Research output: Contribution to journal › Article › peer-review
Neurophotonics’ methods in approach to in vivo animal epileptic models: advantages and limitations. / Цыцарев, Василий Юрьевич; Сопова, Юлия Викторовна; Леонова, Елена Ивановна; Инюшин, М.Ю.; Маркина, Алиса Александровна; Чиринскайте, Ангелина Валерьевна; Вольнова, Анна Борисовна.
In: Epilepsia, 20.12.2023.Research output: Contribution to journal › Article › peer-review
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TY - JOUR
T1 - Neurophotonics’ methods in approach to in vivo animal epileptic models: advantages and limitations
AU - Цыцарев, Василий Юрьевич
AU - Сопова, Юлия Викторовна
AU - Леонова, Елена Ивановна
AU - Инюшин, М.Ю.
AU - Маркина, Алиса Александровна
AU - Чиринскайте, Ангелина Валерьевна
AU - Вольнова, Анна Борисовна
PY - 2023/12/20
Y1 - 2023/12/20
N2 - Neurophotonic technology is a rapidly growing group of techniques that are based on the interactions of light with natural or genetically modified cells of the neural system. New optical technologies make it possible to considerably extend the tools of neurophysiological research, from the visualization of functional activity changes to control of brain tissue excitability. This opens new perspectives for studying the mechanisms underlying the development of human neurological diseases. Epilepsy is one of the most common brain disorders; it is characterized by recurrent seizures and affects >1% of the world's population. However, how seizures occur, spread, and terminate in a healthy brain is still unclear. Therefore, it is extremely important to develop appropriate models to accurately explore the causal relationship of epileptic activity. The use of neurophotonic technologies in epilepsy research falls into two broad categories: the visualization of neural epileptic activity, and the direct optical influence on neurons to induce or suppress epileptic activity. An optogenetic variant of the classical kindling model of epileptic seizures, in which activatable cells are genetically defined, is called optokindling. Research is also underway concerning the application of neurophotonic techniques for suppressing epileptic activity, aiming to bring these methods into clinical practice. This review aims to systematize and describe new approaches that use combinations of different neurophotonic methods to work with in vivo models of epilepsy. These approaches overcome many of the shortcomings associated with classical animal models of epilepsy and thus increase the effectiveness of developing new diagnostic methods and antiepileptic therapy.
AB - Neurophotonic technology is a rapidly growing group of techniques that are based on the interactions of light with natural or genetically modified cells of the neural system. New optical technologies make it possible to considerably extend the tools of neurophysiological research, from the visualization of functional activity changes to control of brain tissue excitability. This opens new perspectives for studying the mechanisms underlying the development of human neurological diseases. Epilepsy is one of the most common brain disorders; it is characterized by recurrent seizures and affects >1% of the world's population. However, how seizures occur, spread, and terminate in a healthy brain is still unclear. Therefore, it is extremely important to develop appropriate models to accurately explore the causal relationship of epileptic activity. The use of neurophotonic technologies in epilepsy research falls into two broad categories: the visualization of neural epileptic activity, and the direct optical influence on neurons to induce or suppress epileptic activity. An optogenetic variant of the classical kindling model of epileptic seizures, in which activatable cells are genetically defined, is called optokindling. Research is also underway concerning the application of neurophotonic techniques for suppressing epileptic activity, aiming to bring these methods into clinical practice. This review aims to systematize and describe new approaches that use combinations of different neurophotonic methods to work with in vivo models of epilepsy. These approaches overcome many of the shortcomings associated with classical animal models of epilepsy and thus increase the effectiveness of developing new diagnostic methods and antiepileptic therapy.
KW - epilepsy models
KW - epileptic
KW - neurophotonics
KW - optogenetics
KW - optokindling
KW - seizures
UR - https://www.mendeley.com/catalogue/a4e0688f-f3c3-3421-a657-c212bac93f17/
U2 - 10.1111/epi.17870
DO - 10.1111/epi.17870
M3 - Article
JO - Epilepsia
JF - Epilepsia
SN - 0013-9580
ER -
ID: 114442026