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Abstract

Introduction:

Generating optimal control algorithms for an artificial pancreas is an intensively researched problem. The available models are all nonlinear and rather complex. Model predictive control or run-to-run-based methodologies have proven to be efficient solutions for individualized treatment of type 1 diabetes mellitus (T1DM). However, the controller has to ensure safety and stability under all circumstances. Robust control methods seek to provide this safety and guarantee to handle even the worst-case situations and, hence, to generalize and complement results obtained by individualized control algorithms. Methods: Modern robust (e.g., H_inf) control is a linear model-based methodology that we have combined with the nonlinear model-based linear parameter varying technique. The control algorithm was designed on the high-complexity modified nonlinear glucose-insulin model of Sorensen, and it was compared step-by-step with linear model-based H_inf control results published in the literature. The applicability of the developed algorithm was tested first on a control cohort of 10 healthy persons' oral glucose tolerance test results and then on a large meal absorption profile adapted from the literature. In the latter case, two preliminary virtual patients were generated based on 1–1 week real continuous glucose monitor measurements.

Results:

We have found that the algorithm avoids hypoglycemia (not caused by physical activity or stress) independently from the considered absorption profiles.

Conclusion:

Use of hard constraints proved their efficiency in fitting blood glucose level within a defined interval. However, in the future, more data of different T1DM patients will be collected and tested, including dynamic absorption model and in silico tests on validated simulators.

Keywords

artificial pancreas linear parameter varying polytopic set robust control type 1 diabetes mellitus

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References

Wild

Roglic

Green

Sicree

King

. Global prevalence of diabetes: Estimates for the year 2000 and projections for 2030. Diabetes Care. 2004; 27 (5): 1047–53.

Shaw

Sicree

Zimmet

. Global estimates of the prevalence of diabetes for 2010 and 2030. Diabetes Res Clin Pract. 2010; 87 (1): 4–14.

International Diabetes Federation. Diabetes in the young: A global perspective. http://www.idf.org/diabetesatlas/diabetes-young-global-perspective. Accessed March 26, 2013.

Fonyó

Ligeti

. Physiology. [In Hungarian] 3rd ed. Medicina; 2008.

Chee

Tyrone

. Closed-loop control of blood glucose. Berlin: Springer-Verlag; 2007.

Bergenstal

Tamborlane

Ahmann

Buse

Dailey

Davis

Joyce

Peoples

Perkins

Welsh

Willi

Wood

; STAR 3 Study Group. Effectiveness of sensor-augmented insulin-pump therapy in type 1 diabetes. N Engl J Med. 2010; 363 (4): 311–20.

Harvey

Wang

Grosman

Percival

Bevier

Finan

Zisser

Seborg

Jovanovic

Doyle

3rd Dassau

. Quest for the artificial pancreas: Combining technology with treatment. IEEE Eng Med Biol Mag. 2010; 29 (2): 53–62.

Cobelli

Renard

Kovatchev

. Artificial pancreas: Past, present, future. Diabetes. 2011; 60 (11): 2672–82.

Heinemann

Benesch

DeVries

. AP@home: A novel European approach to bring the artificial pancreas home. J Diabetes Sci Technol. 2011; 5 (6): 1363–72.

10.

Bergman

Ider

Bowden

Cobelli

. Quantitative estimation of insulin sensitivity. Am J Physiol. 1979; 236 (6): E667–77.

11.

Sorensen

. A physiologic model of glucose metabolism in man and its use to design and assess improved insulin therapies for diabetes. Ph.D. thesis. Cambridge: Department of Chemical Engineering, Massachusetts Institute of Technology; 1985.

12.

Parker

Doyle

3rd Ward

Peppas

. Robust H∞ glucose control in diabetes using a physiological model. AIChE J. 2000; 46 (12): 2537–49.

13.

Hovorka

Canonico

Chassin

Haueter

Massi-Benedetti

Federici

M Orsini

Pieber

Schaller

Schaupp

Vering

Wilinska

. Nonlinear model predictive control of glucose concentration in subjects with type 1 diabetes. Physiol Meas. 2004; 25 (4): 905–20.

14.

Magni

Raimondo

Man

Nicolao

Kovatchev

Cobelli

. Model predictive control of glucose concentration in type 1 diabetic patients: An in silico trial. Biomed Sig Proc Contr. 2009; 4: 338–46.

15.

Cobelli

Man

Sparacino

Magni

De Nicolao

Kovatchev

. Diabetes: Models, signals, and control. IEEE Rev Biomed Eng. 2009; 2: 54–96.

16.

Palerm

. Physiologic insulin delivery with insulin feedback: A control systems perspective. Comput Methods Programs Biomed. 2011; 102 (2): 130–7.

17.

Hovorka

Kumareswaran

Harris

Allen

Elleri

Xing

Kollman

Nodale

Murphy

Dunger

Amiel

Heller

Wilinska

Evans

. Overnight closed loop insulin delivery (artificial pancreas) in adults with type 1 diabetes: Crossover randomised controlled studies. BMJ. 2011; 342: d1855.

18.

Bruttomesso

Farret

Costa

Marescotti

Vettore

Avogaro

Tiengo

Man

C Dalla

Place

Facchinetti

Guerra

Magni

De Nicolao

Cobelli

Renard

Maran

. Closed-loop artificial pancreas using subcutaneous glucose sensing and insulin delivery and a model predictive control algorithm: Preliminary studies in Padova and Montpellier. J Diabetes Sci Technol. 2009; 3 (5): 1014–21.

19.

Clarke

Anderson

Breton

Patek

Kashmer

Kovatchev

. Closed-loop artificial pancreas using subcutaneous glucose sensing and insulin delivery and a model predictive control algorithm: The Virginia experience. J Diabetes Sci Technol. 2009; 3 (5): 1031–8.

20.

Zisser

Palerm

Bevier

Doyle

3rd Jovanovic

. Clinical update on optimal prandial insulin dosing using a refined run-to-run control algorithm. J Diabetes Sci Technol. 2009; 3 (3): 487–91.

21.

Miller

Nimri

Atlas

Grunberg

Phillip

. Automatic learning algorithm for the MD-Logic artificial pancreas system. Diabetes Technol Ther. 2011; 13 (10): 983–90.

22.

Femat

Ruiz-Velazquez

Quiroz

. Weighting restriction for intravenous insulin delivery on T1DM patient via H∞ control. IEEE Trans Auto Sci Eng. 2009; 6 (2): 239–47.

23.

Zhou

Doyle

Glover

. Robust and optimal control. Upper Saddle River: Prentice Hall; 1996.

24.

Kovács

Benyó

Bokor

Benyó

. Induced L2-norm minimization of glucose-insulin system for type I diabetic patients. Comput Methods Programs Biomed. 2011; 102 (2): 105–18.

25.

Kovács

Szalay

Almássy

Benyó

Barkai

. Quasi in-silico validations of a nonlinear LPV model-based robust glucose control algorithm for type i diabetes. Presented at: 18th World Congress of the International Federation of Automatic Control, August 28-September 2, 2011, Milano, Italy, 7114–19.

26.

Kovács

. New principles and adequate control methods for insulin optimization in case of Type I diabetes mellitus. Ph.D. thesis (in Hungarian). Budapest: Budapest University of Technology and Economics; 2007.

27.

Grigoriadis

Packard

. Anti-windup controller design using linear parameter-varying control methods. Int J Contr. 2000; 73 (12): 1104–14.

28.

Tan

. Applications of linear parameter-varying control theory. M.Sc. thesis. Berkley: University of California, Berkley; 1997.

29.

Balas

. Linear parameter-varying control and its application to a turbofan engine. Int J Robust Nonlinear Contr. 2002; 12 (9): 763–96.

30.

Lehmann

Deutsch

. A physiological model of glucose-insulin interaction in type 1 diabetes mellitus. J Biomed Eng. 1992; 14 (3): 235–42.

31.

Gelencsér

. Testing the glucose-insulin interaction form control theory point of view and investigating its glucose intake modelling. M.Sc. thesis (in Hungarian). Budapest: Budapest University of Technology and Economics; 2010.

32.

Kovács

Almássy

Czinner

Benyó

. Applicability results for a robust blood glucose control algorithm. Presented at: 3rd International Conference on Advanced Technologies and Treatment for Diabetes, February 10–13, 2009, Basel, Switzerland.

33.

Korach-André

Roth

Barnoud

Péan

Péronnet

Leverve

. Glucose appearance in the peripheral circulation and liver glucose output in men after a large 13C starch meal. Am J Clin Nutr. 2004; 80 (4): 881–6.

34.

Piotrovskii

. The use of Weibull distribution to describe the in vivo absorption kinetics. J Pharmacokinet Biopharm. 1987; 15 (6): 681–6.

35.

Wang

Zisser

Dassau

Jovanovic

Doyle

, 3rd. Model predictive control with learning-type set-point: Application to artificial pancreatic β-cell. AIChE J. 2009; 56 (6): 1510–8.

36.

De Nicolao

Magni

Man

Cobelli

. Modeling and control of diabetes: Towards the artificial pancreas. Presented at: 18th World Congress of the International Federation of Automatic Control, August 28-September 2, 2011, Milano, Italy, 7092–101.

37.

Daskalaki

Diem

Mougiakakou

. An actor-critic based controller for glucose regulation in type 1 diabetes. Comput Methods Programs Biomed. 2013; 109 (2): 116–25.

38.

Kovatchev

Breton

Man

Cobelli

. In silico preclinical trials: A proof of concept in closed-loop control of type 1 diabetes. J Diabetes Sci Technol. 2009; 3 (1): 44–55.

Applicability Results of a Nonlinear Model-Based Robust Blood Glucose Control Algorithm

Abstract

Introduction:

Results:

Conclusion:

Keywords

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References