Chemotactic synthetic vesicles: Design and applications in blood-brain barrier crossing

In recent years, scientists have created artificial microscopic and nanoscopic self-propelling particles, often referred to as nano- or microswimmers, capable of mimicking biological locomotion and taxis. This active diffusion enables the engineering of complex operations that so far have not been p...

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Detalhes bibliográficos
Autores: Azizi, Juzaili, Joseph, Adrian, Contini, Claudia, Cecchin, Denis, Nyberg, Sophie, Ruiz-Perez, Lorena, Preston, Jane, Volpe, Giorgio, Battaglia, Giuseppe, Gaitzsch, Jens, Fullstone, Gavin, Tian, Xiaohe
Tipo de documento: artigo
Estado:Versão publicada
Data de publicação:2017
País:España
Recursos:Varias* (Consorci de Biblioteques Universitáries de Catalunya, Centre de Serveis Científics i Acadèmics de Catalunya)
Repositório:Recercat. Dipósit de la Recerca de Catalunya
OAI Identifier:oai:recercat.cat:2445/222935
Acesso em linha:https://hdl.handle.net/2445/222935
Access Level:Acceso aberto
Palavra-chave:Barrera hematoencefàlica
Polímers
Quimiotaxi
Blood-brain barrier
Polymers
Chemotaxis
Descrição
Resumo:In recent years, scientists have created artificial microscopic and nanoscopic self-propelling particles, often referred to as nano- or microswimmers, capable of mimicking biological locomotion and taxis. This active diffusion enables the engineering of complex operations that so far have not been possible at the micro- and nanoscale. One of the most promising tasks is the ability to engineer nanocarriers that can autonomously navigate within tissues and organs, accessing nearly every site of the human body guided by endogenous chemical gradients. We report a fully synthetic, organic, nanoscopic system that exhibits attractive chemotaxis driven by enzymatic conversion of glucose. We achieve this by encapsulating glucose oxidase alone or in combination with catalase into nanoscopic and biocompatible asymmetric polymer vesicles (known as polymersomes). We show that these vesicles self-propel in response to an external gradient of glucose by inducing a slip velocity on their surface, which makes them move in an extremely sensitive way toward higher-concentration regions. We finally demonstrate that the chemotactic behavior of these nanoswimmers, in combination with LRP-1 (low-density lipoprotein receptor–related protein 1) targeting, enables a fourfold increase in penetration to the brain compared to nonchemotactic systems.<span style="color:rgba( 0 , 0 , 0 , 0 )"> recent years, </span>