Grafting with RAFT—gRAFT Strategies to Prepare Hybrid Nanocarriers with Core-shell Architecture

Grafting with RAFT—gRAFT Strategies to Prepare Hybrid Nanocarriers with Core-shell Architecture

Stimuli-responsive polymer materials are used in smart nanocarriers to provide the stimuli-actuated mechanical and chemical changes that modulate cargo delivery. To take full advantage of the potential of stimuli-responsive polymers for controlled delivery applications, these have been grafted to th...

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Main Authors: José L. M. Gonçalves, Edgar J. Castanheira, Sérgio P. C. Alves, Carlos Baleizão, José Paulo Farinha
Format: Article
Language:English
Published: MDPI AG 2020-09-01
Series:Polymers
Subjects:
RAFT polymerization
grafting strategies
smart nanocarriers
core-shell hybrid mesoporous silica nanoparticles
pH-responsive polymeric shell
Online Access:https://www.mdpi.com/2073-4360/12/10/2175
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spelling doaj-b825d887f19b42dba2bfcb97d7a328252020-11-25T01:29:01ZengMDPI AGPolymers2073-43602020-09-01122175217510.3390/polym12102175Grafting with RAFT—gRAFT Strategies to Prepare Hybrid Nanocarriers with Core-shell ArchitectureJosé L. M. Gonçalves0Edgar J. Castanheira1Sérgio P. C. Alves2Carlos Baleizão3José Paulo Farinha4Centro de Química Estrutural and Department of Chemical Engineering, Instituto Superior Técnico, University of Lisbon, 1049-001 Lisboa, PortugalCentro de Química Estrutural and Department of Chemical Engineering, Instituto Superior Técnico, University of Lisbon, 1049-001 Lisboa, PortugalCentro de Química Estrutural and Department of Chemical Engineering, Instituto Superior Técnico, University of Lisbon, 1049-001 Lisboa, PortugalCentro de Química Estrutural and Department of Chemical Engineering, Instituto Superior Técnico, University of Lisbon, 1049-001 Lisboa, PortugalCentro de Química Estrutural and Department of Chemical Engineering, Instituto Superior Técnico, University of Lisbon, 1049-001 Lisboa, PortugalStimuli-responsive polymer materials are used in smart nanocarriers to provide the stimuli-actuated mechanical and chemical changes that modulate cargo delivery. To take full advantage of the potential of stimuli-responsive polymers for controlled delivery applications, these have been grafted to the surface of mesoporous silica particles (MSNs), which are mechanically robust, have very large surface areas and available pore volumes, uniform and tunable pore sizes and a large diversity of surface functionalization options. Here, we explore the impact of different RAFT-based grafting strategies on the amount of a pH-responsive polymer incorporated in the shell of MSNs. Using a “grafting to” (gRAFT-<i>to</i>) approach we studied the effect of polymer chain size on the amount of polymer in the shell. This was compared with the results obtained with a “grafting from” (gRAFT-<i>from</i>) approach, which yield slightly better polymer incorporation values. These two traditional grafting methods yield relatively limited amounts of polymer incorporation, due to steric hindrance between free chains in “grafting to” and to termination reactions between growing chains in “grafting from.” To increase the amount of polymer in the nanocarrier shell, we developed two strategies to improve the “grafting from” process. In the first, we added a cross-linking agent (gRAFT-<i>cross</i>) to limit the mobility of the growing polymer and thus decrease termination reactions at the MSN surface. On the second, we tested a hybrid grafting process (gRAFT-<i>hybrid</i>) where we added MSNs functionalized with chain transfer agent to the reaction media containing monomer and growing free polymer chains. Our results show that both modifications yield a significative increase in the amount of grafted polymer.https://www.mdpi.com/2073-4360/12/10/2175RAFT polymerizationgrafting strategiessmart nanocarrierscore-shell hybrid mesoporous silica nanoparticlespH-responsive polymeric shell
collection DOAJ
language English
format Article
sources DOAJ
author José L. M. Gonçalves
Edgar J. Castanheira
Sérgio P. C. Alves
Carlos Baleizão
José Paulo Farinha
spellingShingle José L. M. Gonçalves
Edgar J. Castanheira
Sérgio P. C. Alves
Carlos Baleizão
José Paulo Farinha
Grafting with RAFT—gRAFT Strategies to Prepare Hybrid Nanocarriers with Core-shell Architecture
Polymers
RAFT polymerization
grafting strategies
smart nanocarriers
core-shell hybrid mesoporous silica nanoparticles
pH-responsive polymeric shell
author_facet José L. M. Gonçalves
Edgar J. Castanheira
Sérgio P. C. Alves
Carlos Baleizão
José Paulo Farinha
author_sort José L. M. Gonçalves
title Grafting with RAFT—gRAFT Strategies to Prepare Hybrid Nanocarriers with Core-shell Architecture
title_short Grafting with RAFT—gRAFT Strategies to Prepare Hybrid Nanocarriers with Core-shell Architecture
title_full Grafting with RAFT—gRAFT Strategies to Prepare Hybrid Nanocarriers with Core-shell Architecture
title_fullStr Grafting with RAFT—gRAFT Strategies to Prepare Hybrid Nanocarriers with Core-shell Architecture
title_full_unstemmed Grafting with RAFT—gRAFT Strategies to Prepare Hybrid Nanocarriers with Core-shell Architecture
title_sort grafting with raft—graft strategies to prepare hybrid nanocarriers with core-shell architecture
publisher MDPI AG
series Polymers
issn 2073-4360
publishDate 2020-09-01
description Stimuli-responsive polymer materials are used in smart nanocarriers to provide the stimuli-actuated mechanical and chemical changes that modulate cargo delivery. To take full advantage of the potential of stimuli-responsive polymers for controlled delivery applications, these have been grafted to the surface of mesoporous silica particles (MSNs), which are mechanically robust, have very large surface areas and available pore volumes, uniform and tunable pore sizes and a large diversity of surface functionalization options. Here, we explore the impact of different RAFT-based grafting strategies on the amount of a pH-responsive polymer incorporated in the shell of MSNs. Using a “grafting to” (gRAFT-<i>to</i>) approach we studied the effect of polymer chain size on the amount of polymer in the shell. This was compared with the results obtained with a “grafting from” (gRAFT-<i>from</i>) approach, which yield slightly better polymer incorporation values. These two traditional grafting methods yield relatively limited amounts of polymer incorporation, due to steric hindrance between free chains in “grafting to” and to termination reactions between growing chains in “grafting from.” To increase the amount of polymer in the nanocarrier shell, we developed two strategies to improve the “grafting from” process. In the first, we added a cross-linking agent (gRAFT-<i>cross</i>) to limit the mobility of the growing polymer and thus decrease termination reactions at the MSN surface. On the second, we tested a hybrid grafting process (gRAFT-<i>hybrid</i>) where we added MSNs functionalized with chain transfer agent to the reaction media containing monomer and growing free polymer chains. Our results show that both modifications yield a significative increase in the amount of grafted polymer.
topic RAFT polymerization
grafting strategies
smart nanocarriers
core-shell hybrid mesoporous silica nanoparticles
pH-responsive polymeric shell
url https://www.mdpi.com/2073-4360/12/10/2175
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