Title :
Modeling an artificial pancreas using retarded impulsive differential equation
Author :
Piper, L. ; Scolozzi, D. ; Lay-Ekuakille, Aime ; Vergallo, P. ; De Franchis, E. ; Griffo, G.
Author_Institution :
Dept. of Econ., Math. & Stat., Univ. of Salento, Lecce, Italy
Abstract :
The glucose-insulin regulatory system is characterized by a dynamic that includes some delays in the processes acting inside. This aspect is basically a key issue for people using open-loop or closed-loop artificial pancreas. This paper will focus on the influence that the above delays have in the latest mathematical models, and in particular on those resulting from the delivering of insulin at the subcutaneous level. Such models analyze the fluctuations in the concentration of intravenous glucose and insulin in a system regulated by an open loop or a closed loop (Artificial Pancreas). The paper introduces new features in terms of mathematical aspects to solve the problem of the actual delivering of glucose by using Retarded Differential Equations and Impulsive Differential Equations (in cases of micro-infusion), that analytically describe these dynamics.
Keywords :
biochemistry; blood; closed loop systems; differential equations; diseases; open loop systems; physiological models; artificial pancreas modeling; closed loop system; closed-loop artificial pancreas; fluctuations; glucose-insulin regulatory system; intravenous glucose-insulin concentration; mathematical models; open loop system; open-loop artificial pancreas; retarded impulsive differential equation; subcutaneous level; Blood; Delays; Diabetes; Insulin; Mathematical model; Pancreas; Sugar; Artificial Pancreas; Biomedical Measurement Prediction; Impulsive Differential Equations; Retarded Differential Equations; Type 1 Diabetes Mellitus;
Conference_Titel :
Medical Measurements and Applications Proceedings (MeMeA), 2013 IEEE International Symposium on
Conference_Location :
Gatineau, QC
Print_ISBN :
978-1-4673-5195-9
DOI :
10.1109/MeMeA.2013.6549708
