Characterisation of glomerular haemodynamic responses to SGLT2 inhibition in patients with type 1 diabetes and renal hyperfiltration

To the Editor: Renal hyperfiltration in experimental models of early diabetes is associated with increased intraglomerular pressure, and this condition may promote the development of diabetic nephropathy [1]. Despite the functional characterisation of renal hyperfiltration in animal models of diabetes indicating causal involvement of the afferent arteriole, confirmative data in humans are scarce. This is explained by the fact that direct measurements of human glomerular haemodynamic variables, such as afferent (R_A) and efferent (R_E) arteriolar resistances and glomerular hydrostatic pressure (P_GLO), are technically not feasible. To elucidate mechanisms of renal disease in humans, Gomez et al published formulae derived from animal physiological studies in 1951 to estimate glomerular haemodynamic function by using measured mean arterial blood pressure (MAP), GFR, renal plasma flow, haematocrit and total protein concentrations [2].

More recently, selective sodium–glucose co-transporter 2 (SGLT2) inhibitors have been evaluated in studies involving patients with type 2 and type 1 diabetes. In this context, we recently demonstrated, in a stratified, open-label, single-arm 8 week trial, that SGLT2 inhibition with empagliflozin attenuates renal hyperfiltration in patients with type 1 diabetes, an effect likely due to modulation of tubuloglomerular feedback via increased distal tubular sodium delivery [3]. The objective of this exploratory, post hoc analysis was to apply the Gomez formulae to quantify glomerular haemodynamic variables in patients with type 1 diabetes analysed on the basis of filtration status.

Type 1 diabetic patients were treated with empagliflozin (25 mg daily) in the Adjunctive-To-Insulin and Renal MechAnistic pilot trial of empagliflozin in T1D (ATIRMA trial, ClinicalTrials.gov NCT01392560) [3]. Forty participants completed this study and the primary outcome of changes in renal function with empagliflozin have been published elsewhere [3]. None of the participants was taking medications that could affect blood pressure or other cardiovascular parameters. Other secondary endpoints related to glycaemia and arterial stiffness have also been reported [4, 5]. Studies were performed during two consecutive days at baseline and 8 weeks after empagliflozin treatment. A modified glucose clamp technique was used to maintain euglycaemic (approximately 4–6 mmol/l) conditions on the first day for approximately 6 h, followed by hyperglycaemic (approximately 9–11 mmol/l) conditions on the second day for approximately 6 h (electronic supplementary material [ESM] Fig. 1) [3]. All data are expressed as mean ± SD. For further details of the experimental design and statistical analysis, please see the ESM Methods. The study was approved by the Research Ethics Board at the University Health Network. All participants gave informed consent prior to the start of the study procedures.

Baseline characteristics, and serum and urine biochemical responses to empagliflozin in this cohort, have been reported elsewhere [3]. To assess renal sodium handling further, 24 h fractional excretion of sodium (FENa⁺) was calculated. FENa⁺ increased in type 1 diabetic patients with renal hyperfiltration (T1D-H; 0.54 ± 0.29 to 0.77 ± 0.48, p = 0.03) but not in type 1 diabetic patients with renal normofiltration (T1D-N; 0.63 ± 0.46 to 0.74 ± 0.61, p = 0.61). Using Gomez’s formulae at baseline during clamped euglycaemia, T1D-H patients exhibited lower R_A, and increased P_GLO and ΔP_F (filtration pressure across the glomerular capillaries) than that of T1D-N patients (Fig. 1a–d, ESM Table 1; ESM Methods). There were no differences in R_E or glomerular oncotic pressure (π_G) between the two groups. In response to empagliflozin, R_A increased in T1D-H patients (euglycaemia: 785 ± 442 vs 1,307 ± 615 dyn s cm⁻⁵, p < 0.0001; hyperglycaemia: 690 ± 637 vs 1,454 ± 814 dyn s cm⁻⁵, p < 0.0001; Fig. 1a). Furthermore, intraglomerular pressure (P_GLO, Fig. 1c) decreased in response to empagliflozin in T1D-H patients during clamped euglycaemia (67.4 ± 5.4 vs 61.0 ± 5.2 mmHg, p < 0.0001) and hyperglycaemia (69.3 ± 6.5 vs 61.6 ± 6.3 mmHg, p < 0.0001). ΔP_F (Fig. 1d) also decreased in response to empagliflozin in the T1D-H group during euglycaemia (33.1 ± 4.5 vs 26.7 ± 4.8 mmHg, p < 0.0001) and hyperglycaemia (35.8 ± 6.4 vs 27.5 ± 5.7 mmHg, p < 0.0001). In contrast, these variables remained unchanged in the T1D-N group (Fig. 1). There were no significant differences in R_E in either group (Fig. 1b).

Fig. 1

Glomerular haemodynamics estimated by Gomez’s equations (K_FG = 0.0867) in participants with normofiltration (T1D-N) or hyperfiltration (T1D-H) at baseline (BL) and after empagliflozin (EMPA, 25 mg daily) treatment during clamped euglycaemic (black circles) and hyperglycaemic (open circles) conditions. *p < 0.05 and ***p < 0.001 for within-group differences using a paired Student’s t test. ^††† p < 0.001 for between-group differences (T1D-N [n = 13] vs T1D-H [n = 27]) using Tukey’s post hoc test after ANOVA analysis. Horizontal lines represent means of haemodynamic variables

Owing to higher GFR values in T1D-H patients (mean GFR 172 ± 23 ml min⁻¹ [1.73 m²]⁻¹) compared with the cohort used to derive the ultrafiltration coefficient (K_FG) in previous literature (mean GFR < 130 ml min⁻¹ [1.73 m²]⁻¹), we estimated a K_FG of 0.115 for T1D-H and repeated the Gomez formulae. Using this adjusted K_FG, similar results were obtained (ESM Fig. 2). To assess the appropriateness of the serum albumin concentration to be used, instead of total protein to calculate R_A and P_GLO variables, albumin concentration was multiplied by a calculated conversation factor of 1.695. Haemodynamic variables were strongly correlated (r = 0.91 to 0.99, p < 0.0001) using either serum albumin or total protein (ESM Fig. 3).

Our first main observation was that in a cohort of normotensive, normoalbuminuric patients, T1D-H participants exhibited evidence of afferent vasodilation characterised by lower R_A compared with T1D-N participants. This is consistent with previous animal models of diabetes demonstrating a dominant state of afferent vasodilatation relative to effects at the efferent arteriole [6]. Our second main observation was that treatment with empagliflozin for 8 weeks decreased R_A and also reduced P_GLO in T1D-H patients, with no effect on R_E. On the basis of these haemodynamic responses, empagliflozin significantly improved intraglomerular hypertension and achieved a mean intraglomerular pressure approximating that in T1D-N participants. These first-in-human observations suggested that SGLT2 inhibition exerts a clinically meaningful impact on early renal haemodynamic abnormalities characteristic of type 1 diabetes. Future randomised, appropriately controlled studies should determine whether these haemodynamic effects also occur in patients with renal impairment, and whether SGLT2 inhibition may, as a consequence, be renal protective.

The preferential effect of SGLT2 inhibition on R_A, rather than R_E, is important in light of how these agents could potentially be used in patients taking renin–angiotensin–aldosterone system (RAAS) inhibitors [7]. The renal effects of SGLT2 inhibition could be complementary to the well described changes in R_E achieved with RAAS blockade, an intriguing concept for the design of future renal protection studies using the combination of dual SGLT2–RAAS inhibition (ACE inhibition or angiotensin II receptor blockade) to normalise glomerular hyperfiltration (ESM Fig. 4). Although existing studies suggest that SGLT2 inhibitors have an acceptable renal safety profile, further work is required to determine whether combined SGLT2–RAAS inhibition could fully normalise the intraglomerular hypertension and hyperfiltration associated with the early stages of diabetes, and whether this effect would lead to the long-term preservation of renal function. On the other hand, whether such a combination may reduce intraglomerular pressure to an extent that could increase the risk for acute kidney injury events needs to be elucidated. In light of findings from the Ongoing Telmisartan Alone and in Combination With Ramipril Global Endpoint Trial (ONTARGET), Aliskiren Trial in Type 2 Diabetes Using Cardiovascular and Renal Disease Endpoints (ALTITUDE) and Veterans Affairs Nephropathy in Diabetes trial (VA-NEPHRON-D), which use strategies of dual RAAS blockade [8–10], this is an important consideration that requires further human physiological investigation and surveillance in ongoing clinical trials. Finally, our observations may have particular implications for primary renal preventive strategies in patients with type 1 diabetes, since RAAS blockade monotherapy is ineffective in normotensive, normoalbuminuric patients with preserved renal function. Future studies of SGLT2–RAAS blockade in patients with uncomplicated diabetes are therefore warranted, since simultaneous constriction of the afferent arteriole (SGLT2 inhibition) with efferent vasodilatation (RAAS blockade) has the potential to reverse early renal haemodynamic abnormalities that contribute to hyperfiltration.