Abstract
Periodic rhythms are ubiquitous phenomena that illuminate the underlying mechanism of cyclic activities in biological systems, which can be represented by cyclic attractors of the related biological network. Disorders of periodic rhythms are detrimental to the natural behaviours of living organisms. Previous studies have shown that the state transition from one to another attractor can be accomplished by regulating external signals. However, most of these studies until now have mainly focused on point attractors while ignoring cyclic ones. The aim of this study is to investigate an approach for reconciling abnormal periodic rhythms, such as diminished circadian amplitude and phase delay, to the regular rhythms of complex biological networks. For this purpose, we formulate and solve a mixed-integer nonlinear dynamic optimization problem simultaneously to identify regulation variables and to determine optimal control strategies for state transition and adjustment of periodic rhythms. Numerical experiments are implemented in three examples including a chaotic system, a mammalian circadian rhythm system and a gastric cancer gene regulatory network. The results show that regulating a small number of biochemical molecules in the network is sufficient to successfully drive the system to the target cyclic attractor by implementing an optimal control strategy.
Highlights
Periodic rhythms are regular behaviours in biological systems [1]
It is to note that the minimization of the deviation of the time derivatives has not been considered in previous studies on state transition. We introduce this term in the objective function, since dynamic behaviours corresponding to the desired periodic rhythms are to be followed
Abnormal periodic rhythms lead to disorders of functionality of biological systems
Summary
Periodic rhythms are regular behaviours in biological systems [1]. For instance, the circadian clock helps regulate sleep schedule, body temperature, hormone levels in a daily cycle [2]; monthly rhythms are reflected in reproductive cycles of many marine plants and animals [3]; annual rhythms are expressed in flowering, migration, hibernation or the reproduction and growth of most terrestrial plants and animals in temperate zones [4]. Arise, e.g. sleep disorders for human beings [5]. All these disorders may result in daytime sleepiness, 2 depression, arrhythmogenesis and even cancer [6,7,8,9]. The organism can find itself a way to adjust the disturbed rhythms to the regular ones in the new environment. This recovery process usually takes too much time for the biological system to suffer from. An external intervention can be used to assist the biological system to accelerate the recovery process. Investigations on where and how to intervene in the biological system under consideration have to be made
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