Спонтанная нейронная активность в энторинальной коре новорожденных крыс
Диссертация
Основные результаты работы были доложены на международных форумах БРК (Атланта 2006, Сан Диего 2007, Чикаго 2009) — XX Съезде российских физиологов (Москва, 2007) — на конференциях молодых ученых ИВНД и НФ РАН (Москва, 2006, 2008). Диссертация апробирована 13 октября 2009 года на совместном заседании лаборатории клеточной нейробиологии обучения и лаборатории нейроонтогенеза Института высшей… Читать ещё >
Содержание
- ГЛАВА I. ОБЗОР ЛИТЕРАТУРЫ
- 1. 1. ЭНТОРИНАЛЬНАЯ КОРА
- 1. 1. 1. Строение, связи, функциональное значение
- 1. 1. 2. Ритмическая активность нейронов энторинальной коры
- 1. 2. Спонтанная активность развивающейся нервной системы
- 1. 2. 1. Гиппокамп и новая кора
- 1. 2. 2. Сетчатка
- 1. 2. 3. Роль спонтанной активности сетчатки в развитии зрительной системы
- 1. 2. 4. Спинной мозг
- 1. 2. 5. Связь между спонтанной активностью спинного мозга и ростом аксонов мотонейронов
- 1. 2. 6. Механизм генерации спонтанной активности в развивающейся нервной системе
- 1. 1. ЭНТОРИНАЛЬНАЯ КОРА
- 2. 1. Приготовление срезов
- 2. 2. Растворы и фармакология
- 2. 3. Экспериментальная установка
- 2. 4. Регистрация
- 2. 5. Обработка результатов
- 3. 1. Спонтанная активность в энторинальной коре новорожденных крыс
- 3. 1. 1. Два типа спонтанной активности
- 3. 1. 2. Генерация спонтанной активности в энторинальной коре новорожденных животных происходит с участием ГАМКергических синапсов
- 3. 1. 3. Необходимость глутаматной синаптической передачи
- 3. 1. 4. Флуфенамовая кислота блокирует спонтанную активность в энторинальной коре новорожденных животных
- 3. 1. 5. Рилузол блокирует спонтанную активность в энторинальной коре новорожденных животных
- 3. 1. 6. Уменьшение экстраклеточного кальция приводит к усилению спонтанной активности в энторинальной коре
- 3. 2. Собственная активность нейронов в энторинальной коре новорожденных крыс
- 3. 2. 1. Три типа собственной активности нейронов
- 3. 2. 2. Изменение количества пачечных клеток с пятого по тринадцатый день жизни
- 3. 2. 3. Регистрация пачечной активности в режиме cell attached
- 3. 2. 4. Плато потенциала пачечных нейронов
- 3. 2. 5. Пачечная активность зависит от внутриклеточного кальция
- 3. 2. 6. Инициация и генерация пачек и плато потенциала: ионные токи
- 3. 2. 7. Терминация пачек и плато потенциала: ионные токи
- 3. 2. 8. Генерация пачек обусловлена последовательной активацией ионных токов: схематичное представление
- 3. 2. 9. Пачечные пейсмекерные нейроны могут лежать в основе спонтанной сетевой активности
- 3. 3. Математическое моделирование пачечной активности нейронов
- 3. 3. 1. Роли ионных токов
- 3. 3. 2. Модель воспроизводит основные свойства реальных клеток
- 3. 3. 3. Усиление пачечной активности при уменьшении концентрации экстраклеточного кальция объясняется свойствами NaP тока
- 3. 3. 4. Описание модели
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