Pearce Amanda K, Travanut Alessandra, Couturaud Benoit, Taresco Vincenzo, Howdle Steven M, Alexander Morgan R, Alexander Cameron
Molecular Therapeutics and Formulation Division, School of Pharmacy, ‡EPSRC Programme Grant in Next Generation Biomaterials, School of Pharmacy, §School of Chemistry, and ∥Advanced Healthcare and Materials Division, School of Pharmacy, The University of Nottingham, University Park, NG72RD, Nottingham United Kingdom.
Molecular Therapeutics and Formulation Division, School of Pharmacy, EPSRC Programme Grant in Next Generation Biomaterials, School of Pharmacy, §School of Chemistry, and ∥Advanced Healthcare and Materials Division, School of Pharmacy, The University of Nottingham, University Park, NG72RD, Nottingham United Kingdom.
ACS Macro Lett. 2017 Jul 18;6(7):781-785. doi: 10.1021/acsmacrolett.7b00415. Epub 2017 Jul 5.
The widespread adoption of RAFT polymerization stems partly from the ease and utility of installing a functional chain transfer agent onto the ends of the generated polymer chains. In parallel, the Passerini multicomponent reaction offers great versatility in converting a wide range of easily accessible building blocks to functional materials. In this work, we have combined the two approaches such that a single, commonly available, RAFT agent is used in Passerini reactions to generate a variety of multifunctional RAFT chain transfer agents containing ester linkages. Reactions to generate the multifunctional RAFT agents took place under mild conditions and in good yields. The resulting Passerini-RAFT agents were able to exert control over radical polymerization to generate materials of well-defined molecular weights and dispersity. Furthermore, the presence in these polymer cores of ester and amide functionality through the Passerini chemistries, provided regions in the materials which are inherently biodegradable, facilitating any subsequent biomedical applications. The work overall thus demonstrates a versatile and facile synthetic route to multi functional RAFT chain transfer agents and biodegradable polymers.
可逆加成-断裂链转移(RAFT)聚合的广泛应用部分源于将功能性链转移剂安装到生成的聚合物链末端的简便性和实用性。与此同时,帕瑟里尼多组分反应在将各种易于获得的结构单元转化为功能材料方面具有很大的通用性。在这项工作中,我们将这两种方法结合起来,使得在帕瑟里尼反应中使用单一的、常见的RAFT试剂来生成各种含有酯键的多功能RAFT链转移剂。生成多功能RAFT试剂的反应在温和条件下进行,产率良好。所得的帕瑟里尼-RAFT试剂能够控制自由基聚合,以生成具有明确分子量和分散度的材料。此外,通过帕瑟里尼化学在这些聚合物核中存在酯和酰胺官能团,为材料提供了固有可生物降解的区域,便于随后的任何生物医学应用。因此,这项工作总体上展示了一条通往多功能RAFT链转移剂和可生物降解聚合物的通用且简便的合成路线。
