【 摘 要 】

Background

Our purpose was to develop and test a predictive model of the acute glucose response to exercise in individuals with type 2 diabetes.

Design and methods

Data from three previous exercise studies (56 subjects, 488 exercise sessions) were combined and used as a development dataset. A mixed-effects Least Absolute Shrinkage Selection Operator (LASSO) was used to select predictors among 12 potential predictors. Tests of the relative importance of each predictor were conducted using the Lindemann Merenda and Gold (LMG) algorithm. Model structure was tested using likelihood ratio tests. Model accuracy in the development dataset was assessed by leave-one-out cross-validation.

Prospectively captured data (47 individuals, 436 sessions) was used as a test dataset. Model accuracy was calculated as the percentage of predictions within measurement error. Overall model utility was assessed as the number of subjects with ≤1 model error after the third exercise session. Model accuracy across individuals was assessed graphically. In a post-hoc analysis, a mixed-effects logistic regression tested the association of individuals’ attributes with model error.

Results

Minutes since eating, a non-linear transformation of minutes since eating, post-prandial state, hemoglobin A1c, sulfonylurea status, age, and exercise session number were identified as novel predictors. Minutes since eating, its transformations, and hemoglobin A1c combined to account for 19.6% of the variance in glucose response. Sulfonylurea status, age, and exercise session each accounted for <1.0% of the variance. In the development dataset, a model with random slopes for pre-exercise glucose improved fit over a model with random intercepts only (likelihood ratio 34.5, p < 0.001). Cross-validated model accuracy was 83.3%.

In the test dataset, overall accuracy was 80.2%. The model was more accurate in pre-prandial than postprandial exercise (83.6% vs. 74.5% accuracy respectively). 31/47 subjects had ≤1 model error after the third exercise session. Model error varied across individuals and was weakly associated with within-subject variability in pre-exercise glucose (Odds ratio 1.49, 95% Confidence interval 1.23-1.75).

Conclusions

The preliminary development and test of a predictive model of acute glucose response to exercise is presented. Further work to improve this model is discussed.

【 授权许可】

   
2013 Gibson et al.; licensee BioMed Central Ltd.

【 预 览 】

附件列表

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【 图 表 】

【 参考文献 】

• [1]Rogers M: Acute effect of exercise on glucose tolerance in non-insulin-dependent diabetes. Med Sci Sports Exerc 1989, 21:362-368.
• [2]Vranic M, Berger M: Exercise and Diabetes Mellitus. Diabetes 1979, 28:143-163.
• [3]Praet S, Manders R, Lieverse A, Kuipers H, Stehouwer D, Keizer H, Van Loon L: Influence of Acute Exercise on Hyperglycemia in Insulin-Treated Type 2 Diabetes. Med Sci Sports Exerc 2006, 38:2037-2044.
• [4]Gaudet-Savard T, Ferland A, Broderick TL, Garneau C, Tremblay A, Nadeau A, Poirier P: Safety and magnitude of changes in blood glucose levels following exercise performed in the fasted and the postprandial state in men with type 2 diabetes. Eur J Cardiovasc Prev Rehabil 2007, 14:831-836.
• [5]Ferland A, Brassard P, Lemieux S, Bergeron J, Bogaty P, Simard S, Poirier P: Impact of high-fat/low-carbohydrate, high-, low-glycaemic index or low-caloric meals on glucoregulation during aerobic exercise in type 2 diabetes. Diabetic Med 2009, 26:589-595.
• [6]Ferland A, Brassard P, Croteau S, Lemieux S, Bergeron J, Lacroix S, Fournier L, Poirier P: Impact of beta-blocker treatment and nutritional status on glycemic response during exercise in patients with type 2 diabetes. Clin Invest Med 2007, 30:E257-E261.
• [7]Fritz T, Rosenqvist U: Walking for exercise - immediate effect on blood glucose levels in type 2 diabetes. Scand J Prim Health Care 2001, 19:31-33.
• [8]Jeng C, Ku CT, Huang WH: Establishment of a predictive model of serum glucose changes under different exercise intensities and durations among patients with type 2 diabetes mellitus. J Nurs Res 2003, 11:287-294.
• [9]Jeng C, Chang WY, Chen SR, Tseng IJ: Effects of arm exercise on serum glucose response in type 2 DM patients. J Nurs Res 2002, 10:187-194.
• [10]Colberg S, Zarrabi L, Bennington L, Nakave A, Somma T, Swain D, Sechrist S: Postprandial Walking is Better for Lowering the Glycemic Effect of Dinner than Pre-Dinner Exercise in Type 2 Diabetic Individuals. J Amer Med Dir Assoc 2009, 10:394-397.
• [11]Vancea D, Vancea J, Pires M, Reis M, Moura R, Dib S: Effect of Frequency of Physical Exercise on Glycemic Control and Body Composition in Type 2 Diabetic Patients. Arq Bras Cardiol 2009, 92:22-28.
• [12]Poirier P, Tremblay A, Catellier C, Tancrede G, Garneau C, Nadeau A: Impact of Time Interval from the Last Meal on Glucose Response to Exercise in Subjects with Type 2 Diabetes. J Clin Endocrin Metab 2000, 85:2860-2864.
• [13]International Organization for Standardization: In vitro diagnostic test systems. Requirements for blood-glucose monitoring systems for self-testing in managing diabetes mellitus.International Standard ISO 15197. 2003. http://www.iso.org/iso/home/store/catalogue_tc/catalogue_detail.htm?csnumber=26309 webcite
• [14]Poirier P, Mawhinney S, Grondin L, Tremblay A, Broderick T, Cleroux J: Prior meal enhances the plasma glucose lowering effect of exercise in type 2 diabetes. Med Sci Sports Exerc 2001, 33:1259-1264.
• [15]Rizza R: Pathogenesis of fasting and postprandial hyperglycemia in Type 2 diabetes: Implications for therapy. Diabetes 2010, 59:2697-2707.
• [16]Galbo H, Tobin L, Van Loon LJ: Responses to acute exercise in type 2 diabetes, with an emphasis on metabolism and interaction with oral hypoglycemic agents and food intake. Appl Physiol Nutr Metab 2007, 32:567-575.
• [17]Friedman J, Hastie T, Tibshirani R: Regularization Paths for Generalized Linear Models via Coordinate Descent. J Stat Soft 2010, 33:1-22.
• [18]Grömping U: Relative Importance for Linear Regression in R: The Package relaimpo. J Stat Soft 2006, 17:1-27.
• [19]Raudenbush S, Bryk A: Hierarchical Linear Models: Application and Data Analysis Methods. London: Sage; 2002.
• [20]Olofsen E, Dinges D, Dongen HV: Nonlinear Mixed-Effects Modeling: Individualization and Prediction. Aviat Space Environ Med 2004, 75:A134-A140.
• [21]Laird N, Ware J: Random-Effects Models for Longitudinal Data. Biometrics 1982, 38:963-974.
• [22]Nakagawa S, Schielzeth H: A general and simple method for obtaining R2 from generalized linear mixed-effects models. Meth Ecol Evol 2013, 4:133-142.
• [23]The R Project for Statistical Computing. R 2.15.1 2012. http://www.r-project.org/ webcite
• [24]Schelldorfer J, Buhlmann P, De Geer SV: Estimation for High-Dimensional Linear Mixed-Effects Models Using ℓ1-Penalization. Scand J Stat 2011, 38:197-214.
• [25]Pinheiro J, Bates D, DebRoy S, Deepayan S: Linear and Nonlinear Mixed Effects Models. 2012. http://cran.r-project.org/web/packages/nlme/index.html webcite
• [26]Kosuke I, King G, Lau O: Zelig: Everyone's Statistical Software. 2012. http://GKing.harvard.edu/zelig webcite
• [27]Hagberg JM, Jenkins NT, Spangenburg E: Exercise training, genetics and type 2 diabetes-related phenotypes. Acta. Physiol 2012, 205:456-471.
• [28]Gibson B, Weir C: Development and Preliminary Evaluation of a Simulation-Based Diabetes Education Module. AMIA Annu Symp Proc 2010, 13:246-250.
• [29]Gibson B, Marcus R, Staggers N, Jones J, Samore M, Weir C: Efficacy of a Computerized Simulation in Promoting Walking in Individuals with Diabetes. J Med Internet Res 2012, 14:e71.