Safety and tolerability of sodium-glucose cotransporter-2 inhibitors in children and young adults: a systematic review and meta-analysis

Article information

Ann Pediatr Endocrinol Metab. 2024;29(2):82-89
Publication date (electronic) : 2024 January 2
doi : https://doi.org/10.6065/apem.2346162.081
1Department of Endocrinology, JSS Medical College, JSS Academy of Higher Education and Research, Mysore, India
2Department of Endocrinology, Center for Endocrinology Diabetes Arthritis & Rheumatism (CEDAR) Superspeciality Healthcare, Dwarka, New Delhi, India
3Department of Anaesthesiology, JSS Academy of Higher Education and Research, Mysore, India
4Department of Endocrinology, Khandelwal Diabetes, Thyroid & Endocrinology Clinic, Paschim Vihar, New Delhi, India
5Department of Endocrinology, Apollo Hospitals, Navi Mumbai, India
6Department of Rheumatology, Center for Endocrinology Diabetes Arthritis & Rheumatism (CEDAR) Superspeciality Healthcare, Dwarka, New Delhi, India
Address for correspondence: Deep Dutta Center for Endocrinology, Diabetes, Arthritis & Rheumatism (CEDAR) Superspeciality Healthcare, Dwarka, New Delhi 110075, India Email: deepdutta2000@yahoo.com
Received 2023 July 15; Revised 2023 August 30; Accepted 2023 October 4.

Abstract

Purpose

Sodium glucose cotransporter-2 inhibitors (SGLT2i) have been evaluated in children with type 2 diabetes mellitus (T2DM), type 1 diabetes mellitus (T1DM), and several other nondiabetic conditions. Potential tolerability issues have prevented the routine use of SGLT2i in children with diabetes. However, no meta-analysis to date has evaluated the safety and tolerability of SGLT2i in children. This systematic review and meta-analysis aimed to address this knowledge gap.

Methods

Databases were searched for randomized controlled trials (RCTs), case control, and cohort studies involving children receiving SGLT2i in the intervention-arm. Primary outcome was occurrence of treatment emergent adverse events (TAEs). Secondary outcomes were evaluation of glycemic efficacy and occurrence of severe adverse events (SAEs), hypoglycemia, ketosis, genital or urinary infections, and any other adverse events.

Results

From the 27 articles initially screened, data from 4 RCTs (258 children) were analyzed. In children with T2DM, occurrence of TAEs (odds ratio [OR], 1.77; 95% confidence interval [CI], 0.93–3.36; P=0.08; I2=0%), SAEs (OR, 0.45; 95% CI, 0.08–2.54; P=0.37; I2=0%), ketoacidosis (OR, 0.33; 95% CI, 0.01–8.37; P=0.50), urinary tract infections (OR, 2.34; 95% CI, 0.44–12.50; P=0.32; I2=0%), and severe hypoglycemia (OR, 4.47; 95% CI, 0.21–96.40; P=0.34) were comparable among the SGLTi group and placebo. Compared to placebo, T2DM children receiving SGLTi had significantly lower glycosylated hemoglobin at 24–26 weeks (mean difference [MD], -0.79%; 95% CI, -1.33 to -0.26; P=0.004; I2=0%). In T1DM children, β-hydroxybutyrate levels were significantly higher in the SGLTi group than the placebo group (MD, 0.11 mmol/L; 95% CI, 0.05–0.17; P=0.0005; I2=53%). In T1DM, there was not a single report of an SAE, ketoacidosis, or severe hypoglycemia in either the placebo or treatment groups, but time-in-range was considerably greater in the SGLT2i group than the placebo group (68%±6% vs. 50%±13%, P<0.001).

Conclusions

SGLT2i use in children and young adults appears to be both safe and tolerable based on our meta-analyses and review of the literature.

Highlights

· Sodium glucose cotransporter-2 inhibitors (SGLT2i) use leads to significantly lower glycosylated hemoglobin without increase in adverse effects in children and young adults with type 2 diabetes mellitus.

· SGLT2i use in type 1 diabetes mellitus (T1DM) leads to increased time-in range with a reduction in insulin dosage.

· SGLT2i use in T1DM leads to increased beta hydroxybutyrate levels but this does not translate to increased occurrence of diabetic ketoacidosis.

Introduction

The U.S. Food and Drug Agency (FDA) approved the use of sodium-glucose cotransporter-2 inhibitors (SGLT2i), specifically empagliflozin, for the treatment of type 2 diabetes mellitus (T2DM) in children aged 10 years or older on June 20, 2023 [1]. The exponential increase in the burden of obesity in the general population and specifically in children in the last few decades has given rise to the new problem of T2DM in children. A recent systematic review of data from 8,942 children with T2DM documented the prevalence of obesity in these children at the time of diagnosis of T2DM to be 77.24% (95% confidence interval [CI], 70.55%–83.34%) [2]. A recent meta-analysis of data from 228,184 children reported that the prevalence of T2DM in obese children was 1.3% (95% CI, 0.6%–2.1%), which is 13 times the prevalence in normal weight children (0.1%; 95% CI, 0.01%–0.2%) [3]. The approval of empagliflozin by the FDA is likely to exponentially increase the use of SGLT2i in children with T2DM.

The glycemic efficacy of SGLT2i as antidiabetes medications has been well established across the globe with clinical use spanning more than a decade. However, the tolerability and side-effect profiles of this class has drugs has prevented their widespread used in in children with diabetes, specifically T2DM. SGLT2i have been tried in children with type 1 diabetes mellitus (T1DM), especially in those who are overweight or obese [4,5]. More recently, SGLT2i have been used to treat nondiabetic conditions in children such as congenital severe insulin resistance syndromes [6,7], neutropenia in children with glycogen storage disease type 1b [8], Prader Willi syndrome [9], heart failure [10], and hereditary proteinuric kidney disease [11].

It is therefore critically important to document the safety and tolerability of use of SGLT2i in children with different clinical conditions before more extensive use in clinical practice. A literature review revealed that to date, no meta-analysis evaluating the safety and tolerability of SGLT2i in children has been published. Hence, our aim in this systematic review and meta-analysis was to evaluate the safety and tolerability of SGLT2i use in children.

Materials and methods

The meta-analysis was carried out according to the recommendations of the Cochrane Handbook for Systematic Reviews of Interventions and followed the PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-Analyses), the filled checklist of which can be found at the end of the manuscript [12]. The predefined protocol was registered in PROSPERO under registration number CRD42023439736. All randomized controlled trials (RCTs), case control studies, and cohort studies published till May 2023 were considered for this systematic review. Since ethical approval already exists for the individual studies included in the meta‑analysis, no separate approval was required for this study. PICOS (Population, Intervention, Comparison, Outcomes, and Study) criteria were used to screen and select studies for this systematic review. Only children and young adults receiving any SGLT2i for a clinical condition such as T2DM, T1DM, insulin resistance syndrome, cardiac disease, and renal disease were considered for this systematic review. Adults (individuals older than 25 years) were excluded from this study.

The primary outcome was the occurrence of treatment emergent adverse events (TAEs). The secondary outcomes of this study were the occurrence of severe adverse events (SAEs), hypoglycemia, euglycemic ketosis, hyperglycemic ketosis, genital infections, urinary tract infections (UTIs), pyelonephritis, any other adverse event reported, glycemic efficacy in children with diabetes, and any other pleotropic benefit documented.

Electronic databases of MEDLINE (via PubMed), Embase (via Ovid SP), Cochrane central register of controlled trials (CENTRAL) (for trials only), ctri.nic.in, clinicaltrials.gov, global health, and Google scholar were searched using the following Boolean search strategy: "(SGLT2) OR (dapagliflozin) OR (empagliflozin) OR (sodium glucose co-transporter 2)" AND "(children) OR (adolescent)". Data extraction was carried out independently by 2 authors. Details of data extraction are described in a previous publication from our group [13]. Three authors independently assessed the risk of bias using the risk of bias assessment tool in Review Manager (Revman) version 5.4 (The Cochrane Collaboration, Oxford, UK 2014) software as described previously [14]. For continuous variables, outcomes were expressed as mean differences (MDs). For dichotomous outcomes (treatment success), results were expressed as odds ratios (ORs) with 95% confidence intervals (CIs). RevMan 5.4 was used to compare the MDs of different primary and secondary outcomes. Data were pooled in random effect models to analyze primary and secondary outcomes. Outcomes were expressed as 95% CI. Heterogeneity was initially assessed by studying Forest plots generated for the primary and secondary outcomes of this study. Subsequently heterogeneity was analyzed using a chi-square test with N-1 degrees of freedom [15]. Details of these analyses are provided in our previous publications [13,14]. Overall grading of the evidence (certainty of the evidence) related to each of the primary and secondary outcomes was done using the GRADE (Grades of Recommendation, Assessment, Development and Evaluation) approach [16] as described previously [14]. GRADEpro Guideline Development Tool software (McMaster University and Evidence Prime Inc, 2015) was used to create the summary of findings table for this meta-analysis.

Publication bias was assessed by generating funnel plots [16]. Presence of one or more of the smaller studies outside the inverted funnel plot was taken as evidence of the presence of significant publication bias [17].

Results

Three duplicate articles were removed from the initial set of 27 articles found after the initial search (Fig. 1). Further screening of titles, abstracts, and full-texts reduced our search down to 11 studies which were evaluated in detail (Fig. 1). Data from 4 trials involving 177 individuals with T2DM and 81 individuals with T1DM were analyzed. The RCT by Laffel et al. [18] was included in the meta-analysis as it evaluated the efficacy of empagliflozin in children with T2DM as compared to placebo and linagliptin. The RCT by Tamborlane et al. [19] was also included in the meta-analysis as it evaluated the efficacy and safety of dapagliflozin as compared to placebo in children with T2DM. Biester et al. [20,21] evaluated the safety and efficacy of dapagliflozin in addition to insulin therapy in patients with T1DM. Baseline characteristics of the studies included in the analysis are depicted in Table 1. Laffel et al. [22] and Tirucherai et al. [23] evaluated the pharmacokinetics and pharmacodynamics of empagliflozin and dapagliflozin, respectively, in T2DM, but did not have a control arm and their studies were therefore excluded from the meta-analysis. Studies by Grünert et al. [8] and Halligan et al. [24] were observational studies evaluating the safety and efficacy of empagliflozin in children with glycogen storage disease type 1b. Cui et al. [11] evaluated the safety and efficacy of dapagliflozin in children with inherited proteinuric kidney disease. Newland et al. [10] studied the impact of dapagliflozin in pediatric heart failure. Dapagliflozin was found to be useful in young obese children with T1DM with regards to reduction in body weight, glycemic control, and insulin requirements [25]. Studies excluded from analysis are summarized in Table 2.

Fig. 1.

Flowchart describing study retrieval and inclusion in the meta-analysis. RCT, randomized controlled trial.

Summary of major randomized controlled trials/cohort studies published on the use of sodium-glucose cotransporter-2 inhibitors in children

Summary of major observational/single arm studies published on the use of sodium-glucose cotransporter-2 inhibitors in children

1. Risk of bias in the included studies

Supplementary Fig. 1A and B elaborate the risk of bias. All 4 studies included in the meta-analysis were at low risk for random sequence generation, allocation concealment bias, performance bias, detection bias, attrition bias, and reporting bias (100%). Source of funding, especially pharmaceutical industry funding, defined as one or more authors from the pharmaceutical organization involved in the development of the drug, involvement of pharmaceutical organization in data analysis and manuscript preparation, or conflicts of interest were evaluated in the "other bias" section. All 4 studies were at high risk for this type of bias (100%).

2. Effects of SGLT2 inhibitors on primary and secondary outcomes

1) T2DM: safety and efficacy of SGLT2 inhibitors in T2DM

The occurrence of treatment emergent adverse events (TAEs) (OR, 1.77; 95% CI, 0.93–3.36; P=0.08; I2=0%; low heterogeneity [LH]; high certainty of evidence (HCE); Fig. 2A), serious adverse events (SAEs) (OR, 0.45; 95% CI, 0.08–2.54; P=0.37; I2=0%; LH; HCE; Fig. 2B), diabetic ketoacidosis (OR, 0.33; 95% CI, 0.01–8.37; P=0.50; HCE; Fig. 2C), UTIs (OR, 2.34; 95% CI, 0.44–12.50; P=0.32; I2=0%; LH; HCE; Fig. 2D), and severe hypoglycemia requiring assistance (OR, 4.47; 95% CI, 0.21–96.40; P=0.34; HCE) were comparable among patients receiving SGLT2i as compared to placebo.

Fig. 2.

Forest plot highlighting the impact of SGLT2i as compared to placebo in type 2 diabetes on (A) treatment emergent adverse events; (B) serious adverse events; (C) diabetic ketoacidosis; (D) urinary tract infections; (E) forest plot highlighting the impact of SGLT2i as compared to placebo in type 2 diabetes on HbA1c; (F) forest plot highlighting the impact of SGLT2i as compared to placebo in type 1 diabetes on beta hydroxybutyrate levels. SGLT2i, sodium-glucose cotransporter-2 inhibitors; HbA1c, glycosylated hemoglobin; M-H, Mantel-Haenszel; IV, inverse variance; CI, confidence interval; df, degrees of freedom; SD, standard deviation.

As compared to placebo, patients receiving SGLT2i had significantly lower HbA1c at 24–26 weeks (MD, -0.79%; 95% CI, -1.33 to -0.26; P=0.004; I2=0%; LH; HCE; Fig. 2E).

2) T1DM: safety and efficacy of SGLT2 inhibitors in T1DM

Beta hydroxybutyrate levels were significantly higher in the SGLT2i group than the placebo group (MD, 0.11 mmol/L; 95% CI, 0.05–0.17; P=0.0005; I2=53%; moderate heterogeneity; moderate certainty of evidence; Fig. 2F). There was no occurrence of SAEs, diabetic ketoacidosis, or severe hypoglycemia in the treatment or placebo groups.

Time-in-range was considerably greater in the SGLT2i group than the placebo group (68%±6% vs. 50%±13%, P<0.001), and nocturnal glucose was significantly lower with dapagliflozin (6.2±0.7 mmol/L vs. 7.3±1.7 mmol/L, P=0.003) without an increase in time-below-range [20]. In another study, regardless of baseline HbA1c, mean total insulin dosage over the course of 24 hours was significantly lower (P<0.0001) following SGLT2i therapy than placebo administration (0.92 U/kg/24 hr vs. 1.10 U/kg/24 hr), representing a mean reduction of -13.6% [21]. Funnel plots drawn to assess publication bias are presented in Supplementary Fig. 2. Key outcomes of this study are described in Table 3.

Summary of findings of the key outcomes of this metanalysis in children with type 2 diabetes

Discussion

In a population-based study from India involving data from 35,830 adolescents, the prevalence of prediabetes or diabetes was 12.3% and 8.4%, respectively [26]. An exponential increase in the prevalence of obesity among adults and kids following the coronavirus disease 2019 (COVID 19) pandemic has contributed to the increased prevalence of T2DM in children. A network meta-analysis published in 2022 highlighted that metformin, saxagliptin, linagliptin, exenatide, liraglutide and dapagliflozin have been evaluated in different clinical trials in children with T2DM and advocated for the use of the saxagliptin metformin combination to treat T2DM in children [27]. Saxagliptin use has decreased significantly in adults with T2DM following the issue of a black box warning for heart failure [28]. Since then, many more studies have been published on oral antidiabetes medication use in children, especially SGLT2i like empagliflozin.

In a phase 2 study involving 24 children (10–17 years old) with T2DM, dapagliflozin was shown to have pharmacokinetics and pharmacodynamics in children similar to that of adults, indicating no need for dose adjustment with regard to dapagliflozin use in children [23]. A similar study of 27 children aged 10–17 years with T2DM demonstrated empagliflozin had similar pharmacokinetics and pharmacodynamics in children as were observed in adults, indicating no need for dose adjustment with regards to empagliflozin use in children [22].

Our analysis indicated that use of SGLT2i (dapagliflozin and empagliflozin) in children with both T1DM and T2DM is safe. SGLT2i are in general well tolerated in children and have a side-effect profile similar to that noted in adults. Though it is plausible that increased urinary glucose excretion brought about by SGLT2i can cause a UTI, the incidence of UTIs was similar in the treatment and placebo groups of children with T2DM. Though β hydroxybutyrate levels were significantly higher in the SGLTi group than the placebo in T1DM, this elevation was mild and was not severe enough to cause DKA. Health advantages of modest hyperketonemia are also possible. The mild hyperketonemia brought on by the SGLT2i metabolic substrate shift observed in the current study as well as the rapid onset of cardiovascular disease benefits in the EMPA-Reg trial may be directly related to β-HBA being freely taken up by the heart among other organs and oxidized in preference to fatty acids, and it will be interesting to see if this applies to T1DM subgroups as well [29]. Patients with T1DM with metabolic syndrome on SGLT2i are at higher risk of euglycemic ketosis during sick days. Sick day guidelines should therefore be more efficiently implemented during those days in patients with a low threshold for increasing the total daily insulin dose requirements, and if needed, SGLT2i should be withheld for a few days until the patient recovers [30].

Current diabetes management guidelines recommend the use of metformin and glucagon-like peptide-1 receptor agonists, especially liraglutide, in adolescents and children with T2DM [31]. The Australasian Pediatric Endocrine Group guidelines suggest exploring newer antidiabetes medicines already approved for managing T2DM in adults in children [32]. Based on the current efficacy and safety data, it is very likely that other SGLT2i in addition to empagliflozin will be approved for managing T2DM in children, apart from the conditional approval for use of SGLT2i in T1DM children with metabolic syndrome. Pleotropic benefits of SGLT2i include a reduction in fatty liver disease, uric acid levels and blood pressure, which are of importance in children with diabetes and metabolic syndrome [33,34]. It must be realized that the benefits of use of SGLT2i in kids would primarily be in T2DM with obesity (diabesity). Caution should be exerted in lean children.

Limitations of our systematic review include the small number of RCTs available for analysis. Hence there remains an urgent need for bigger RCTs with a longer duration of follow-up evaluating all the different types of SGLT2i in children and adolescents with T2DM. To conclude, our systematic review provides us with reassuring data on the safety of use of SGLT2i in children and young adults.

Supplementary Material

Supplementary Figs. 1 and 2 can be found via https://doi.org/10.6065/apem.2346036.018.

Supplementary Fig. 1.

(A) Risk of bias graph: review of authors' judgements about risk of bias item presented as percentages across all included studies. (B) Risk of bias summary: review of authors' judgements about risk of bias for each item for each included study.

apem-2346162-081-Supplementary-Figure-1-2.pdf
Supplementary Fig. 2.

Funnel plot assessing the publication bias for key outcomes of this meta-analysis. (A) Treatment emergent adverse events with SGLT2i in type 2 diabetes mellitus (T2DM) as compared to placebo; (B) serious adverse events with SGLT2i in T2DM as compared to placebo, (C) DKA with SGLTi in T2DM as compared to placebo, (D) UTI with SGLT2i in T2DM as compared to placebo, (E) severe hypoglycemia requiring assistance with SGLT2i in T2DM as compared to placebo. SGLT2i, sodium-glucose cotransporter-2 inhibitors; DKA, diabetic ketoacidosis; SE, standard error; OR, odds ratio.

apem-2346162-081-Supplementary-Figure-1-2.pdf

Notes

Conflicts of interest

No potential conflict of interest relevant to this article was reported.

Funding

This study received no specific grant from any funding agency in the public, commercial, or not-for-profit sectors.

Author contribution

Conceptualization: DD, MS; Data curation: LN, DD, TL, MS; Formal analysis: LN, DD, BGH, DK; Methodology: DK, TL; Writing - original draft: LN, DD, BGH, DK, TL, MS; Writing - review & editing: LN, DD, BGH, DK, TL, MS

References

1. U.S. Food and Drug Agency (FDA). FDA approves new class of medicines to treat pediatric type 2 diabetes [Internet]. Silver Spring (MD): FDA; 2023. [cited 2023 Jun 28]. Available from: https://www.fda.gov/news-events/press-announcements/fda-approves-new-class-medicines-treat-pediatric-type-2-diabetes.
2. Cioana M, Deng J, Nadarajah A, Hou M, Qiu Y, Chen SSJ, et al. The prevalence of obesity among children with type 2 diabetes: a systematic review and meta-analysis. JAMA Netw Open 2022;5e2247186.
3. He QX, Zhao L, Tong JS, Liang XY, Li RN, Zhang P, et al. The impact of obesity epidemic on type 2 diabetes in children and adolescents: a systematic review and meta-analysis. Prim Care Diabetes 2022;16:736–44.
4. Phillip M, Mathieu C, Lind M, Araki E, di Bartolo P, Bergenstal R, et al. Long-term efficacy and safety of dapagliflozin in patients with inadequately controlled type 1 diabetes: pooled 52-week outcomes from the DEPICT-1 and -2 studies. Diabetes Obes Metab 2021;23:549–60.
5. Mathieu C, Dandona P, Birkenfeld AL, Hansen TK, Iqbal N, Xu J, et al. Benefit/risk profile of dapagliflozin 5 mg in the DEPICT-1 and -2 trials in individuals with type 1 diabetes and body mass index ≥27 kg/m2. Diabetes Obes Metab 2020;22:2151–60.
6. Dos Santos SS, Ramaldes LA, Gabbay MAL, Moises RCS, Dib SA. Use of a sodium-glucose cotransporter 2 inhibitor, empagliflozin, in a patient with Rabson-Mendenhall syndrome. Horm Res Paediatr 2021;94:313–6.
7. Galderisi A, Tamborlane W, Taylor SI, Attia N, Moretti C, Barbetti F. SGLT2i improves glycemic control in patients with congenital severe insulin resistance. Pediatrics 2022;150e2021055671.
8. Grünert SC, Derks TGJ, Adrian K, Al-Thihli K, Ballhausen D, Bidiuk J, et al. Efficacy and safety of empagliflozin in glycogen storage disease type Ib: Data from an international questionnaire. Genet Med Off J Am Coll Med Genet 2022;24:1781–8.
9. Candler T, McGregor D, Narayan K, Moudiotis C, Burren CP. Improvement in glycaemic parameters using SGLT-2 inhibitor and GLP-1 agonist in combination in an adolescent with diabetes mellitus and Prader-Willi syndrome: a case report. J Pediatr Endocrinol Metab 2020;33:951–5.
10. Newland DM, Law YM, Albers EL, Friedland-Little JM, Ahmed H, Kemna MS, et al. Early clinical experience with dapagliflozin in children with heart failure. Pediatr Cardiol 2023;44:146–52.
11. Cui JY, Liu JJ, Fang XY, Chen J, Zhai YH, Xu H, et al. [Short-term efficacy of dapagliflozin in children with hereditary proteinuric kidney disease]. Zhonghua Er Ke Za Zhi Chin J Pediatr 2023;61:164–8.
12. Higgins JPT, Altman DG, Gøtzsche PC, Jüni P, Moher D, Oxman AD, et al. The Cochrane Collaboration’s tool for assessing risk of bias in randomised trials. BMJ 2011;343:d5928.
13. Dutta D, Bhattacharya S, Surana V, Aggarwal S, Singla R, Khandelwal D, et al. Efficacy and safety of saroglitazar in managing hypertriglyceridemia in type-2 diabetes: a meta-analysis. Diabetes Metab Syndr 2020;14:1759–68.
14. Dutta D, Agarwal A, Maisnam I, Singla R, Khandelwal D, Sharma M. Efficacy and safety of the novel dipeptidyl peptidase-4 inhibitor gemigliptin in the management of type 2 diabetes: a meta-analysis. Endocrinol Metab (Seoul) 2021;36:374–87.
15. Liberati A, Altman DG, Tetzlaff J, Mulrow C, Gøtzsche PC, Ioannidis JPA, et al. The PRISMA statement for reporting systematic reviews and meta-analyses of studies that evaluate healthcare interventions: explanation and elaboration. BMJ 2009;339:b2700.
16. Guyatt GH, Oxman AD, Vist GE, Kunz R, Falck-Ytter Y, Alonso-Coello P, et al. GRADE: an emerging consensus on rating quality of evidence and strength of recommendations. BMJ 2008;336:924–6.
17. Song F, Eastwood AJ, Gilbody S, Duley L, Sutton AJ. Publication and related biases. Health Technol Assess Winch Engl 2000;4:1–115.
18. Laffel LM, Danne T, Klingensmith GJ, Tamborlane WV, Willi S, Zeitler P, et al. Efficacy and safety of the SGLT2 inhibitor empagliflozin versus placebo and the DPP-4 inhibitor linagliptin versus placebo in young people with type 2 diabetes (DINAMO): a multicentre, randomised, double-blind, parallel group, phase 3 trial. Lancet Diabetes Endocrinol 2023;11:169–81.
19. Tamborlane WV, Laffel LM, Shehadeh N, Isganaitis E, Van Name M, Ratnayake J, et al. Efficacy and safety of dapagliflozin in children and young adults with type 2 diabetes: a prospective, multicentre, randomised, parallel group, phase 3 study. Lancet Diabetes Endocrinol 2022;10:341–50.
20. Biester T, Muller I, von dem Berge T, Atlas E, Nimri R, Phillip M, et al. Add-on therapy with dapagliflozin under full closed loop control improves time in range in adolescents and young adults with type 1 diabetes: The DAPADream study. Diabetes Obes Metab 2021;23:599–608.
21. Biester T, Aschemeier B, Fath M, Frey M, Scheerer MF, Kordonouri O, et al. Effects of dapagliflozin on insulin-requirement, glucose excretion and β-hydroxybutyrate levels are not related to baseline HbA1c in youth with type 1 diabetes. Diabetes Obes Metab 2017;19:1635–9.
22. Laffel LMB, Tamborlane WV, Yver A, Simons G, Wu J, Nock V, et al. Pharmacokinetic and pharmacodynamic profile of the sodium-glucose co-transporter-2 inhibitor empagliflozin in young people with Type 2 diabetes: a randomized trial. Diabet Med J Br Diabet Assoc 2018;35:1096–104.
23. Tirucherai GS, LaCreta F, Ismat FA, Tang W, Boulton DW. Pharmacokinetics and pharmacodynamics of dapagliflozin in children and adolescents with type 2 diabetes mellitus. Diabetes Obes Metab 2016;18:678–84.
24. Halligan RK, Dalton RN, Turner C, Lewis KA, Mundy HR. Understanding the role of SGLT2 inhibitors in glycogen storage disease type Ib: the experience of one UK centre. Orphanet J Rare Dis 2022;17:195.
25. Urakami T, Yoshida K, Suzuki J. Efficacy of low-dose dapagliflozin in young people with type 1 diabetes. Intern Med 2023;62:177–86.
26. Kumar P, Srivastava S, Mishra PS, Mooss ET. Prevalence of pre-diabetes/type 2 diabetes among adolescents (10-19 years) and its association with different measures of overweight/obesity in India: a gendered perspective. BMC Endocr Disord 2021;21:146.
27. Wu S, He Y, Wu Y, Ji Y, Hou L, Liu X, et al. Comparative efficacy and safety of glucose-lowering drugs in children and adolescents with type 2 diabetes: a systematic review and network meta-analysis. Front Endocrinol 2022;13:897776.
28. Scirica BM, Braunwald E, Raz I, Cavender MA, Morrow DA, Jarolim P, et al. Heart failure, saxagliptin, and diabetes mel litus : obs er v at ions f rom t he S AVOR- TI MI 53 randomized trial. Circulation 2015;132e198.
29. Ferrannini E, Mark M, Mayoux E. CV Protection in the EMPA-REG OUTCOME Trial: A "Thrifty Substrate" Hypothesis. Diabetes Care 2016;39:1108–14.
30. Urakami T. Treatment strategy for children and adolescents with type 2 diabetes-based on ISPAD Clinical Practice Consensus Guidelines 2022. Clin Pediatr Endocrinol 2023;32:125–36.
31. American Diabetes Association Professional Practice Committee. 14. Children and Adolescents: Standards of Care in Diabetes-2024. Diabetes Care 2024;47 Suppl 1:S258–81.
32. Peña AS, Curran JA, Fuery M, George C, Jefferies CA, Lobley K, et al. Screening, assessment and management of type 2 diabetes mellitus in children and adolescents: Australasian Paediatric Endocrine Group guidelines. Med J Aust 2020;213:30–43.
33. Ong Lopez AMC, Pajimna JAT. Efficacy of sodium glucose cotransporter 2 inhibitors on hepatic fibrosis and steatosis in non-alcoholic fatty liver disease: an updated systematic review and meta-analysis. Sci Rep 2024;14:2122.
34. Cowie MR, Fisher M. SGLT2 inhibitors: mechanisms of cardiovascular benefit beyond glycaemic control. Nat Rev Cardiol 2020;17:761–72.

Article information Continued

Fig. 1.

Flowchart describing study retrieval and inclusion in the meta-analysis. RCT, randomized controlled trial.

Fig. 2.

Forest plot highlighting the impact of SGLT2i as compared to placebo in type 2 diabetes on (A) treatment emergent adverse events; (B) serious adverse events; (C) diabetic ketoacidosis; (D) urinary tract infections; (E) forest plot highlighting the impact of SGLT2i as compared to placebo in type 2 diabetes on HbA1c; (F) forest plot highlighting the impact of SGLT2i as compared to placebo in type 1 diabetes on beta hydroxybutyrate levels. SGLT2i, sodium-glucose cotransporter-2 inhibitors; HbA1c, glycosylated hemoglobin; M-H, Mantel-Haenszel; IV, inverse variance; CI, confidence interval; df, degrees of freedom; SD, standard deviation.

Table 1.

Summary of major randomized controlled trials/cohort studies published on the use of sodium-glucose cotransporter-2 inhibitors in children

Variable Laffel et al. (2023) [18]
Tamborlane et al. (2022) [19]
Biester et al. [20] (2021)
Biester et al. [21] (2017)
Empagliflozin group (n=52) Placebo group (n=53) Dapagliflozin group (n=39) Placebo group (n=33) Dapagliflozin group (n=30) Study group (n=33)
Age (yr) 14.4±1.9 14.6±1.8 16.1±3.3 16.2±3.6 17 (12-20) -
Male sex 19 (37%) 19 (36%) 15 (38%) 14 (42%) -
Disease duration (yr) <1 yr, 33%; 1–3 yr, 40%; >3 yr, 27% <1 yr, 34%; 1–3 yr, 45%; >3 yr, 21% <3 yr, 56%; 3–10 yr, 38%; >10 yr, 5% <3 yr, 56%; 3–10 yr, 38%; >10 yr, 5% 11 (3–18) -
BMI (kg/m2) 35.54±7.17 36.07±10.07 31.3±7.5 33.6±8.8 23 (18–32) -
SBP (mm Hg) 120.23±9.97 118.13±11.85 119.4±12.9 118.2±15.2 - -
DBP (mm Hg) 72.03±8.38 72.22±9.27 73.4±8.8 75.8±7.6 - -
Baseline HbA1c (%) 8.0±1.29 8.05±1.23 7.95±1.59 7.85±1.19 8.40 (6.6–9.9) 5%–7.5%, n=11
 7.5%–9%, n=11
 >9%, n=11
Side effects Any adverse event, 77%; SAE, 2%; DKA, 0% Any adverse event, 64%; SAE, 5%; DKA, 2% Any adverse event, 69%; SAE, 3%; DKA, 0%; hypoglycemia, 28%; UTI, 5% Any adverse event, 58%; SAE, 6%; DKA, 0%; hypoglycemia, 18%; UTI, 3% No SAE, severe hypoglycemia, DKA No SAE; headache dapagliflozin 15% vs. placebo 15.6%; URTI dapagliflozin 9.1% vs. placebo 15.6%

BMI, body mass index; SBP, systolic blood pressure; DBP, diastolic blood pressure; HbA1c, glycosylated hemoglobin; SAE, serious adverse events; DKA, diabetic ketoacidosis; UTI, urinary tract infection; URTI, upper respiratory tract infection.

Table 2.

Summary of major observational/single arm studies published on the use of sodium-glucose cotransporter-2 inhibitors in children

Study No. of patients; clinical condition Intervention Key outcomes Safety
Grünert et al. [8] (2022) 112; GSD Ib; no control group: median age, 12.8 yr (range, 0–38 yr) Empagliflozin 0.35 mg/kg/day 55% Patients previously treated with G-CSF had completely stopped G-CSF; 15 (17%) were able to reduce the dose. Severe hypoglycemia (18%), DKA (1%)
Newland et al. [10] (2023) 30; Heart failure (LVEF<45%); no control group: median age, 12.2 yr (IQR, 6.2–17.5 yr) Dapagliflozin 0.1–0.2 mg/kg once daily (maximum 10 mg) Median follow-up: 130 days (IQR. 76–332 days); LVEF increased from 32% to 37.2% (P=0.006) Symptomatic UTI necessitating antibiotics, 15.8%; hypoglycemia, 0; hypovolemia, 0
Cui et al. [11] (2023) 23; primary proteinuric kidney disease (Alport, Dent’s, FSGS); no control group: age, 10.8±2.9 yr Dapagliflozin 5 mg per day (body weight <30 kg) or 10 mg per day (body weight >30 kg) for 12 wk 24-hr proteinuria decreased from baseline at 12 wk (1.75 [1.46–2.20] g/m2 vs. 1.84 [1.14–2.54] g/m2, P<0.05) Hypoglycemia, 0; SAE, 0
Laffel et al. [22] (2018) 27; T2DM; no control group: age, 10–17 yr 5, 10, 25-mg empagliflozin in 9,8 and 10 participants Adjusted mean decreases in fasting plasma glucose were 0.9 mmol/L (95% CI, -1.7, -1.8, -0.1), 0.9 mmol/L (95% CI, -0.2), and 1.1 mmol/L (95% CI, 0.5) for the 5-, 10-, and 25-mg doses, respectively Hypoglycemia, 0; SAE, 0; mild dehydration, 3.7%
Tirucherai et al. [23] (2016) 24; T2DM; no control group: age, 10–17 yr 2.5, 5, and 10-mg dapagliflozin in 8 participants each Mean FPG concentrations were lower for all dose groups on day 2 (6.9, 6.2, and 6.8 mmol/L for 2.5, 5, and 10-mg groups, respectively SAE, 0; deaths, 0
Urakami et al. [25] (2023) 22; T1DM; no control group: mean age, 25.5±5.1 yr Dapaglifozin 5 mg as an adjunct to insulin therapy After 12 months, glycemic control improved significantly (fasting plasma glucose: -18.7 mg/dL, HbA1c: -0.62%, P<0.001), BMI reduction was significant (-1.7 kg/m2, P<0.001). Insulin dose decreased (-0.17 units/kg, P<0.001) SAE, 0; 1 episode of DKA

GSD, Glycogen storage disease; G-CSF, granulocyte-colony stimulating factor; DKA, diabetic ketoacidosis; LVEF, left ventricular ejection fraction; IQR, interquartile range; UTI, urinary tract infection; FSGS, focal segmental glomerulosclerosis; T2DM, type 2 diabetes mellitus; CI, confidence interval; SAE, severe adverse events; FPG, fasting plasma glucose; T1DM, type 1 diabetes; BMI, body mass index.

Table 3.

Summary of findings of the key outcomes of this metanalysis in children with type 2 diabetes

Outcome Anticipated absolute effects* (95% CI)
Relative effect (95% CI) No. of participants (studies) Certainty of the evidence (GRADE)
Risk with placebo Risk with SGLT2i
Any adverse event 616 per 1,000 740 per 1,000 (599 to 844) OR 1.77 (0.93 to 3.36) 177 (2 RCTs) ⊕⊕⊕⊕
High
Serious adverse events 47 per 1,000 21 per 1,000 (4 to 110) OR 0.45 (0.08 to 2.54) 177 (2 RCTs) ⊕⊕⊕⊕
High
Diabetic ketoacidosis 12 per 1,000 4 per 1,000 (0 to 90) OR 0.33 (0.01 to 8.37) 177 (2 RCTs) ⊕⊕⊕⊕
High
Urinary tract infection 24 per 1,000 53 per 1,000 (10 to 231) OR 2.34 (0.44 to 12.50) 177 (2 RCTs) ⊕⊕⊕⊕
High
Severe hypoglycemia requiring assistance 0 per 1,000 0 per 1,000 (0 to 0) OR 4.47 (0.21 to 96.40) 177 (2 RCTs) ⊕⊕⊕⊕
High

CI, confidence interval; SGLT2i, sodium-glucose contransporter-2 inhibitor; OR, odds ratio; RCT, randomized controlled trial.

*

The risk in the intervention group (and its 95% confidence interval) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI).