Effect of pyridoxine supplementation on plasma oxalate concentrations in patients receiving dialysis

Determinants of oxalate balance in patients on chronic peritoneal dialysis

We assessed plasma levels and removal rates of oxalate in 24 patients on chronic peritoneal dialysis (CPD) for oxalosis-unrelated renal failure. The ion-chromatographic (IC) measurements of oxalate in plasma, dialysate, and urine (in seven patients with residual renal function) were used to calculate peritoneal and renal clearances of oxalate. The serum state of saturation with calcium oxalate was calculated by means of a computer-based model system. Patient data were compared with those from 19 healthy individuals. Peritoneal clearance of oxalate was 6.3 +/- 4.7 mL/min, ie, 8% of the normal renal clearance. As a result, both plasma oxalate and calcium oxalate saturation were higher than in controls and did not overlap. Plasma was supersaturated with calcium oxalate in only two of 24 patients (8%). Removal of oxalate by dialysis was related to the amount of fluid infused. Overall removal of oxalate (dialysate plus urine) was similar to 24-hour excretion of normal subjects and was taken as a measure of its generation. Oxalate generation rate was dependent on protein (whole and animal) intake, but not on caloric intake or pyridoxine status. Pyridoxine supplementation, 75 and 300 mg daily for 1 months, was not effective in reducing plasma levels or generation rates of oxalate. Residual renal function had a minor influence on oxalate patterns. We conclude that current programs are adequate to maintain oxalate balance in patients on CPD under basic conditions.

Effects of oral pyridoxine upon plasma and 24-hour urinary oxalate levels in normal subjects and stone formers with idiopathic hypercalciuria

The effect of pyridoxine hydrochloride, 200 mg/day (0.97 mmol/day) for 3 weeks, upon plasma and urinary oxalate has been determined in ten normal subjects and seven patients with idiopathic hypercalciuria while both groups were on low-oxalate diets. Patients had higher basal urinary oxalate levels than normal subjects. In normal subjects pyridoxine administration decreased plasma oxalate levels and raised urinary oxalate. The patients showed no change in either plasma or urinary oxalate.

Ascorbate-induced hyperoxalaemia has no significant effect on lactate generation or erythrocyte 2,3,diphosphoglycerate in dialysis patients

To examine the possible effects of hyperoxalaemia on anaerobic metabolism and erythrocyte pyruvate kinase activity, we induced a rise in plasma oxalate in 11 dialysis patients by the oral administration of ascorbic acid, 500 mg day-1 for 3 weeks. Blood samples were taken from the same antecubital vein before and after the supplementation period, without venous stasis, after an overnight fast. This protocol allowed patients to be used as their own controls. Five healthy subjects underwent an identical protocol to exclude any effect of ascorbate per se. Mean (SEM) plasma oxalate (mumol l-1) rose from 30.3 (3.5) to 48.4 (6.1) in patients and from 1.4 (0.2) to 6.8 (0.9) in healthy subjects. Whole blood ascorbate (mg l-1) rose from 7.0 (0.7) to 26.6 (2.5) in patients and from 9.3 (1.2) to 17.8 (1.8) in healthy subjects (reference range 7.5-20.0 mg l-1). No changes were observed in either group in plasma creatinine, bicarbonate, haemoglobin, or erythrocyte 2,3,diphosphoglycerate (2,3 DPG) after the 3 week supplementation period. Before supplementation lactate generation (area under curve, mmol min l-1) in the 5 min following a 60 s period of standardized ischaemic forearm exercise was significantly (P = 0.026) greater in patients [69.1 (4.7)] than in healthy subjects [46.9 (6.7)]; no significant change in lactate generation occurred in either group after ascorbate-induced hyperoxalaemia. We conclude that changes in plasma oxalate of the order of 20 mumol l-1 have no significant effect on lactate generation or 2,3,DPG levels in uraemic subjects.