Distal renal tubular acidosis with intact capacity to lower urinary pH.

The sine qua non for the diagnosis of distal renal tubular acidosis requires that the urinary pH cannot decrease maximally during systemic acidosis. A defect in distal acidification however, could also result from a decrease in the capacity (or rate) of distal hydrogen ion secretion. In this type of defect, the ability to lower the urinary pH during acidemia could be preserved as long as a certain capacity for hydrogen ion secretion remained. In this report, we describe four patients with deranged distal urinary acidification, in whom urinary pH was able to decrease (4.99 +/- 0.11) during acidemia. One of the patients had hyperchloremic metabolic acidosis whereas the remaining three were not spontaneously acidotic. In these patients, the defect for distal urinary acidification was disclosed by the inability of the urine-blood pCO2 gradient to increase normally (i.e., above 30 mm Hg) during bicarbonate loading. In contrast, a normal increase in the urine-blood pCO2 gradient was observed in each patient in response to neutral sodium phosphate infusion. The reabsorptive capacity of bicarbonate was not depressed in these patients, which indicated that the acidification process in the proximal nephron was intact. We propose that our four patients had a defect in distal urinary acidification caused by a reduction in the rate of distal hydrogen ion secretion rather than an inability to generate a steep pH gradient across the distal nephron. Our data also suggest that the inability to raise urinary pCO2 normally during sodium bicarbonate loading may be the most sensitive index of decreased distal urinary acidification available.

Amelioration of polyuria by amiloride in patients receiving long-term lithium therapy.

Vasopressin-resistant diabetes insipidus is a common side effect of the treatment of affective disorders with lithium. We studied the effect of amiloride on lithium-induced polyuria in nine such patients receiving maintenance lithium therapy who had a vasopressin-resistant defect in urinary concentrating ability. After a mean (+/- S.E.) of 24 +/- 6 days of amiloride administration, the urine volume fell (from 4.7 +/- 0.6 to 3.1 +/- 0.3 liters per 24 hours; P less than 0.005), and the urine osmolality increased (from 228 +/- 35 to 331 +/- 34 mOsm per kilogram of H2O; P less than 0.001). The decrease in urine output was sustained during six months of observation in the absence of any significant change in plasma levels of lithium, potassium, or bicarbonate; urinary excretion of sodium or lithium; or creatinine clearance. Amiloride administration was also associated with a significant increase in urine osmolality (from 575 +/- 54 to 699 +/- 48 mOsm per kilogram of H2O; P less than 0.005) measured after fluid deprivation and the injection of exogenous vasopressin. We conclude that amiloride mitigates lithium-induced polyuria, at least partly, by blunting the inhibitory effect of lithium on water transport in the renal collecting tubule. Thus, amiloride may provide a specific therapy for polyuria in lithium-treated patients while obviating the need for potassium supplementation in the treatment of this kind of polyuria.

Distal nephron function in patients receiving chronic lithium therapy.

Renal tubular function was studied in 14 patients chronically treated with lithium for affective disorders. Patients were separated into two groups according to the duration of lithium therapy: long-term (35 +/- 7.0 months) and short-term (4.8 +/- 0.8 months). At comparable urine lithium concentrations, patients on long-term therapy had a lower maximal urine osmolality (Umax) and free water reabsorption (TcH2O) than did patients on short-term therapy. The latter group achieved a Umax above 800 mOsm kg H2O. In contrast, both groups of patients failed to increase the urine-blood (U-B) Pco2 gradient normally during acute sodium bicarbonate loading. This low U-B Pco2 was observed at comparable urine bicarbonate concentrations between both groups of patients and controls, and thus was associated with a higher urine pH in patients. These findings indicate that the inability of these patients to achieve a normal U-B Pco2 in a maximally alkaline urine was the result of decreased distal hydrogen ion secretion rather than inability to raise urine bicarbonate concentrations as a result of a concentrating defect. Bicarbonate reabsorptive capacity was normal in our lithium-treated subjects. Both groups of patients achieved a normal U-B Pco2 gradient in response to sodium phosphate loading. They also were able to achieve a minimal urine pH and a maximal acid excretion similar to those of controls in response to a 3-day ammonium chloride loading test. Our data demonstrate that chronic lithium therapy is associated with a mild distal acidification defect disclosed only by the finding of a low U-B Pco2 gradient during sodium bicarbonate loading. This peculiar defect can be found in short-term lithium-treated patients in whom the concentrating capacity is relatively well preserved.