Cellularly-Driven Differences in Network Synchronization Propensity Are Differentially Modulated by Firing Frequency

Fink, Christian G.; Booth, Victoria; Żochowski, Michał

doi:10.1371/journal.pcbi.1002062

Cited by 51 publications

(74 citation statements)

References 36 publications

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“…Our findings can be explained with PRC theory, which we previously used to explain the effects of the stimulus at different frequency amplitudes and its effect on population synchrony (Beverlin et al, 2011). The effect of firing rate shifting the peak of the PRC to the left in response to excitatory inputs is generally true and should therefore not be heavily model dependent (Gutkin et al, 2005; Fink et al, 2011). We chose the M–L model because it is one of the simplest conductances based neuronal models that can demonstrate this effect.…”

Section: Discussionmentioning

confidence: 99%

Dynamic control of modeled tonic-clonic seizure states with closed-loop stimulation

Beverlin¹,

Netoff²

2013

Front. Neural Circuits

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Seizure control using deep brain stimulation (DBS) provides an alternative therapy to patients with intractable and drug resistant epilepsy. This paper presents novel DBS stimulus protocols to disrupt seizures. Two protocols are presented: open-loop stimulation and a closed-loop feedback system utilizing measured firing rates to adjust stimulus frequency. Stimulation suppression is demonstrated in a computational model using 3000 excitatory Morris–Lecar (M–L) model neurons connected with depressing synapses. Cells are connected using second order network topology (SONET) to simulate network topologies measured in cortical networks. The network spontaneously switches from tonic to clonic as synaptic strengths and tonic input to the neurons decreases. To this model we add periodic stimulation pulses to simulate DBS. Periodic forcing can synchronize or desynchronize an oscillating population of neurons, depending on the stimulus frequency and amplitude. Therefore, it is possible to either extend or truncate the tonic or clonic phases of the seizure. Stimuli applied at the firing rate of the neuron generally synchronize the population while stimuli slightly slower than the firing rate prevent synchronization. We present an adaptive stimulation algorithm that measures the firing rate of a neuron and adjusts the stimulus to maintain a relative stimulus frequency to firing frequency and demonstrate it in a computational model of a tonic-clonic seizure. This adaptive algorithm can affect the duration of the tonic phase using much smaller stimulus amplitudes than the open-loop control.

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Section: Discussionmentioning

confidence: 99%

Dynamic control of modeled tonic-clonic seizure states with closed-loop stimulation

Beverlin¹,

Netoff²

2013

Front. Neural Circuits

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“…The model features a fast Na + current, a delayed rectifier K + current and a leakage current (Amitai, 1994; Stiefel et al, 2009; Rich et al, 2016). The current balance equation for cell i is:

\begin{matrix} eqnarrayright center left \\ C \frac{d V_{i}}{d t} = - g_{N a} m_{\infty}^{3} h false(V_{i} - E_{N a} false) - g_{K d r} n^{4} false(V_{i} - E_{K} false) \\ - g_{L} false(V_{i} - E_{L} false) + I_{e x t} - I_{i}^{s y n}, \end{matrix}

where C = 1.0 μF/cm 2 , g Na = 24.0 mS/cm 2 ,

g_{K d r} = 3.0 text mS / text c {text m}^{2}

g_{L} = 0.02 text mS / text c {text m}^{2}

, E Na = 55.0 mV , E K = −90.0 mV, E L = −60.0 mV (Amitai, 1994; Stiefel et al, 2009; Fink et al, 2011). I ext is the external current (measured in μA/cm 2 ) that controls the firing frequency of the neuron.…”

Section: Methodsmentioning

confidence: 99%

Synaptic Impairment and Robustness of Excitatory Neuronal Networks with Different Topologies

Mirzakhalili

Gourgou

Booth

et al. 2017

Front. Neural Circuits

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Synaptic deficiencies are a known hallmark of neurodegenerative diseases, but the diagnosis of impaired synapses on the cellular level is not an easy task. Nonetheless, changes in the system-level dynamics of neuronal networks with damaged synapses can be detected using techniques that do not require high spatial resolution. This paper investigates how the structure/topology of neuronal networks influences their dynamics when they suffer from synaptic loss. We study different neuronal network structures/topologies by specifying their degree distributions. The modes of the degree distribution can be used to construct networks that consist of rich clubs and resemble small world networks, as well. We define two dynamical metrics to compare the activity of networks with different structures: persistent activity (namely, the self-sustained activity of the network upon removal of the initial stimulus) and quality of activity (namely, percentage of neurons that participate in the persistent activity of the network). Our results show that synaptic loss affects the persistent activity of networks with bimodal degree distributions less than it affects random networks. The robustness of neuronal networks enhances when the distance between the modes of the degree distribution increases, suggesting that the rich clubs of networks with distinct modes keep the whole network active. In addition, a tradeoff is observed between the quality of activity and the persistent activity. For a range of distributions, both of these dynamical metrics are considerably high for networks with bimodal degree distribution compared to random networks. We also propose three different scenarios of synaptic impairment, which may correspond to different pathological or biological conditions. Regardless of the network structure/topology, results demonstrate that synaptic loss has more severe effects on the activity of the network when impairments are correlated with the activity of the neurons.

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“…The E-I networks studied here are comprised of neurons modeled, in the HodgkinHuxley formalism, on the cortical pyramidal neuron (Fink et al 2011;Stiefel et al 2009). This neuron is modulated by ACh such that it can display either Type I or Type II properties, and thus allows us to analyze the role of neuromodulation in these networks.…”

Section: Neuron Modelsmentioning

confidence: 99%

Effects of Neuromodulation on Excitatory–Inhibitory Neural Network Dynamics Depend on Network Connectivity Structure

2018

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Acetylcholine (ACh), one of the brain's most potent neuromodulators, can affect intrinsic neuron properties through blockade of an M-type potassium current. The effect of ACh on excitatory and inhibitory cells with this potassium channel modulates their membrane excitability, which in turn affects their tendency to synchronize in networks. Here, we study the resulting changes in dynamics in networks with inter-connected excitatory and inhibitory populations (E-I networks), which are ubiquitous in the brain. Utilizing biophysical models of E-I networks, we analyze how the network connectivity structure in terms of synaptic connectivity alters the influence of ACh on the generation of synchronous excitatory bursting. We investigate networks containing all combinations of excitatory and inhibitory cells with high (Type I properties) or low (Type II properties) modulatory tone. To vary network connectivity structure, we focus on the effects of the strengths of inter-connections between excitatory and inhibitory cells (E-I synapses and I-E synapses), and the strengths of intra-connections among excitatory cells (E-E synapses) and among inhibitory cells (I-I synapses). We show that the presence of ACh may or may not affect the generation of network synchrony depending on the network connectivity. Specifically, strong network inter-connectivity induces synchronous excitatory bursting regardless of the cellular propensity for synchronization, which aligns with predictions of 123J Nonlinear Sci the PING model. However, when a network's intra-connectivity dominates its interconnectivity, the propensity for synchrony of either inhibitory or excitatory cells can determine the generation of network-wide bursting.

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Cellularly-Driven Differences in Network Synchronization Propensity Are Differentially Modulated by Firing Frequency

Cited by 51 publications

References 36 publications

Dynamic control of modeled tonic-clonic seizure states with closed-loop stimulation

Dynamic control of modeled tonic-clonic seizure states with closed-loop stimulation

Synaptic Impairment and Robustness of Excitatory Neuronal Networks with Different Topologies

Effects of Neuromodulation on Excitatory–Inhibitory Neural Network Dynamics Depend on Network Connectivity Structure

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