Kidney Clearance of Secretory Solutes Is Associated with Progression of CKD: The CRIC Study

Data Source and Participants

We performed an ancillary study to the Chronic Renal Insufficiency Cohort (CRIC) study, a prospective study of CKD progression and cardiovascular disease among patients with CKD.^8,9 From 2003 to 2008, the CRIC study originally enrolled 3939 patients with an eGFR of between 20 and 70 ml/min per 1.73 m² for ages 21–44 years, 20 and 60 ml/min per 1.73 m² for ages 45–64 years, and 20 and 50 ml/min per 1.73 m² for ages 65–74 years. Major exclusion criteria included kidney transplantation, active immunosuppression, polycystic kidney disease, multiple myeloma, pregnancy, HIV infection, cirrhosis, and severe heart failure. Study participants completed annual in-person follow-up visits and were contacted by telephone at 6-month intervals.

For the purposes of this ancillary study, we excluded 515 participants who did not have 24-hour urine or plasma samples available from the baseline CRIC study visit and eight participants who had a baseline eGFR of <15 ml/min per 1.73 m² based on the CRIC study equation. For analyses of CKD progression, we further excluded 209 participants who lacked follow-up data for this outcome (Supplemental Figure 1). The CRIC protocol was approved by institutional review boards at all participating institutions. All participants provided written informed consent.

Measurements of Kidney Clearances of Suspected Secretory Solutes

Through literature review, we selected candidate secretory solutes based on one or more of the following characteristics: reported specificity for organic anion transporters (OAT1 and OAT3), an increase in circulating concentrations after OAT3-transporter knockout in experimental models, a high reported protein-binding percentage, and/or kidney clearances that substantially exceed GFR or creatinine clearance.^10–12 We then developed a targeted liquid chromatography–tandem mass spectrometry (LC-MS/MS) assay for these solutes in plasma and urine.¹³ We determined protein-binding characteristics for each solute in patients with CKD using centrifugal ultrafiltration (Table 1). These studies revealed lower protein-binding percentages than previously reported for three solutes (isovalerylglycine, tiglylglycine, and xanthosine). However, we retained these solutes in our analyses because their kidney clearances greatly exceeded eGFR, suggesting tubular secretion as the major kidney pathway of elimination.

We measured total plasma concentrations of secretory solutes at the CRIC baseline visit using protein precipitation, solid phase extraction, and LC-MS/MS, and we measured 24-hour urine concentrations at the baseline visit using solid phase extraction and LC-MS/MS. Calibration was achieved using a single-point calibration approach to account for potential drift that may be caused by changes in reagents, calibrator lots, equipment, or settings. First, the peak areas of each solute were normalized to peak areas of labeled internal standards added to each well. Next, peak area ratios were standardized to the single-point calibrators (set of five replicates on each study plate). Laboratory coefficients of variation were generally low (Supplemental Table 1). We have previously determined accurate concentrations of each secretory solute in the single-point calibrators (pooled human serum and urine) by standard addition of solutions of pure compounds analyzed by quantitative nuclear magnetic resonance.

We calculated the clearance of each solute as:where U_X represents the 24-hour urine concentration of solute X, V represents the 24-hour urine volume, and P_X represents the plasma concentration. We focused on the kidney clearances of suspected secretory solutes, rather than plasma levels alone, to avoid the potential influence of nonkidney-related factors on circulating levels.

Measurement of Outcomes

Study outcomes were CKD progression and all-cause mortality. The CRIC study defined CKD progression by a 50% decline in eGFR from baseline, the initiation of chronic dialysis, or kidney transplantation, whichever occurred first. We also evaluated the slope of GFR decline during follow-up as a secondary outcome. GFR was estimated at each CRIC study visit based on concentrations of serum creatinine and cystatin C, age, sex, and black race using an equation that was developed in a subcohort of 1433 CRIC participants who underwent ^125-iothalamate GFR (iGFR) clearance studies.¹⁴ Serum-creatinine concentrations were measured using an enzyme-based assay on the Hitachi Vitros 950 AT with values traceable to isotope dilution mass spectrometry. Serum cystatin-C concentrations were measured using a Siemens BNII instrument and longitudinal control materials were used to correct for drift over time when using different calibrator and reagent lots.¹⁵ Ascertainment of dialysis and transplantation status in the CRIC study was based on self-report during biannual surveillance and supplemented by crosslinkage with the United States Renal Data System. Mortality was ascertained from reports of next of kin, death certificates, hospital records, and linkage with the Social Security Death Master File.¹⁶ To address the potential issue of competing risk, we also evaluated a composite end point of CKD progression or all-cause death.¹⁷

Measurements of Covariates

Trained study staff collected participants’ self-reported baseline information regarding sociodemographic characteristics, medical histories, and current medications.^8,9 Serum albumin, phosphorus, and glucose were measured on the Hitachi Vitros 950 AT. iGFR was measured in a subset of 1433 participants at baseline using a standardized protocol after a low protein (<10 g) meal. Urinary albumin was measured on a Siemens Immulite.¹⁴ Resting seated BP was measured three times, and the average of the second and third readings recorded. Diabetes was defined by a fasting glucose concentration ≥126 mg/dl (7.0 mmol/L), a nonfasting glucose ≥200 mg/dl (11.1 mmol/L), or the use of antidiabetic medications. The cause of CKD was self-reported at baseline.

Statistical Analyses

We created a summary measure of the clearances of secretory solutes to facilitate the tabular presentation of participant characteristics and to provide a singular metric for summarizing associations with study outcomes. Because the kidney clearances of each solute inherently reside on different scales, we log transformed the individual clearances and then standardized them to a common 0–100 scale:where ln(clearance) represents the natural log-transformed clearance value, min(ln[clearance]) represents the minimum value of ln-clearance in the distribution, and range(ln[clearance]) represents the difference between the maximum and minimum values. We then computed the summary score as the average of the 11 standardized clearances (Supplemental Figure 2). This computed summary score is specific to the CRIC study population and may obscure potential contrasts among the individual solutes. To identify potential characteristics associated with the summary secretion score independent of eGFR, we regressed this score on each baseline characteristic adjusting for eGFR only, or for eGFR plus age, sex, race, and body mass index (BMI).

We used Cox proportional hazards regression to estimate associations of kidney clearances of suspected secretory solutes at baseline with study outcomes. Primary models of CKD progression were censored for mortality; secondary models considered a composite outcome of CKD progression or death. The exact time of halving of eGFR was interpolated assuming a linear decline between study visits.¹⁸ We constructed nested models to evaluate potential confounding characteristics. Model 1 adjusted for age, race, sex, baseline eGFR, and log-transformed 24-hour urinary albumin excretion. Model 2 additionally adjusted for clinical site, BMI, history of diabetes, smoking status, systolic BP, history of cardiovascular disease, and use of angiotensin-converting enzyme inhibitors or angiotensin receptor blockers. We determined that 1206 events of CKD progression in a total analytic sample size of 3207 participants would provide at least 90% power to detect a hazard ratio of 1.13 per 10-units-lower summary secretion score (SD=7.6) at a two-sided α level of 0.05. Given correlations among the clearances of secretory solutes, we did not mutually adjust for multiple clearances in the same model. We investigated the possibility that baseline levels of eGFR or albuminuria could modify associations between clearances of secretory solutes and rates of study outcomes using stratified Poisson regression.

For GFR slope analyses, we used linear mixed-effects models with both random intercepts and random slopes to assess the association between kidney clearances of secretory solute at baseline and the change in eGFR, adjusting for the same covariates as in the above survival analysis. Natural log-transformed values of eGFR at each study visit served as the dependent variable and differences in slope were assessed by a time-by-exposure interaction. The results of these models can be interpreted as the difference in annualized decline of eGFR per 50% lower in the kidney clearance of each secretory solute.

In sensitivity analyses, we added adjustment for medications that could potentially influence the clearances of secretory solutes through interactions with basolateral transporters. To address the possibility of residual confounding by GFR, we repeated our analyses among the subsample of participants who completed iGFR measurements at baseline with additional adjustment for iGFR. To test generalizability, we repeated our analyses using GFR estimated by the CKD Epidemiology Collaboration equation, a more widely used equation, to define CKD progression.¹⁹ We used the Hommel method to correct for multiple comparisons.²⁰ A two-sided P value of 0.05 after correction was used to declare statistical significance. Because covariates were missing in <1% of participants, we used complete-case analysis. We used scaled Schoenfeld residuals to test the proportional hazards assumption in Cox models. No evidence of violation of the proportional hazard assumption was detected. We estimated changes in the regression coefficients upon deleting each observation in turn to check the possibility of influential observations. Analyses were performed using Stata/IC 14.2 (Stata Statistical Software: release 14; StataCorp, College Station, TX) and RStudio 3.4.3 (R Core Team, Vienna, Austria).