Adrenomedullin, a potent hypotensive peptide, reduces blood pressure and pulmonary vascular resistance, and increases pulmonary blood flow. The mRNA for adrenomedullin and its receptor is highly expressed in the lung, suggesting a regulatory role for adrenomedullin in the pulmonary circulation. To investigate the clinical significance of adrenomedullin in patients with pulmonary hypertension, we studied the relationship between plasma levels of adrenomedullin and pulmonary haemodynamics. Venous, arterial and pulmonary arterial blood samples were obtained during cardiac catheterization and plasma levels of adrenomedullin were measured by specific radioimmunoassay in 33 consecutive patients with severe pulmonary hypertension (12 cases of primary pulmonary hypertension, 21 with chronic thromboembolic pulmonary hypertension; age 49+/-16 years, mean pulmonary arterial pressure 50+/-15mmHg). In addition, plasma levels of adrenomedullin were measured before and after acute nitric oxide inhalation. The changes in plasma adrenomedullin during the follow-up period of 10.3+/-4.3 months were also evaluated (n=5). Sixty-two healthy subjects served as the control group. Adrenomedullin was measured in an antecubital vein in the controls. Plasma levels of adrenomedullin were significantly higher in the patients with pulmonary hypertension than in the control subjects (10.1+/-8.7 versus 4.9+/-1.1pmol/l, P<0.01). Plasma levels of adrenomedullin, expressed as their natural logarithm, were significantly correlated with mean right atrial pressure (r=0.71, P<0.01), stroke volume (r=-0.63, P<0.01), total pulmonary resistance (r=0.60, P<0.01), mean pulmonary arterial pressure (r=0.37, P<0.05), and the natural logarithm of plasma atrial natriuretic peptide (r=0. 63, P<0.01). Plasma levels of adrenomedullin did not change significantly after nitric oxide inhalation, but significantly increased in association with the elevation of the total pulmonary resistance during the long-term follow-up period. These results suggest that plasma levels of adrenomedullin increase in proportion to the extent of pulmonary hypertension.
Previous studies have shown that levels of plasma brain natriuretic peptide (BNP) increase in an early phase of acute myocardial infarction. However, the relations between plasma BNP levels and left ventricular remodelling, which occurs long after acute myocardial infarction, are not fully understood. Venous plasma BNP levels were measured 2, 7, 14, 30, 90 and 180 days after the onset of acute myocardial infarction in 21 patients. Left ventricular end-diastolic volume index (EDVI, ml/m2) in acute (5 days) and chronic (6 months) phases were assessed by electron-beam computed tomography using Simpson's method. The remodelling group (n=9) was defined by an increase in EDVI >/=5 ml/m2 relative to the baseline value. Plasma BNP levels on days 2, 7, 14, 30 and 90 were significantly higher in the remodelling group than in the non-remodelling group (n=12, P<0.05). Sustained elevation of plasma BNP levels was noted from day 2 (61+/-12 pmol/l) to day 90 (55+/-12 pmol/l) and significantly decreased on day 180 (24+/-3 pmol/l) in the remodelling group. In contrast, plasma BNP levels significantly decreased from day 2 (25+/-4 pmol/l) to day 90 (9+/-1 pmol/l) and reached a steady level thereafter in the non-remodelling group. Plasma BNP levels on day 7 correlated positively with an increase in EDVI (r=0.70, P<0.001) from the acute to chronic phase. More importantly, the sustained elevation of plasma BNP (percentage decrease smaller than 25%) from day 30 to day 90 identified patients in the remodelling group with a sensitivity of 100% and a specificity of 83%. In conclusion, not only the high levels of plasma BNP in an acute phase, but also the sustained elevation of plasma BNP in a chronic phase, may be associated with progressive ventricular remodelling occurring long after acute myocardial infarction.
Adrenomedullin (AM), a novel hypotensive peptide, preferentially dilates pulmonary vessels rather than systemic vessels. This suggests the possibility that AM is a circulating hormone which participates in regulation of the pulmonary circulation. A recent study revealed that two molecular forms of AM, i.e. a mature, active form of AM (AM-m) and an intermediate, inactive, glycine-extended form of AM (AM-Gly), circulate in human plasma. In the present study we investigated the production and clearance sites and pathophysiological significance of the two molecular forms of AM in the pulmonary circulation in patients with mitral stenosis. We measured the plasma levels of AM-m and total AM (AM-T; AM-m+AM-Gly) using a recently developed specific immunoradiometric assay, and thus calculated plasma AM-Gly levels, in blood samples obtained from the femoral vein, pulmonary artery, left atrium and aorta of 28 consecutive patients with mitral stenosis (20 females and eight males; age 53+/-10 years). Patients with mitral stenosis had significantly higher venous concentrations of AM-T, AM-Gly and AM-m than age-matched normal controls (AM-T, 15.9+/-2.5 and 10.6+/-2.1 pmol/l respectively; AM-Gly, 14.0+/-2.1 and 9.8+/-1.9 pmol/l respectively; AM-m, 1.9+/-0.6 and 1.1+/-0.3 pmol/l respectively; each P<0.001). There was a significant decrease in the concentrations of AM-m and AM-T between the pulmonary artery and the left atrium (AM-T, 16.1+/-2.7 and 14.0+/-2.4 pmol/l respectively; AM-m, 2.0+/-0.6 and 0.7+/-0.2 pmol/l respectively; each P<0.001); however, there were no differences in plasma AM-Gly levels between the pulmonary artery and the left atrium (14.1+/-2.3 and 13.5+/-2.3 pmol/l respectively). The venous concentrations of AM-m, AM-Gly and AM-T showed similar correlations with mean pulmonary artery pressure (AM-T, r=0.67; AM-Gly, r=0.63; AM-m, r=0.59; each P<0.001) and total pulmonary vascular resistance (AM-T, r=0.77; AM-Gly, r=0.70; AM-m, r=0.75; each P<0.001). These results suggest that the plasma concentration of AM-m is increased in parallel with those of AM-Gly and AM-T, and that the main site for clearance of AM-m from the plasma is the lung; the extracted AM-m in the lungs may help to attenuate the increased pulmonary arterial resistance in secondary pulmonary hypertension due to mitral stenosis.
Experimental studies have demonstrated that adrenomedullin (AM) has a positive inotropic action and exerts inhibitory effects against ventricular remodelling as an autocrine and paracrine factor. However, there is no clinical evidence for AM acting as a local regulator in the human heart. We measured the levels of various molecular forms of AM, i.e. an active form of mature AM (AM-m), an intermediate inactive form of glycine-extended AM (AM-Gly) and total AM (AM-T=AM-m+AM-Gly), in plasma and pericardial fluid using our newly developed immunoradiometric assay in consecutive 67 patients undergoing coronary artery bypass graft surgery. Pericardial fluid and plasma cAMP, atrial natriuretic peptide and brain natriuretic peptide levels were also measured. The relationships between pericardial fluid AM levels and ventricular functions and other hormone levels were analysed. The level of each molecular form of AM in pericardial fluid was closely correlated with that of the other molecular forms of AM in the fluid. However, levels were not correlated with those in plasma. AM-T levels were slightly higher in pericardial fluid than in plasma (+72%; P<0.05), whereas AM-m levels and AM-m/AM-T ratios were markedly higher in pericardial fluid than in plasma (AM-m, +994%; AM-m/AM-T ratio, +443%; both P<0.01). AM-m, AM-Gly and AM-T levels in pericardial fluid were correlated with indices of left ventricular function, and with atrial natriuretic peptide and brain natriuretic peptide levels. Interestingly, AM and cAMP levels were positively correlated in plasma, but negatively correlated in pericardial fluid. In addition, AM-m, AM-Gly and AM-T levels in pericardial fluid were higher in patients with acute coronary syndrome than in those with stable ischaemic heart disease (AM-m, +80%; AM-Gly, +96%; AM-T, +83%; all P<0.01). These results suggest that AM in pericardial fluid reflects cardiac synthesis, and that enhanced cardiac secretion of AM is associated with left ventricular dysfunction, ventricular overload and myocardial ischaemia. Considering that AM has positive inotropic, coronary vasodilatory and anti-remodelling actions, increased cardiac AM may play a compensatory role in the ischaemic and failing myocardium.
Adrenomedullin (AM) has vasodilatory, diuretic and natriuretic actions. Two molecular forms of AM circulate in human plasma: an active, mature form of AM (AM-m) and an intermediate, inactive, glycine-extended form of AM (AM-Gly). In the present study we investigated the pathophysiological significance of the two molecular forms of AM in plasma and urine in patients with acute myocardial infarction. We serially measured venous and arterial plasma levels and urinary excretion of AM-m, AM-Gly and total AM (Am-T; =AM-m+AM-Gly) over 2 weeks using our recently developed immunoradiometric assay in 26 consecutive patients with acute myocardial infarction and in age-matched normal controls, and studied the relationships between AM levels and clinical parameters. Plasma AM-m, AM-Gly and AM-T levels were increased on admission in patients with acute myocardial infarction compared with age-matched normal controls. Levels of AM-m, AM-Gly and AM-T in plasma reached a peak 24 h after the onset of symptoms. Plasma AM-m, AM-Gly and AM-T levels were significantly correlated with plasma levels of brain natriuretic peptide and pulmonary arterial pressure. Plasma AM-Gly levels in the vein were similar to those in the artery, whereas plasma AM-m levels were significantly lower in the artery than in the vein. Urinary excretion of AM-m, AM-Gly and AM-T was also increased on admission, and reached a peak at 12 h after the onset of symptoms. Urinary excretion of AM-m and AM-Gly was significantly correlated with urinary sodium excretion. The AM-m/AM-T ratio was significantly higher in the urine than in the vein or artery. AM-m levels were significantly correlated with AM-Gly levels in both the urine and plasma; however, there were no significant correlations between plasma and urinary AM levels. The results suggest that levels of both molecular forms of AM are increased in the urine as well as in the plasma in the acute phase of myocardial infarction. Since AM exerts potent cardiovascular and renal effects, increased concentrations of AM in plasma and urine in the acute phase of myocardial infarction may be involved in the defence mechanism against further elevations of peripheral and pulmonary vascular resistance and oliguria in acute myocardial infarction.
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