Пероксидазы хрена и сои для определения фенольных и эндопероксидных соединений в водных, водно-органических средах и гидрофильных ионных жидкостях
Диссертация
Практическая значимость таких исследований возрастет, если при их проведении будут сопоставлены каталитическая активность и субстратная специфичность двух коммерческих растительных пероксидаз: пероксидазы хрена, ПХ (высокоактивного и стабильного фермента, давно и успешно зарекомендовавшего себя в практике биохимического анализа), и пероксидазы сои, ПС (аналитические возможности которой пока… Читать ещё >
Содержание
- Обзор литературы
- Глава 1. Методы определения катехоламинов. в фармацевтических препаратах
- 1. 1. Спектроскопические, кинетические и биохимические методы определения катехоламинов
- 1. 1. 1. Спектроскопические методы
- 1. 1. 1. 1. Спектрофотометрия в УФ и видимой областях спектра
- 1. 1. 1. 2. Люминесцентный метод
- 1. 1. 1. 3. Метод ядерного магнитного резонанса
- 1. 1. 2. Кинетические методы
- 1. 1. 3. Биохимические методы
- 1. 1. 1. Спектроскопические методы
- 1. 1. Спектроскопические, кинетические и биохимические методы определения катехоламинов
- 2. 1. Общие сведения об эндопероксидных соединениях
- 2. 2. Инструментальные методы определения антималярийных эндопероксидных соединений
- 2. 2. 1. Хроматографические методы
- 2. 2. 1. 1. Методы газовой хроматографии
- 2. 2. 1. 2. Методы жидкостной хроматографии
- 2. 2. 2. Оптические методы
- 2. 2. 3. Ферментативные методы
- 2. 2. 4. Электрохимические методы
- 2. 2. 1. Хроматографические методы
- 3. 1. Общие сведения об ионных жидкостях
- 3. 2. Ионные жидкости в химическом анализе и биотехнологии
- 3. 3. Использование ионных жидкостей в ферментативном катализе и биохимических методах анализа
- 3. 3. 1. ИЖ как реакционная среда для проведения ферментативных реакций
- 3. 3. 2. Применение ионных жидкостей для создания оптических биосенсоров
- 4. 1. Исходные вещества
- 4. 2. Посуда, аппаратура
- 4. 3. Методики эксперимента
- 4. 4. Обработка результатов измерений
- 6. 1. Кинетика реакций индивидуального пероксидазного окисления катехоламинов
- 6. 2. Кинетика реакций пероксидазного окисления катехоламинов в присутствии активаторов
- 6. 2. 1. Пероксидазное окисление допамина в присутствии о-фенилендиамина
- 6. 2. 2. Пероксидазное окисление катехоламинов в присутствии тироидных гормонов
- 6. 2. 3. Пероксидазное окисление а-метилдопы в присутствии 4-аминоантипирина
- 6. 3. Разработка ферментативных методик определения катехоламинов и пирокатехина
- 6. 4. Ферментативное определение катехоламинов в фармацевтических препаратах
- 7. 1. Спектрофотометрические системы
- 7. 2. Люминесцентные системы
- 7. 3. Разработка методик определения артемизинина и 1,2,4,5-тетраоксана
- 8. 1. Обоснование выбора молекулярных органических растворителей и гидрофильных ионных жидкостей
- 8. 2. Оптимизация условий пероксидазного окисления модельных фенольных соединений в водных и водно-органических средах
- 8. 2. 1. Водная среда
- 8. 2. 2. Среда вода-молекулярный органический растворитель
- 8. 2. 3. Среда вода-гидрофильная ионная жидкость
- 8. 3. Сравнительный анализ кинетики пероксидазного окисления гваякола и о-хлорфенола в водной и смешанных средах
- 8. 4. Разработка ферментативных методик определения гваякола и о-хлорфенола в водно-органических средах и в присутствии ионных жидкостей
- 8. 5. Анализ фармацевтического препарата на основе гваякола
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