Sage Journals: Discover world-class research

Abstract

Objective

To evaluate the role of individual peritoneal membrane transport characteristics on buffer balance through the peritoneal membrane, and thus on the final acid-base status.

Design

Cross-sectional assessment of peritoneal membrane transport characteristics and acid-base status in continuous ambulatory peritoneal dialysis (CAPD) patients.

Setting

Peritoneal dialysis unit in tertiary university hospital.

Patients

The study included 143 clinically stable patients maintained on CAPD more than 6 months using 40 mmol/L of lactate-based dialysate.

Main Outcome Measure

Comparison of acid-base status based on arterial blood gas analysis, dialytic lactate gain, bicarbonate loss, and total base gain according to membrane transport characteristics as defined by dialysate/plasma creatinine ratio (D/P Cr) of standard peritoneal equilibration test (PET).

Results

Mean arterial bicarbonate concentration was 24.5 ± 3.5 mmol/L (16.2 35.7 mmol/L) and mean dialytic base gain was 29.3± 16.7 mmol/day. Only 15 (10.5%) patients showed metabolic acidosis, while 44 (30.8%) patients had various degrees of metabolic alkalosis. Distribution of peritoneal membrane characteristics in our subject showed the highest prevalence of low average (n = 66, 46.2%), followed by high average (n = 54, 37.8%), low (n = 13, 9.1 %), and high (n = 10, 6.9%) transporters. The 4hour D/P Cr was positively correlated with dialytic albumin loss, lactate gain, dialytic base gain, arterial pH, and bicarbonate concentration. Lactate gain and dialytic base gain were significantly higher in high transporters, which resulted in increased pH (7.4 ± 0.03 vs 7.38 ± 0.03, p < 0.05) and bicarbonate level (26.7 ± 3.2 vs 23.4 ± 2.8 mmol/L, p < 0.05) compared to patients with a low transport rate. Multiple regression analysis revealed that lactate gain, duration of peritoneal dialysis, CAP and normalized protein equivalent of nitrogen appearance were the independent factors determining the arterial bicarbonate level.

Conclusion

The peritoneal membrane transport char acteristics can be one of the important factors determining the acid-base status of peritoneal dialysis patients. Duration of dialysis, protein catabolic rate, and acute phase responses of patients also influence arterial bicarbonate level independently. Prospective long-term follow-up studies evaluating the potential role of membrane transport characteristics on acid-base stutus will be needed to further ascertain the clinical implication of this relationship.

Keywords

Peritoneal transport characteristics acid-base status

Get full access to this article

View all access options for this article.

References

Zucchelli

, Santoro

Correction of acid-base balance by dialysis.

Kidney Int 1993; 43(Suppl 41): S179–83.

Bailey

J.L.

, Mitch

W.E.

Metabolic acidosis as a uremic toxin.

Semin Nephrol 1996; 16: 160–6.

Teehan

B.P.

, Schleifer

C.R.

, Reichard

G.A.

, Cupit

M.C.

, Sigler

M.H.

, Halt

A.C.

Acid base studies in continuous ambulatory peritoneal dialysis. In: Moncrief

J.W.

, and Popovich

R.P.

, eds. CAPD update. New York: Masson, 1981: 95–102.

La Greca

, Biasioli

, Chiaramonte

, Davi

, Fabris

, Feriani

Acid-base balance on peritoneal dialysis.

Clin Nephrol 1981; 16: 1–7.

Feriani

Adequacy of acid base correction in continuous ambulatory peritoneal dialysis patients.

Perit Dial Int 1994; 14(Suppl 3): S133–8.

Feriani

, Ronco

, La Greca

Acid-base balance with different CAPD solutions.

Perit Dial Int 1996; 16(Suppl 1): S126–9.

Uribarri

, Buquing

, Oh

M.S.

Acid-base balance in chronic peritoneal dialysis patients.

Kidney Int 1995; 47: 269–73.

Graham

K.A.

, Reaich

, Goodship

T.H.J.

Acid-base regulation in peritoneal dialysis.

Kidney Int 1994; 46(Suppl 48): S47–50.

Detsky

A.S.

, McLaughlin

J.R.

, Baker

J.P.

, Johnston

, Whit taker

, Mendelson

R.A.

What is subjective global assessment of nutritional status?

J Parenter Enteral Nutr 1987; 11: 8–13.

10.

Maas

A.H.J.

, Van Heijst

A.N.P.

, and Visser

B.F.

The determination of the true equilibrium constant and the practical equilibrium coefficient for the first ionization of carbonic acid in solutions of sodium bicarbonate, cerebrospinal fluid, plasma and serum at 25°C and 38°C.

Clin Chim Acta 1971; 33: 325–43.

11.

Twardowski

Z.J.

Clinical values of standard equilibration tests in CAPD patients.

Blood Purif 1989; 7: 95–108.

12.

Bergström

, Furst

, Alvestrand

, Lindholm

Protein and energy intake, nitrogen balance and nitrogen losses in patients treated with continuous ambulatory peritoneal dialysis.

Kidney Int 1993; 44: 1048–51.

13.

Bergström

, Lindholm

Nutrition and adequacy of dialysis: How do hemodialysis and CAPD compare?

Kidney Int 1993; 43(Suppl 40): S39–50.

14.

Sennesael

J.J.

, De Smedt

, Van der Niepen

, Verbeelen

D.L.

The impact of peritonitis on peritoneal and systemic acid-base status of patients on continuous ambulatory peritoneal dialysis patients.

Perit Dial Int 1994; 14: 61–5.

15.

Fabris

, Biasioli

, Feriani

Buffer metabolism in CAPD: Relationship with respiratory dynamics.

ASAIO Trans 1982; 28: 270–5.

16.

Baxter Healthcare Corporation. Internal Baxter evaluation of 806 patients at 40 U.S. centers. McGaw Park, IL: Baxter Healthcare Corporation, 1996.

17.

Young

G.A.

, Kopple

J.D.

, Lindholm

, Vonesh

, Vecchi

A.D.

, Scalamogna

Nutritional assessment of continuous ambulatory peritoneal dialysis patients: An international study.

Am J Kidney Dis 1991; 17: 462–71.

18.

Rippe

, Stelin

, Haraldsson

Simulations of peritoneal solute transport in CAPD patients. Application of two pore formalism.

Kidney Int 1989; 35: 1234–44.

19.

Churchill

D.N.

, Thorpe

K.E.

, Nolph

K.D.

, Keshaviah

P.R.

, Page

, Oreopoulos

D.G.

Increased peritoneal transport is associated with decreased CAPD technique and patient survival.

J Am Soc Nephrol 1997; 8: 189A.

20.

Blake

What is the problem with high transporters?

Perit Dial Int 1997; 17: 317–20.

Impact of Peritoneal Membrane Transport Characteristics on Acid-Base Status in Capd Patients

Abstract

Objective

Design

Setting

Patients

Main Outcome Measure

Results

Conclusion

Keywords

Get full access to this article

References