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.

Highlights

  • Reversible addition-fragmentation chain transfer (RAFT) polymerization is a well-known reversible-deactivation radical polymerization (RDRP) mechanism that has attracted great attention due to its versatility in controlling the composition and molecular weight (Mw ) of the resulting polymers using mild reaction conditions [1,2]

  • 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

  • Complementary studies to better understand the interactions between the copolymer, biotin, and avidin were performed using Langmuir monolayers of the copolymer at the air/water interface, which proved that these interactions are time dependent

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Summary

Introduction

Reversible addition-fragmentation chain transfer (RAFT) polymerization is a well-known reversible-deactivation radical polymerization (RDRP) mechanism that has attracted great attention due to its versatility in controlling the composition and molecular weight (Mw ) of the resulting polymers using mild reaction conditions [1,2]. This polymerization mechanism has been explored to encapsulate inorganic cores in order to obtain well-defined core–shell nanostructures via RAFT-assisted encapsulating emulsion polymerization (REEP) [3,4]. This strategy involves two main steps: first, the adsorption of a previously prepared amphiphilic polymer containing a chain transfer agent (CTA)–the macroRAFT (MR) agent, onto the inorganic core; and chain extension via RAFT emulsion polymerization under monomer-starved conditions. The combination of RAFT polymerization with click chemistry has been carried out via two pathways: (1) by using “clickable” RAFT agents or (2) by incorporating “clickable” monomers in the polymerization This second strategy allows the preparation of polymers with higher functional group densities. Complementary studies to better understand the interactions between the copolymer, biotin, and avidin were performed using Langmuir monolayers of the copolymer at the air/water interface, which proved that these interactions are time dependent

Reagents
Synthesis of MacroRAFT Agents
Preparation of N3-MacroRAFT Agent
Copolymerization of MacroRAFT Agent via RAFT Emulsion Polymerization
Synthesis of Alkynated Biotin
Biosensing Tests
Characterization
4.4.Results
Visible μL of of BSA
Langmuir–Blodgett
Findings
Langmuir
Conclusions

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