Immunosuppressant quantification in intravenous microdialysate - towards novel quasi-continuous therapeutic drug monitoring in transplanted patients.

OBJECTIVES: Therapeutic drug monitoring (TDM) plays a crucial role in personalized medicine. It helps clinicians to tailor drug dosage for optimized therapy through understanding the underlying complex pharmacokinetics and pharmacodynamics. Conventional, non-continuous TDM fails to provide real-time information, which is particularly important for the initial phase of immunosuppressant therapy, e.g., with cyclosporine (CsA) and mycophenolic acid (MPA). METHODS: We analyzed the time course over 8 h of total and free of immunosuppressive drug (CsA and MPA) concentrations measured by liquid chromatography-tandem mass spectrometry (LC-MS/MS) in 16 kidney transplant patients. Besides repeated blood sampling, intravenous microdialysis was used for continuous sampling. Free drug concentrations were determined from ultracentrifuged EDTA-plasma (UC) and compared with the drug concentrations in the respective microdialysate (µD). µDs were additionally analyzed for free CsA using a novel immunosensor chip integrated into a fluorescence detection platform. The potential of microdialysis coupled with an optical immunosensor for the TDM of immunosuppressants was assessed. RESULTS: Using LC-MS/MS, the free concentrations of CsA (fCsA) and MPA (fMPA) were detectable and the time courses of total and free CsA comparable. fCsA and fMPA and area-under-the-curves (AUCs) in µDs correlated well with those determined in UCs (r≥0.79 and r≥0.88, respectively). Moreover, fCsA in µDs measured with the immunosensor correlated clearly with those determined by LC-MS/MS (r=0.82). CONCLUSIONS: The new microdialysis-supported immunosensor allows real-time analysis of immunosuppressants and tailor-made dosing according to the AUC concept. It readily lends itself to future applications as minimally invasive and continuous near-patient TDM.

Peritoneal magnesium elimination and its clinical relevance in peritoneal dialysis patients.

BACKGROUND: Dialysis patients are at increased risk for vascular calcification and cardiovascular disease. Emerging data suggests that magnesium might be protective for the vascular system in peritoneal dialysis (PD) patients as well. However, only limited data is available on the elimination of magnesium through PD treatment. This study aims to evaluate the peritoneal magnesium elimination characteristics in comparison to other small solutes and the influence of peritoneal transport status. MATERIALS AND METHODS: Peritoneal elimination of magnesium, blood-urea-nitrogen (BUN), and creatinine during a 4-hour peritoneal equilibration test (PET) was assessed in 30 stable PD patients. Absolute magnesium elimination was compared overall and between creatinine transport tertiles. RESULTS: Median age was 61 years, 50% of patients were male, 20% were on automated PD treatment. Serum magnesium was 0.84 mmol/L, and dialysate magnesium at the end of the PET was 0.57 mmol/L in the overall cohort and did not differ significantly between tertiles. The magnesium dialysate-to-plasma ratio was significantly different between the subgroups (lower tertile: median 0.60 (minimum 0.52, maximum 0.68) vs. middle tertile: 0.64 (0.58, 0.68) vs. upper tertile: 0.69 (0.67, 0.74), p < 0.001). The elimination per liter of dialysis fluid was also significantly different (8.6 (6.6, 10.4) vs. 9.4 (8.0, 10.5) vs. 10.6 (0.2, 11.8) mg/L, p = 0.002), as was the absolute removal during the 4-hour dwell (18.6 (15.8, 21.2) vs. 19.4 (13.4, 24.6) vs. 22.7 (19.6, 31.9) mg, p = 0.007, respectively). CONCLUSION: Peritoneal magnesium elimination is similar to small solute transport characteristics. However, the absolute differences among patients with slower and faster transport types are small. Therefore, magnesium supplementation in PD patients should be guided by serum magnesium concentrations rather than the amount of peritoneal elimination.