Safety and Efficacy of GLP-1 Receptor Agonists in Type 2 Diabetes Mellitus with Advanced and End-Stage Kidney Disease: A Systematic Review and Meta-Analysis

Chronic kidney disease (CKD) is a major global public health issue that considerably contributes to the burden of cardiovascular disease (CVD), premature mortality, healthcare expenditure, and decreased quality of life [1,2]. Approximately half of all worldwide incidences of end-stage kidney disease (ESKD) are due to diabetic kidney disease, primarily type 2 diabetes mellitus (T2DM), which is associated with increased CVD and death [3,4,5]. Therefore, the 2022 Kidney Disease Improving Global Outcomes (KDIGO) guidelines emphasized the need for a comprehensive approach to managing people with diabetes and CKD to improve both kidney and cardiovascular outcomes [6]. One of the strategies recommended is the use of glucose-lowering medications with secondary cardiorenal benefits, including sodium-glucose cotransporter-2 inhibitors (SGLT-2is) and glucagon-like peptide-1 receptor agonists (GLP-1RAs), as first- and second-line therapy in T2DM with CKD, respectively [6]. The American Diabetes Association (ADA) also recommends these agents as initial therapy for T2DM patients with CKD, regardless of albuminuria levels [7].

GLP-1 is an incretin hormone, INtestine seCRETion of INsulin secreted by the neuroendocrine L-cells of the intestine after a meal. Natural GLP-1 has a very short plasma half-life (1–2 min) because it is cleaved by the dipeptidyl peptidase-4 (DPP-4) enzyme. Since it is recognized that patients with T2DM have a markedly blunted incretin secretory response, GLP-1RAs were developed to increase the action of GLP-1, thus essentially prolonging its half-life activity [8]. Currently, there are eight GLP-1RAs approved for T2DM treatment, including exenatide (2006), liraglutide (2009), exenatide long-acting release (2011), lixisenatide (2013), albiglutide 2014), dulaglutide (2014), semaglutide (2017), and tirzepatide (2022).

In contrast to sulfonylureas, GLP-1RAs stimulate insulin release in a glucose-dependent pathway and inhibit glucagon release. They also slow gastric emptying time and suppress appetite, thus promoting weight loss [6,9]. GLP-1RAs not only effectively improve glycemic control but have also been shown to reduce major adverse cardiac events (MACE), all-cause mortality, hospitalization due to heart failure, and worsening kidney function among T2DM patients with high cardiovascular risk [6,10,11,12,13,14].

Unlike SGLT-2is, GLP-1RAs may be used in patients with advanced CKD and ESKD, since the elimination of GLP-1RAs depends on both enzymatic pathway (peptidases) and kidney excretion, whereas SGLT-2is are primarily eliminated by the kidneys [15]. Although advanced CKD patients are generally excluded from most randomized controlled trials (RCTs) [10,11,12,13,14,16,17,18,19], there is emerging evidence suggesting that GLP-1RAs may be safe and effective for the treatment of T2DM in advanced CKD/ESKD patients and it may even confer cardiovascular benefits in this high-risk population [20,21,22,23,24,25,26,27]. Thus, we conducted a systematic review and meta-analysis to assess the safety and efficacy of GLP-1RAs in T2DM patients with advanced CKD and ESKD.

A funnel plot was not constructed due to the paucity of studies included. Conventionally, it is recommended that tests for asymmetry in funnel plots be employed only when the number of study groups equals or exceeds 10. Owing to this limitation in the number of studies, the statistical power of the test remains inadequate to effectively discern between random variation and actual asymmetry [36]. Egger’s regression asymmetry test showed no publication bias with p > 0.05 for all analyses.

A recent meta-analysis by Sattar et al. [14] demonstrated that GLP-1RAs reduce the composite MACE, which consists of cardiovascular death, myocardial infarction, and stroke, by 14% in individuals with T2DM. In addition, GLP-1RAs have been shown to decrease all-cause mortality, hospitalization for heart failure, and composite kidney outcomes without any increased risk of adverse events [14]. However, it is highlighted that the RCTs included in this aforementioned meta-analysis had a small proportion of patients (14.6%) with significant CKD (eGFR < 60 mL/min/1.73 m²), and none of them had advanced CKD (eGFR < 15 mL/min/1.73 m²) or ESKD [10,11,12,13,16,17,18,19,37,38]. Since kidneys are responsible for the partial excretion of GLP-1RAs, it is not surprising that these advanced CKD patients were initially excluded from RCTs [15].

While liraglutide and dulaglutide are the most commonly used GLP-1RAs among patients with advanced CKD and ESKD in our review, there have been some case reports that have demonstrated the favorable effectiveness and safety of semaglutide in individuals with ESKD [20,24,39]. In contrast to short-acting GLP-1RAs and exenatide, the majority of liraglutide, dulaglutide, and semaglutide is primarily eliminated through the peptidases enzymatic pathway, with only a small percentage of the drug excreted in the kidneys [15]. Therefore, the findings of our meta-analysis showing that the use of GLP-1RAs in patients with advanced CKD did not significantly increase the risk of hypoglycemia appears rational.

Despite a higher incidence of SAEs in the GLP-1RAs group compared to the control (8.6% vs. 1.5%), it is noted that all reported SAEs cases were primarily from only one RCT [22], and no such cases were reported in the other studies included in this systematic review. Furthermore, the authors of that RCT stated that none of the SAEs were related to the GLP-1RAs and that all patients fully recovered without permanent injury [22]. GI side effects, however, were reported more frequently in ESKD patients treated with GLP-1RAs, with a 3.8-fold increased risk of nausea and a 35.6-fold increased risk of vomiting when compared to the control group. A previous meta-analysis of GLP-1RAs in a general population without significant CKD similarly found that liraglutide increased the risk of nausea and vomiting, with an odds ratio (OR) range between 3.6–5.3 and 6.1–6.9, respectively [40]. Thus, although the use of GLP-1RAs in patients with advanced CKD and ESKD may carry a higher risk of vomiting compared to a general population, there were also no reported cases of severe dehydration or other sequelae, even in those with the most severe cases [22].

The benefit of GLP-1RAs on long-term mortality outcomes was assessed primarily in one nationwide cohort study [32]. Compared to the control group, GLP-1RAs decreased all-cause mortality in advanced CKD patients by 30%, significantly higher than the 12% associated in patients without significant CKD [14]. It is noted that the greatest reduction in all-cause mortality among advanced CKD and ESKD patients was predominantly driven by sepsis- and infection-related deaths rather than CV deaths, which are commonly observed in those T2DM patients in general [14,32]. Considering that diabetes and CKD are both recognized as diseases that increase susceptibility to infection and are associated with poor outcomes following sepsis [32,41,42], it is plausible that incretin-based therapy could improve outcomes by decreasing excessive inflammation and microvascular thrombosis in sepsis via GLP-1 receptor activation [32,43,44]. Conversely, despite being classified as an incretin-based therapy, DPP-4is have been associated with higher infection-related mortality [32]. This association with increased mortality in diabetic patients may have resulted from COVID-19 infection during the pandemic [45]. To determine the long-term benefit of GLP-1RAs on CV mortality, more studies with longer follow-up times are needed.

The efficacy of cardiovascular outcomes was evaluated using cardiac function tests rather than standard MACE due to the limited events during the follow-up duration of the studies included. In this meta-analysis, GLP-1RAs significantly reduced CTR from baseline, pro-BNP levels and LMVI in ESKD patients compared to the control group. Notably, these beneficial effects of GLP-1RAs on left ventricular (LV) function cannot be solely attributed to changes in blood pressure, as shown by a nonsignificant change in SBP in this meta-analysis, but rather due to both glucose-dependent and non-glucose-dependent mediated pathways [46]. A recent study by Nikolaidis et al. also demonstrated an improvement in LV function in patients with acute MI and severe systolic dysfunction after successful primary angioplasty within 72 h of GLP-1RAs infusion [46]. Altogether, the available evidence may support the hypothesis that GLP-1RAs improve CV outcomes via numerous favorable cardiac effects, including increased glucose uptake, decreased metabolism of free fatty acid and accumulation of triglyceride, improved production of nitric oxide (NO), enhanced reduction of vasorelaxation/afterload, and increased cardiac contractility [15,47,48].

The effect on blood glucose was evaluated in this meta-analysis, and it was surprising to find that GLP-1RAs treatment did not significantly lower HbA1c compared to the control group. One possible explanation for this lack of significance is that the mean baseline HbA1c level of the included patients was 6.2 ± 0.7%, which falls within the acceptable range for most individuals with diabetes [6,49]. Given that GLP-1RAs stimulate insulin release in a glucose-dependent manner, its effectiveness may not be apparent in populations with well-controlled blood glucose [9,15,50]. Another possible reason for the lack of statistical difference in HbA1c is that the differences in blood glucose between GLP1-RAs vs. controls, while statistically significant, are very subtle with an SMD of −1.1 mg/dL and in the setting of concurrent alternative hyperglycemic drug treatment depending on study control group. Hence, this between-group difference is too small to affect the HbA1c. Finally, HbA1c measurements may have limited accuracy in patients with advanced CKD due to various factors such as anemia, treatment with erythropoiesis-stimulating agents (ESAs), or iron supplements, which can lead to underestimation of HbA1c levels [6]. Although GLP-1RAs did not lower the maximum blood glucose level in our meta-analysis, it is noteworthy that the treatment did lead to a significant improvement in postprandial glucose excursion in one study [21].

Continuous glucose monitoring (CGM) is another glucose measurement tool recommended by KDIGO in diabetic patients with advanced CKD and ESKD. This meta-analysis revealed that GLP-1RAs significantly reduced mean blood glucose levels compared to the control group. Despite each individual study showing a significant improvement in glucose fluctuation with GLP-1RAs, GLP-1RAs did not decrease blood glucose variability. This may be due to the limited numbers of patients and high heterogeneity among the included studies, making it difficult to detect the glucose fluctuations [21,23].

As compared to a previous meta-analysis, weight reduction with GLP-1RAs resulted in less benefit for patients with advanced CKD than those in the general population, with an SMD of −2.2 kg (95% CI −2.9, −1.5) and −7.1 kg (95% CI −9.2, −5.0), respectively [51]. This discrepancy can be attributed to the greater BMI of the participants in the previous study than ours. It is also possible that patients with advanced CKD and uremia have multiple inflammatory milieu and comorbidities that result in increased fatigue, decreased activity, and reduced metabolism.

We found limited evidence regarding the impact of GLP-1RAs on renal outcomes, as only one cohort study reported a significant reduction in eGFR decline in stage 5 CKD patients. An ongoing FLOW trial is currently underway to evaluate the effects of semaglutide on kidney outcomes in individuals diagnosed with T2DM and CKD, with anticipated results slated for release in 2024. It is pertinent to note, however, that the preliminary mean eGFR in this study stood at 47 mL/min/1.73 m², an indicative of a non-advanced CKD or ESKD population [35]. Therefore, further studies are needed to draw a definitive conclusion on the benefits of GLP-1RAs on renal outcomes in this patient population.

There are several limitations in our systematic review and meta-analysis that should be acknowledged. Firstly, the inclusion of a few studies with a limited number of patients in each analysis resulted in significant heterogeneity among the included studies on certain outcomes of interest, including SBP, HbA1c, and hypoglycemia. Secondly, the short-term follow-up period of the included studies, most of which were within one year, limits our ability to assess long-term outcomes such as mortality and MACE. Thirdly, the included studies predominantly involved Asian populations, which may limit the generalizability of our findings to other ethnic groups. This study did not include patients with ESKD who were transplanted, nor did it have sufficient numbers to perform a subgroup analysis on the type of dialysis modality and the associated impact of GLP-1RAs. Finally, only a few studies evaluated blood glucose levels with CGM, and none of them reported self-monitoring blood glucose (SMBG), which is more reliable than HbA1c in patients with advanced CKD and ESKD [6]. Thus, future studies with larger sample sizes, longer follow-up periods, and more diverse populations are needed to confirm our findings and address these limitations. Despite these limitations, our systematic review provides important insights into the safety and efficacy of GLP-1RAs among T2DM patients with advanced CKD.

To the best of our knowledge, this is the first systematic review and meta-analysis that evaluates the safety and efficacy of GLP-1RAs among T2DM patients with advanced CKD. Our finding demonstrated that the use of GLP-1RAs in patients with advanced CKD and ESKD is generally safe, except for an increased risk of vomiting that necessitates close monitoring following drug initiation. Furthermore, these patients exhibit favorable cardiovascular outcomes, blood glucose control, and weight reduction from GLP-1RAs, similar to the benefits observed in T2DM patients without significant CKD. Nonetheless, further studies with long-term follow-up are needed to confirm the benefit of GLP-1RAs on mortality and MACE.

Our study summarizes the safety and efficacy size of GLP-1RAs among T2DM patients with advanced CKD and ESKD. While GLP-1RAs might increase the risk of GI side effects, GLP-1RAs demonstrate significant improvements in blood glucose control, weight reduction, and potential benefit in cardiovascular outcomes.

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/diseases12010014/s1↗, Figure S1: Cochrane Risk of Bias (RoB 2) Tool Utilization in Randomized Controlled Trials (RCTs). Figure S2: Weight Reduction Efficacy of GLP-1RAs. This figure presents a meta-analysis of weight change outcomes in patients treated with GLP-1RAs, compared to controls. Table S1: Data Extraction Form Used for Study Inclusion. Table S2: Risk of Bias In Non-randomized Studies—of Interventions (ROBIN-I) Assessment Results.

Conceptualization, P.K. and W.C.; methodology, P.K., C.T. and W.C.; software, W.C.; validation, P.K., K.S., C.T. and W.C.; formal analysis, P.K. and W.C.; investigation, P.K., K.S., C.T., M.A.M. and W.C.; resources, C.T., data curation, P.K., C.T. and W.C.; writing—original draft preparation, P.K., K.S., P.P., C.T., J.M., M.A.M., S.S., S.T., I.M.C. and W.C.; writing—review and editing, P.K., K.S., P.P., C.T., J.M., M.A.M., S.S., S.T., I.M.C. and W.C.; visualization, P.K., K.S. and W.C.; supervision, C.T., J.M., I.M.C. and W.C.; project administration, K.S. and W.C. All authors have read and agreed to the published version of the manuscript.

The study received approval from the Institutional Review Board (or Ethics Committee) of Mayo Clinic Institutional Review Board (IRB number 23-001615).

Not applicable.

The data supporting this study can be found in the original publication, reports, and preprints referenced in the citations.

The authors declare no conflicts.

This research received no external funding.