Dapagliflozin's impact on hormonal regulation and ketogenesis in type 1 diabetes: a randomised controlled crossover trial.
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BORIS DOI
Publisher DOI
PubMed ID
40629004
Description
Aims/hypothesis
This study aimed to assess the impact of adding dapagliflozin to insulin therapy on key hormonal determinants of glucose regulation and ketogenesis. We hypothesise that dapagliflozin increases glucagon-like peptide 1 (GLP-1), glucagon and ketone body concentrations, based on the results of a pilot study.Methods
The study was designed as a randomised, placebo-controlled, open-label, crossover intervention study with two periods (dapagliflozin and placebo intake), including patients of the Department of Diabetes, Endocrinology, Clinical Nutrition & Metabolism, Inselspital, Bern University Hospital, University of Bern. Individuals with type 1 diabetes (C-peptide concentrations <0.1 nmol/l) with a duration >5 years and a BMI of 20-29 kg/m2 were included. They received 10 mg of dapagliflozin or placebo daily for 7 days throughout two independent treatment periods, separated by a 14 day washout period. Allocation was done by a computed randomisation tool (REDCap), without blinding of the participants or the investigators. On day 7 of each treatment period, hyperinsulinaemic-euglycaemic clamps (HECs) and OGTT clamps (OGTTCs) were performed to assess changes in the secretion of GLP-1, glucagon, somatostatin and total ketone bodies. The objective was to evaluate the effects of adding the sodium-glucose cotransporter 2 (SGLT2) inhibitor dapagliflozin to insulin therapy on GLP-1 during OGTTC (primary endpoint), GLP-1 secretion during HEC, and glucagon, somatostatin and ketogenesis during OGTTC and HEC (secondary endpoints). The primary endpoint was concentrations of GLP-1 during OGTTC. Secondary endpoints included GLP-1 during HEC and glucagon, somatostatin and ketone body concentrations during OGTTC and HEC.Results
A total of 13 individuals with type 1 diabetes were included and randomised. All of them received dapagliflozin and placebo, finished the sequences per protocol and were analysed per protocol. GLP-1 concentrations did not differ significantly between treatments in the OGTTC (median [IQR] dapagliflozin 192.8 [129.8-257.2] pmol/l vs placebo 176.3 [138.4-227.4] pmol/l; p=0.7) or HEC (median [IQR] dapagliflozin 208.6 [133.6-294.0] pmol/l vs placebo 203.1 [150.2-291.8] pmol/l; p=0.7). Glucagon concentrations did not significantly differ between treatments in the OGTTC (median [IQR] dapagliflozin 1.54 [0.84-3.68] ng/l vs placebo 1.54 [0.82-4.64] ng/l; p=0.8) or HEC (median [IQR] dapagliflozin 1.59 [0.87-3.54] ng/l vs placebo 1.63 [0.91-3.96] ng/l; p=0.3). Somatostatin concentrations remained comparable between treatments during the HEC (median [IQR] dapagliflozin 41.1 [26.8-73.8] pmol/l vs placebo 47.0 [23.0-77.6] pmol/l; p=0.2) and OGTTC (median [IQR] dapagliflozin 51.1 [31.1-77.0] pmol/l vs placebo 45.3 [30.0-70.5] pmol/l; p=0.2). Plasma ketone bodies were higher with dapagliflozin during the HEC (median [IQR] dapagliflozin 0.15 [0.04-0.47] mmol/l vs placebo 0.03 [0.01-0.12] mmol/l; p<0.001) and OGTTC (median [IQR] dapagliflozin 0.10 [0.03-0.22] mmol/l vs placebo 0.03 [0.01-0.12] mmol/l; p<0.001).Conclusions/interpretation
Short-term dapagliflozin treatment in type 1 diabetes increases plasma ketone concentrations without affecting the secretion of GLP-1, glucagon or somatostatin. Higher ketone body concentrations highlight the elevated risk of diabetic ketoacidosis associated with the adjunct intake of dapagliflozin.Trial Registration
ClinicalTrials.gov NCT04035031.Funding
Swiss National Science Foundation, project number 32003B_185019.
This study aimed to assess the impact of adding dapagliflozin to insulin therapy on key hormonal determinants of glucose regulation and ketogenesis. We hypothesise that dapagliflozin increases glucagon-like peptide 1 (GLP-1), glucagon and ketone body concentrations, based on the results of a pilot study.Methods
The study was designed as a randomised, placebo-controlled, open-label, crossover intervention study with two periods (dapagliflozin and placebo intake), including patients of the Department of Diabetes, Endocrinology, Clinical Nutrition & Metabolism, Inselspital, Bern University Hospital, University of Bern. Individuals with type 1 diabetes (C-peptide concentrations <0.1 nmol/l) with a duration >5 years and a BMI of 20-29 kg/m2 were included. They received 10 mg of dapagliflozin or placebo daily for 7 days throughout two independent treatment periods, separated by a 14 day washout period. Allocation was done by a computed randomisation tool (REDCap), without blinding of the participants or the investigators. On day 7 of each treatment period, hyperinsulinaemic-euglycaemic clamps (HECs) and OGTT clamps (OGTTCs) were performed to assess changes in the secretion of GLP-1, glucagon, somatostatin and total ketone bodies. The objective was to evaluate the effects of adding the sodium-glucose cotransporter 2 (SGLT2) inhibitor dapagliflozin to insulin therapy on GLP-1 during OGTTC (primary endpoint), GLP-1 secretion during HEC, and glucagon, somatostatin and ketogenesis during OGTTC and HEC (secondary endpoints). The primary endpoint was concentrations of GLP-1 during OGTTC. Secondary endpoints included GLP-1 during HEC and glucagon, somatostatin and ketone body concentrations during OGTTC and HEC.Results
A total of 13 individuals with type 1 diabetes were included and randomised. All of them received dapagliflozin and placebo, finished the sequences per protocol and were analysed per protocol. GLP-1 concentrations did not differ significantly between treatments in the OGTTC (median [IQR] dapagliflozin 192.8 [129.8-257.2] pmol/l vs placebo 176.3 [138.4-227.4] pmol/l; p=0.7) or HEC (median [IQR] dapagliflozin 208.6 [133.6-294.0] pmol/l vs placebo 203.1 [150.2-291.8] pmol/l; p=0.7). Glucagon concentrations did not significantly differ between treatments in the OGTTC (median [IQR] dapagliflozin 1.54 [0.84-3.68] ng/l vs placebo 1.54 [0.82-4.64] ng/l; p=0.8) or HEC (median [IQR] dapagliflozin 1.59 [0.87-3.54] ng/l vs placebo 1.63 [0.91-3.96] ng/l; p=0.3). Somatostatin concentrations remained comparable between treatments during the HEC (median [IQR] dapagliflozin 41.1 [26.8-73.8] pmol/l vs placebo 47.0 [23.0-77.6] pmol/l; p=0.2) and OGTTC (median [IQR] dapagliflozin 51.1 [31.1-77.0] pmol/l vs placebo 45.3 [30.0-70.5] pmol/l; p=0.2). Plasma ketone bodies were higher with dapagliflozin during the HEC (median [IQR] dapagliflozin 0.15 [0.04-0.47] mmol/l vs placebo 0.03 [0.01-0.12] mmol/l; p<0.001) and OGTTC (median [IQR] dapagliflozin 0.10 [0.03-0.22] mmol/l vs placebo 0.03 [0.01-0.12] mmol/l; p<0.001).Conclusions/interpretation
Short-term dapagliflozin treatment in type 1 diabetes increases plasma ketone concentrations without affecting the secretion of GLP-1, glucagon or somatostatin. Higher ketone body concentrations highlight the elevated risk of diabetic ketoacidosis associated with the adjunct intake of dapagliflozin.Trial Registration
ClinicalTrials.gov NCT04035031.Funding
Swiss National Science Foundation, project number 32003B_185019.
Date of Publication
2025-10
Publication Type
Article
Subject(s)
600 - Technology::610 - Medicine & health
Keyword(s)
Dapagliflozin
•
Diabetic ketoacidosis
•
GLP-1
•
Glucagon
•
Ketogenesis
•
Somatostatin
•
Type 1 diabetes
Language(s)
en
Contributor(s)
Additional Credits
Department of Clinical Research (DCR)
Institute of Clinical Chemistry
University Clinic for Diabetes, Endocrinology, Clinical Nutrition and Metabolism (UDEM)
Series
Diabetologia
Publisher
Springer
ISSN
1432-0428
0012-186X
Access(Rights)
open.access