Two cases of severe vitamin D3 intoxication treated with therapeutic plasma exchange and high cut-off hemodialysis.

We report on a 53-year-old female patient and a 33-year-old male patient presenting with life-threatening hypercalcemic crisis caused by self-induced vitamin-D intoxication. Both patients took high doses of vitamin D3 supplements, cumulatively up to 2,500,000-10,000,000 I.U. over several months. Accordingly, serum 25-OH-vitamin D concentrations were increased to 663 and 1289 nmol/L (reference 50-175 nmol/L), respectively. As forced diuresis and bisphosphonates failed to correct recurrent hypercalcemia, we hypothesized that add-on extracorporeal treatments might help overcome the refractory situation. Considering the binding of vitamin D3 metabolites to vitamin D-binding protein (VDBP, 59 kDa), we started extracorporeal treatments involving total plasma exchange with replacement by human albumin and by fresh frozen plasma, online hemodiafiltration and high cut-off hemodialysis. We found that in the former case, total plasma exchange with albumin and fresh frozen plasma and high cut-off hemodialysis lowered both 25-OH-vitamin D3 and 1,25-OH-vitamin D3, whereas in the latter case total plasma exchange with albumin was found to more effectively remove vitamin D metabolites compared to high cut-off hemodialysis. In contrast, the amount of total plasma calcium removed by high cut-off hemodialysis was higher compared to total plasma exchange with albumin. During follow up, patients 1 and 2 achieved almost normal total plasma calcium and vitamin D concentrations after 355 and 109 days, respectively. These two cases suggest that extracorporeal treatments with high cut-off hemodialysis and total plasma exchange with albumin may be considered as add-on treatment in refractory cases of vitamin D3-induced hypercalcemia to lower plasma 25-OH-vitamin D3 concentrations.

Routine Monitoring of Sodium and Phosphorus Removal in Peritoneal Dialysis (PD) Patients Treated with Continuous Ambulatory PD (CAPD), Automated PD (APD) or Combined CAPD+APD.

BACKGROUND: Adequate removal of sodium (Na) and phosphorus (P) is of paramount importance for patients with dialysis-dependent kidney disease can easily quantified in peritoneal dialysis (PD) patients. Some studies suggest that automated PD (APD) results in lower Na and P removal. METHODS: In this study we retrospectively analysed our data on Na and P removal in PD patients after implementation of a routine monitoring in 2011. Patients were stratified in those treated with continuous ambulatory PD (CAPD, n=24), automated PD (APD, n=23) and APD with one bag change (CAPD+APD, n=10). Until 2015 we collected time-varying data on Na and P removal from each patient (median 5 [interquartile range 4-8] values). RESULTS: Peritoneal Na and P removal (mmol per 24h ± standard deviation) was 102 ± 48 and 8 ± 2 in the CAPD, 90 ± 46 and 9 ± 3 in the APD and 126 ± 39 and 13 ± 2 in the CAPD+APD group (ANOVA P=0.141 and <0.001). Taking renal excretion into account total Na and P removal (mmol per 24h) was 221 ± 65 and 16 ± 5 in the CAPD, 189 ± 58 and 17 ± 6 in the APD and 183 ± 38 and 16 ± 6 in the CAPD+APD group (P=0.107 and 0.764). Over time, peritoneal removal of Na but not that of P increased in all groups. In patients with modifications of PD treatment, Na but not P removal was significantly increased over-time. CONCLUSIONS: Overall Na and P removal were similar with different PD modalities. Individualized adjustments of PD prescription including icodextrin use or higher glucose concentration can improve Na removal while P removal is mainly determined by the dialysate volume.

Impact of phosphorus restriction and vitamin D-substitution on secondary hyperparathyroidism in a proteinuric mouse model.

BACKGROUND/AIMS: Since the discovery of FGF23, secondary hyperparathyroidism (SHPT) in renal disease has been considered to result primarily from phosphorus retention rather than vitamin D deficiency. However, the impact of phosphorus restriction and vitamin D supplementation on SHPT is still ill defined. METHODS: We investigated the development of SHPT in a doxorubicin-induced proteinuric mouse model and tested different treatment strategies including a low phosphorus diet and substitution with native or active vitamin D in 129 S1/SvImJ wild-type mice. RESULTS: Development of SHPT at day 30 was strongly related to the magnitude of induced proteinuria. In mice with a proteinuria <100 mg/mg creatinine, SHPT was mild (PTH increase 2.4-fold), and serum levels of FGF23, phosphate and urea remained almost stable, whereas mice with heavy proteinuria (>100 mg/mg creatinine) developed marked SHPT (PTH increase 10.1-fold) accompanied by massive increase in FGF23 (27.0-fold increase), hyperphosphatemia (1.8-fold increase), renal failure (7.3-fold urea increase) and depletion of both 25-OH vitamin D and 1,25-OH vitamin D. Substitution with native or active vitamin D was unable to suppress SHPT, whereas a low-phosphorus diet (Pi content 0.013%) completely suppressed SHPT in mice with both mild and heavy proteinuria. CONCLUSIONS: The development of SHPT resulted from phosphate retention in this proteinuric model and could completely be suppressed with a low-phosphorus diet.