Periodical Solutions in a Pulse-Modulated Model of Endocrine Regulation With Time-Delay

Author

Churilov, Alexander ; Medvedev, Alexander ; Mattsson, Per

Author_Institution

Dept. of Math. & Mech., St. Petersburg State Univ., St. Petersburg, Russia

Volume

59

Issue

3

fYear

2014

fDate

Mar-14

Firstpage

728

Lastpage

733

Abstract

A hybrid mathematical model of endocrine regulation obtained by augmenting the classical continuous Smith model with a pulse-modulated feedback to describe episodic (pulsatile) secretion is considered. Conditions for existence and local orbital stability of periodical solutions with m impulses in the least period ( m-cycles) are derived. An important implication of the performed analysis is that the nonlinear dynamics of the pulse-modulated system and not the delay itself cause the sustained closed-loop oscillations. Furthermore, simulation and bifurcation analysis indicate that increasing the time delay in the system in hand typically, but not always, leads to less complex dynamic pattern in the closed-loop system by giving rise to stable cycles of lower periodicity.

Keywords

bifurcation; biocontrol; closed loop systems; delays; physiological models; pulsatile flow; bifurcation analysis; classical continuous Smith model; endocrine regulation; episodic secretion; hybrid mathematical model; local orbital stability; m-cycles; nonlinear dynamics; periodical solutions; pulsatile secretion; pulse-modulated feedback; pulse-modulated model; sustained closed-loop oscillations; time delay; Biochemistry; Delay effects; Delays; Mathematical model; Orbits; Stability analysis; Vectors; Delay systems; impulsive systems; oscillations; periodic solutions;

fLanguage

English

Journal_Title

Automatic Control, IEEE Transactions on

Publisher

ieee

ISSN

0018-9286

Type

jour

DOI

10.1109/TAC.2013.2273284

Filename

6558799