Canagliflozin Slows Progression of Renal Function Decline Independently of Glycemic Effects

Study Design and Participants

The study design has been published previously.³ In short, this randomized, double-blind, active-controlled trial was conducted in 157 research centers in 19 countries. The study consisted of a 2-week, single-blind, placebo run-in period; a 52-week, double-blind, core treatment period; and a 52-week, prespecified, double-blind, extension treatment period during which patients continued their originally assigned treatment. The 52-week, double-blind, extension period was prespecified to provide a more complete characterization of the efficacy and safety of canagliflozin over 104 weeks of treatment. The prespecified primary efficacy end point was the change in HbA1c from baseline to week 52. The sample size calculation assumed that 277 patients per group would be needed to provide approximately 90% power to show noninferiority of canagliflozin compared with glimepiride for the lowering of HbA1c, with an assumed between-group difference of 0.0% and an SD of 1.0. The primary efficacy results showed that canagliflozin 100 mg was noninferior to glimepiride in reducing HbA1c whereas canagliflozin 300 mg was superior to glimepiride.³ Eligible patients were between 18 and 80 years of age and had type 2 diabetes with an HbA1c between 7.0% and 9.5% while receiving metformin ≥2000 mg/d (or ≥1500 mg/d if higher doses were not tolerated). Patients with an eGFR of <55 ml/min per 1.73 m² (or <60 ml/min per 1.73 m² if based on restriction of metformin use in the local label) or serum creatinine concentrations ≥124 μmol/L for men and ≥115 μmol/L for women were excluded. No inclusion or exclusion criteria were specified for albuminuria. Glimepiride was uptitrated if patients met protocol-specified glycemic criteria after ≥2 weeks at the current dose, and uptitration could occur at any time during the study; patients receiving canagliflozin were mock uptitrated. Glycemic rescue therapy was initiated with pioglitazone (where approved) for patients who were at the maximum level of study drug titration and met prespecified glycemic criteria.

The trial was conducted in accordance with the Declaration of Helsinki and good clinical practice guidelines. Ethics committees and institutional review boards approved the research protocol. All patients provided written informed consent before entering the trial. The study was registered with ClinicalTrials.gov (identifier: NCT00968812).

Randomization and Masking

During the run-in period, all patients received single-blind placebo capsules matching the study drug once daily. After the run-in period, patients were stratified according to whether they were taking a stable, protocol-defined dose of metformin before screening versus whether they had undergone dose adjustments in their metformin dose during the run-in period or had discontinued use of a second glucose-lowering drug. Patients were randomly assigned to receive oral, once-daily glimepiride (uptitrated to 6 or 8 mg/d based on the maximum approved dose in the country of the investigational site), canagliflozin 100 mg/d, or canagliflozin 300 mg/d at a 1:1:1 ratio by a computer-generated schedule prepared by the sponsor. Patients and all study personnel (except the safety monitoring committee) were masked to treatment allocation. To allow for masked increases or decreases in the glimepiride dose throughout the double-blind treatment, study drugs were supplied in five levels (levels 1–5).

Procedures

After randomization, patients collected first morning void urine at baseline and weeks 12, 26, 52, 78, and 104 for assessment of U_ACR. Urine albumin was measured by a nephelometric assay and creatinine was measured by a rate-blanked colorimetric assay in a central laboratory (Covance [Indianapolis, IN; Meyrin-Geneva, Switzerland; Singapore]). Serum creatinine and HbA1c were measured at baseline and weeks 4, 12, 18 (HbA1c only), 26, 36, 44, 52, 64, 78, 88, and 104. Serum creatinine was used to calculate eGFR with the Modification of Diet in Renal Disease equation: eGFR = 175×(serum creatinine [mg/dl])^−1.154×(age [years])^−0.203×(0.742 if female)×(1.212 if black).²¹

Safety was monitored throughout the study by assessing adverse events, laboratory data, vital sign measurements, physical examinations, self-monitoring of blood glucose, and 12-lead electrocardiograms. Reported adverse events were recorded during the trial and analyzed with a standard coding dictionary (Medical Dictionary for Regulatory Activities) to classify adverse event terms. Serious adverse events were defined as any adverse event that resulted in death, was immediately life-threatening, required hospital admission or prolonged existing hospitalization, resulted in persistent or significant disability or incapacity, was a birth defect, or was an event that jeopardized the patient’s health or required intervention.

Outcomes

The main efficacy end point for this post hoc analysis was the yearly rate of eGFR decline over the 104 weeks of follow-up. Exploratory efficacy end points were the least squares mean change from baseline in eGFR and U_ACR to week 104. The effects on eGFR and U_ACR were assessed by comparing mean levels across the treatment period and by assessing the number of individuals who developed a 30% or 40% reduction in eGFR during the study period, as recommended in a recent National Kidney Foundation–sponsored workshop.²² The effect of the interventions on these end points was assessed in the overall population and in a subgroup that was defined by baseline U_ACR≥30 mg/g (n=230). Since all patients had a baseline eGFR >55 ml/min per 1.73 m², eGFR subgroups were not examined.

Statistical Analyses

Differences in eGFR and U_ACR between randomized groups during follow-up were estimated from repeated measures analysis. Differences between randomized groups in eGFR decline during follow-up were estimated from a mixed-effects model for repeated measures (MMRM). The model included treatment, visit (expressed in time in years since randomization), and treatment-by-visit interaction as factors. The latter was used to estimate the overall between-group difference in eGFR over the course of the study. The MMRM model was also used to calculate the least squares mean change from baseline in eGFR and U_ACR over time. For these analyses, baseline eGFR and U_ACR were entered as covariates in the model. U_ACR was log-transformed before entering in the MMRM analysis to alleviate the skewness of the data. To allow generality for the covariance structure for repeated measures, the variance-covariance matrix was assumed to be unstructured (i.e., purely data-dependent). In the MMRM model, all patients and all data points were included. No patients were excluded due to missing data and no imputation was carried out for missing data.

The effects of randomized treatment on the 30% or 40% eGFR decline end points were estimated from Cox proportional hazard models. Cox proportional hazard models were conducted on the basis of the intention to treat principle. For patients who experienced more than one event during follow-up, survival time to the first 30% or 40% eGFR decline end point was used in each analysis. Patients were censored at their date of death or, for those still alive at the end of follow-up, the date of their last clinic visit before the termination of this study arm. Patients with unknown vital status were censored when they were last known to be alive. A P value <0.05 (two-sided) was considered to indicate a statistically significant difference. Analyses were performed using SAS 9.2 for Windows (SAS Institute, Cary, NC).