Continuous-time interval model identification of blood glucose dynamics for type 1 diabetes

While good physiological models of the glucose metabolism in type 1 diabetic patients are well known, their parameterisation is difficult. The high intra-patient variability observed is a further major obstacle. This holds for data-based models too, so that no good patient-specific models are available. Against this background, this paper proposes the use of interval models to cover the different metabolic conditions. The control-oriented models contain a carbohydrate and insulin sensitivity factor to be used for insulin bolus calculators directly. Available clinical measurements were sampled on an irregular schedule which prompts the use of continuous-time identification, also for the direct estimation of the clinically interpretable factors mentioned above. An identification method is derived and applied to real data from 28 diabetic patients. Model estimation was done on a clinical data-set, whereas validation results shown were done on an out-of-clinic, everyday life data-set. The results show that the interval model approach allows a much more regular estimation of the parameters and avoids physiologically incompatible parameter estimates.

[1]  Pier Giorgio Fabietti,et al.  Clinical validation of a new control-oriented model of insulin and glucose dynamics in subjects with type 1 diabetes. , 2007, Diabetes technology & therapeutics.

[2]  Claudio Cobelli,et al.  Meal Simulation Model of the Glucose-Insulin System , 2007, IEEE Transactions on Biomedical Engineering.

[3]  Biao Huang,et al.  System Identification , 2000, Control Theory for Physicists.

[4]  Robert S. Parker,et al.  Advanced model predictive control (MPC) for type I diabetic patient blood glucose control , 2000, Proceedings of the 2000 American Control Conference. ACC (IEEE Cat. No.00CH36334).

[5]  Liuping Wang,et al.  Identification of Continuous-time Models from Sampled Data , 2008 .

[6]  Srinivasan Rajaraman,et al.  Predicting Subcutaneous Glucose Concentration in Humans: Data-Driven Glucose Modeling , 2009, IEEE Transactions on Biomedical Engineering.

[7]  Rolf Johansson Continuous-Time Model Identification and State Estimation Using Non-Uniformly Sampled Data , 2009 .

[8]  Marc Lavielle,et al.  Maximum likelihood estimation in nonlinear mixed effects models , 2005, Comput. Stat. Data Anal..

[9]  Niels Kjølstad Poulsen,et al.  Control of Blood Glucose for People with Type 1 Diabetes: an in Vivo Study , 2012 .

[10]  L. Magni,et al.  Multinational Study of Subcutaneous Model-Predictive Closed-Loop Control in Type 1 Diabetes Mellitus: Summary of the Results , 2010, Journal of diabetes science and technology.

[11]  Dale E. Seborg,et al.  Control-Relevant Models for Glucose Control Using A Priori Patient Characteristics , 2012, IEEE Transactions on Biomedical Engineering.

[12]  Lutz Heinemann,et al.  Comparison of the Numerical and Clinical Accuracy of Four Continuous Glucose Monitors , 2008, Diabetes Care.

[13]  Dale E. Seborg,et al.  I. Glucose control strategies for treating type 1 diabetes mellitus , 2007 .

[14]  Su Whan Sung,et al.  Prediction Error Identification Method for Continuous-Time Processes with Time Delay , 2001 .

[15]  Pier Giorgio Fabietti,et al.  Control oriented model of insulin and glucose dynamics in type 1 diabetics , 2006, Medical and Biological Engineering and Computing.

[16]  F. Doyle,et al.  Quest for the Artificial Pancreas: Combining Technology with Treatment , 2010, IEEE Engineering in Medicine and Biology Magazine.

[17]  Maciej Niedzwiecki,et al.  Fast recursive basis function estimators for identification of time-varying processes , 2002, IEEE Trans. Signal Process..

[18]  David Q. Mayne,et al.  Robust model predictive control of constrained linear systems with bounded disturbances , 2005, Autom..

[19]  S. Genuth,et al.  The effect of intensive treatment of diabetes on the development and progression of long-term complications in insulin-dependent diabetes mellitus. , 1993, The New England journal of medicine.

[20]  C. C. Palerm,et al.  Effect of input excitation on the quality of empirical dynamic models for type 1 diabetes , 2009 .

[21]  J. P. Norton,et al.  Identification and application of bounded-parameter models , 1985, Autom..

[22]  W. Tamborlane,et al.  A tale of two compartments: interstitial versus blood glucose monitoring. , 2009, Diabetes technology & therapeutics.

[23]  Maciej Niedzwiecki,et al.  Identification of Time-Varying Processes , 2000 .

[24]  Rolf Johansson,et al.  Direct continuous time system identification of MISO transfer function models applied to type 1 diabetes , 2011, IEEE Conference on Decision and Control and European Control Conference.

[25]  Sergei V. Pereverzyev,et al.  A meta-learning approach to the regularized learning - Case study: Blood glucose prediction , 2012, Neural Networks.

[26]  J. Norton,et al.  Bounding Approaches to System Identification , 1996 .

[27]  Luigi del Re,et al.  Estimating Interval Process Models for Type 1 Diabetes for Robust Control Design , 2011 .

[28]  Roman Hovorka Management of diabetes using adaptive control , 2005 .

[29]  T. Veneman,et al.  Comparison of the accuracy of the HemoCue glucose analyzer with the Yellow Springs Instrument glucose oxidase analyzer, particularly in hypoglycemia. , 2005, European journal of endocrinology.

[30]  Luigi del Re,et al.  Performance Evaluations of Continuous Glucose Monitoring Systems: Precision Absolute Relative Deviation is Part of the Assessment , 2013, Journal of diabetes science and technology.

[31]  Rolf Johansson,et al.  Identification of continuous-time models , 1994, IEEE Trans. Signal Process..

[32]  G. Jaramillo,et al.  Prediction of postprandial blood glucose under intra-patient variability and uncertainty and its use in the design of insulin dosing strategies for type 1 diabetic patients , 2011 .

[33]  Rolf Johansson,et al.  System modeling and identification , 1993 .