The Effects of n-3 Long-Chain Polyunsaturated Fatty Acid Supplementation on Biomarkers of Kidney Injury in Adults With Diabetes

CONCLUSIONS

In this randomized, controlled clinical trial, daily supplementation with n-3 PUFA had nonsignificant effects on urine albumin excretion (−7.2%; 95% CI −20.6 to 8.5; P = 0.35) and significant effects on urine NGAL excretion (−16% [−29.1 to −0.5%]; P = 0.04) in adults with diabetes and proteinuria. In contrast, n-3 PUFA supplements increased fasting glucose by 6.5 mg/dL. In the subgroup of participants taking stable doses of RAAS inhibitors, n-3 PUFA supplementation significantly reduced multiple markers of kidney injury including NGAL (−27%), LFABP (−37%), NAG (−30%), and albuminuria (−17%).

The effects of n-3 PUFA supplements on urine protein excretion have been tested in trials of primarily nondiabetic participants with diverse underlying causes of CKD. In a meta-analysis of 17 trials, we reported a 19% reduction (95% CI −34 to −4; P = 0.01) in urine protein excretion with n-3 PUFA across all trials (20). A similar magnitude of effect was noted in the subgroup of trials (n = 7) that enrolled participants with diabetic kidney disease (−21% [−46 to 4]; P = 0.10).

We can only speculate on mechanisms that may account for the beneficial effects of n-3 PUFA supplementation on kidney-injury processes. Effects on vascular function and renal hemodynamics are possible (4,21). A systematic review of fish oil supplements in hypertensive patients (five trials) reported that an average of 3 g/day of n-3 PUFA reduced SBP/DBP by 5.5/3.5 mmHg (22). Our trial demonstrated a similar reduction in SBP, which could explain reductions in proteinuria and other markers of kidney injury via hemodynamic effects. However, in spite of small differences in BP between the n-3 PUFA and placebo periods, we did not detect an effect of n-3 PUFA supplementation on β₂-microglobulin, cystatin C, or creatinine-based eGFR. These results suggest that n-3 PUFA effects on kidney injury markers are likely independent of hemodynamic effects that effect GFR.

n-3 PUFA supplementation may also alter the balance of n-3 and n-6 fatty acids available for prostaglandin production, causing a favorable shift toward production of prostaglandins with more vasodilator effects, enhanced immune function, and reduced inflammation (16,23), mechanisms that may contribute to CKD progression in diabetic kidney disease. n-3 PUFA supplementation may also decrease renal ischemic effects through rheostatic changes on erythrocyte membranes. Stirban et al. (21) noted improved postprandial microvascular reactive hyperemia after ischemia in adults with non–insulin-dependent diabetes with 2 g/day of n-3 PUFA. This mechanism was believed to be largely independent of nitric oxide–mediated regulations of vascular tone and more related to the influence of n-3 PUFA on prostaglandin pathways.

In our trial, n-3 PUFA had nonsignificant effects on urine albumin excretion (−7.2%; 95% CI −20.6 to 8.5; P = 0.35). The nonsignificant overall effects of n-3 PUFA supplementation on the primary outcome variable of urine albumin excretion suggest a lack of benefit or reflect a trial is underpowered. Nonetheless, in subgroup analyses, n-3 PUFA significantly reduced urine albumin excretion only in participants on RAAS-inhibition therapy, representing 70% of participants in this trial. Indeed, the use of RAAS-inhibition therapy would be considered a standard of care for patients with diabetes and evidence of kidney disease (2). A priori, one would expect that RAAS inhibitors would have had considerable antiproteinuric effects, limiting the ability to detect the effects of additional agents. In our trial, the opposite occurred. For the most part, previous trials did not report whether the antiproteinuric effects of n-3 PUFA were affected by the concurrent use of RAAS inhibition, but similar results were reported in a trial of patients with immunoglobulin A nephropathy treated with RAAS. In this trial, enhanced antiproteinuric effects were noted with the addition of 3 g/day of n-3 PUFA compared with RAAS treatment alone (24). Possible causes of additional antiproteinuric effects may include anti-inflammatory effects, reduced blood viscosity, and increased erythrocyte flexibility leading to reduced renal tubular ischemia (5,25). The potential interaction between RAAS inhibitors and n-3 PUFA may have important clinical implications and needs to be further investigated as a potential renoprotective combination in patients with diabetes and proteinuria.

Our trial has several strengths. First, the crossover design and relatively short-term intervention periods allowed for assessments of the acute effects on urine albumin excretion and eGFR in the setting of stable doses of medications that may affect urine protein excretion. Second, we enrolled diabetic participants with proteinuria, a common complication and early sign of CKD in patients with diabetes. Third, the diabetes, hyperlipidemia (if present), and hypertension were treated. Hence, supplementation with n-3 PUFA may have added benefit to conventional therapies in those with diabetes and early CKD. Fourth, the high rates of adherence and follow-up, the use of 24-h urine sample collections, and the use of high-quality laboratory methods enhance the internal validity of the trial. Fifth, novel markers of kidney injury are not susceptible to hemodynamic changes that may alter urine albumin excretion.

There are also several limitations. We used a short-term crossover trial design, selected to enhance power to detect differences. Although no carryover effects were detected in the analyses of outcome variables, we detected a carryover effect of the intervention on EPA levels in erythrocytes. Erythrocyte EPA levels did not return to baseline at the end of the study in the group first assigned to n-3 PUFA despite a 2-week washout period and a 6-week period on placebo. We note that this type of carryover effect will tend to mask the effects of n-3 PUFA in the crossover analysis. Hence, future short-term trials of n-3 PUFA would benefit from a longer washout period or a parallel-arm design. Another limitation pertains to our reporting a large number of secondary outcomes and subgroup analyses stratified by baseline medication use. With this approach, one must be cautious in interpreting statistical significance due to multiple comparisons and the risk of type 1 errors. For example, although we report significant reductions in urine excretion of albumin, NAG, NGAL, and LFABP in those participants on RAAS therapy at baseline, there was evidence of increased urine excretion of NAG in those not taking RAAS therapy. This finding can either reflect the truth or, because of type 1 error associated with post hoc subgroup analyses, may be inappropriate. However, we feel that subgroup reporting from this small trial is both informative and clinically relevant and may be helpful in the design of future trials of n-3 PUFA on kidney injury.

Each intervention capsule was a highly concentrated source of DHA/EPA derived from marine fish oils, and the dose was 4.0 g/day. This high dose of n-3 PUFA is far above the daily average intake of U.S. adults (0.15 g/day) (26) and contributes minimally to total calorie intake (∼40 kcal/day). This dose has therapeutic efficacy for triglyceride reduction (∼25–40%) and is the dose currently sold by prescription for the treatment of hypertriglyceridemia. A lower dose of n-3 PUFA (1.0 g/day) has reduced cardiovascular events in some (27,28) but not all (29) clinical trials. In our prior meta-analysis of n-3 PUFA supplementation on urine protein excretion, the dose of n-3 PUFA did not modify the findings, but few trials used doses ≤1 g/day. Since 1 g/day is the currently recommended daily dose of EPA/DHA for adults with coronary heart disease (30), further research is also needed to evaluate the effects of n-3 PUFA across a wider range of doses. Within the Vitamin D and Omega-3 Trial, a National Institutes of Health–funded trial, 1,500 Vitamin D and Omega-3 Trial participants with diabetes, randomly assigned in a 2 × 2 factorial design to vitamin D3 (cholecalciferol) 1,600 IU daily versus placebo and to EPA 500 mg plus DHA 500 mg daily versus placebo, will be studied to ascertain effects of study interventions on albuminuria and GFR (31). Their trial is expected to finish in the year 2015.

Dose effects are also relevant to the observed adverse effects of n-3 PUFA supplements on fasting serum glucose. Increased fasting glucose with n-3 PUFA supplementation has been reported in many, but not all, trials. A recent Cochrane meta-analysis of 15 trials of fish oil supplementation on glucose homeostasis reported a nonsignificant pooled increase in fasting glucose of 2.9 mg/dL (95% CI −2.3 to 8.3 mg/dL), with no effects on HbA_1c (32). The mechanisms involved in increasing fasting glucose are unclear, but n-3 PUFA reduce hepatic synthesis of triglycerides and increase hepatic fatty acid β-oxidation, resulting in increased hepatic glucose output through increased glycogenolysis and/or gluconeogenesis (33). Nonetheless, whether a lower dose of n-3 PUFA is sufficient to lower kidney injury but below a threshold to cause hyperglycemic effects needs to be tested.

In conclusion, in this randomized, controlled clinical trial, n-3 PUFA failed to reduce the primary outcome of urine albumin excretion. However, there was a consistent trend of benefit for all urine biomarkers and a significant reduction in NGAL. Furthermore, our post hoc subgroup findings raise the intriguing possibility that the greatest effects of n-3 PUFA are in individuals on RAAS inhibitors. There were small reductions in SBP and DBP, an increase in fasting glucose, but no apparent effect on eGFR with n-3 PUFA supplementation. Our results in the context of prior studies provide a strong rationale for larger trials that are adequately powered for smaller effects on urine albumin excretion or trials that are conducted in participants who take ACE/ARB therapy. In long-term trials of n-3 PUFA with clinical outcomes such as CKD progression, which are underway, careful consideration should be given for the potential beneficial interactions between RAAS therapy and n-3 PUFA.