Пиридилфениленовые дендримеры: фундаментальные и прикладные аспекты тема диссертации и автореферата по ВАК РФ 02.00.06, доктор химических наук Шифрина, Зинаида Борисовна

80-ые годы прошлого века ознаменовались появлением нового класса макромолекулярных соединений - монодисперсных полимеров с регулярной и сильно разветвленной трехмерной архитектурой и четко определенной химической структурой, получивших название дендримеры (от греческого 8гу8ро\' (ёепёгоп) -дерево, ветвь). Дендримеры получают путем повторяющейся последовательности химических превращений, в которой каждая дополнительная итерация приводит к увеличению генерации дендримера. Синтез дендримеров с помощью специально разработанных химических реакций, протекающих с высоким выходом, является одним из примеров управляемого иерархического синтеза.

Первыми подробно изученными дендритными системами стали полиамидоаминные дендримеры (ПАМАМ), синтезированные в группе профессора ТотаНа [1] и «агЬого1» дендримеры профессора Кешкоте [2]. Оба типа дендримеров были синтезированы дивергентным методом, когда рост молекулы осуществляется от многофункционального центра к периферии. Позднее, взяв за основу пионерские работы, [3], МЫНаирг [4] и ёе ВгаЬапс1ег [5] описали полипропилениминовые дендримеры (ППИ), также полученные дивергентным методом. В 1990 году РгёсЬе! разработал конвергентный подход к синтезу дендримеров [6,7]. В случае конвергентной процедуры синтез начинается от периферии и развивается к центру молекулы. Известные к настоящему времени дендримеры получают либо дивергентным, либо конвергентным методом, в некоторых случаях возможна комбинация обоих подходов.

В настоящее время мир дендримеров обширен, а их специфические свойства многообразны. Дендримеры обладают уникальной молекулярной регулярностью, имеют мультифункциональную периферию и значительные внутренние «полости». Периферия, внутренние области и ядро дендримеров могут быть произвольно модифицированы. К числу несомненных достоинств дендримеров стоит отнести их монодисперсность и возможность надежного контроля над размерами, формой и функциональностью, реализуемого в процессе многоступенчатого синтеза макромолекулы. Указанные особенности позволяют дендримерам занять определенную нишу в тех современных технологиях, где использование традиционных полимерных соединений невозможно или малоэффективно.

Дендримеры нашли широкое применение в медицине в качестве контрастных агентов в магнито-резонансной томографии, средств доставки лекарств, в in vitro диагностике, в бор-нейтронозахватной терапии, а также в качестве наноразмерных реакторов и систем, имитирующих мицеллы.

Дендримеры эффективно используются в различных химических технологиях. Так, например, дендримеры, содержащие на периферии каталитические активные центры, активируют полимеризацию мономеров, а затем могут быть отделены от реакционной смеси путем микрофильтрации. Известны дендримеры, являющиеся катализаторами электрохимического восстановления двуокиси углерода в монооксид углерода. Некоторые функционализированные дендримеры используются для экстракции гидрофильных соединений из воды в сверхкритический СО?. Кроме того дендримеры способны инкапсулировать нерастворимые продукты или наночастицы металлов во внутренние «полости» и переносить их в растворители. Особый интерес исследователей вызывают композиты дендримеров с неорганическими наноразмерными частицами благодаря уникальным свойствам, возникающим в результате сложных физико-химических взаимодействий наноразмерных составляющих неорганической и органической природы.

Обсуждение синтеза дендримеров и каталитических, оптических, магнитных и некоторых других свойств таких систем, а также их возможные применения нашли свое отражение в многочисленных оригинальных статьях и обзорах последнего десятилетия. Проблемы химии дендримеров также рассматривались на многочисленных международных научных форумах.

Первые дендримеры, содержащие только ароматические группы, были синтезированы в 1990 году по конвергентной схеме Miller и Neenan[8] с использованием реакции Pd катализируемого кросс-сочетания. Дивергентный метод, который позволил получить полифениленовые дендримеры, не прибегая к металлорганическому синтезу, был разработан в 1996 году в группе профессора Muellen [9]. Позднее в этой группе был разработан и конвергентный подход [10].

Полифениленовые дендримеры имеют ряд особенностей, определяемых их химической структурой. Так, дендримеры обладают высокой жесткостью и постоянной формой, обусловленной присутствием в структуре разветвленных цепочек фенильных колец, соединенных между собой в пара-положении (Рис. 1).

Рисунок 1 - Модель дендрона: разные цепи жестких полифениленовых фрагментов показаны разным цветом В то время как достаточно длинные цепи пара-фениленов могут в некоторой степени изгибаться[11], относительно короткие цепочки (что характерно для дендримеров), состоящие из 3-9 фенильных колец, остаются неизменно прямыми и не загибаются внутрь. Средняя персистентная длина 20 нм соответствует цепочке, состоящей из 46 фенильных колец [12-15]. Таким образом, в отличие от других типов дендримеров, состоящих их гибких блоков, полифениленовые дендримеры не изменяют форму в зависимости от внешних условий. Этому также способствует и достаточно плотная упаковка ветвей. Жесткость и неизменная форма дендримеров были доказаны с помощью ряда методов, таких как малоугловое нейтронное рассеяние (МУНР) [16], атомно-силовая микроскопия (АСМ) [17] и ЯМР твердого тела [18,19]. Химическая структура полифениленовых дендримеров определяет их высокую термическую и химическую стабильность.

Полифениленовые дендримеры нашли свое применение в органической оптоэлектронике [20,21], а также в качестве составляющих супрамолекулярных ансамблей [22,23]. Вместе с тем отсутствие в структуре полифениленовых дендримеров функциональных групп, способных специфически взаимодействовать с химическими соединениями разной природы, приводя к формированию комплексных систем с новыми полезными свойствами, ограничивает развитие и области применения этих дендримеров. Нами было предложено введение в структуру фениленовых дендримеров азотсодержащих ароматических фрагментов, что приводило к получению нового типа ароматических дендримеров и открывало перспективы для их использования в современной науке и технологиях. При этом постоянная форма, высокая термическая и химическая стабильность, внутренние гидрофобные полости также характерны для новой группы дендримеров. Присутствие азотсодержащих ароматических фрагментов в дендримерах способствует разработке широкого спектра композитных наноматериалов на основе процессов комплексообразования с различными соединениями металлов. Кроме того, возможность изменения гидрофобной природы дендримеров на гидрофильную за счет функционализации пиридиновых фрагментов, приводит к получению дендримеров, способных взаимодействовать с биологическими объектами, расширяя области возможных применений дендримеров.

Таким образом, исследования, направленные на развитие химии функциональных ароматических дендримеров, разработку молекулярного дизайна таких дендримеров, а также поиск возможных областей их применения, представлялись весьма актуальными и важными.

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