The factors predicting glucose and weight response to injectable semaglutide (Ozempic): real-world data from the Association of British Clinical Diabetologists’ audit programme

THOMAS SJ CRABTREE,^1,2,3 KAREN ADAMSON,⁴ ALEX BICKERTON,⁵ ALISON EVANS,⁶ SUZANNE PHILLIPS,⁶ ALISON GALLAGHER,⁷ NIELS LARSEN,² DENNIS BARNES,⁸ KETAN DHATARIYA,^9,10 BENJAMIN CT FIELD,^11,12 ISKANDER IDRIS,^2,3 ROBERT EJ RYDER,¹ on behalf of all ABCD semaglutide audit contributors

Abstract

Background: Previous randomised controlled trials have observed individual differences in response to Glucagon-Like Peptide-1 Receptor Agonists (GLP1RA) according to baseline characteristics such as glycated haemoglobin (HbA_1c) and weight. The Association of British Clinical Diabetologists (ABCD) launched a nationwide UK audit in January 2019 to assess the clinical utility, efficacy and safety of injectable semaglutide in routine practice. The aim of this analysis was to investigate associations between baseline characteristics and HbA_1c and weight reductions with semaglutide in real-world use.

Methods: Data were extracted from the secure online tool and individuals who had baseline and follow-up data available within a defined 6 (3-9) month window were included. Variables were assessed as both continuous variables and categorical variables in a multivariate regression model. Missing data were multiply imputed.

Results: In total, 620 individuals were included. Baseline characteristics: (mean±SD) age was 58.7±10.7 years, HbA_1c 81.6±18.5 mmol/mol (9.5±1.7%), weight 108.2±24.2 kg and body mass index (BMI) 37.6±7.6 kg/m². Median diabetes duration was 11.2 years (IQR 6.6-16) and 50.5% (313/620) of subjects were male. The median follow-up time was 0.5 years. HbA_1c reduced by 14.9 mmol/mol (95% CI 13.5, 16.1) [-1.4% (95% CI - 1.2, -1.5)]; p<0.001; and weight reduced by 4.2kg (95% CI 3.6, 4.8; p<0.001). Higher HbA_1c, younger age and GLP1RA naïvety were associated with larger HbA_1c reduction. Higher baseline weight/BMI and GP1RA naïvety were associated with larger weight reduction.

Conclusion: In this real-world study, baseline HbA_1c and weightwere important predictors of HbA_1c and weight reduction outcomes following initiation of semaglutide in routine clinical practice. Our data mirror existing randomised controlled trial data, but further evidence is being collected over a longer follow-up period.

Br J Diabetes 2023;23:94-100

https://doi.org/10.15277/bjd.2023.418

Key words: Semaglutide, audit, real-world

Introduction

Type 2 diabetes (T2DM) is estimated to affect 3.4 million people in England and 537 million worldwide.^1,2 It is increasingly recognised as a heterogenous condition.^3-5 Individuals with different clinical phenotypes may have different responses to the range of therapies currently available and there is increasing interest in utilising precision medicine approaches to stratify individuals towards the best treatment option for them.^6,7 Whilst work is ongoing to identify potential biomarkers and genetic factors, their cost may prohibit their wide use in public-funded healthcare systems.⁸ Routinely measured clinical data may be useful to stratify individuals, identifying those who are most likely to benefit from a given treatment, though evidence in this area is remains limited.⁵

Glucagon-like peptide 1 receptor agonists (GLP1RAs) are increasingly used in the management of T2DM, with greater emphasis on their use in recent national and international guidelines.^9-11 Semaglutide is a once-weekly injectable GLP1RA licensed for the treatment of T2DM; it is also available as a once- daily oral preparation.¹²

The SUSTAIN series of randomised controlled trials consistently demonstrated efficacy of semaglutide, with mean weight loss of 4.11 kg and HbA_1c reductions of 15 mmol/mol at the maximally titrated 1mg dose when results were pooled by meta-analysis.¹³ Reductions in major adverse cardiovascular events have also been reported across the trials.^14,15 Although SUSTAIN-6 reported increased rates of retinopathy, these findings were not observed across the trials by meta-analysis.^16,17 However, the trials included were of relatively short duration: work is ongoing to understand retinopathy risk with more prolonged follow-up.¹⁸

Several trials reported no difference in HbA_1c and weight response to semaglutide across individuals with different baseline clinical characteristics,¹⁹ but two reported differential responses across baseline characteristics. First, SUSTAIN-8 demonstrated larger HbA_1c reductions in individuals with higher baseline BMI and HbA_1c levels.²⁰ Second, real-world evidence from an Italian clinic found HbA_1c reductions were greatest at six months in individuals with higher baseline HbA_1c, greater weight loss and longer diabetes duration.²¹ This latter study also found that higher baseline BMI predicted greater weight loss and that GLP1RA-naïve individuals reached similar end-points to those switching from alternative GLP1Ras. Previous Association of British Clinical Diabetologists (ABCD) audit programme has also reported the additional benefits of switching to semaglutide from alternative GLP1RA preparations.²² Only minor differences have been observed in terms of race or ethnicity across the SUSTAIN trails.²³

The nationwide ABCD injectable semaglutide audit was launched in January 2019 with the aim to collect routine clinical data on individuals using semaglutide in the UK and to assess outcomes in real-world clinical practice. The aim of this analysis was to assess the clinical characteristics which may predict HbA_1c and weight responses associated with semaglutide in the real world, using data from the ABCD audit.

Methods

Participating centres were invited to collect anonymised, routinely collected, clinical data on individuals commenced on injectable semaglutide (0.25-1 mg, Ozempic) to a secure online tool. De-identified data were then extracted for analysis in this cohort study. All individuals with baseline data and at least one follow-up entry for HbA_1c and/or weight were included. Individuals with large amounts of missing data in key covariates of imputation (e.g. age, gender) were excluded (n=14). The follow-up period was defined as 6 months, with a window of 3- 9 months. Key co-variates were identified as follows: baseline HbA_1c, baseline weight, age, gender, duration of diabetes and previous GLP1RA use. Ethnicity could not be assessed due to missing data. For all other variables, missing data were multiply imputed with 10 imputations, and Rubin’s rules were applied for the analysis.²⁴

HbA_1c and both absolute and relative weight change from baseline were assessed using a multivariate linear regression analysis incorporating the above characteristics into the model as continuous covariates. The overall model co-efficient and significance levels were also calculated and reported. Subgroup analyses were then performed by classifying these characteristics into groups as follow:

• Age – <60 years; ≥60 years
• Gender
• Duration of diabetes – <10 years; ≥10 years
• HbA_1c – 48-64 mmol/mol [6.5-8%]; 64.1-80 mmol/mol [8-9.5%]; >80 mmol/mol [>9.5%]
• BMI – <30 kg/m²; 30-40 kg/m²; >40 kg/m²
• Previous GLP1RA use

Statistical significance was defined as p<0.05. When including multiple groups pairwise comparisons were adjusted for multiple comparisons using a Bonferroni correction. All analyses were performed in Stata 16.

The ABCD audit programme is approved by the Confidentiality Advisory Group and a Caldicott Guardian.²⁵

Results

In total 620 individuals were included in this analysis. The flow diagram for inclusion in this analysis is available in Appendix 1. The baseline characteristics are summarised in table 1.

Over a median follow-up time of 0.5 years (0.4-0.7), across the entire population HbA_1c reduced by 14.9 mmol/mol (95% CI 13.5, 16.1; p<0.001) [-1.4% (95%CI -1.2, -1.5)]. Absolute weight reductions of 4.2kg (95% CI 3.6-4.8; p<0.001) and relative weight reductions of 3.9% (95% CI 3.4-4.5%; p<0.001) were observed.

The models and coefficients calculated for baseline characteristics when used in continuous data format are displayed in table 2. The coefficients represent the difference in HbA_1c reduction per-one unit change in the covariate assessed (for continuous values) or compared to reference (for categorical i.e. GLP1RA-naïve vs previous GLP1RA use). Baseline HbA_1c, baseline weight and previous GLP1RA use were significant predictors of HbA_1c response to injectable semaglutide. Those with high baseline HbA_1c levels had greater HbA_1c reductions, and those switching from an alternative GLP1RA to semaglutide had attenuated HbA_1c reductions.

Only baseline weight significantly predicted weight loss response to semaglutide, although previous GLP1RA use was trending towards statistical significance. Those with higher weight at baseline lost more weight in association with injectable semaglutide use. For relative weight change, no factors predicted weight loss in response to semaglutide.

The change in HbA_1c from baseline in the subgroup analysis is demonstrated in figure 1. Those with HbA_1c ≥80 mmol/mol (9.5%) had larger HbA_1c reductions than those in the lower HbA_1c groups, and those switched from alternative GLP1RA drugs had a smaller HbA_1c reduction than GLP1RA- naïve individuals. This persisted for relative HbA_1c changes, although we have not reported these as we considered they would not be clinically meaningful. In addition, individuals aged <60 years had greater HbA_1c reductions than those aged ≥60 years.

The change in absolute weight from baseline in the subgroup analysis is demonstrated in figure 2. Those with BMI >40 kg/m² at baseline had larger weight reductions associated with semaglutide than those with BMI 30-40 kg/m² at baseline but not those with BMI <30 kg/m². Those who switched to semaglutide from an alternative GLP1RA were experienced less weight loss than GLP1RA-naïve individuals. The relative change in weight from baseline is demonstrated in figure 3. No statistically significant differences were noted between subgroups.

Discussion

Our results from the ABCD audit programme demonstrate that HbA_1c and both absolute and relative weight reductions with injectable semaglutide translate evidence from randomised controlled trials into real-world clinical practice.

The HbA_1c and weight reductions observed were comparable to those in the SUSTAIN trials.^13,20 Additionally, our results mirrored the findings from SUSTAIN-8 in that those with higher HbA_1c and weight baseline achieved larger reductions by follow-up.²⁰ There was no significant difference noted between individuals with BMI <30 kg/m² and those with BMI >40 kg/m² .This is likely due to relatively small numbers in the lowest BMI group (n=74).

We did not observe any difference in response across different diabetes durations, in contrast to reports from SUSTAIN-8 and the real-world Italian study highlighted in the introduction.^20,21 We report similar observations to SUSTAIN-8, with a statistically significant impact of baseline weight on HbA_1c change, with heavier individuals achieving statistically larger reductions.²⁰ It should be noted, however, that the coefficient for this is small, and therefore unlikely to be clinically meaningful. The difference across weight did not persist within the subgroup analysis.

GLP1RA-naïve individuals had larger HbA_1c and weight reductions than those switching from other GLP1RA medications, although reductions were observed in both groups. This is a finding we have reported previously and that was reported in SUSTAIN-8.^20,22

Strengths and limitations
The pragmatic real-world study design allows us to observe the use of injectable semaglutide in clinical practice and compare findings in this population to existing RCT data. Our findings confirm that trial results can be generalised to UK clinical practice, despite clinical practice including individuals who are less closely monitored or who perhaps have more extreme baseline characteristics and would therefore have been excluded from trials. In our analysis, baseline HbA_1c (81.6 vs 67.2 mmol/mol in SUSTAIN-8) and weight (108 kg vs 90.6 kg in SUSTAIN-8) were higher, and diabetes duration (11.2 years vs 7.5 years in SUSTAIN-8) was longer than in clinical trials. If drug shortages persist these data may help in guiding who may benefit the most from semaglutide.²⁶

Real-world data have their limitations. Although the use of multiple imputations may mitigate problems caused by missing data, it does not resolve this completely. Nonetheless, we excluded individuals with high levels of missing data in key covariates. Notably, dose data were not available. Although it is assumed that individuals were maximally titrated, assessment or adjustment for doses was not possible. Additionally, unobserved confounders may impact the results but we are reassured that our findings complement and mirror the existing extensive data on semaglutide well. Ethnicity and deprivation data were not available and further work should focus on uptake and outcomes in these key groups to assess real-world equitability.

Conclusion

In this real-world analysis from the ABCD audit programme, injectable semaglutide was associated with greater HbA_1c reduction in those who were younger, vs. older, and in those who had higher, vs. lower, baseline HbA_1c. Weight reductions were largest in those who weighed most at baseline. Whilst reductions in weight and HbA_1c were observed in individuals switching to semaglutide from other members of the GLP1RA class, these were smaller than in GLP1RA-naïve individuals. Data collection for the ABCD audit is ongoing, and further follow-up will allow us to assess the impact of semaglutide on key outcomes in the long term.

Conflict of interest TSJC has received speaker fees and/or support to attend conferences from NovoNordisk, Lilly, Sanofi, Abbott Diabetes Care, Insulet and Dexcom.

Funding The ABCD audit programme is an independent audit programme supported by an unrestricted grant from NovoNordisk.

Ethics statement This study utilises data from a clinic audit and was assessed against health regulatory authority criteria. No ethical approvals were required for this analysis.

References

1. International Diabetes Federation. Diabetes Atlas, 2023. Accessed 27/06/2023. Available from: https://diabetesatlas.org/
2. Ong KL, Stafford LK, McLaughlin SA, et al; GBD 2021 Diabetes Collaborators. Global, regional, and national burden of diabetes from 1990 to 2021, with projections of prevalence to 2050: a systematic analysis for the Global Burden of Disease Study 2021. Lancet 2023;402:203-34. https://doi.org/10.1016/S0140-6736(23)01301-6
3. NHS Digital. National Diabetes Audit Core Report 1: Target 2021-22. 2023 [cited 2023 05/01/2022]; Available from: https://digital.nhs.uk/data-and-information/publications/statistical/national-diabetes-audit/nda-core-21-22/nda-core-21-22-data.
4. Ahlqvist E, Storm P, Karajamaki A, et al. Novel subgroups of adult- onset diabetes and their association with outcomes: a data-driven cluster analysis of six variables. Lancet Diabetes Endocrinol 2018; 6(5):361-9. https://doi.org/10.1016/S221308587(18)30051-2
5. Misra S, Wagner R, Ozkan B, et al. Systematic review of precision subclassification of type 2 diabetes. medRxiv https://doi.org/2023.04.19.23288577.
6. Dennis JM. Precision medicine in type 2 diabetes: using individualized prediction models to optimize selection of treatment. Diabetes 2020;69:2075-85. https://doi.org/10.2337/dbi20-0002
7. Dennis JM, Shields BM, Henley WE, et al. Disease progression and treatment response in data-driven subgroups of type 2 diabetes compared with models based on simple clinical features: an analysis using clinical trial data. Lancet Diabetes Endocrinol 2019;7(6):442-51. https://doi.org/10.1016/S2213-8587(19)30087-7
8. Malandrino N, Smith RJ. Personalized medicine in diabetes. Clinical Chemistry 2011;57(2):231-40. https://doi.org/10.1373/clinchem.2010.156901
9. National Institute for Health and Care Excellence. Type 2 diabetes in adults: management. NICE guideline 28 2015, updated 2022.
10. National institute for Health and Care Excellence. NG28 Patient Decision Aid on type 2 diabetes, 2022 [cited 2023 16/01/2023]; Available from: https://www.nice.org.uk/guidance/ng28/resources/patient-decision-aid-pdf-2187281198
11. Davies MJ, Aroda VR, Collins BS, et al. Management of hyperglycemia in type 2 diabetes, 2022. A consensus report by the American Diabetes Association (ADA) and the European Association for the Study of Diabetes (EASD). Diabetes Care 2022;45(11):2753-86. https://doi.org/10.2337/dci22-0034
12. Anderson SL, Beutel TR, Trujillo JM. Oral semaglutide in type 2 diabetes. J Diabetes Complications 2020;34(4):107520. https://doi.org/10.1016/j.jdiacomp.2019.107520
13. Andreadis P, Karagiannis T, Malandris k, et al. Semaglutide for type 2 diabetes mellitus: a systematic review and meta-analysis. Diabetes, Obes Metab 2018;20(9):2255-63. https://doi.org/10.1111/dom.13361
14. Husain M, Bain SC, Holst AG, et al. Effects of semaglutide on risk of cardiovascular events across a continuum of cardiovascular risk: combined post hoc analysis of the SUSTAIN and PIONEER trials. Cardiovasc Diabetol 2020;19(1):156. https://doi.org/10.1186/s12933-01106-4
15. Husain M, Bain SC, Jeppesen OK, et al. Semaglutide (SUSTAIN and PIONEER) reduces cardiovascular events in type 2 diabetes across varying cardiovascular risk. Diabetes Obes Metab 2020;22(3):442-51. https://doi.org/10.1111/dom.13955
16. Marso SP, Bain SC, Consoli A, et al. Semaglutide and cardiovascular outcomes in patients with type 2 diabetes. New Engl J Med 2016; 375(19):1834-44. https://doi.org/10.1056/NEJMoa1607141
17. Wang F, Mao Y, Wang H, et al. Semaglutide and diabetic retinopathy risk in patients with type 2 diabetes mellitus: a meta-analysis of randomized controlled trials. Clin Drug Investig 2022;42:17-28. https://doi.org/10.1007/s40261-021-01110-w
18. Health Research Authority. FOCUS – semaglutide effect on diabetic retinopathy, 2023. Accessed 04/07/2023. Available from: https://hra.nhs.uk/planning-and-improving-research/application-summaries/research-summaries/focus-semaglutide-effect-on-diabetic-retinopathy/
19. Davies M, Pieber TR, Hartoft-Nielsen M-L, et al. Effect of oral semaglutide compared with placebo and subcutaneous semaglutide on glycemic control in patients with type 2 diabetes: a randomized clinical trial. JAMA 2017318(15):1460-70. https://doi.org/10.1001/jama.2017.14752
20. Lingvay I, Catarig A-M, Frias JP, et al. Efficacy and safety of once- weekly semaglutide versus daily canagliflozin as add-on to metformin in patients with type 2 diabetes (SUSTAIN 8): a double-blind, phase 3b, randomised controlled trial. Lancet Diabetes Endocrinol 2019; 7(11):834-44. https://doi.org/10.1016/S2213-8587(19)30311-0
21. Marzullo P, Daffara T, Mele C, et al. Real-world evaluation of weekly subcutaneous treatment with semaglutide in a cohort of Italian diabetic patients. J Endocrinol Invest 2022;45(8):1587-98. https://doi.org/10.1007/s40618-022-01799-2
22. Crabtree TSJ, Adamson K, Reid H, et al. Injectable semaglutide and reductions in HbA_1c and weight in the real world in people switched from alternative glucagon-like peptide-1 receptor agonists. Diabetes Obes Metab 2022;24(7):1398-401. https://doi.org/10.1111/dom.14701
23. DeSouza C, Cariou B, Garg S, et al. Efficacy and safety of semaglutide for type 2 diabetes by race and ethnicity: a post hoc analysis of the SUSTAIN trials. The Journal of Clinical Endocrinology & Metabolism 2020;105(2):543-56. https://doi.org/10.1210/clinem/dgz072
24. Marshall A, Altman DG, Holder RL, et al. Combining estimates of interest in prognostic modelling studies after multiple imputation: current practice and guidelines. BMC Med Res Methodology 2009; 9:57. https://doi.org/10.1186/1471-2288-9-57
25. Health Research Authority. Confidentiality Advisory Group. 2021 [cited 2022 02/03/2022]. Available from: https://www.hra.nhs.uk/approvals-amendments/what-approvals-do-i-need/confidentiality-advisory-group/
26. Department of Health and Social Care, Medicines Supply Notification – MSN/2022/08 Semaglutide (Ozempic^®) 1mg/0.74ml solution for injection 3ml pre-filled disposable device 2022: gov.uk

Appendix 1. Flow diagram for numbers included in this analysis