Comparison of three PET methods to assess peritoneal membrane transport

Romani, RF.; Waniewski, J.; Kruger, L.; Lindholm, B.; Nascimento, M.M.

doi:10.1590/1414-431X20198596

Abstract

The peritoneal equilibration test (PET) is the most widespread method for assessing water and solute transport across the peritoneal membrane. This study compared three methods: traditional PET (t-PET), mini-PET, and modified PET (mod-PET). Non-diabetic adults (n=21) who had been on peritoneal dialysis (PD) for at least three months underwent t-PET (glucose 2.5%-4 h), mini-PET (glucose 3.86%-1 h), and mod-PET (glucose 3.86%-4 h) to determine dialysate-to-plasma concentration ratio (D/P) for creatinine and dialysate-to-baseline dialysate concentration ratio (D/D0) for glucose. Agreement between methods regarding D/P creatinine and D/D0 glucose was assessed using analysis of variance (ANOVA), Pearson's correlation coefficient, and Bland-Altman analysis. D/P creatinine differed between t-PET and mini-PET (P<0.001) and between mod-PET and mini-PET (P<0.01) but not between t-PET and mod-PET (P=0.746). The correlation of D/P creatinine with t-PET vs mod-PET was significant (r=0.387, P=0.009) but not that of t-PET vs mini-PET (r=0.088, P=0.241). Estimated bias was −0.029 (P=0.201) between t-PET and mod-PET, and 0.206 (P<0.001) between t-PET and mini-PET. D/D0 glucose differed between t-PET and mod-PET (P=0.003) and between mod-PET and mini-PET (P=0.002) but not between t-PET and mini-PET (P=0.885). The correlations of D/D0 glucose in t-PET vs mod-PET (r=−0.017, P=0.421) or t-PET vs mini-PET (r=0.152, P=0.609) were not significant. Estimated bias was 0.122 (P=0.026) between t-PET and mod-PET, and 0.122 (P=0.026) between t-PET and mini-PET. The significant correlation of D/P creatinine between t-PET and mod-PET suggested that the latter is a good alternative to t-PET. There was no such correlation between t-PET and mini-PET.

Peritoneal dialysis; Peritoneal membrane; Peritoneal equilibration test; Dialysis adequacy; Peritoneal solute transport

Introduction

Peritoneal dialysis (PD) is a modality of renal replacement therapy in which the peritoneal membrane (PM), semipermeable to water and solutes, allows the diffusion of solutes between the uremic plasma and the dialysate residing in the peritoneal cavity (¹1. Oreopoulos DG. Peritoneal dialysis in the past 20 years: an exciting journey. Perit Dial Int 1999; 19 (Suppl 3): S6–S8.). During the PD process, the transport characteristics of the PM differ between patients with regard to the rate of transport of solutes and water and this may have clinical implications on dialysis therapy prescription (²2. Chavez Valencia V, Orizaga de la Cruz C, Pazarin Villasenor HL, Fuentes Ramirez F, Parra Michel R, Aragaki Y, et al. Frequency of peritoneal transport in a population of the Hospital General Regional No. 46, Instituto Mexicano del Seguro Social. Gaceta Medica de Mexico 2014; 150: 186–193.). Therefore, to achieve the best possible treatment, patients need to be classified according to the PM transport profile (³3. Rajakaruna G, Caplin B, Davenport A. Peritoneal protein clearance rather than faster transport status determines outcomes in peritoneal dialysis patients. Perit Dial Int 2015; 35: 216–221, doi: 10.3747/pdi.2013.00217.
https://doi.org/10.3747/pdi.2013.00217... ,⁴4. Janda K, Krzanowski M, Dumnicka P, Kusnierz-Cabala B, Miarka P, Sulowicz W. Peritoneal solute transport rate as an independent risk factor for total and cardiovascular mortality in a population of peritoneal dialysis patients. Adv Perit Dial 2014; 30: 15–20.).

For this purpose, the peritoneal equilibrium test (known by its acronym PET) was described in 1987 by Twardowski et al. (⁵5. Twardowski ZJ, Nolph KD, Khanna R, Prowant BF, Ryan LR, Moore HL, et al. Peritoneal equilibration test. Perit Dial Bull 1987; 7: 138–148.) who classified the PM solute transport profile of a patient according to the membrane's permeability to two small molecules, creatinine, MW 113, and glucose, MW 180, using dialysis fluid with 2.5/2.27% anhydrous glucose as osmotic agent. An alternative to the traditional PET (t-PET) is a similar test that uses a solution with a higher concentration (4.25/3.86% of glucose), known as hypertonic PET or modified PET (mod-PET). The mod-PET is advocated by the International Society for Peritoneal Dialysis (⁶6. Smit W, Langedijk MJ, Schouten N, van den Berg N, Struijk DG, Krediet RT. A comparison between 1.36% and 3.86% glucose dialysis solution for the assessment of peritoneal membrane function. Perit Dial Int 2000; 20: 734–741.). The results obtained with mod-PET for solute transport appear to be comparable to those of t-PET, but mod-PET provides additional information such as the indirect assessment of free water transport across the peritoneal water-only channels (aquaporins) through the determination of sodium transport and sieving of sodium.

Another alternative test is the mini-PET, which was introduced in 2005 by La Milia et al. (⁷7. La Milia V, Di Filippo S, Crepaldi M, Del Vecchio L, Dell'Oro C, Andrulli S, et al. Mini-peritoneal equilibration test: a simple and fast method to assess free water and small solute transport across the peritoneal membrane. Kidney Int 2005; 68: 840–846, doi: 10.1111/j.1523-1755.2005.00465.x.
https://doi.org/10.1111/j.1523-1755.2005... ). It uses bags with 2 L of fluid with 4.25/3.86% glucose, but the dialysate is drained after only 1 h. It appears to provide information equivalent to the t-PET with regard to the transport of small molecules (⁷7. La Milia V, Di Filippo S, Crepaldi M, Del Vecchio L, Dell'Oro C, Andrulli S, et al. Mini-peritoneal equilibration test: a simple and fast method to assess free water and small solute transport across the peritoneal membrane. Kidney Int 2005; 68: 840–846, doi: 10.1111/j.1523-1755.2005.00465.x.
https://doi.org/10.1111/j.1523-1755.2005... ).

The aim of the present study was to compare these three methods (mini-PET, mod-PET, and t-PET) in the assessment of PM small-solute transport profile in patients with chronic kidney disease (CKD) undergoing PD.

Material and Methods

This study was part of a collaboration between the Fundação Pró-Renal (FPR), Brazil, Karolinska Institute, Sweden, and Polish Academy of Sciences, Poland, in evaluating the transport of solutes and insulin resistance in patients undergoing PD. One hundred and eighty-eight patients on PD from the FPR, aged ≥18 years, were included in the initial evaluation. Patients with diabetes and patients who had been on PD for less than three months were excluded. Twenty-one patients who agreed to participate were selected through convenience sampling.

The PM transport profile of these patients was assessed using t-PET and mini-PET, and a 4-hour dialysis session with dialysis fluid containing 3.86% glucose was subsequently performed with the collection of serial blood and dialysate samples (mod-PET). Commercially available dialysis solutions (Dianeal^®, Baxter Healthcare Corporation, USA) in bags for manual infusion were used. The composition of the solution was as follows: 132 mEq/L sodium, 95 mEq/L chloride, 2.5 mEq/L calcium, 0.5 mEq/L magnesium, and 40 mEq/L lactate (Dianeal^®, Baxter Healthcare Corporation).

Written informed consent was obtained from all patients and the study protocol was approved by the Ethics Committee of the Faculdade Evangélica do Paraná (FEPAR), under protocol number 7876/11 (12 June 2011).

t-PET

All tests were performed in the Dialysis Center by a trained nursing team and under the supervision of a medical team. The standard procedure began with the complete drainage of remaining fluid from the patient's peritoneal cavity, and the 2.27% glucose dialysis solution was then infused. The dwell time was 4 h. Dialysate samples (10 mL) were collected at 0 min (immediately after infusion), and 2 and 4 h after infusion. A blood sample (10 mL) was collected at 2 h. The infusion initiation and drainage times were recorded (⁸8. Waniewski J. Peritoneal fluid transport: mechanisms, pathways, methods of assessment. Arch Med Res 2013; 44: 576–583, doi: 10.1016/j.arcmed.2013.10.010.
https://doi.org/10.1016/j.arcmed.2013.10... ).

mini-PET

The standard procedure began with drainage of fluid from the peritoneal cavity and then the 3.86% glucose dialysis solution was infused. The dwell time was 1 h. The dialysate samples (10 mL) were collected at 0 h (immediately after infusion) and at 1 h after infusion. A blood sample (10 mL) was collected at 1 h. The infusion initiation and drainage times were recorded. These tests were performed at least 48 h after performance of the t-PET (⁸8. Waniewski J. Peritoneal fluid transport: mechanisms, pathways, methods of assessment. Arch Med Res 2013; 44: 576–583, doi: 10.1016/j.arcmed.2013.10.010.
https://doi.org/10.1016/j.arcmed.2013.10... ).

mod-PET

The standard procedure began with drainage of fluid from the patient's peritoneal cavity followed by the infusion of the 3.86% glucose dialysis solution with a dwell time of 4 h. Dialysate samples (10 mL) were collected every hour, at 0 h (immediately after infusion), and 1, 2, 3, and 4 h after infusion. Blood samples (10 mL) were collected every 30 min, at 0 h (immediately after infusion), and at 0.5, 1, 1.5, 2, 2.5, 3, 3.5, and 4 h after infusion. Dialysis infusion initiation and drainage times were recorded. The test was performed at least 48 h after the application of the mini-PET. The dialysate samples collected at 0, 2, and 4 h and the blood samples collected at 2 h were used to calculate the results of mod-PET (⁸8. Waniewski J. Peritoneal fluid transport: mechanisms, pathways, methods of assessment. Arch Med Res 2013; 44: 576–583, doi: 10.1016/j.arcmed.2013.10.010.
https://doi.org/10.1016/j.arcmed.2013.10... ).

Analyses

The blood and dialysate samples were obtained between April 2012 and January 2013 according to the protocols described above and were kept in cryogenic storage (–30°C) until they were sent for analysis at the Karolinska Institute in Stockholm, Sweden.

For the purposes of the study, the concentrations of creatinine and glucose in blood and dialysate samples were determined. Glucose levels (mmol/L) were measured using the colorimetric enzymatic method, and creatinine levels (umol/L) were determined by the Jaffé method. The blood sample of one patient used in the mod-PET could not be analyzed due to hemolysis and was excluded from the final analysis.

The determination of creatinine levels in the dialysate using the Jaffé method is affected by the high glucose concentration. The falsely high results produced by this method must be corrected and a correction factor must be provided by the laboratory (⁹9. Tam P, Sheldrake P, Ng A, Oreopoulos DG, Sloand JA. Peritoneal equilibration testing: correcting the correction factor. Perit Dial Int 2009; 29: 352–355.). The correction factor applied in this protocol was: creatinine level –0.234 × glucose level

The creatinine result of one patient in the mod-PET, glucose results of two patients in the mini-PET, and the glucose result of one patient in the mod-PET were excluded because of sample analysis problems.

The dialysate-to-plasma concentration ratio (D/P) for creatinine and the dialysate-to-baseline dialysate concentration ratio (D/D0) for glucose were calculated for the three tests using Microsoft Excel^® software, version 14.00 for Mac (Microsoft Corporation, USA).

D/P creatinine

a) D/P creatinine in the t-PET was calculated using the results of the dialysate samples at 0, 2, and 4 h in the numerator and the results of the plasma samples in the denominator. The value obtained at 4 h was used as reference for analysis (⁵5. Twardowski ZJ, Nolph KD, Khanna R, Prowant BF, Ryan LR, Moore HL, et al. Peritoneal equilibration test. Perit Dial Bull 1987; 7: 138–148.,¹⁰10. La Milia V. Peritoneal transport testing. J Nephrol 2010; 23: 633–647.); b) D/P creatinine in the mini-PET was calculated using the results of creatinine in the dialysate samples at 0 and 1 h in the numerator and the results of the plasma samples in the denominator (¹⁰10. La Milia V. Peritoneal transport testing. J Nephrol 2010; 23: 633–647.); c) D/P creatinine in the mod-PET was calculated using the creatinine results of the dialysate samples at 0, 2, and 4 h in the numerator and the results of the plasma samples in the denominator. The value obtained at 4 h was used as reference for analysis (¹⁰10. La Milia V. Peritoneal transport testing. J Nephrol 2010; 23: 633–647.).

D/D0 glucose

a) D/D0 glucose in the t-PET was calculated using the glucose results of the dialysate samples at 4 h in the numerator and at 0 h in the denominator (¹⁰10. La Milia V. Peritoneal transport testing. J Nephrol 2010; 23: 633–647.); b) D/D0 glucose in the mini-PET was calculated using the glucose results of the dialysate samples at 1 h in the numerator and at 0 h in the denominator (¹⁰10. La Milia V. Peritoneal transport testing. J Nephrol 2010; 23: 633–647.); c) D/D0 glucose in the mod-PET was calculated using the glucose results of the dialysate samples at 4 h in the numerator and at 0 h in the denominator (¹⁰10. La Milia V. Peritoneal transport testing. J Nephrol 2010; 23: 633–647.).

Statistical analysis

The results of quantitative variables are described as means, medians, minimum and maximum values, and standard deviations, as appropriate. Qualitative variables are described as frequencies and percentages. The repeated measures analysis of variance (ANOVA) was used to compare quantitative variables between the three methods (t-PET, mini-PET, and mod-PET). Multiple comparisons were performed using the test of least significant difference (LSD). The variables that did not meet the condition of normality (evaluated using the Kolmogorov-Smirnov test) were subject to logarithmic transformation. To assess the inter-method agreement regarding transport classification (low, average, or high), the Kappa coefficient of agreement was estimated. The correlation between the methods was determined using Pearson's coefficient of correlation, and Bland-Altman analysis was used to assess the agreement between the techniques. Values of P<0.05 indicated statistical significance. The data were analyzed using the SPSS Statistics for Windows, version 20.0. (USA).

Results

Clinical and demographic data of study participants (n=21) are summarized in Table 1.

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Table 1.
Clinical and demographic characteristics of 21 peritoneal dialysis (PD) patients.

D/P Creatinine

Repeated measures ANOVA did not show a significant difference in D/P creatinine between t-PET and mod-PET (P=0.746), but there was a significant difference between t-PET and mini-PET (P<0.001) and between mod-PET and mini-PET (P>0.001, Figure 1).

Figure 1.
Dialysate-to-plasma concentration ratio (D/P) for creatinine in traditional peritoneal equilibration test (t-PET) vs mini-PET vs modified (mod)-PET (n=20). According to the repeated measures ANOVA, D/P creatinine did not differ between t-PET and mod-PET (P=0.746), but there was a significant difference between t-PET and mini-PET (P<0.001) and between mod-PET and mini-PET (P>0.001).

In addition, there was a significant positive correlation between t-PET and mod-PET (r=0.387, P=0.009, Figure 2) but not between t-PET and mini-PET (r=0.088, P=0.241).

Figure 2.
Correlation of dialysate-to-plasma concentration ratio (D/P) for creatinine between traditional peritoneal equilibration test (t-PET) vs modified (mod)-PET (r=0.387, P=0.009; n=20).

The bias between t-PET and mod-PET estimated using the Bland-Altman analysis was –0.029 (P=0.201), which indicated that the hypothesis of the absence of a bias between the results of PET and mod-PET was not rejected (Figure 3). The bias between t-PET and mini-PET was 0.206 (P<0.001), which indicated that the hypothesis of the absence of a bias between PET and mini-PET results was rejected.

Figure 3.
Bland-Altman analysis for dialysate-to-plasma concentration ratio (D/P) for creatinine between traditional peritoneal equilibration test (t-PET) vs modified (mod)-PET (n=20). There was no significant bias between t-PET and mod-PET (−0.029; P=0.201).

Analysis of agreement between the methods with regard to membrane profile classification showed that there was no significant agreement between t-PET and mini-PET. The estimated Kappa coefficient of agreement was 0.01 (poor agreement) and not statistically significant (P=0.415). Moreover, there was no significant agreement between t-PET and mod-PET. The estimated Kappa coefficient of agreement was 0.08 (poor agreement), without statistical significance (P=0.676). The estimated Kappa coefficient of agreement between mini-PET and mod-PET was 0.07 (poor agreement; P=0.250).

The accuracy of the mod-PET in identifying high and low transporters was 65% in relation to t-PET.

D/D0 Glucose

Repeated measures ANOVA showed significant differences in D/D0 glucose between t-PET and mini-PET (P=0.001), between t-PET and mod-PET (P=0.031), and between mod-PET and mini-PET (P<0.001).

In addition, no significant correlation was observed between t-PET and mod-PET (r=−0.017, P=0.421) and between t-PET and mini-PET (r=0.152, P=0.609).

The bias between t-PET and mod-PET estimated by Bland-Altman analysis was 0.122 (P=0.026), thus indicating that the hypothesis of the absence of a bias between the t-PET and mod-PET results was rejected. The estimated bias between t-PET and mini-PET was 0.122 (P=0.026), which indicated that the hypothesis of the absence of a bias between the PET and mini-PET results was rejected.

Analysis of agreement between the methods with regard to membrane profile classification showed that there was no significant agreement between t-PET and mini-PET. The estimated Kappa coefficient of agreement was −0.03 (poor agreement), without significance (P=0.627). Furthermore, there was no significant agreement between t-PET and mod-PET. The estimated Kappa coefficient of agreement was −0.09 (poor agreement), without statistical significance (P=0.494). The estimated Kappa coefficient of agreement between mini-PET and mod-PET was 0.01 (poor agreement), without statistical significance (P=0.847).

Ultrafiltration

Analysis of variance showed a statistical difference between t-PET and mod-PET (P<0.001) with regard to ultrafiltration (UF); however, there was no statistical difference between t-PET and mini-PET (P=0.375).

There was no correlation between t-PET and mod-PET (r=−0.159, P=0.425); however, there was a correlation between t-PET and mini-PET (r=0.260, P=0.009).

The bias between t-PET and mod-PET estimated by Bland-Altman analysis was −473.3 (P<0.001), which indicated that the hypothesis of the absence of a bias between PET and mod-PET was rejected. The estimated bias between t-PET and mini-PET was −76.7 (P=0.426), thus indicating that the hypothesis of the absence of a bias between the t-PET and mini-PET results was not rejected.

Discussion

t-PET vs mod-PET

The results of the present study are in line with those obtained by Smit et al. (⁶6. Smit W, Langedijk MJ, Schouten N, van den Berg N, Struijk DG, Krediet RT. A comparison between 1.36% and 3.86% glucose dialysis solution for the assessment of peritoneal membrane function. Perit Dial Int 2000; 20: 734–741.) who compared peritoneal transport with 1.36 and 3.86% glucose solutions and did not find an effect of solute tonicity on the creatinine D/P ratio. Peritoneal permeability analysis performed in the same study demonstrated that there was no effect of dialysis solution tonicity on the area of small-solute mass transfer, which implies that there is no influence on effective peritoneal area. There was no correlation between the two methods with regard to D/D0 glucose because it was lower in the mod-PET. The authors suggested that this may be due to higher UF and consequent dilution of the dialysate (⁶6. Smit W, Langedijk MJ, Schouten N, van den Berg N, Struijk DG, Krediet RT. A comparison between 1.36% and 3.86% glucose dialysis solution for the assessment of peritoneal membrane function. Perit Dial Int 2000; 20: 734–741.). The results led the authors to conclude that the mod-PET is the test of choice because it provides information similar to that provided by the t-PET plus additional information on free-water transport and UF.

Pride et al. (¹¹11. Pride ET, Gustafson J, Graham A, Spainhour L, Mauck V, Brown P, et al. Comparison of a 2.5% and a 4.25% dextrose peritoneal equilibration test. Perit Dial Int 2002; 22: 365–370.) compared t-PET and mod-PET with regard to the transport of creatinine, glucose, and sodium and, similar to the present study, obtained reproducibility in the classification of the transport across the membrane using D/P creatinine. The volume of UF and the evaluation of aquaporin function differed between the two methods. The authors concluded that the mod-PET provides additional information without prejudice to molecule transport classification.

La Milia et al. (¹²12. La Milia V, Pozzoni P, Virga G, Crepaldi M, Del Vecchio L, Andrulli S, et al. Peritoneal transport assessment by peritoneal equilibration test with 3.86% glucose: a long-term prospective evaluation. Kidney Int 2006; 69: 927–933, doi: 10.1038/sj.ki.5000183.
https://doi.org/10.1038/sj.ki.5000183... ) performed a prospective analysis of 95 patients with annual application of the mod-PET for D/P creatinine, D/D0 glucose, UF, and sodium sieving. These authors observed a gradual drop in UF from the second year onwards. In multivariate analysis, the loss of aquaporin function, which was assessed by sodium sieving, correlated with the risk of UF loss (risk ratio (RR) 0.797 (0.649–0.965), P=0.020). They concluded that the mod-PET provides more information than t-PET, without prejudice to solute transport assessment, and that there is a gradual loss in aquaporin transport over the years on PD that correlates with UF failure.

The equivalence between t-PET and mod-PET with regard to transport profile assessment appears to be confirmed by our analysis. The data allowed inference that with a similar time of exposure to the dialysis solution, as occurs in the two tests, the effect of tonicity and subsequent solute (creatinine) convection have little effect on the result of the assessment of peritoneal transport by both methods.

The comparison between t-PET and mod-PET with regard to D/D0 glucose showed a significant difference; there was a bias between the methods and there was no correlation between linear values or the categorical classification. This difference may be explained by the different concentrations of glucose, and is similar to that obtained in other studies that compared tests with distinct glucose concentrations (⁶6. Smit W, Langedijk MJ, Schouten N, van den Berg N, Struijk DG, Krediet RT. A comparison between 1.36% and 3.86% glucose dialysis solution for the assessment of peritoneal membrane function. Perit Dial Int 2000; 20: 734–741.,¹¹11. Pride ET, Gustafson J, Graham A, Spainhour L, Mauck V, Brown P, et al. Comparison of a 2.5% and a 4.25% dextrose peritoneal equilibration test. Perit Dial Int 2002; 22: 365–370.,¹²12. La Milia V, Pozzoni P, Virga G, Crepaldi M, Del Vecchio L, Andrulli S, et al. Peritoneal transport assessment by peritoneal equilibration test with 3.86% glucose: a long-term prospective evaluation. Kidney Int 2006; 69: 927–933, doi: 10.1038/sj.ki.5000183.
https://doi.org/10.1038/sj.ki.5000183... ). D/P creatinine is, however, the most commonly used parameter in clinical decision-making and appears to be the best parameter for peritoneal transport classification tests with hypertonic glucose.

t-PET vs mini-PET

Performing t-PET is laborious and time-consuming and, therefore, the use of simpler and quicker methods, such as the mini-PET, has been studied, with different results (¹³13. Cano F, Rojo A, Azocar M, Ibacache MJ, Delucchi A, Ugarte F, et al. The mini-PET in pediatric peritoneal dialysis: a useful tool to predict volume overload? Pediatr Nephrol 2013; 28: 1121–1126, doi: 10.1007/s00467-013-2447-2.
https://doi.org/10.1007/s00467-013-2447-... 14. Warady BA, Jennings J. The short PET in pediatrics. Perit Dial Int 2007; 27: 441–445.–¹⁸18. Kazancioğlu R, Topcuoglu D, Kiricimli N, Cinkilic A, Celik H. Comparison of fast peritoneal equilibrium test with the standard method: a pilot study. J Ren Care 2012; 38: 29–33, doi: 10.1111/j.1755-6686.2011.00241.x.
https://doi.org/10.1111/j.1755-6686.2011... ). La Milia et al. (⁷7. La Milia V, Di Filippo S, Crepaldi M, Del Vecchio L, Dell'Oro C, Andrulli S, et al. Mini-peritoneal equilibration test: a simple and fast method to assess free water and small solute transport across the peritoneal membrane. Kidney Int 2005; 68: 840–846, doi: 10.1111/j.1523-1755.2005.00465.x.
https://doi.org/10.1111/j.1523-1755.2005... ) demonstrated equivalence between mini-PET and t-PET in the characterization of small molecule transport. In addition, the study suggested the possibility of assessing free-water transport through the aquaporins.

Baştuğ et al. (¹⁷17. Baştuğ F, Dursun I, Dursun J, Gündüz Z, Günay D, Yel S, et al. Could mini-PET be used to instead of 4 h original-PET to assess peritoneal permeability in children on peritoneal dialysis? Ren Fail 2014; 36: 562–566, doi: 10.3109/0886022X.2013.879368.
https://doi.org/10.3109/0886022X.2013.87... ) demonstrated, using Pearson's correlation and bias assessment with the Bland-Altman test, that the characterization of transport using PET and mini-PET was similar, as was the categorical classification of high, average, and low transport using D/P creatinine evaluation. Kazancioğlu et al. (¹⁸18. Kazancioğlu R, Topcuoglu D, Kiricimli N, Cinkilic A, Celik H. Comparison of fast peritoneal equilibrium test with the standard method: a pilot study. J Ren Care 2012; 38: 29–33, doi: 10.1111/j.1755-6686.2011.00241.x.
https://doi.org/10.1111/j.1755-6686.2011... ) and Cano et al. (¹⁹19. Cano F, Sanchez L, Rebori A, Quiroz L, Delucchi A, Delgado I, et al. The short peritoneal equilibration test in pediatric peritoneal dialysis. Pediatr Nephrol 2010; 25: 2159–2164, doi: 10.1007/s00467-010-1566-2.
https://doi.org/10.1007/s00467-010-1566-... ) also demonstrated a positive correlation between t-PET and mini-PET, performed by infusing the dialysate for 2 h.

Cuevas et al. (¹⁶16. Cuevas M, Zambrano P, Dinamarca H, Gilbert M, Cano F. Short PET in pediatric peritoneal dialysis. Pediatr Nephrol 2008; 23: 1853–1858, doi: 10.1007/s00467-008-0892-0.
https://doi.org/10.1007/s00467-008-0892-... ) conducted a prospective study of the results of 81 PET tests in 81 patients. They analyzed the results collected after 4 h (t-PET) and after 2 h (mini-PET) for glucose and creatinine and did not find a correlation between the results.

The comparison between t-PET and mini-PET in the present study with regard to D/P creatinine showed a significant difference; there was a bias between the methods and there was no correlation between the linear values or the categorical classification. Our results suggest that mini-PET was not equivalent to t-PET with regard to the classification of peritoneal transport, despite its ease of application.

UF Assessment

UF failure is defined as UF lower than 400 mL after 4 h of exposure to a 3.36% glucose solution (²⁰20. Yuvaraj A, Koshy PJ, Rohit A, Nagarajan P, Nair S, Revathi L, et al. Diagnostic dilemma of ultrafiltration failure in a continuous ambulatory peritoneal dialysis patient. Perit Dial Int 2015; 35: 233–234, doi: 10.3747/pdi.2014.00086.
https://doi.org/10.3747/pdi.2014.00086... 21. Rippe B. How to measure ultrafiltration failure: 2.27% or 3.86% glucose? Perit Dial Int 1997; 17: 125–128. 22. Shetty A, Oreopoulos DG. Ultrafiltration failure in CAPD. J Postgrad Med 1994; 40: 185–193. 23. Selgas R, Bajo MA, Castro MJ, Sanchez-Tomero JA, Cirugeda A. Managing ultrafiltration failure by peritoneal resting. Perit Dial Int 2000; 20: 595–597.–²⁴24. Ho-dac-Pannekeet MM, Atasever B, Struijk DG, Krediet RT. Analysis of ultrafiltration failure in peritoneal dialysis patients by means of standard peritoneal permeability analysis. Perit Dial Int 1997; 17: 144–150.). According to Ho-dac-Pannekeet et al. (²⁴24. Ho-dac-Pannekeet MM, Atasever B, Struijk DG, Krediet RT. Analysis of ultrafiltration failure in peritoneal dialysis patients by means of standard peritoneal permeability analysis. Perit Dial Int 1997; 17: 144–150.), the use of a 3.36% glucose solution is better for UF evaluation as it reveals the true UF capacity of the PM because the proportion of UF flow through aquaporins is higher.

In the present study, a secondary analysis was performed of the correlation of UF of t-PET and mini-PET, respectively, with mod-PET, which is considered the reference test to evaluate UF failure. UF in the t-PET and mini-PET differed from that in the mod-PET and, according to our findings, these tests (i.e., t-PET and mini-PET) were not adequate for UF failure assessment.

The present study has some limitations. This was a small convenience sample and, therefore, the results should be carefully interpreted. The prevalence of high and average-high transporters was high, which may create a bias in the analysis of transport compared to other patient populations undergoing PD.

Conclusion

This study confirmed that the rate of creatinine removal as assessed by D/P creatinine was similar with mod-PET and t-PET. This strengthened the evidence that mod-PET is a method that provides additional information (evaluation of UF and of free water transport) without prejudice to the evaluation of small solute transport as compared to t-PET. While the main advantages of the mini-PET are its fast execution and the possibility of assessing aquaporin function, its lack of equivalence to t-PET in the evaluation of solute removal as observed in the current study is a limitation. On the other hand, the majority of previous studies in adults or children show good correlation between evaluations of solute transport at 1, 2, or 4 h (⁷7. La Milia V, Di Filippo S, Crepaldi M, Del Vecchio L, Dell'Oro C, Andrulli S, et al. Mini-peritoneal equilibration test: a simple and fast method to assess free water and small solute transport across the peritoneal membrane. Kidney Int 2005; 68: 840–846, doi: 10.1111/j.1523-1755.2005.00465.x.
https://doi.org/10.1111/j.1523-1755.2005... ,¹⁵15. Twardowski ZJ, Prowant BF, Moore HL, Lou LC, White E, Farris K. Short peritoneal equilibration test: impact of preceding dwell time. Adv Perit Dial 2003; 19: 53–58.,¹⁷17. Baştuğ F, Dursun I, Dursun J, Gündüz Z, Günay D, Yel S, et al. Could mini-PET be used to instead of 4 h original-PET to assess peritoneal permeability in children on peritoneal dialysis? Ren Fail 2014; 36: 562–566, doi: 10.3109/0886022X.2013.879368.
https://doi.org/10.3109/0886022X.2013.87... ,¹⁹19. Cano F, Sanchez L, Rebori A, Quiroz L, Delucchi A, Delgado I, et al. The short peritoneal equilibration test in pediatric peritoneal dialysis. Pediatr Nephrol 2010; 25: 2159–2164, doi: 10.1007/s00467-010-1566-2.
https://doi.org/10.1007/s00467-010-1566-... ). We concluded that t-PET remained a reliable test for the study of solute transport across the PM; however, mod-PET has been shown to be a useful alternative when more detailed information about UF and free water transport are required.

Acknowledgments

We thank the patients and the nursing staff at Hospital Universitário Evangélico de Curitiba for their time and effort allowing us to collect samples, and the laboratory staff at Karolinska Institute for analyzing samples. Pro-Renal Foundation, Brazil, supported the study and provided dialysis solutions produced by Baxter Healthcare Corporation. Baxter Novum is the result of a grant from Baxter Healthcare Corporation to Karolinska Institute. Bengt Lindholm is employed by Baxter Healthcare Corporation. None of the other authors declare any conflict of interest. The funders did not have any role in the study design, data collection and analysis, decision to publish, or preparation of the manuscript.

References

¹
Oreopoulos DG. Peritoneal dialysis in the past 20 years: an exciting journey. Perit Dial Int 1999; 19 (Suppl 3): S6–S8.
²
Chavez Valencia V, Orizaga de la Cruz C, Pazarin Villasenor HL, Fuentes Ramirez F, Parra Michel R, Aragaki Y, et al. Frequency of peritoneal transport in a population of the Hospital General Regional No. 46, Instituto Mexicano del Seguro Social. Gaceta Medica de Mexico 2014; 150: 186–193.
³
Rajakaruna G, Caplin B, Davenport A. Peritoneal protein clearance rather than faster transport status determines outcomes in peritoneal dialysis patients. Perit Dial Int 2015; 35: 216–221, doi: 10.3747/pdi.2013.00217.
» https://doi.org/10.3747/pdi.2013.00217
⁴
Janda K, Krzanowski M, Dumnicka P, Kusnierz-Cabala B, Miarka P, Sulowicz W. Peritoneal solute transport rate as an independent risk factor for total and cardiovascular mortality in a population of peritoneal dialysis patients. Adv Perit Dial 2014; 30: 15–20.
⁵
Twardowski ZJ, Nolph KD, Khanna R, Prowant BF, Ryan LR, Moore HL, et al. Peritoneal equilibration test. Perit Dial Bull 1987; 7: 138–148.
⁶
Smit W, Langedijk MJ, Schouten N, van den Berg N, Struijk DG, Krediet RT. A comparison between 1.36% and 3.86% glucose dialysis solution for the assessment of peritoneal membrane function. Perit Dial Int 2000; 20: 734–741.
⁷
La Milia V, Di Filippo S, Crepaldi M, Del Vecchio L, Dell'Oro C, Andrulli S, et al. Mini-peritoneal equilibration test: a simple and fast method to assess free water and small solute transport across the peritoneal membrane. Kidney Int 2005; 68: 840–846, doi: 10.1111/j.1523-1755.2005.00465.x.
» https://doi.org/10.1111/j.1523-1755.2005.00465.x
⁸
Waniewski J. Peritoneal fluid transport: mechanisms, pathways, methods of assessment. Arch Med Res 2013; 44: 576–583, doi: 10.1016/j.arcmed.2013.10.010.
» https://doi.org/10.1016/j.arcmed.2013.10.010
⁹
Tam P, Sheldrake P, Ng A, Oreopoulos DG, Sloand JA. Peritoneal equilibration testing: correcting the correction factor. Perit Dial Int 2009; 29: 352–355.
¹⁰
La Milia V. Peritoneal transport testing. J Nephrol 2010; 23: 633–647.
¹¹
Pride ET, Gustafson J, Graham A, Spainhour L, Mauck V, Brown P, et al. Comparison of a 2.5% and a 4.25% dextrose peritoneal equilibration test. Perit Dial Int 2002; 22: 365–370.
¹²
La Milia V, Pozzoni P, Virga G, Crepaldi M, Del Vecchio L, Andrulli S, et al. Peritoneal transport assessment by peritoneal equilibration test with 3.86% glucose: a long-term prospective evaluation. Kidney Int 2006; 69: 927–933, doi: 10.1038/sj.ki.5000183.
» https://doi.org/10.1038/sj.ki.5000183
¹³
Cano F, Rojo A, Azocar M, Ibacache MJ, Delucchi A, Ugarte F, et al. The mini-PET in pediatric peritoneal dialysis: a useful tool to predict volume overload? Pediatr Nephrol 2013; 28: 1121–1126, doi: 10.1007/s00467-013-2447-2.
» https://doi.org/10.1007/s00467-013-2447-2
¹⁴
Warady BA, Jennings J. The short PET in pediatrics. Perit Dial Int 2007; 27: 441–445.
¹⁵
Twardowski ZJ, Prowant BF, Moore HL, Lou LC, White E, Farris K. Short peritoneal equilibration test: impact of preceding dwell time. Adv Perit Dial 2003; 19: 53–58.
¹⁶
Cuevas M, Zambrano P, Dinamarca H, Gilbert M, Cano F. Short PET in pediatric peritoneal dialysis. Pediatr Nephrol 2008; 23: 1853–1858, doi: 10.1007/s00467-008-0892-0.
» https://doi.org/10.1007/s00467-008-0892-0
¹⁷
Baştuğ F, Dursun I, Dursun J, Gündüz Z, Günay D, Yel S, et al. Could mini-PET be used to instead of 4 h original-PET to assess peritoneal permeability in children on peritoneal dialysis? Ren Fail 2014; 36: 562–566, doi: 10.3109/0886022X.2013.879368.
» https://doi.org/10.3109/0886022X.2013.879368
¹⁸
Kazancioğlu R, Topcuoglu D, Kiricimli N, Cinkilic A, Celik H. Comparison of fast peritoneal equilibrium test with the standard method: a pilot study. J Ren Care 2012; 38: 29–33, doi: 10.1111/j.1755-6686.2011.00241.x.
» https://doi.org/10.1111/j.1755-6686.2011.00241.x
¹⁹
Cano F, Sanchez L, Rebori A, Quiroz L, Delucchi A, Delgado I, et al. The short peritoneal equilibration test in pediatric peritoneal dialysis. Pediatr Nephrol 2010; 25: 2159–2164, doi: 10.1007/s00467-010-1566-2.
» https://doi.org/10.1007/s00467-010-1566-2
²⁰
Yuvaraj A, Koshy PJ, Rohit A, Nagarajan P, Nair S, Revathi L, et al. Diagnostic dilemma of ultrafiltration failure in a continuous ambulatory peritoneal dialysis patient. Perit Dial Int 2015; 35: 233–234, doi: 10.3747/pdi.2014.00086.
» https://doi.org/10.3747/pdi.2014.00086
²¹
Rippe B. How to measure ultrafiltration failure: 2.27% or 3.86% glucose? Perit Dial Int 1997; 17: 125–128.
²²
Shetty A, Oreopoulos DG. Ultrafiltration failure in CAPD. J Postgrad Med 1994; 40: 185–193.
²³
Selgas R, Bajo MA, Castro MJ, Sanchez-Tomero JA, Cirugeda A. Managing ultrafiltration failure by peritoneal resting. Perit Dial Int 2000; 20: 595–597.
²⁴
Ho-dac-Pannekeet MM, Atasever B, Struijk DG, Krediet RT. Analysis of ultrafiltration failure in peritoneal dialysis patients by means of standard peritoneal permeability analysis. Perit Dial Int 1997; 17: 144–150.

Publication Dates

Publication in this collection
05 Aug 2019
Date of issue
2019

History

Received
21 Feb 2019
Accepted
31 May 2019

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Oreopoulos DG. Peritoneal dialysis in the past 20 years: an exciting journey. Perit Dial Int 1999; 19 (Suppl 3): S6–S8.

[2] ²
Chavez Valencia V, Orizaga de la Cruz C, Pazarin Villasenor HL, Fuentes Ramirez F, Parra Michel R, Aragaki Y, et al. Frequency of peritoneal transport in a population of the Hospital General Regional No. 46, Instituto Mexicano del Seguro Social. Gaceta Medica de Mexico 2014; 150: 186–193.

[3] ³
Rajakaruna G, Caplin B, Davenport A. Peritoneal protein clearance rather than faster transport status determines outcomes in peritoneal dialysis patients. Perit Dial Int 2015; 35: 216–221, doi: 10.3747/pdi.2013.00217.
» https://doi.org/10.3747/pdi.2013.00217

[4] ⁴
Janda K, Krzanowski M, Dumnicka P, Kusnierz-Cabala B, Miarka P, Sulowicz W. Peritoneal solute transport rate as an independent risk factor for total and cardiovascular mortality in a population of peritoneal dialysis patients. Adv Perit Dial 2014; 30: 15–20.

[5] ⁵
Twardowski ZJ, Nolph KD, Khanna R, Prowant BF, Ryan LR, Moore HL, et al. Peritoneal equilibration test. Perit Dial Bull 1987; 7: 138–148.

[6] ⁶
Smit W, Langedijk MJ, Schouten N, van den Berg N, Struijk DG, Krediet RT. A comparison between 1.36% and 3.86% glucose dialysis solution for the assessment of peritoneal membrane function. Perit Dial Int 2000; 20: 734–741.

[7] ⁷
La Milia V, Di Filippo S, Crepaldi M, Del Vecchio L, Dell'Oro C, Andrulli S, et al. Mini-peritoneal equilibration test: a simple and fast method to assess free water and small solute transport across the peritoneal membrane. Kidney Int 2005; 68: 840–846, doi: 10.1111/j.1523-1755.2005.00465.x.
» https://doi.org/10.1111/j.1523-1755.2005.00465.x

[8] ⁸
Waniewski J. Peritoneal fluid transport: mechanisms, pathways, methods of assessment. Arch Med Res 2013; 44: 576–583, doi: 10.1016/j.arcmed.2013.10.010.
» https://doi.org/10.1016/j.arcmed.2013.10.010

[9] ⁹
Tam P, Sheldrake P, Ng A, Oreopoulos DG, Sloand JA. Peritoneal equilibration testing: correcting the correction factor. Perit Dial Int 2009; 29: 352–355.

[10] ¹⁰
La Milia V. Peritoneal transport testing. J Nephrol 2010; 23: 633–647.

[11] ¹¹
Pride ET, Gustafson J, Graham A, Spainhour L, Mauck V, Brown P, et al. Comparison of a 2.5% and a 4.25% dextrose peritoneal equilibration test. Perit Dial Int 2002; 22: 365–370.

[12] ¹²
La Milia V, Pozzoni P, Virga G, Crepaldi M, Del Vecchio L, Andrulli S, et al. Peritoneal transport assessment by peritoneal equilibration test with 3.86% glucose: a long-term prospective evaluation. Kidney Int 2006; 69: 927–933, doi: 10.1038/sj.ki.5000183.
» https://doi.org/10.1038/sj.ki.5000183

[13] ¹³
Cano F, Rojo A, Azocar M, Ibacache MJ, Delucchi A, Ugarte F, et al. The mini-PET in pediatric peritoneal dialysis: a useful tool to predict volume overload? Pediatr Nephrol 2013; 28: 1121–1126, doi: 10.1007/s00467-013-2447-2.
» https://doi.org/10.1007/s00467-013-2447-2

[14] ¹⁴
Warady BA, Jennings J. The short PET in pediatrics. Perit Dial Int 2007; 27: 441–445.

[15] ¹⁵
Twardowski ZJ, Prowant BF, Moore HL, Lou LC, White E, Farris K. Short peritoneal equilibration test: impact of preceding dwell time. Adv Perit Dial 2003; 19: 53–58.

[16] ¹⁶
Cuevas M, Zambrano P, Dinamarca H, Gilbert M, Cano F. Short PET in pediatric peritoneal dialysis. Pediatr Nephrol 2008; 23: 1853–1858, doi: 10.1007/s00467-008-0892-0.
» https://doi.org/10.1007/s00467-008-0892-0

[17] ¹⁷
Baştuğ F, Dursun I, Dursun J, Gündüz Z, Günay D, Yel S, et al. Could mini-PET be used to instead of 4 h original-PET to assess peritoneal permeability in children on peritoneal dialysis? Ren Fail 2014; 36: 562–566, doi: 10.3109/0886022X.2013.879368.
» https://doi.org/10.3109/0886022X.2013.879368

[18] ¹⁸
Kazancioğlu R, Topcuoglu D, Kiricimli N, Cinkilic A, Celik H. Comparison of fast peritoneal equilibrium test with the standard method: a pilot study. J Ren Care 2012; 38: 29–33, doi: 10.1111/j.1755-6686.2011.00241.x.
» https://doi.org/10.1111/j.1755-6686.2011.00241.x

[19] ¹⁹
Cano F, Sanchez L, Rebori A, Quiroz L, Delucchi A, Delgado I, et al. The short peritoneal equilibration test in pediatric peritoneal dialysis. Pediatr Nephrol 2010; 25: 2159–2164, doi: 10.1007/s00467-010-1566-2.
» https://doi.org/10.1007/s00467-010-1566-2

[20] ²⁰
Yuvaraj A, Koshy PJ, Rohit A, Nagarajan P, Nair S, Revathi L, et al. Diagnostic dilemma of ultrafiltration failure in a continuous ambulatory peritoneal dialysis patient. Perit Dial Int 2015; 35: 233–234, doi: 10.3747/pdi.2014.00086.
» https://doi.org/10.3747/pdi.2014.00086

[21] ²¹
Rippe B. How to measure ultrafiltration failure: 2.27% or 3.86% glucose? Perit Dial Int 1997; 17: 125–128.

[22] ²²
Shetty A, Oreopoulos DG. Ultrafiltration failure in CAPD. J Postgrad Med 1994; 40: 185–193.

[23] ²³
Selgas R, Bajo MA, Castro MJ, Sanchez-Tomero JA, Cirugeda A. Managing ultrafiltration failure by peritoneal resting. Perit Dial Int 2000; 20: 595–597.

[24] ²⁴
Ho-dac-Pannekeet MM, Atasever B, Struijk DG, Krediet RT. Analysis of ultrafiltration failure in peritoneal dialysis patients by means of standard peritoneal permeability analysis. Perit Dial Int 1997; 17: 144–150.

Gender (M), n (%)	15 (71)
Age (years)	52±15
Time on PD (months)	18±14
Underlying disease	SAH: 6; Glomerulopathy: 10; Other: 5
Smoking (%)	14
Dyslipidemia (%)	28
BMI (kg/m²)	23.4±3.05
Hemoglobin (g/dL)	12.2±1.9
Serum calcium (mg/dL)	9.02±0.59
Phosphorous (mg/dL)	4.53±1.73
iPTH (ng/mL)	357±276
Urea (mg/dL)	113±29
Serum albumin (g/dL)	3.8±0.69

Brasil