Optogenetic inhibition of chemically induced hypersynchronized bursting in mice

Berglind, Fredrik; Ledri, Marco; Sørensen, Andreas T.; Nikitidou, Litsa; Melis, Miriam; Bielefeld, Pascal; Kirik, Deniz; Deisseroth, Karl; Andersson, My; Kokaia, Mérab

doi:10.1016/j.nbd.2014.01.015

Cited by 45 publications

(37 citation statements)

References 41 publications

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“…Global activation of various populations of inhibitory interneurons could produce prolonged suppression of epileptiform activity during light stimulation (29). Direct hyperpolarization of the principal cells through chloride channel could be responsible for the suppressive effects (30). However, similar to a previous study (30), longer duration of light exposure for global activation of interneurons reduced the suppressive effects…”

Section: Discussionmentioning

confidence: 99%

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Seizure Suppression by High Frequency Optogenetic Stimulation Using In Vitro and In Vivo Animal Models of Epilepsy

Chiang¹,

Ladas²,

Gonzalez‐Reyes

et al. 2014

Brain Stimulation

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Background: Electrical high frequency stimulation (HFS) has been shown to suppress seizures. However, the mechanisms of seizure suppression remain unclear and techniques for blocking specific neuronal populations are required. Objective: The goal is to study the optical HFS protocol on seizures as well as the underlying mechanisms relevant to the HFS-mediated seizure suppression by using optogenetic methodology. Methods: Thy1-ChR2 transgenic mice were used in both vivo and in vitro experiments. Optical stimulation with pulse trains at 20 and 50 Hz was applied on the focus to determine its effects on in vivo seizure activity induced by 4-AP and recorded in the bilateral and ipsilateral-temporal hippocampal CA3 regions. In vitro methodology was then used to study the mechanisms of the in vivo suppression. Results: Optical HFS was able to generate 82.4 % seizure suppression at 50 Hz with light power of 6.1 mW and 80.2 % seizure suppression at 20 Hz with light power of 2.0 mW. The suppression percentage increased by increasing the light power and saturated when the power reached above-mentioned values. In vitro experimental results indicate that seizure suppression was mediated by activation of GABA receptors. Seizure suppression effect decreased with continued application but the suppression effect could be restored by intermittent stimulation. Conclusions: This study shows that optical stimulation at high frequency targeting an excitatory opsin has potential therapeutic application for fast control of an epileptic focus. Furthermore, electrophysiological observations of extracellular and intracellular signals reveled that GABAergic neurotransmission activated by optical stimulation was responsible for the suppression.

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Section: Discussionmentioning

confidence: 99%

“…Direct hyperpolarization of the principal cells through chloride channel could be responsible for the suppressive effects (30). However, similar to a previous study (30), longer duration of light exposure for global activation of interneurons reduced the suppressive effects…”

Section: Discussionmentioning

confidence: 99%

Seizure Suppression by High Frequency Optogenetic Stimulation Using In Vitro and In Vivo Animal Models of Epilepsy

Chiang¹,

Ladas²,

Gonzalez‐Reyes

et al. 2014

Brain Stimulation

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show abstract

“…To address this issue, a recent study has used an optic fiber attached to a metal electrode and a glass capillary for the delivery of a solution containing a selective GABA A receptor antagonist ( i.e. bicuculline methiodide) to the opsin-transfected population (Berglind et al, 2014). Though successful, this route of drug delivery suffers from a number of potential drawbacks, including (i) mechanical instability of the neuronal tissue at the time of injection (with chances of loosing the recorded neurons and thus eliminating the possibility of recording the same neurons before and during drug application), (ii) delivery of an unknown drug concentration at, and around, the site of injection, and (iii) poor control of the spatial extent of drug action.…”

Section: Introductionmentioning

confidence: 99%

Investigating local and long-range neuronal network dynamics by simultaneous optogenetics, reverse microdialysis and silicon probe recordings in vivo

Taylor

Schmiedt

Çarçak

et al. 2014

Journal of Neuroscience Methods

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“…Furthermore, the repertoire of optogenetic tools is ever expanding to include opsins with altered ion specificity and increased effectiveness (Berndt et al 2014;Chuong et al 2014), and this technology is being used to research possible treatments for a multitude of neurological disorders, including epilepsy, Parkinson's disease, and Alzheimer's disease (Gradinaru et al 2009;Krook-Magnuson and Soltesz 2015;Yamamoto et al 2015). By using optogenetics to control the activity of specific circuits, important discoveries have been made regarding the circuits involved in epileptiform activity in in vitro and in vivo seizure or epilepsy models (Tønnesen et al 2009;Kokaia 2011;Wykes et al 2012;Armstrong et al 2013;Krook-Magnuson et al 2013Paz et al 2013;Rossignol et al 2013;Sukhotinsky et al 2013;Berglind et al 2014;Ledri et al 2014). Soon after early experiments showing optogenetic control of seizure-like events in hippocampal culture preparations (Tønnesen et al 2009), several in vivo studies showed that optogenetics can be used to manipulate specific neuronal circuits within rodent models of epilepsy to control seizures (Wykes et al 2012;Armstrong et al 2013;Krook-Magnuson et al 2013Paz et al 2013).…”

Section: Optogenetic Targeting Of Specific Circuits In Epilepsy Applimentioning

confidence: 99%

Microcircuits in Epilepsy: Heterogeneity and Hub Cells in Network Synchronization

Bui

Kim

Maroso

et al. 2015

Cold Spring Harb Perspect Med

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Epilepsy is a complex disorder involving neurological alterations that lead to the pathological development of spontaneous, recurrent seizures. For decades, seizures were thought to be largely repetitive, and had been examined at the macrocircuit level using electrophysiological recordings. However, research mapping the dynamics of large neuronal populations has revealed that seizures are not simply recurrent bursts of hypersynchrony. Instead, it is becoming clear that seizures involve a complex interplay of different neurons and circuits. Herein, we will review studies examining microcircuit changes that may underlie network hyperexcitability, discussing observations from network theory, computational modeling, and optogenetics. We will delve into the idea of hub cells as pathological centers for seizure activity, and will explore optogenetics as a novel avenue to target and treat pathological circuits. Finally, we will conclude with a discussion on future directions in the field.

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Optogenetic inhibition of chemically induced hypersynchronized bursting in mice

Cited by 45 publications

References 41 publications

Seizure Suppression by High Frequency Optogenetic Stimulation Using In Vitro and In Vivo Animal Models of Epilepsy

Seizure Suppression by High Frequency Optogenetic Stimulation Using In Vitro and In Vivo Animal Models of Epilepsy

Investigating local and long-range neuronal network dynamics by simultaneous optogenetics, reverse microdialysis and silicon probe recordings in vivo

Microcircuits in Epilepsy: Heterogeneity and Hub Cells in Network Synchronization

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