Your search keyword '"Barros-Timmons, Ana"' showing total 8 results

1. Biotinylation of optically responsive gold/polyelectrolyte nanostructures

Author

Pereira, Sónia O., Trindade, Tito, and Barros-Timmons, Ana

Published

2015

2. Polymer@gold Nanoparticles Prepared via RAFT Polymerization for Opto-Biodetection.

Author

Pereira, Sónia O., Barros-Timmons, Ana, and Trindade, Tito

Subjects

*COLLOIDAL gold, *GOLD nanoparticles, *REVERSIBLE phase transitions, *CHAIN transfer (Chemistry), *SURFACE plasmon resonance, *BIOSENSORS

Abstract

Colloidal gold nanoparticles (Au NPs) have been used in several biological applications, which include the exploitation of size- and shape-dependent Localized Surface Plasmon Resonance (LSPR) in biosensing devices. In order to obtain functional and stable Au NPs in a physiological medium, surface modification and functionalization are crucial steps in these endeavors. Reversible addition-fragmentation chain transfer (RAFT) polymerization meets this need offering the possibility of control over the composition and architecture of polymeric shells coating Au NPs. Furthermore, playing with a careful choice of monomers, RAFT polymerization allows the possibility to design a polymer shell with the desired functional groups aiming at Au based nanocomposites suitable for biorecognition and biotargeting. This review provides important aspects concerning the synthesis and optical properties of Au NPs as well as concepts of RAFT polymerization. Understanding these concepts is crucial to appreciate the chemical strategies available towards RAFT-polymer coated Au core-shell nanostructures, which are here reviewed. Finally, examples of applications in opto-biodetection devices are provided and the potential of responsive "smart" nanomaterials based on such structures can be applied to other biological applications. [ABSTRACT FROM AUTHOR]

Published

2018

3. Biofunctionalisation of colloidal gold nanoparticles via polyelectrolytes assemblies.

Author

Pereira, Sónia, Barros-Timmons, Ana, and Trindade, Tito

Subjects

*GOLD nanoparticles, *POLYELECTROLYTES, *MOLECULAR self-assembly, *PARTICLE size distribution, *CLUSTERING of particles, *THICKNESS measurement, *NANOCOMPOSITE materials, *ELECTROSTATICS

Abstract

Bioapplications of gold nanoparticles (Au NPs) have received significant attention due to their sensitive optical characteristics which depend on particle size and shape, state of aggregation and to surrounding (bio)chemical environment. In this review, we present an overview of several methods to synthesise stable colloidal Au NPs with focus on the use of the electrostatic assembly method of polyelectrolytes (PE) to functionalise Au NPs. This versatile method allows adjusting the thickness, chemical functions and the surface charge of the shells surrounding the Au NPs, thus the relevance of these features for the bioapplications of Au NPs involving surface-mediated processes is discussed. Moreover, because the PE used can be functionalised with organic fluorophores, drugs or antibodies yielding multifunctional nanocomposites useful for those applications, this review also provides an overview of the electrostatic assembly of functionalised PE onto Au NPs and their bioapplications. [ABSTRACT FROM AUTHOR]

Published

2014

4. Biofunctional Polymer Coated Au Nanoparticles Prepared via RAFT-Assisted Encapsulating Emulsion Polymerization and Click Chemistry.

Author

Pereira, Sónia O., Trindade, Tito, and Barros-Timmons, Ana

Subjects

CLICK chemistry, EMULSION polymerization, COLLOIDAL gold, POLYMERS, GOLD nanoparticles, THERMORESPONSIVE polymers, FOOD emulsions

Abstract

The use of reversible addition-fragmentation chain transfer (RAFT)-assisted encapsulating emulsion polymerization (REEP) has been explored to prepare diverse types of colloidal stable core–shell nanostructures. A major field of application of such nanoparticles is in emergent nanomedicines, which require effective biofunctionalization strategies, in which their response to bioanalytes needs to be firstly assessed. Herein, functional core–shell nanostructures were prepared via REEP and click chemistry. Thus, following the REEP strategy, colloidal gold nanoparticles (Au NPs, d = 15 nm) were coated with a poly(ethylene glycol) methyl ether acrylate (PEGA) macroRAFT agent containing an azide (N3) group to afford N3–macroRAFT@Au NPs. Then, chain extension was carried out from the NPs surface via REEP, at 44 °C under monomer-starved conditions, to yield N3–copolymer@Au NPs–core–shell type structures. Biotin was anchored to N3–copolymer@Au NPs via click chemistry using an alkynated biotin to yield biofunctionalized Au nanostructures. The response of the ensuing biotin–copolymer@Au NPs to avidin was followed by visible spectroscopy, and the copolymer–biotin–avidin interaction was further studied using the Langmuir–Blodgett technique. This research demonstrates that REEP is a promising strategy to prepare robust functional core–shell plasmonic nanostructures for bioapplications. Although the presence of azide moieties requires the use of low polymerization temperature, the overall strategy allows the preparation of tailor-made plasmonic nanostructures for applications of biosensors based on responsive polymer shells, such as pH, temperature, and photoluminescence quenching. Moreover, the interaction of biotin with avidin proved to be time dependent. [ABSTRACT FROM AUTHOR]

Published

2020

5. Impact of critical micelle concentration of macroRAFT agents on the encapsulation of colloidal Au nanoparticles.

Author

Pereira, Sónia O., Trindade, Tito, and Barros-Timmons, Ana

Subjects

*CRITICAL micelle concentration, *COLLOIDAL stability, *GOLD nanoparticles, *COLLOIDAL gold, *MOLECULAR weights, *EMULSION polymerization

Abstract

Graphical abstract Abstract Hypothesis Reversible addition fragmentation chain transfer (RAFT) - assisted encapsulating emulsion polymerization (REEP) has received considerable attention as an efficient strategy to prepare colloidal stable shell@core nanoparticles. Generally, amphipathic macroRAFT agents are used but the effect of working above or below the critical micelle concentration (CMC) of macroRAFT agents needs to be addressed. Hence, it is necessary to understand if this parameter has an impact not only on the stability of the colloids but also on the molecular mass of the polymer shell. Methods Here, the CMC of three different macroRAFT agent was determined and the effect of macroRAFT agents concentration on the colloidal stability of gold nanoparticles coated with macroRAFT agents (macroRAFT@Au) assessed. The subsequent chain extension from macroRAFT@Au NPs, resulting in encapsulated Au nanoparticles (copolymer@Au), has also been systematically studied. Findings Using the REEP approach it was possible to obtain stable encapsulated Au NPs. Moreover, this strategy opens the possibility of adjusting the macroRAFT agents concentration to tune the length of the polymer chains grown around Au cores which is of major interest for the design of biosensors based on responsive polymer shells, such as pH, temperature and photoluminescence quenching. [ABSTRACT FROM AUTHOR]

Published

2019

6. Effect of colloidal silver and gold nanoparticles on the thermal behavior of poly(t-butyl acrylate) composites.

Author

Fateixa, Sara, Daniel-da-Silva, Ana L., Jordão, Noémi, Barros-Timmons, Ana, and Trindade, Tito

Subjects

*COLLOIDAL silver, *GOLD nanoparticles, *POLYMERIC composites, *POLYBUTENES, *PARTICLE size distribution, *SURFACE chemistry

Abstract

Highlights: [•] Preparation of metal (Ag or Au) based nanocomposites by two distinct methods. [•] Study the effect of colloidal fillers on the T g of the poly(tert-butyl acrylate). [•] Variation of the chemical nature of the metal, average particle size and metal content. [•] Highlights the effect of the surface of organically capped colloids on T g . [ABSTRACT FROM AUTHOR]

Published

2013

7. Probing the interaction of oppositely charged gold nanoparticles with DPPG and DPPC Langmuir monolayers as cell membrane models.

Author

Torrano, Adriano A., Pereira, Ângela S., Oliveira, Osvaldo N., and Barros-Timmons, Ana

Subjects

*MOLECULAR probes, *GOLD nanoparticles, *LANGMUIR probes, *CELL membranes, *LECITHIN, *PHOSPHATIDYLGLYCEROL, *ZWITTERIONS

Abstract

Abstract: The growing use of nanoparticles in a variety of applications calls for detailed studies of their toxicology, which in turn require understanding the interactions between nanoparticles and living cells. Since simulating the interaction with real cell membranes is rather complex, Langmuir monolayers (LMs) have been used to mimic the first barrier encountered by a nanoparticle as it approaches a biological membrane to assess molecular-level interactions. In this study, we show how oppositely charged gold nanoparticles (Au-NPs) interact with monolayers of the zwitterionic dipalmitoylphosphatidyl choline (DPPC) and negatively charged dipalmitoylphosphatidyl glycerol (DPPG). The monolayers were spread on subphases containing two concentrations of either negatively charged Au-NPs coated with citrate anions or positively charged Au-NPs functionalized with the cationic polyelectrolyte poly(allylamine hydrochloride) (PAH). For DPPG, electrostatic effects dominated which depended strongly on the NPs capping agent, being obviously larger for the positive nanoparticles. The in-plane elasticity for DPPG monolayers within the surface pressure range corresponding to real cell membranes increased with adsorption of positively charged NPs, but decreased with the negative ones. For the zwitterionic DPPC, on the other hand, significant effects only occurred for negatively charged NPs, including a decrease in elasticity. Therefore, it is concluded that the nature, namely the charge of the capping agents, is crucial for the interaction of charged NPs with the cell membrane. [Copyright &y& Elsevier]

Published

2013

8. Preparação de nanoestruturas multifuncionais de polímero@ouro e preparação de filmes finos em multicamadas para biodeteção

Author

Christé, Suzanne, Barros-Timmons, Ana Margarida Madeira Viegas de, and Pereira, Sónia Oliveira

Subjects

Surface modification and functionalization, RAFT polymerization, Biosensing, Química inorgânica e materiais, Gold nanoparticles, Multilayered thin films, Ouro - Nanopartículas, Filmes finos de multicamadas, Layer-by-Layer, Shell@core nanostructure

Abstract

Mestrado em Química Inorgânica e Materiais O objetivo desta tese de mestrado era desenvolver nanoestruturas robustas e multifuncionais do tipo coroa@núcleo para servir como base num sensor biológico. A estabilidade e as propriedades óticas das nanopartículas de ouro (Au NPs), nomeadamente a ressonância de plasmão de superfície localizada (LSPR), tornam as excelentes candidatos para o desenvolvimento de biossensores baseados em SPR. No seguimento de um trabalho anterior, procedeu-se primeiro à otimização da encapsulação e funcionalização dasAu NPs. Em segundo lugar, preparou-se filmes finos de multicamadas que incorporam as nanopartículas encapsuladas. Au NPs (15  4 nm) foram sintetizadas pelo método de Turkevich, e sua superfície foi revestida por polimerização de transferência de cadeia reversível por adição-fragmentação (RAFT) assistida em encapsulante emulsão (REEP). Foram explorados dois tipos de nanoestruturas: i) nanoestruturas não funcionalizadas foram preparadas com sucesso adsorvendo um agente macroRAFT (MR) P(PEGA40)-TTC) não funcionalizado nas Au NPs, seguido pelo crescimento do bloco hidrofóbico usando uma mixtura (10:1 w/w) de metacrilato de metilo (MMA) e de acrilato de butilo (BA) a partir de MR@Au NPs; e ii) nanoestruturas funcionalizadas foram preparadas usando um agente MR funcionalizado com um bioreceptor (biotina) e um fluoróforo (isotiocianato de fluoresceína - FITC). Foram realizadas tentativas para crescer o bloco hidrofóbico apartir das nanoestruturas multifuncionais MR@Au com o objetivo de melhorar a sua resposta óptica aumentando a distância entre o núcleo e o fluoróforo. No entanto, concluiu-se que a estratégia seguida para preparar estas nanoestruturas multifuncionais tem de ser revista. O tamanho e a estabilidade das nanoestruturas de ouro foi avaliado por espectroscopia UV-Visível e fluorescência, STEM (microscopia eletrónica de transmissão de varrimento), DLS (dispersão dinâmica de luz) e medidas de potencial zeta. A caracterização química e estrutural dos polímeros foi feita por espectroscopias de 1H-RMN (ressonância magnética nuclear de protões) e de infravermelho, e cromatografia de permeação de gel – cromatografia de exclusão por tamanho (GPC-SEC). Em seguida, foram realizados testes de biodeteção usando a nanoestrutura multifuncional de coroa@núcleo no sentido de avaliar a sua resposta óptica na presença de um bioanalito específico - avidin. No entanto, estes testes não foram conclusivos devido às limitações da estratégia seguida para preparar as nanoestruturas multifuncionais. Paralelamente ao trabalho descrito acima, estudou-se a preparação de filmes finos usando o método camada a camada (Layer-by-Layber, LbL) baseado em interações electrostáticas, para isso foi usado o hidrocloreto de polialilamina (PAH) e as nanoestruturas de Au. Foram estudados alguns parâmetros nomeadamente o peso molecular, tempo de deposição, pH e força iónica, e o número de camadas. O objetivo final era depositar na última camada as nanoestruturas de ouro funcionalizadas com biotina-FITC. O procedimento para a deposição por LbL das NPs de Au encapsuladas foi realizado com sucesso, mas uma vez que os testes de biodeteção não foram conclusivos este último passo não foi efectuado. The aim of this master thesis was to develop robust, easily prepared multifunctional shell@core gold nanostructures to serve as a basis for customization into a specific biological sensor. The stability and optical properties of gold nanoparticles (Au NPs), namely the localized surface plasmon resonance (LSPR), makes them excellent candidates for the development of SPR-based biosensors. In this work, the preparation and functionalization of the gold nanoparticles was first optimized, on the basis of the previous work. Next, multilayered thin-films embedding these gold nanostructures were prepared. Au NPs (15  4 nm) were synthetized by the Turkevich method, and their surface was coated via reversible addition fragmentation chain transfer (RAFT) assisted encapsulating emulsion polymerization (REEP). The preparation of two types of nanostructures was explored: i) non-functionalized nanostructures were successfully prepared using the macroRAFT (MR) agent P(PEGA40)-TTC) adsorbed onto Au NPs, followed the growth of a hydrophobic block using a 10:1 (w/w) mixture of methyl methacrylate and butyl acrylate from MR@Au NPs; and ii) functionalized nanostructures were prepared using a MR agent functionalized with a bio-receptor (biotin) and a fluorophore (fluorescein isothiocyanate - FITC). Attempts to grow a hydrophobic block from the multifunctional MR@Au NPs were carried out to enhance the optical response by increasing the distance between the core and fluorophore. Yet, the synthetic strategy followed to prepare this type of multifunctional nanostructures needs to be revised. The size and stability of gold nanostructures were characterized by UV-Visible and fluorescence spectroscopy, STEM (scanning transmission electron microscopy), DLS (dynamic light scattering) and Zeta potential measurements. The chemical and structural characterization of polymers was carried out by 1HNMR (proton nuclear magnetic resonance), infrared spectroscopies and gel permeation chromatography – size exclusion chromatography (GPC-SEC). Then, biosensing tests were performed on the multifunctional shell@core nanostructures synthetized to assess their optical response towards a specific bioanalyte - avidin. However, these tests were inconclusive due to the limitations of the synthetic strategy followed to prepare the Au nanostructures. Parallel to the synthetic work described above, the preparation of thin films via electrostatic interactions using the Layer-by-Layer (LbL) method was studied, using poly(allylamine hydrochloride) (PAH) and carboxylic acid terminated non-functionalized Au nanostructures. Various parameters were studied such as molecular weight, deposition time, pH and ionic strength, as well as the number of layers. The final goal was to deposit the biotin-FITC-functionalized gold nanostructure as last layer. The optimized procedure for LbL deposition of the encapsulated Au NPs was fully accomplished, in view of the fact that the biosensing tests were inconclusive, this last step was not carried out.

Published

2017