Explosive, continuous and frustrated synchronization transition in spiking Hodgkin–Huxley neural networks: The role of topology and synaptic interaction

Khoshkhou, Mahsa; Montakhab, Afshin

doi:10.1016/j.physd.2020.132399

Cited by 14 publications

(16 citation statements)

References 61 publications

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“…First, we establish the occurrence of a synchronization transition in this cognitive system. The amount of synchronization in neural networks with static synapses can be controlled upon changing the average synaptic strength [44,54]. In the present study synaptic strength is an autonomous variable which is modified by the internal dynamics of the network through the RL process.…”

Section: Resultsmentioning

confidence: 92%

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Optimal reinforcement learning near the edge of synchronization transition

Khoshkhou,

Montakhab

2022

Preprint

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Recent experimental and theoretical studies have indicated that the putative criticality of cortical dynamics may corresponds to a synchronization phase transition. The critical dynamics near such a critical point needs further investigation specifically when compared to the critical behavior near the standard absorbing state phase transition. Since the phenomena of learning and self-organized criticality (SOC) at the edge of synchronization transition can emerge jointly in spiking neural networks due to the presence of spike-timing dependent plasticity (STDP), it is tempting to ask: What is the relationship between synchronization and learning in neural networks? Further, does learning benefit from SOC at the edge of synchronization transition? In this paper, we intend to address these important issues. Accordingly, we construct a biologically inspired model of a cognitive system which learns to perform stimulus-response tasks. We train this system using a reinforcement learning rule implemented through dopamine-modulated STDP. We find that the system exhibits a continuous transition from synchronous to asynchronous neural oscillations upon increasing the average axonal time delay. We characterize the learning performance of the system and observe that it is optimized near the synchronization transition. We also study neuronal avalanches in the system and provide evidence that optimized learning is achieved in a slightly supercritical state.

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Section: Resultsmentioning

confidence: 92%

“…t m i is the time that neuron i emits its m th spike. Next we evaluate a time-dependent order parameter [39,44,54]:…”

Section: Model and Methodsmentioning

confidence: 99%

Optimal reinforcement learning near the edge of synchronization transition

Khoshkhou,

Montakhab

2022

Preprint

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“…Khoshkhou and Montakhab 13 investigated the influence of synaptic interaction (chemical and electrical) as well as structural connectivity on beta-band synchronization transition in network models of lzhikevich neurons, and these results indicated that biologically meaningful models of neural dynamics show a synchronization transition that relies on the average firing frequency of neurons, which is contrary to the case of simple phase oscillators. The authors also provided a systematic study of gamma-band synchronization in spiking Hodgkin-Huxley neurons which interact via electrical or chemical synapses, and concluded that gamma-rhythms are distinctly different from beta-rhythms in 14 . Boaretto et al 16 explored the non-monotonic synchronization transition in a Huber-Braun model, and showed that this non-monotonic phase transition occurs due to an interplay between the individual-regular behavior of the neurons and the influence of the synaptic current.…”

Section: Introductionmentioning

confidence: 99%

Long-range connections are crucial for synchronization transition in a computational model of Drosophila brain dynamics

Qiu

Sun

2022

Sci Rep

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The synchronization transition type has been the focus of attention in recent years because it is associated with many functional characteristics of the brain. In this paper, the synchronization transition in neural networks with sleep-related biological drives in Drosophila is investigated. An electrical synaptic neural network is established to research the difference between the synchronization transition of the network during sleep and wake, in which neurons regularly spike during sleep and chaotically spike during wake. The synchronization transition curves are calculated mainly using the global instantaneous order parameters S. The underlying mechanisms and types of synchronization transition during sleep are different from those during wake. During sleep, regardless of the network structure, a frustrated (discontinuous) transition can be observed. Moreover, the phenomenon of quasi periodic partial synchronization is observed in ring-shaped regular network with and without random long-range connections. As the network becomes dense, the synchronization of the network only needs to slightly increase the coupling strength g. While during wake, the synchronization transition of the neural network is very dependent on the network structure, and three mechanisms of synchronization transition have emerged: discontinuous synchronization (explosive synchronization and frustrated synchronization), and continuous synchronization. The random long-range connections is the main topological factor that plays an important role in the resulting synchronization transition. Furthermore, similarities and differences are found by comparing synchronization transition research for the Hodgkin-Huxley neural network in the beta-band and gammma-band, which can further improve the synchronization phase transition research of biologically motivated neural networks. A complete research framework can also be used to study coupled nervous systems, which can be extended to general coupled dynamic systems.

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“…Neurons with intrinsic properties can be described by a large number of mathematical models. One kind of the well-known and biologically plausible models are the Hodgkin–Huxley equations and their simplified versions, which are widely used to analyze the synchronous in the neuronal network [ 10 – 12 ]. When a large number of conducted neuron models are considered, the number of coupled differential equations can be often a problem for computer simulations.…”

Section: Introductionmentioning

confidence: 99%

Correlation Analysis of Synchronization Type and Degree in Respiratory Neural Network

Yuan

2021

Computational Intelligence and Neuroscience

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Pre-Bötzinger complex (PBC) is a necessary condition for the generation of respiratory rhythm. Due to the existence of synaptic gaps, delay plays a key role in the synchronous operation of coupled neurons. In this study, the relationship between synchronization and correlation degree is established for the first time by using ISI bifurcation and correlation coefficient, and the relationship between synchronization and correlation degree is discussed under the conditions of no delay, symmetric delay, and asymmetric delay. The results show that the phase synchronization of two coupling PBCs is closely related to the weak correlation, that is, the weak phase synchronization may occur under the condition of incomplete synchronization. Moreover, the time delay and coupling strength are controlled in the modified PBC network model, which not only reveals the law of PBC firing transition but also reveals the complex synchronization behavior in the coupled chaotic neurons. Especially, when the two coupled neurons are nonidentical, the complete synchronization will disappear. These results fully reveal the dynamic behavior of the PBC neural system, which is helpful to explore the signal transmission and coding of PBC neurons and provide theoretical value for further understanding respiratory rhythm.

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Explosive, continuous and frustrated synchronization transition in spiking Hodgkin–Huxley neural networks: The role of topology and synaptic interaction

Cited by 14 publications

References 61 publications

Optimal reinforcement learning near the edge of synchronization transition

Optimal reinforcement learning near the edge of synchronization transition

Long-range connections are crucial for synchronization transition in a computational model of Drosophila brain dynamics

Correlation Analysis of Synchronization Type and Degree in Respiratory Neural Network

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