МЕТАБОЛИЧЕСКИЙ КОНТРОЛЬ ВЫСОКОЧАСТОТНЫХ ГАММА-ОСЦИЛЛЯЦИЙ В ГОЛОВНОМ МОЗГЕ

Высокочастотная электрическая активность в диапазоне 30–100 Гц, известная как гамма-ритмы, наблюдается во многих областях мозга, где она обеспечивает синхронизацию активности нейронных сетей, которые обрабатывают, передают, хранят и получают информацию. Гамма-ритмы играют ключевую роль в процессах высшей нервной деятельности, таких как внимание, сенсорное восприятие и формирование памяти, а их нарушение является общим симптомом заболеваний, связанных с нарушениями когнитивной функции, в т. ч. болезни Альцгеймера, эпилепсии и шизофрении. Исследования последних лет показали, что особая популяция ингибирующих ГАМКергических нейронов, а именно парвальбумин-положительных (PV+) интернейронов, является источником высокочастотных осцилляций. Поддержание гамма-ритмов является чрезвычайно энергозатратным процессом, который опирается на высокую скорость окислительного фосфорилирования в митохондриях нейронов и лимитируется наличием глюкозы. Инсулин, возможно, участвует в метаболическом контроле гамма-осцилляций, т. к. PV+ интернейроны селективно экспрессируют инсулин-зависимый транспортер глюкозы GLUT4, который может обеспечить дополнительный приток глюкозы в условиях функционирования, близких к предельным, как это происходит в периоды высокочастотных гамма-осцилляций. Настоящий обзор суммирует имеющиеся в научной литературе данные о связи метаболизма и высокочастотной электрической активности мозга, с упором на возможный вклад центральной инсулиновой резистентности в нарушения гамма-ритмов мозга.

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