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Abstract

Objective:

To predict hypoglycemia and hyperglycemia risk during and after activity for adolescents with type 1 diabetes (T1D) using real-world data from the Type 1 Diabetes Exercise Initiative Pediatric (T1DEXIP) study.

Methods:

Adolescents with T1D (n = 225; [mean ± SD] age = 14 ± 2 years; HbA1c = 7.1 ± 1.3%; T1D duration = 5 ± 4 years; 56% using hybrid closed loop), wearing continuous glucose monitors (CGMs), logged 3738 total activities over 10 days. Repeated Measures Random Forest (RMRF) and Repeated Measures Logistic Regression (RMLR) models were used to predict a composite risk of hypoglycemia (<70 mg/dL) and hyperglycemia (>250 mg/dL) within 2 h after starting exercise.

Results:

RMRF achieved high precision predicting composite risk and was more accurate than RMLR Area under the receiver operating characteristic curve (AUROC 0.737 vs. 0.661; P < 0.001). Activities with minimal composite risk had a starting glucose between 132 and 160 mg/dL and a glucose rate of change at activity start between −0.4 and −1.9 mg/dL/min. Time <70 mg/dL and time >250 mg/dL during the prior 24 h, HbA1c level, and insulin on board at activity start were also predictive. Separate models explored factors at the end of activity; activities with glucose between 128 and 133 mg/dL and glucose rate of change between 0.4 and −0.6 mg/dL/min had minimal composite risk.

Conclusions:

Physically active adolescents with T1D should aim to start exercise with an interstitial glucose between 130 and 160 mg/dL with a flat or slightly decreasing CGM trend to minimize risk for developing dysglycemia. Incorporating factors such as historical glucose and insulin can improve prediction modeling for the acute glucose responses to exercise.

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References

Adolfsson

, Taplin

, Zaharieva

, et al. ISPAD clinical practice consensus guidelines 2022: Exercise in children and adolescents with diabetes. Pediatr Diabetes, 2022; 23(8):1341–1372; doi: 10.1111/pedi.13452

Tansey

, Tsalikian

, Beck

, et al. The effects of aerobic exercise on glucose and counterregulatory hormone concentrations in children with type 1 diabetes. Diabetes Care, 2006; 29(1):20–25; doi: 29/1/20[pii]

Costing the quality of life. Br J Hosp Med, 1988; 40(2):147.

Riddell

, Li

, Gal

, et al. T1DEXI Study Group. Examining the acute glycemic effects of different types of structured exercise sessions in type 1 diabetes in a real-world setting: The type 1 diabetes and exercise initiative (t1dexi). Diabetes Care, 2023; 46(4):704–713; doi: 10.2337/dc22-1721

Thomas

, Pretty

, Desaive

, Chase

. Blood glucose levels of subelite athletes during 6 days of free living. J Diabetes Sci Technol, 2016; 10(6):1335–1343; doi: 10.1177/1932296816648344

Riddell

, Gal

, Bergford

, et al. The acute effects of real-world physical activity on glycemia in adolescents with type 1 diabetes: The type 1 diabetes exercise initiative pediatric (T1DEXIP) study. Diabetes Care, 2023; 47(1):132–139; doi: 10.2337/dc23-1548

Taylor

, Smith

, Capper

, et al. Postexercise glycemic control in type 1 diabetes is associated with residual β-cell function. Diabetes Care, 2020; 43(10):2362–2370; doi: 10.2337/dc20-0300

Temple

, Bar-Or

, Riddell

. The reliability and repeatability of the blood glucose response to prolonged exercise in adolescent boys with IDDM. Diabetes Care, 1995; 18(3):326–332; doi: 10.2337/diacare.18.3.326

Chetty

, Shetty

, Fournier

, et al. Exercise management for young people with type 1 diabetes: A structured approach to the exercise consultation. Front Endocrinol (Lausanne), 2019; 10:326; doi: 10.3389/fendo.2019.00326

10.

Roberts

, Yi-Frazier

, Aitken

, et al. Do youth with type 1 diabetes exercise safely? A focus on patient practices and glycemic outcomes. Pediatr Diabetes, 2017; 18(5):367–375; doi: 10.1111/pedi.12402

11.

Sherr

, Bergford

, Gal

, et al. Exploring factors that influence postexercise glycemia in youth with type 1 diabetes in the real world: The Type 1 Diabetes Exercise Initiative Pediatric study (T1DEXIP). Diabetes Care, 2024; 47(5):849–857; doi: 10.2337/dc23-2212

12.

Tsalikian

, Kollman

, Tamborlane

, et al. Prevention of hypoglycemia during exercise in children with type 1 diabetes by suspending basal insulin. Diabetes Care, 2006; 29(10):2200–2204; doi: 10.2337/dc06-0495

13.

Hobbs

, Hajizadeh

, Rashid

, et al. Improving glucose prediction accuracy in physically active adolescents with type 1 diabetes. J Diabetes Sci Technol, 2019; 13(4):718–727; doi: 10.1177/1932296818820550

14.

Abraham

, Davey

, O’Grady

, et al. Effectiveness of a predictive algorithm in the prevention of exercise-induced hypoglycemia in type 1 diabetes. Diabetes Technol Ther, 2016; 18(9):543–550; doi: 10.1089/dia.2016.0141

15.

DeBoer

, Cherñavvsky

, Topchyan

, et al. Heart rate informed artificial pancreas system enhances glycemic control during exercise in adolescents with t1d. Pediatr Diabetes, 2017; 18(7):540–546; doi: 10.1111/pedi.12454

16.

Reddy

, Resalat

, Wilson

, et al. Prediction of hypoglycemia during aerobic exercise in adults with type 1 diabetes. J Diabetes Sci Technol, 2019; 13(5):919–927; doi: 10.1177/1932296818823792

17.

Prasanna

, Barua

, Siller

, et al. Hypoglycemia risk with physical activity in type 1 diabetes: A data-driven approach. Front Digit Health, 2023; 5:1142021; doi: 10.3389/fdgth.2023.1142021

18.

Bergford

, Riddell

, Jacobs

, et al. The type 1 diabetes and exercise initiative: Predicting hypoglycemia risk during exercise for participants with type 1 diabetes using repeated measures random forest. Diabetes Technol Ther, 2023; 25(9):602–611; doi: 10.1089/dia.2023.0140

19.

Breiman

. Random forest. Machine Learning, 2001; 45(1):5–32; doi: 10.1023/A:1010933404324

20.

Calhoun

, Levine

, Fan

. Repeated measures random forests (rmrf): Identifying factors associated with nocturnal hypoglycemia. Biometrics, 2021; 77(1):343–351; doi: 10.1111/biom.13284

21.

Moser

, Riddell

, Eckstein

, et al. Glucose management for exercise using continuous glucose monitoring (CGM) and intermittently scanned CGM (ISCGM) systems in type 1 diabetes: Position statement of the european association for the study of diabetes (EASD) and of the international society for pediatric and adolescent diabetes (ISPAD) endorsed by JDRF and supported by the American Diabetes Association (ADA). Diabetologia, 2020; 63(12):2501–2520; doi: 10.1007/s00125-020-05263-9

22.

Midroni

, Leimbigler

, Baruah

, et al. Predicting glycemia in type 1 diabetes patients: Experiments with XGBoost. Paper presented at: Proceedings of the 3rd International Workshop on Knowledge Discovery in Healthcare Data, 2018.

23.

Ben Brahim

, Place

, Renard

, Breton

. Identification of main factors explaining glucose dynamics during and immediately after moderate exercise in patients with type 1 diabetes. J Diabetes Sci Technol, 2015; 9(6):1185–1191; doi: 10.1177/1932296815607864

24.

Cichosz

, Jensen

, Olesen

. Development and validation of a machine learning model to predict weekly risk of hypoglycemia in patients with type 1 diabetes based on continuous glucose monitoring. Diabetes Technol Ther, 2024; doi: 10.1089/dia.2023.0532

25.

Riddell

, Milliken

. Preventing exercise-induced hypoglycemia in type 1 diabetes using real-time continuous glucose monitoring and a new carbohydrate intake algorithm: An observational field study. Diabetes Technol Ther, 2011; 13(8):819–825; doi: 10.1089/dia.2011.0052

26.

Delvecchio

, Zecchino

, Salzano

, et al. Effects of moderate-severe exercise on blood glucose in type 1 diabetic adolescents treated with insulin pump or glargine insulin. J Endocrinol Invest, 2009; 32(6):519–524; doi: 10.1007/bf03346499

27.

Riddell

, Zaharieva

, Tansey

, et al. Individual glucose responses to prolonged moderate intensity aerobic exercise in adolescents with type 1 diabetes: The higher they start, the harder they fall. Pediatr Diabetes, 2019; 20(1):99–106; doi: 10.1111/pedi.12799

28.

Miller

, Beck

, Foster

, Maahs

. Hba1c levels in type 1 diabetes from early childhood to older adults: A deeper dive into the influence of technology and socio-economic status on hba1c in the t1d exchange clinic registry findings. Diabetes Technol Ther, 2020; 22(9):645–650; doi: 10.1089/dia.2019.0393

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Predicting Hypoglycemia and Hyperglycemia Risk During and After Activity for Adolescents with Type 1 Diabetes

Abstract

Objective:

Methods:

Results:

Conclusions:

Get full access to this article

References

Supplementary Material