Acid–base kinetics during hemodialysis using bicarbonate and lactate as dialysate buffer bases based on the H + mobilization model

Abstract

Background:

The H⁺ mobilization model has been recently reported to accurately describe intradialytic kinetics of plasma bicarbonate concentration; however, the ability of this model to predict changing bicarbonate kinetics after altering the hemodialysis treatment prescription is unclear.

Methods:

We considered the H⁺ mobilization model as a pseudo-one-compartment model and showed theoretically that it can be used to determine the acid generation (or production) rate for hemodialysis patients at steady state. It was then demonstrated how changes in predialytic, intradialytic, and immediate postdialytic plasma bicarbonate (or total carbon dioxide) concentrations can be calculated after altering the hemodialysis treatment prescription.

Results:

Example calculations showed that the H⁺ mobilization model when considered as a pseudo-one-compartment model predicted increases or decreases in plasma total carbon dioxide concentrations throughout the entire treatment when the dialysate bicarbonate concentration is increased or decreased, respectively, during conventional thrice weekly hemodialysis treatments. It was further shown that this model allowed prediction of the change in plasma total carbon dioxide concentration after transfer of patients from conventional thrice weekly to daily hemodialysis using both bicarbonate and lactate as dialysate buffer bases.

Conclusion:

The H⁺ mobilization model can predict changes in plasma bicarbonate or total carbon dioxide concentration during hemodialysis after altering the hemodialysis treatment prescription.

Keywords

Acid base bicarbonate carbon dioxide hemodialysis lactate mathematical modeling

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References

Abramowitz

. Bicarbonate balance and prescription in ESRD. J Am Soc Nephrol 2017; 28(3): 726–734.

Uribarri

. Alkali delivery in chronic hemodialysis: would more acetate be helpful. Semin Dial 2019; 32(3): 229–231.

Casagrande

Bianchi

Vito

, et al. Patient-specific modeling of multicompartmental fluid and mass exchange during dialysis. Int J Artif Organs 2016; 39(5): 220–227.

Morel

Jaffrin

Lux

, et al. A comparison of bicarbonate kinetics and acid-base status in high flux hemodialysis and on-line post-dilution hemodiafiltration. Int J Artif Organs 2012; 35(4): 288–300.

Scharfetter

Wirnsberger

Hutten

, et al. Development and critical evaluation of an improved comprehensive multicompartment model for the exchange processes during hemodialysis. Biomed Tech 1995; 40(3): 54–63.

Thews

. Model-based decision support system for individual prescription of the dialysate bicarbonate concentration in hemodialysis. Int J Artif Organs 1992; 15(8): 447–455.

Ursino

Coli

Brighenti

, et al. Mathematical modeling of solute kinetics and body fluid changes during profiled hemodialysis. Int J Artif Organs 1999; 22(2): 94–107.

Sargent

Marano

, et al. Acid-base homeostasis during hemodialysis: new insights into the mystery of bicarbonate disappearance during treatment. Semin Dial 2018; 31(5): 468–478.

Sargent

Marano

, et al. Changing dialysate composition to optimize acid-base therapy. Semin Dial 2019; 32(3): 248–254.

10.

Cherif

Maheshwari

Fuertinger

, et al. Acid-base dynamics during hemodialysis: quantitative in sights from a novel physiology-based mathematical model. Nephrol Dial Transplant 2019; 34: gfz102SuO001.

11.

Cherif

Maheshwari

Fuertinger

, et al. Predicting prescribed dialysis bicarbonate to correct acidemia: application of a novel physiology-based mathematical model. Nephrol Dial Transplant 2019; 34: gfz102SuO005.

12.

Agar

Akonur

, et al. Kinetic model of phosphorus mobilization during and after short and conventional hemodialysis. Clin J Am Soc Nephrol 2011; 6(12): 2854–2860.

13.

Debowska

Poleszczuk

Wojcik-Zaluska

, et al. Phosphate kinetics during weekly cycle of hemodialysis sessions: application of mathematical modeling. Artif Organs 2015; 39(12): 1005–1014.

14.

Leypoldt

Agar

Akonur

, et al. Determinants of phosphorus mobilization during hemodialysis. Kidney Int 2013; 84(4): 841–848.

15.

Yashiro

Kotera

Matsukawa

, et al. Evaluation of a pseudo-one-compartment model for phosphorus kinetics by later-phase dialysate collection during blood purification. Int J Artif Organs 2015; 38(3): 126–132.

16.

Agar

Culleton

Fluck

, et al. Potassium kinetics during hemodialysis. Hemodial Int 2015; 19: 23–32.

17.

Leypoldt

Agar

Akonur

, et al. Steady state phosphorus mass balance model during hemodialysis based on a pseudo one-compartment kinetic model. Int J Artif Organs 2012; 35(11): 969–980.

18.

Leypoldt

Agar

Culleton

. Simplified phosphorus kinetic modeling: predicting changes in predialysis serum phosphorus concentration after altering the hemodialysis prescription. Nephrol Dial Transplant 2014; 29(7): 1423–1429.

19.

Leypoldt

Agar

Bernardo

, et al. Prescriptions of dialysate potassium concentration during short daily or long nocturnal (high dose) hemodialysis. Hemodial Int 2016; 20(2): 218–225.

20.

Marano

. Frontiers in hemodialysis: solutions and implications of mathematical models for bicarbonate restoring. Biomed Signal Pr Control 2019; 52: 321–329.

21.

Leypoldt

Kraus

Jaber

, et al. Effect of dialysate potassium and lactate on serum potassium and bicarbonate concentrations during daily hemodialysis at low dialysate flow rates. BMC Nephrol 2019; 20(1): 252.

22.

Oettinger

Oliver

. Normalization of uremic acidosis in hemodialysis patients with a high bicarbonate dialysate. J Am Soc Nephrol 1993; 3: 1804–1807.

23.

Harris

Yuill

Chesher

. Correcting acidosis in hemodialysis: effect on phosphate clearance and calcification risk. J Am Soc Nephrol 1995; 6(6): 1607–1612.

24.

Williams

Dittmer

McArley

, et al. High bicarbonate dialysate in haemodialysis patients: effects on acidosis and nutritional status. Nephrol Dial Transplant 1997; 12(12): 2633–2637.

25.

Kohn

Kjellstrand

Ing

. Dual-concentrate bicarbonate-based hemodialysis: know your buffers. Artif Organs 2012; 36(9): 765–768.

26.

Kooistra

Vos

Koomans

, et al. Daily home haemodialysis in The Netherlands: effects on metabolic control, haemodynamics, and quality of life. Nephrol Dial Transplant 1998; 13(11): 2853–2860.

27.

Williams

Chebrolu

Ing

, et al. Early clinical, quality-of-life, and biochemical changes of “daily hemodialysis” (6 dialyses per week). Am J Kidney Dis 2004; 43(1): 90–102.

28.

Gennari

. Acid-base assessment of patients receiving hemodialysis. What Are Our Management Goals? Semin Dial 2018; 31: 382–387.

29.

Moran

Doss

Leypoldt

, et al. Lactate dialysate requirements in short daily hemodialysis therapy. J Am Soc Nephrol 2004; 15: 365A–366A.

30.

Tentori

Karaboyas

Robinson

, et al. Association of dialysate bicarbonate concentration with mortality in the Dialysis Outcomes and Practice Patterns Study (DOPPS). Am J Kidney Dis 2013; 62(4): 738–746.

31.

Dalal

Gupta

, et al. L-lactate high-efficiency hemodialysis: hemodynamics, blood gas changes, potassium/phosphorus, and symptoms. Kidney Int 1990; 38(5): 896–903.

32.

Dalal

Ajam

Gupta

, et al. L-lactate for high-efficiency hemodialysis: feasibility studies and a randomized comparison with acetate and bicarbonate. Int J Artif Organs 1989; 12(10): 611–617.

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