in rats with heart failure (HF, $bullet$ ) and in sham-operated control rats ( $open circle$ ). There were no significant changes in mean arterial pressure (MAP), cardiac output (CO), right ventricular systolic pressure (RVSP), or right atrial pressure (RAP) in either HF or control. Before, before infusion of AM or saline; after, after infusion of AM or saline. Values are means ± SE. * P < 0.05 vs. control.

Effects of AM on systemic and pulmonary circulation. Infusion of saline did not significantly change MAP, CO, RVSP, or RAP in HF rats (Table 2). The infusion of low-dose AM (0.01µg · kg body wt¹ · min¹) did not significantly alter any hemodynamic variables in eitherHF or control rats (Fig. 1). In contrast, high-dose AM (0.05 µg· kg body wt¹ · min¹) produced a slight decrease in MAP and a marked increase in COin both HF and control rats (Fig. 2). High-dose AM significantlyreduced RVSP and RAP in HF rats, although it did not significantlyalter these variables in control rats. HR was not significantlychanged during infusion of low-dose AM (HF, 383 ± 31 to 386 ±30 beats/min; control, 390 ± 47 to 400 ± 40 beats/min) or high-doseAM (HF, 372 ± 25 to 371 ± 20 beats/min; control, 380 ± 25 to 378± 26 beats/min).

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Table 2. Hemodynamic and renal parameters in HF rats during saline infusion

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Fig. 2. Hemodynamic responses to infusion of high-dose AM (0.05 µg · kg body wt¹ · min¹) in rats with HF ( $bullet$ ) and in sham-operated control rats ( $open circle$ ). Before, before infusion of AM; after, after infusion of AM. Values are means ± SE. * P < 0.05 vs. control; $dagger$ P < 0.05 vs. before.

Effects of AM on renal function. Infusion of saline did not change any renal variables in HF rats (Table 2). Infusion of low-dose AM (0.01 µg · kg body wt¹ · min¹) significantly increased urine volume (UV) and urinary sodiumexcretion (U_NaV) in both HF and control rats, but it did not changeGFR or ERPF (Fig. 3). RVR was not significantly changed by low-doseAM (HF, 2.7 ± 0.4 to 2.6 ± 0.4 mmHg · ml¹ · min · kg; control, 2.7 ± 0.4 to 2.6 ± 0.5 mmHg · ml¹ · min · kg). In contrast, high-dose AM (0.05 µg · kg body wt¹ · min¹) resulted in slight, but significant, increases in GFR and ERPFas well as increases in UV and U_NaV in both HF and control rats(Fig. 4). RVR in both groups was significantly decreased by high-doseAM (HF, 2.8 ± 0.8 to 2.4 ± 1.0 mmHg · ml¹ · min · kg; control, 2.6 ± 0.7 to 1.9 ± 0.7 mmHg · ml¹ · min · kg, P < 0.05, respectively).

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Fig. 3. Renal responses to infusion of low-dose AM (0.01 µg · kg body wt¹ · min¹) in rats with HF and in sham-operated control rats. Values are means ± SE. UV, urine volume; U_NaV, urinary sodium excretion; GFR, glomerular filtration rate; ERPF, effective renal plasma flow. * P < 0.05 vs. before.

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Fig. 4. Renal responses to infusion of high-dose AM (0.05 µg · kg body wt¹ · min¹) in rats with HF and in sham-operated control rats. Values are means ± SE. * P < 0.05 vs. before.

Neurohumoral measurements. Plasma AM levels in HF rats treated with saline were significantly increased compared with a normal value of plasma AM inrats (3.5 fmol/ml). Plasma AM levels in HF rats treated with low-doseAM tended to be increased (1.4-fold) compared with those in HFrats treated with saline, but not to a statistically significantextent (Table 3). In contrast, plasma AM levels in HF rats treatedwith high-dose AM were significantly elevated (sevenfold) comparedwith those in HF rats treated with saline. Interestingly, thesame dose of AM (0.05 µg · kg body wt¹ · min¹) resulted in different changes in plasma AM levels between HFrats (56 ± 29 fmol/ml) and control rats (30 ± 8 fmol/ml).

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Table 3. Plasma levels of AM and urinary excretion of cAMP and cGMP in control and heart failure rats

Urinary cGMP excretion at baseline was markedly increased in HF rats compared with control rats. During the infusion of low-or high-dose AM, urinary cGMP excretion remained unchanged inHF and control rats. Urinary cAMP excretion at baseline did notsignificantly differ between HF and control rats. The infusionof low- or high-dose AM did not significantly change urinary cAMPexcretion in eithergroup.

	DISCUSSION

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In this study, we examined the cardiovascular and renal effects of intravenous infusion of AM in HF rats and sham-operatedcontrol rats using two doses of AM that did not induce a markeddecrease in arterial pressure. We demonstrated for the first time1) that intravenous infusion of low-dose AM significantly increasedUV and U_NaV without changes in GFR, ERPF, or any hemodynamic variablesin HF and control rats. We also demonstrated 2) that high-doseAM infusion significantly decreased MAP and increased CO in bothHF and control rats, whereas high-dose AM significantly reducedRVSP and RAP only in HF rats with pulmonary hypertension, and3) that high-dose AM significantly increased GFR and ERPF as wellas UV and U_NaV in both groups. These results suggest that AM playsa role in the regulation of pressure and volume homeostasis viarenal and cardiovascular effects inHF.

To date, the biological actions of AM have been examined in a variety of normal animals, whereas the therapeutic effects ofAM on HF are not fully understood. Intravenous infusion of AMhas been shown to produce a marked decrease in arterial pressurevia its strong vasorelaxant effect mediated by the accumulationof cAMP (22, 24). However, the AM-induced hypotension maycause adverse effects in HF such as decreased renal perfusionpressure. Thus, in a preliminary study, we determined two dosesof AM that would not induce a marked decrease in arterial pressure.In this study, infusion of low-dose AM (0.01 µg · kg body wt¹ · min¹) did not significantly decrease MAP, whereas high-dose AM (0.05µg · kg body wt¹ · min¹) produced a slight but significant decrease in MAP from baselinevalue ( $-$ 6 mmHg in HF rats; $-$ 3 mmHg in controlrats).

In this study, we showed that high-dose AM increased CO in HF and control rats. This is consistent with results from a previousstudy using conscious sheep (22). One of the mechanisms underlyingthis increase in CO may be a fall of cardiac afterload by decreasingMAP. Recently, Szokodi et al. (26) showed that AM produced adirect positive inotropic action via Ca²⁺ release from intracellular ryanodine- and thapsigargin-sensitiveCa²⁺ stores, activation of protein kinase C, and Ca²⁺ influx through L-type Ca²⁺ channels. These findings suggest that the increase in CO maybe attributed not only to the fall of cardiac afterload but alsoto the positive inotropic action ofAM.

Interestingly, in this study, AM significantly decreased RVSP only in HF rats with pulmonary hypertension, not in controlrats. It has been reported that there are many binding sites ofAM in the lung (19) and that AM preferentially dilates pulmonaryarterial resistance vessels (3, 18). Circulating AM has beenshown to be increased and to be partially metabolized in the lungsof patients with pulmonary hypertension (14, 28). These findingsraise the possibility that AM is involved in the pathophysiologyof pulmonary hypertension. Recently, Lippton et al. (9) showedthat AM does not alter pulmonary arterial pressure under conditionsof resting pulmonary vascular tone, whereas it produces a dose-dependentreduction in pulmonary arterial pressure under conditions of increasedpulmonary vascular tone, consistent with our results. Thus itmay be interesting to speculate that AM is more effective in ratswith increased pulmonary vascular resistance secondary to severeleftHF.

AM has been shown to have diuretic and natriuretic activities in normal animals (6, 10, 11). In this study, we demonstratedthat low-dose AM significantly increased UV and U_NaV without increasesin GFR or ERPF in both HF and control rats. Edwards et al. (2)have reported that AM dose dependently increases intracellularcAMP levels in the cortical thick ascending limb and distal convolutedtubule dissected from rat kidney. These findings suggest thatAM has a direct action on the renal tubules via the accumulationof cyclic AMP, and thereby AM may be involved in the regulationof urine flow and U_NaV. However, in the present study, intravenousinfusion of AM did not increase urinary cAMP level, consistentwith a previous report (11). It is possible that AM stimulatedintracellular cAMP at the tissue level sufficiently to inducea biological response but insufficiently to induce a measurablerise in urinary level. In addition, AM did not significantly increaseurinary cGMP level. This result suggests that the renal actionof AM might not be mediated mainly by the nitric oxide-cGMP pathwayin rats. Moreover, in this study we showed that intravenous administrationof high-dose AM significantly increased GFR and RPF in both HFand control rats, supporting the earlier findings that intrarenalinfusion of AM increases GFR and RPF (6, 11). These resultssuggest that AM dilates renal arteries as well as peripheral vessels.Recently, Rademaker et al. (22) showed that intravenous infusionof AM increases U_NaV without an increase in urine flow or creatinineclearance in pacing-induced HF sheep. In their study, MAP at baselinewas considerably low (72 mmHg) in HF sheep, and AM infusion induceda further reduction in MAP to 63 mmHg. Thus the discrepancy betweentheir results and ours with regard to changes in UV and GFR maybe explained, in part, by the difference in renal perfusionpressure.

It remains unclear whether exogenous AM functions at pathophysiological or pharmacological levels. In this study, plasma AMlevels in HF rats treated with low-dose AM tended to be increased(1.4-fold) compared with those in HF rats treated with saline,but not to a statistically significant extent. In contrast, plasmaAM levels in HF rats treated with high-dose AM were significantlyelevated compared with those in HF rats treated with saline (sevenfold).Accordingly, intravenous infusion of low-dose AM may cause natriuresisand diuresis at pathophysiological levels, whereas high-dose infusionmay induce hemodynamic effects as well as natriuresis and diuresisat pharmacological levels. In this study, the same dose of AM(0.05 µg · kg body wt¹ · min¹) resulted in different increases in plasma AM levels betweenHF rats (56 ± 29 fmol/ml) and control rats (30 ± 8 fmol/ml). Theseresults raise the possibility that the clearance of AM may bedecreased in HFrats.

Limitations. First, we could not assess the effect of AM on other vasoactive peptides such as renin and aldosterone because their measurementsrequire a large volume of blood. Second, we could only measureRVSP as an index of pulmonary arterial systolic pressure. A moredetailed analysis of pulmonary arterial pressure is needed toexamine effects of AM on pulmonary circulation. Finally, thisstudy was conducted in rats with chronic HF that was relativelywell compensated. The effects of AM in the acute phase, or inthe development of HF, need furtherstudy.

In conclusion, intravenous infusion of AM exerted diuresis and natriuresis without inducing hypotension and in the higherdose produced beneficial hemodynamic and renal vasodilator effectsin rats with compensatedHF.

Perspectives

The natriuretic and diuretic effects of AM infusion without a marked decrease in arterial pressure suggest that AM may bebeneficial in the treatment of HF. Moreover, intravenous infusionof AM at pharmacological levels produced vasodilatation and increasedCO in association with diuresis and natriuresis. These findings,together with the direct inotropic effect of AM (26), implythat AM may have a place among inotropic and vasodilator agentssuch as phosphodiesterase inhibitors. Thus intravenous infusionof AM may be a new therapeutic approach to the treatment of HF.Because AM has the great advantage of being an endogenous substance,large-scale human studies are necessary to confirm a potentialtherapeutic benefit of AM in patients withHF.

	ACKNOWLEDGEMENTS

We thank Yoko Saito for technicalassistance.

	FOOTNOTES

This work was supported in part by the Special Coordination Funds for Promoting Science and Technology (Encouragement Systemof Center of Excellence from the Science and Technology Agencyof Japan.)

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate thisfact.

Address for reprint requests: T. Nishikimi, Dept. of Internal Medicine, National Cardiovascular Center, 5-7-1 Fujishirodai, Suita, Osaka 565, Japan.

Received 13 July 1998; accepted in final form 22 September 1998.

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[Abstract] [Full Text] [PDF]

E. Dobrzynski, D. Montanari, J. Agata, J. Zhu, J. Chao, and L. Chao
Adrenomedullin improves cardiac function and prevents renal damage in streptozotocin-induced diabetic rats
Am J Physiol Endocrinol Metab, December 1, 2002; 283(6): E1291 - E1298.
[Abstract] [Full Text] [PDF]

T. Nishikimi, F. Yoshihara, A. Kanazawa, I. Okano, T. Horio, N. Nagaya, C. Yutani, H. Matsuo, H. Matsuoka, and K. Kangawa
Role of increased circulating and renal adrenomedullin in rats with malignant hypertension
Am J Physiol Regulatory Integrative Comp Physiol, December 1, 2001; 281(6): R2079 - R2087.
[Abstract] [Full Text] [PDF]

P. Kinnunen, I. Szokodi, M. G. Nicholls, and H. Ruskoaho
Impact of NO on ET-1- and AM-induced inotropic responses: potentiation by combined administration
Am J Physiol Regulatory Integrative Comp Physiol, August 1, 2000; 279(2): R569 - R575.
[Abstract] [Full Text] [PDF]

I. Hamanaka, Y. Saito, T. Nishikimi, T. Magaribuchi, S. Kamitani, K. Kuwahara, M. Ishikawa, Y. Miyamoto, M. Harada, E. Ogawa, et al.
Effects of cardiotrophin-1 on hemodynamics and endocrine function of the heart
Am J Physiol Heart Circ Physiol, July 1, 2000; 279(1): H388 - H396.
[Abstract] [Full Text] [PDF]

N. Nagaya, T. Nishikimi, F. Yoshihara, T. Horio, A. Morimoto, and K. Kangawa
Cardiac adrenomedullin gene expression and peptide accumulation after acute myocardial infarction in rats
Am J Physiol Regulatory Integrative Comp Physiol, April 1, 2000; 278(4): R1019 - R1026.
[Abstract] [Full Text] [PDF]

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				M. Luodonpaa, H. Leskinen, M. Ilves, O. Vuolteenaho, and H. Ruskoaho Adrenomedullin modulates hemodynamic and cardiac effects of angiotensin II in conscious rats Am J Physiol Regulatory Integrative Comp Physiol, June 1, 2004; 286(6): R1085 - R1092. [Abstract] [Full Text] [PDF]

				K. Nakanishi, H. Osada, M. Uenoyama, F. Kanazawa, N. Ohrui, Y. Masaki, T. Hayashi, Y. Kanatani, T. Ikeda, and T. Kawai Expressions of adrenomedullin mRNA and protein in rats with hypobaric hypoxia-induced pulmonary hypertension Am J Physiol Heart Circ Physiol, June 1, 2004; 286(6): H2159 - H2168. [Abstract] [Full Text] [PDF]

				E. Dobrzynski, D. Montanari, J. Agata, J. Zhu, J. Chao, and L. Chao Adrenomedullin improves cardiac function and prevents renal damage in streptozotocin-induced diabetic rats Am J Physiol Endocrinol Metab, December 1, 2002; 283(6): E1291 - E1298. [Abstract] [Full Text] [PDF]

				T. Nishikimi, F. Yoshihara, A. Kanazawa, I. Okano, T. Horio, N. Nagaya, C. Yutani, H. Matsuo, H. Matsuoka, and K. Kangawa Role of increased circulating and renal adrenomedullin in rats with malignant hypertension Am J Physiol Regulatory Integrative Comp Physiol, December 1, 2001; 281(6): R2079 - R2087. [Abstract] [Full Text] [PDF]

				P. Kinnunen, I. Szokodi, M. G. Nicholls, and H. Ruskoaho Impact of NO on ET-1- and AM-induced inotropic responses: potentiation by combined administration Am J Physiol Regulatory Integrative Comp Physiol, August 1, 2000; 279(2): R569 - R575. [Abstract] [Full Text] [PDF]

				I. Hamanaka, Y. Saito, T. Nishikimi, T. Magaribuchi, S. Kamitani, K. Kuwahara, M. Ishikawa, Y. Miyamoto, M. Harada, E. Ogawa, et al. Effects of cardiotrophin-1 on hemodynamics and endocrine function of the heart Am J Physiol Heart Circ Physiol, July 1, 2000; 279(1): H388 - H396. [Abstract] [Full Text] [PDF]

				N. Nagaya, T. Nishikimi, F. Yoshihara, T. Horio, A. Morimoto, and K. Kangawa Cardiac adrenomedullin gene expression and peptide accumulation after acute myocardial infarction in rats Am J Physiol Regulatory Integrative Comp Physiol, April 1, 2000; 278(4): R1019 - R1026. [Abstract] [Full Text] [PDF]