RSS-Feed abonnieren
PDF herunterladen
DOI: 10.3414/ME14-01-0034
Prediction Model for Glucose Metabolism Based on Lipid Metabolism[*]
Publikationsverlauf
received:10. März 2014
accepted:18. April 2014
Publikationsdatum:
20. Januar 2018 (online)
Summary
Objectives: We developed a robust, long-term clinical prediction model to predict conditions leading to early diabetes using laboratory values other than blood glucose and insulin levels. Our model protects against missing data and noise that occur during long-term analysis.
Methods: Results of a 75-g oral glucose tolerance test (OGTT) were divided into three groups: diabetes, impaired glucose tolerance (IGT), and normal (n = 114, 235, and 325, respectively). For glucose metabolic and lipid metabolic parameters, near 30-day mean values and 10-year integrated values were compared. The relation between high-density lipoprotein cholesterol (HDL-C) and variations in HbA1c was analyzed in 158 patients. We also constructed a state space model consisting of an observation model (HDL-C and HbA1c) and an internal model (disorders of lipid metabolism and glucose metabolism) and applied this model to 116 cases.
Results: The root mean square error between the observed HbA1c and predicted HbA1c was 0.25.
Conclusions: In the observation model, HDL-C levels were useful for prediction of increases in HbA1c. Even with numerous missing values over time, as occurs in clinical practice, clinically valid predictions can be made using this state space model.
* Supplementary material published on our website www.methods-online.com
-
References
- 1 The world health statistics 2012 Geneva: World Health Organization; 2012
- 2 Blaak EE, Antoine JM, Benton D, Björck I, Bozzetto L, Brouns F, Diamant M. et al. Impact of postprandial glycaemia on health and prevention of disease. Obes Rev 2012; 13: 923-984.
- 3 Perreault L, Pan Q, Mather KJ, Watson KE, Hamman RF, Kahn SE. Diabetes Prevention Program Research Group. Effect of regression from prediabetes to normal glucose regulation on long-term reduction in diabetes risk: results from the Diabetes Prevention Program Outcomes Study. Lancet 2012; 379: 2243-2251.
- 4 Handelsman Y, Jellinger PS. Overcoming obstacles in risk factor management in type 2 diabetes mellitus. J Clin Hypertens (Greenwich) 2011; 13: 613-620.
- 5 de Groot M, Doyle T, Kushnick M, Shubrook J, Merrill J, Rabideau E. et al. Can lifestyle interventions do more than reduce diabetes risk? Treating depression in adults with type 2 diabetes with exercise and cognitive behavioral therapy. Curr Diab Rep 2012; 12: 157-166.
- 6 Isaman DJ, Barhak J, Ye W. Indirect estimation of a discrete-state discrete-time model using secondary data analysis of regression data. Stat Med 2009; 28: 2095-2115.
- 7 Goel G, Chou IC, Voit EO. System estimation from metabolic time-series data. Bioinformatics 2008; 24: 2505-2511.
- 8 Riva A, Bellazzi R. Learning temporal probabilistic causal models from longitudinal data. Artif Intell Med 1996; 8: 217-234.
- 9 Watson EM, Chappell MJ, Ducrozet F, Poucher SM, Yates JW. A new general glucose homeostatic model using a proportional-integral-derivative controller. Comput Methods Programs Biomed 2011; 102: 119-129.
- 10 Marshall G, De la Cruz-Mesia R, Quintana FA, Baron AE. Discriminant analysis for longitudinal data with multiple continuous responses and possibly missing data. Biometrics 2009; 65: 69-80.
- 11 Docherty PD, Chase JG, Lotz T, Hann CE, Shaw GM, Berkeley JE. et al. DISTq: An iterative analysis of glucose data for low-cost, real-time and accurate estimation of insulin sensitivity. Open Med Inform J 2009; 3: 65-76.
- 12 Burattini R, Morettini M. Identification of an integrated mathematical model of standard oral glucose tolerance test for characterization of insulin potentiation in health. Comput Methods Programs Biomed 2012; 107: 248-261.
- 13 Schildcrout JS, Haneuse S, Peterson JF, Denny JC, Matheny ME, Waitman LR. et al. Analyses of longitudinal, hospital clinical laboratory data with application to blood glucose concentrations. Stat Med 2011; 30: 3208-3220.
- 14 Chen CL, Tsai HW, Wong SS. Modeling the physiological glucose-insulin dynamic system on diabetics. J Theor Biol 2010; 265: 314-322.
- 15 Chen CL, Tsai HW. Modeling the physiological glucose-insulin system on normal and diabetic subjects. Comput Methods Programs Biomed 2010; 97: 130-140.
- 16 Silber HE, Jauslin PM, Frey N, Karlsson MO. An integrated model for the glucose-insulin system. Basic Clin Pharmacol Toxicol 2010; 106: 189-194.
- 17 Topp B, Promislow K, deVries G, Miura RM, Finegood DT. A model of beta-cell mass, insulin, and glucose kinetics: pathways to diabetes. J Theor Biol 2000; 206: 605-619.
- 18 Pedersen MG. A biophysical model of electrical activity in human â-cells. Biophys J 2010; 99: 3200-3207.
- 19 Abbasi A, Corpeleijn E, Gansevoort RT, Gans RO, Hillege HL, Stolk RP. et al. Role of HDL-C cholesterol and estimates of HDL-C particle composition in future development of type 2 diabetes in the general population: The PREVEND Study. J Clin Endocrinol Metab 2013; 98: E1352-E1359.
- 20 Seo MH, Bae JC, Park SE, Rhee EJ, Park CY, Oh KW. et al. Association of lipid and lipoprotein profiles with future development of type 2 diabetes in nondiabetic Korean subjects: a 4-year retrospective, longitudinal study. J Clin Endocrinol Metab 2011; 9: E2050-E2054.
- 21 Kitagawa G, Gersch W. A smoothness priors-state space approach to the modeling of time series with trend and seasonality. J Am Stat Assoc 1984; 79: 378-389.
- 22 Tabak AG, Jokela M, Akbaraly TN, Brunner EJ, Kivimaki M, Witte DR. Trajectories of glycaemia, insulin sensitivity, and insulin secretion before diagnosis of type 2 diabetes: an analysis from the Whitehall II study. Lancet 2009; 373: 2215-2221.
- 23 Akashi H, Kumamoto H, Nose K. Application of Monte Carlo method to optimal control for linear systems under measurement noise with Markov dependent statistical property. Int J Control 1975; 22: 821-836.
- 24 Kitagawa G. Monte Carlo filter and smoother for non-Gaussian nonlinear state space models. J Comp Graph Stat 1996; 5: 1-25.