Closed-loop optogenetic control of thalamus as a tool for interrupting seizures after cortical injury

Paz, Jeanne T.; Davidson, Thomas J.; Fréchette, Éric; Delord, Bruno; Parada, Isabel; Peng, Kathy; Deisseroth, Karl; Huguenard, John R.

doi:10.1038/nn.3269

Cited by 491 publications

(521 citation statements)

References 32 publications

(48 reference statements)

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“…This cell type specificity allows manipulation of specific circuits and thus more targeted manipulations, which should help pinpoint the circuits and molecular mechanisms that underlie diseases. Optogenetic approaches have been used in rodents to probe neural circuits for several neurological/neurodegenerative diseases, including Parkinson's disease [78,79], epilepsy [80,81], and stroke [26,82]. In the next sections we will first introduce optogenetics and its developments, and then review the current understanding of remapping and recovery after stroke from recent studies using peripheral and optogenetic stimulation, as well as the use of optogenetic stimulation to enhance post-stroke recovery.…”

Section: Current Brain Stimulation Techniques Used To Study Stroke Rementioning

confidence: 99%

Optogenetic Approaches to Target Specific Neural Circuits in Post-stroke Recovery

2016

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Stroke is a leading cause of death and disability in the USA, yet treatment options are very limited. Functional recovery can occur after stroke and is attributed, in part, to rewiring of neural connections in areas adjacent to or remotely connected to the infarct. A better understanding of neural circuit rewiring is thus an important step toward developing future therapeutic strategies for stroke recovery. Because stroke disrupts functional connections in peri-infarct and remotely connected regions, it is important to investigate brain-wide network dynamics during post-stroke recovery. Optogenetics is a revolutionary neuroscience tool that uses bioengineered lightsensitive proteins to selectively activate or inhibit specific cell types and neural circuits within milliseconds, allowing greater specificity and temporal precision for dissecting neural circuit mechanisms in diseases. In this review, we discuss the current view of post-stroke remapping and recovery, including recent studies that use optogenetics to investigate neural circuit remapping after stroke, as well as optogenetic stimulation to enhance stroke recovery. Multimodal approaches employing optogenetics in conjunction with other readouts (e.g., in vivo neuroimaging techniques, behavior assays, and next-generation sequencing) will advance our understanding of neural circuit reorganization during post-stroke recovery, as well as provide important insights into which brain circuits to target when designing brain stimulation strategies for future clinical studies.

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Section: Current Brain Stimulation Techniques Used To Study Stroke Rementioning

confidence: 99%

Optogenetic Approaches to Target Specific Neural Circuits in Post-stroke Recovery

2016

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“…Several early studies of optogenetics in vitro and in animal models of epilepsy have shown promising results. The earliest application of optogenetics to epilepsy was by Tønnesen et al [33], who demonstrated that halorhodopsin-an inhibitory chloride pump-was capable of suppressing epileptiform activity in hippocampal organotypic slice cultures. More recently, 3 groups have demonstrated that inhibition of particular targets can interrupt seizures in vivo in rat models of epilepsy.…”

Section: Future Directionsmentioning

confidence: 99%

“…Thalamic relays are also thought to mediate the benefits from lesions and electrical stimulation of the cerebellum for epilepsy, but this circuit and its influence is less clearly defined [30][31][32]. More precise work identifying and manipulating neural signaling within the thalamocortical network is currently being performed [33].…”

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confidence: 99%

Deep Brain Stimulation for the Treatment of Epilepsy: Circuits, Targets, and Trials

2014

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Deep brain stimulation (DBS) has proven remarkably safe and effective in the treatment of movement disorders. As a result, it is being increasingly applied to a range of neurologic and psychiatric disorders, including medically refractory epilepsy. This review will examine the use of DBS in epilepsy, including known targets, mechanisms of neuromodulation and seizure control, published clinical evidence, and novel technologies. Cortical and deep neuromodulation for epilepsy has a long experimental history, but only recently have better understanding of epileptogenic networks, precise stereotactic techniques, and rigorous trial design combined to improve the quality of available evidence and make DBS a viable treatment option. Nonetheless, underlying mechanisms, anatomical targets, and stimulation parameters remain areas of active investigation.

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“…Une large fraction des neurones thalamocorticaux (excitateurs) interconnectés avec la région corticale lésée étaient ensuite photosensibilisés par expression de la NpHR à l'aide d'un vecteur viral. Le protocole d'illumination de ces neurones en boucle fermée s'est révélé capable de stopper les crises d'épilepsie moins d'une seconde après leur apparition, et ce jusqu'à un an après implantation du système chez les animaux [51]. Dans une deuxième étude, un modèle d'épilepsie du lobe temporal était obtenu chez la souris par lésion pharmacologique focale de l'hippocampe à l'acide kaïnique.…”

Section: Perspectives Thérapeutiques Offertes Par Les Outils Optogénéunclassified

Potentiel thérapeutique de la neuromodulation optogénétique

et al. 2015

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Closed-loop optogenetic control of thalamus as a tool for interrupting seizures after cortical injury

Cited by 491 publications

References 32 publications

Optogenetic Approaches to Target Specific Neural Circuits in Post-stroke Recovery

Optogenetic Approaches to Target Specific Neural Circuits in Post-stroke Recovery

Deep Brain Stimulation for the Treatment of Epilepsy: Circuits, Targets, and Trials

Potentiel thérapeutique de la neuromodulation optogénétique

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