Proatrial natriuretic peptide (1-98), but not cystatin C, is predictive for occurrence of acute renal insufficiency in critically ill septic patients.

Acute renal failure has important prognostic implications in critically ill patients, but the effects of acute renal failure on in-hospital mortality in the subset of patients with cardiogenic shock are not known. All consecutive patients who presented with acute coronary syndrome at our cardiovascular intensive care unit from 1993 to 2000 and who were in cardiogenic shock were enrolled. Acute renal failure was defined as a urine volume or = 0.5 mg/dL or > 50% above the baseline value. There were 118 patients (83 men [70%]; mean [+/- SD] age, 66 +/- 10 years), 39 (33%) of whom developed acute renal failure within 24 hours after the onset of shock. In-hospital mortality was 87% (34/39) in patients with acute renal failure and 53% (42/79) in patients without acute renal failure (odds ratio [OR] = 6.0; 95% confidence interval [CI]: 2.1 to 17; P < 0.001). Other significant univariate predictors of mortality included the peak serum lactate level, epinephrine dose, and the maximum serum creatinine level. Multivariate logistic regression analysis identified acute renal failure as the only independent predictor of mortality. Acute renal failure was common in patients with cardiogenic shock and strongly associated with in-hospital mortality.

Biologically active N-terminal fragments such as proANP(1-30), proANP(31-67), and proANP(1-98) derive from the prohormone of alpha-human atrial natriuretic peptide [proANP(99-126) or alpha-ANP]. No systematic data are available for patients with different kidney diseases. Specific immunoassays were developed to determine plasma and urine concentrations of these fragments in 121 patients with different degrees of kidney function and urinary protein excretion, respectively. In patients with kidney disease and normal renal function without proteinuria, circulating proANP(1-30) and proANP(31-67) increased 2.8-fold and 6.5-fold, respectively. Urinary excretion of proANP(31-67) increased by a factor of 7.7 in these patients, whereas proANP(1-30) was not affected. Patients with impaired renal function had a dramatic increase of urinary proANP(31-67) excretion even before serum creatinine levels started to rise. The progression of renal failure caused a significant rise of circulating proANP(1-30) (4.3-fold) and proANP(31-67) (3.0-fold) compared with patients with normal renal function. Urinary excretion of proANP peptides significantly increased, particularly when the serum creatinine level was> 5.0 mg/dL [proANP(1-30) 26-fold, proANP(31-67) 8.4-fold]. Urinary excretion of proANP(1-30) increased up to 4.4-fold and urinary excretion of proANP(31-67) increased up to 2.4-fold in patients with proteinuria in excess of 3 g/24 h. Plasma concentrations and urinary excretion of proANP(1-30) and proANP(31-67) are affected by kidney disease and function, but not by proteinuria per se. It is proposed that the diseased kidney increases early urinary excretion of proANP fragments to participate in the regulation of renal function as well as sodium and water excretion.