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	Provedor de dados Rev. Microbiol. (1) BJPS (1) Electron. J. Biotechnol. (1) Autor Alves,Carlucio R (1) Assis,Odilio B.G (1) Furtado,Roselayne F (1) Guedes,Maria Izabel F (1) Moorefield,Charles N. (1) Newkome,George R. (1) Pimenta,Maria Gardenny R (1) Schultz,Anthony (1) Silva,Rui C.B (1) Trevors,J.T. (1) Vieira,Regine H.S.F (1) Mais... Palavra-chave Self-assembly (3) Arborol (1) Bacteria (1) Cell division (1) Dendrimer (1) Escherichia coli (1) Lysozyme (1) Molecular evolution (1) Supramolecular (1) Terpyridine (1) Mais... Tipo do documento Info:eu-repo/semantics/article (2) Journal article (1) Ano 2013 (1) 2007 (1) 1998 (1) País Brazil (2) Chile (1) Idioma Inglês (3)		Registro completo Provedor de dados:  BJPS País:  Brazil Título:  From dendrimers to fractal polymers and beyond Autores:  Moorefield,Charles N. Schultz,Anthony Newkome,George R. Data:  2013-01-01 Ano:  2013 Palavras-chave:  Arborol Dendrimer Supramolecular Terpyridine Self-assembly Resumo:  The advent of dendritic chemistry has facilitated materials research by allowing precise control of functional component placement in macromolecular architecture. The iterative synthetic protocols used for dendrimer construction were developed based on the desire to craft highly branched, high molecular weight, molecules with exact mass and tailored functionality. Arborols, inspired by trees and precursors of the utilitarian macromolecules known as dendrimers today, were the first examples to employ predesigned, 1 → 3 C-branched, building blocks; physical characteristics of the arborols, including their globular shapes, excellent solubilities, and demonstrated aggregation, combined to reveal the inherent supramolecular potential (e.g., the unimolecular micelle) of these unique species. The architecture that is a characteristic of dendritic materials also exhibits fractal qualities based on self-similar, repetitive, branched frameworks. Thus, the fractal design and supramolecular aspects of these constructs are suggestive of a larger field of fractal materials that incorporates repeating geometries and are derived by complementary building block recognition and assembly. Use of terpyridine-M2+-terpyridine (where, M = Ru, Zn, Fe, etc) connectivity in concert with mathematical algorithms, such as forms the basis for the Seirpinski gasket, has allowed the beginning exploration of fractal materials construction. The propensity of the fractal molecules to self-assemble into higher order architectures adds another dimension to this new arena of materials and composite construction. Tipo:  Info:eu-repo/semantics/article Idioma:  Inglês Identificador:  http://www.scielo.br/scielo.php?script=sci_arttext&pid=S1984-82502013000700007 Editor:  Universidade de São Paulo, Faculdade de Ciências Farmacêuticas Relação:  10.1590/S1984-82502013000700007 Formato:  text/html Fonte:  Brazilian Journal of Pharmaceutical Sciences v.49 n.spe 2013 Direitos:  info:eu-repo/semantics/openAccess Fechar

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