JCM | Free Full-Text | Contrast-Induced Acute Kidney Injury in Patients with Heart Failure on Sodium–Glucose Cotransporter-2 Inhibitors Undergoing Radiocontrast Agent Invasive Procedures: A Propensity-Matched Analysis
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2. Materials and Methods
2.1. Study Population
This single-center, retrospective study enrolled all consecutive patients with HF undergoing ICM invasive procedures at Careggi University Hospital from January 2019 to December 2023, including both coronary and structural Interventions.
Automatic software-based research was performed through electronic medical records and operative logs for all consecutive patients who underwent coronary angiography, PCI, transcatheter aortic valve replacement or another iodinated contrast medium procedure. Among these, we identified those with HF and reduced or mildly reduced ejection fraction (HFrEF or HFmrEF) and, based on HF therapy at the admission, we categorized them into SGLT2-i users (in the era of gliflozins prescribed for HF) and SGLT2-i non-users (in the pre-gliflozin era).
Definition of HF with reduced left ventricular ejection fraction (LVEF) (HFrEF, LVEF ≤ 40%) and mildly reduced LV systolic function (HFmrEF, LVEF between 41% and 49%) was based on the most recent ESC guidelines [9]. Patients with HF and preserved LVEF (HFpEF) were excluded.
We defined “SGLT2-i users” the patients who were admitted on chronic SGLT2-i therapy (empagliflozin or dapagliflozin) and started it at least 6 months before PCI. This cut-off of 6 months was chosen since SGLT2-i may exhibit beneficial effects after a 6-month period, as indicated in several studies [10,11].
Indication for invasive procedures (coronary angiography, PCI or structural interventions, patent foramen oval closure and left atrial appendage occlusion, or endomyocardial biopsy), referral, and timing were managed according to the current guidelines and after a multidisciplinary discussion by a team of expert in coronary and valvular heart disease, including a clinical and interventional cardiologist, cardiac surgeons, imaging specialists with expertise in interventional imaging, cardiovascular anesthesiologists, and other specialists if necessary (e.g., heart failure specialists or electrophysiologists)—the “Heart Team”.
The exclusion criteria were as follows: cardiogenic shock and multi-organ failure or hemodynamic instability requiring ino-vasopressors agents, dialysis treatment or continuous renal replacement therapy (CRRT) at the time of the procedure, patients on SGLT2-i therapy for less than 6 months, and incomplete information on medical therapy.
All patients were informed about their participation in the study and provided informed consent for the anonymous publication of scientific data.
2.2. Endpoints
The primary endpoint was the incidence of CI-AKI during the hospitalization. Serum creatinine concentration and estimated glomerular filtration rate (eGFR) according to the Chronic Kidney Disease Epidemiology Collaboration (CKD-EPI) equation were measured in all patients at hospital admission and daily during the hospital stay. CI-AKI was defined as an absolute (≥0.5 mg/dL) or relative increase (≥25%) in serum creatinine at 48–72 h after the index PCI compared to baseline serum creatinine values according to the latest definition [12]. CI-AKI was considered either as a new-onset or an exacerbation of renal dysfunction following administration of ICM without other potential causes. We considered the Mehran score, which includes the most clinically relevant variables associated with CI-AKI, i.e., age, anemia, contrast media volume, eGFR, congestive heart failure, hypotension, use of intra-aortic balloon pump to predict the risk of CI-AKI after PCI [13].
To prevent contrast-induced nephropathy, according to our institutional protocol, all patients in the study underwent pre-procedural intravenous fluid administration of 1 mg/kg/h normal saline or Hartmann’s solution if in the HFmrEF group or 0.5 mg/kg/h if in the HFrEF group.
The iodinated contrast available in our institution is Iobitridol 350 (Xenetix®, Guerbet, Villepinte, France), which was used in all patients undergoing coronary angiography and other procedures in our institution.
The secondary endpoint was a composite of all-cause mortality at median follow-up and need for in-hospital hemodialysis, also including CRRT. We considered both patients who underwent in-hospital CRRT after the ICM procedure and those who underwent prophylactic CRRT by receiving hemodialysis either before or after the administration of radiocontrast agent in case of pre-existing renal failure, since in the literature, the evidence regarding the role of CRRT in CI-AKI prevention is controversial [14].
2.3. Statistical Analysis
Histograms and q-plot assessed the normal distribution of continuous variables; the Shapiro–Wilk test was used when required. Continuous variables with normal distribution were expressed as the mean ± standard deviation and non-normally distributed as median and interquartile range. Normal ranges were presented as the 5th and 95th percentiles. Categorical variables were expressed as counts and percentages. Differences between groups were analyzed using the t-test or the Mann–Whitney U test for continuous variables and the chi-square test or the Fisher’s exact test for categorical variables, as appropriate.
Propensity scores were calculated using logistic regression of SLGT2 inhibitor use on age, gender, body mass index (BMI), hypertension, heart failure class, LVEF at admission, eGFR at admission, prevalent peripheral arterial disease, prevalent diabetes, prevalent atrial fibrillation, and smoking. For participants with missing values in any of these covariates, exact matches were required on missing status. Propensity matching was performed with a 1:1 match for case and control subjects in which the nearest neighbor was selected without replacement.
A p-value < 0.05 was considered statistically significant. All analyses were performed using Statistical Package for Social Sciences, version 28.0 (SPSS, Chicago, IL, USA) and R version 4.0.
4. Discussion
In the present study, we investigated the potential impact of SGLT2-i in reducing the risk of CI-AKI among HF patients. The most important result was a clear association between SGLT2i treatment and a reduced risk of CI-AKI. This finding was persistent after propensity matching analysis and correction for potential confounding by multivariable analysis. A reduction in the composite secondary endpoint (renal failure requiring CRRT + all-cause mortality) was also observed.
SGLT2-i exhibited a consistent benefit of the reduction in CI-AKI across different patients’ comorbidity and indications to undergo invasive procedures with ICM suggesting its protection in all spectra of HF patients, with no differences based on the presence of pre-existing chronic kidney disease and/or diabetes, as already demonstrated in previous investigations [15]. SGLT2-i use was also associated with mortality reduction probably due to the reno-protective effect, since the post-procedural need for CRRT was lower among patients treated with gliflozins.
To the best of our knowledge, this is the first study on the potential protective role of SGLT2-i from CI-AKI in HF patients undergoing invasive procedures with ICM, independently from the presence of diabetes, chronic kidney disease and acute coronary syndromes.
In the literature, some data suggesting a protective role of SGLT2-i from CI-AKI are available, but only in specific settings such as diabetes, chronic kidney disease (CKD) patients and patients with AMI undergoing primary PCI.
Despite an initial warning advanced by the Food and Drug Administration about the risk of AKI related to the use of gliflozins [16], further studies aimed to demonstrate that this class of drugs not only do not increase the risk of AKI but also presents a nephroprotective effect associated with CI-AKI prevention compared to other glucose-lowering therapies [17,18].
Firstly, Hua et al. [19] demonstrated the safety of SGLT2-i treatment administered at least 6 months before and continued after PCI. In this study, the authors not only did not observe any increased risk of CI-AKI with SGLT2-i usage after PCI but also observed an unadjusted ORs of CI-AKI KDIGO 54% lower in the SGLT2-i user group compared with the non-user group [0.46 (95% CI: 0.276–0.75); p = 0.02]. This study was clinically relevant as it provided the first evidence regarding the safety of gliflozin treatment without the need for discontinuation prior to exposure to contrast media. Similar safety data are not definitive for other classes of glucose-lowering drugs such as metformin.
With these premises, other studies investigated the role of SGLT2-i for renal protection in specific populations undergoing ICM procedures. In a large cohort of type 2 diabetes mellitus (T2DM) patients, a propensity-matched analysis published by Nadkarni et al. [20] showed that the CI-AKI risk was reduced with SGLT2-i treatment (HR 0.4 [95% CI: 0.2–0.7]; p = 0.01).
Furthermore, in a multicentre international registry (the SGLT2-i AMI PROTECT registry) recently published by Paolisso et al. [8], the authors demonstrated that the SGLT2-i use was associated with a lower risk of CI-AKI in T2DM patients with AMI, mostly in patients without CKD. However, as mentioned before, this study included only diabetic patients with AMI. We should acknowledge that patients with AMI have a higher risk of developing renal failure due to the high thrombogenic state, the inflammation status, and the decrease in renal perfusion. On the contrary, our population included a large proportion of patients with CKD and chronic coronary syndromes.
Well-established risk factors for CI-AKI included age, diabetes, CKD, HF, and other elements related to intervention procedures, such as type and amount of ICM usage, repeated PCI, and use of mechanical circulatory support such as IABP, as assessed by the Mehran score. In addition to what is reported in the literature, our multivariable regression analysis showed that SGLT2-i usage was a predictor of CI-AKI (Table 3).
Furthermore, SGLT2-i use was also an independent protective factor for the secondary composite endpoint of renal failure requiring CRRT and/or all-cause mortality, whereas independent related risk factors were eGFR at admission and the Mehran score (Table 4). These results are congruent with previous studies reporting the prognostic significance of the proposed score to predict one-year mortality and the need for in-hospital hemodialysis [13].
All the above-mentioned studies probably share a common beneficial effect conferred by gliflozins therapy. In fact, although the underlying mechanisms are not completely understood, the nephroprotective effect of SGLT2-i appears to be independent of the blood-glucose-lowering effects. Actually, gliflozin’s effects might be mediated by natriuresis and glucose-induced osmotic diuresis, leading to a reduction in intraglomerular pressure (and consequently a reduction in hyperfiltration) and exposure time of each nephron to contrast agent direct toxicity and a decrease in ischemic injury mediated by vasoconstriction and limited renal blood flow [21]. Therefore, gliflozins are involved in maintaining the glomerular balance between renal perfusion, filtration rate and fluid reabsorption in the proximal tubule, a vulnerable system that is perturbated in HF. In addition, in patients with HF, the renal hemodynamic effects of the SGLT2-i resulting from pre-glomerular vasoconstriction is often combined with the efferent arteriolar vasodilatation mediated by RAAS inhibitors, another pillar of HF therapy. Thus, a combination of SGLT2-i and RAAS inhibitors may result in a nephroprotective synergic therapy and CI-AKI prevention strategy in HF patients.
Emerging data from Huang X et al. [22] demonstrated that even dapagliflozin may ameliorate CI-AKI through suppression of HIF-1a/HE4/NF-kB signaling in vitro and in vivo, which is the pathway involved in hypoxia-induced injury. Furthermore, SGLT2-i can affect vascular remodeling and neointimal hyperplasia after ICM [7]. Other renal protective effects could be represented by inflammatory response modulation, reduction in endothelial activation, fibrosis and oxidative stress production [23].
In our experience, gliflozin use was also associated with a significative lower mortality, and this result was maintained even after propensity-matched analysis. This result is also consistent with mortality data derived from pivotal trials about gliflozins in the HF population [7,11,24].
The results of our study provide further evidence of the potential role of gliflozins in CI-AKI prevention. To date, no drugs have been demonstrated to have this role. There is only some evidence of statins providing renal protection when administered before ICM [25]. The only ascertained preventive strategies remain adequate volume expansion and reduction in the contrast dose administered [26]. In the future, randomized clinical trials are needed to definitively clarify the role of SGLT2-i as a key element for CI-AKI prevention, with tailored protocols of administration before and after ICM procedures, especially in CI-AKI high-risk patients.
Our study presents some limitations. First, the major limitation is the retrospective nature of the study with the two groups of patients enrolled in two different periods: pre- and post-SGLT2 prescription and reimbursement for HF, even though we conducted propensity score-matched analysis to minimize the impact of confounding factors
Second, even if the multivariable analysis clearly showed that contrast medium volume was not associated with a higher risk of CI-AKI, we should highlight that patients in the non-user group were exposed to a larger volume of ICM.
Thus, a larger sample size and multicenter studies are needed to further confirm the effectiveness of gliflozins in reducing CI-AKI risk for patients scheduled for an ICM invasive procedure. Furthermore, the limited number of patients enrolled, and the short follow-up data are not sufficient to assess hard clinical endpoints, such as permanent replacement therapy, dialysis, and mortality, and to ascertain the impact of SGLT2-i on patients’ long-term prognosis.
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