Bioresponsive Polymers 2020
DOI: 10.1201/9780429325243-1
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Introduction to Bioresponsive Polymers

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“…Therefore, the active PDMA could be exposed after the degradation and detachment of PCM-b-PEG under selected bacteria-associated microenvironment. [20][21][22][23][24][25] Moreover, our design allows traceable monitoring of the enzymatic degradation of the caging polymers by using dye-labeled PCM-b-PEG with fluorescence signals, which is quenched in the caged nanoparticles by AuNRs and recovers once being released from the AuNR surface. Finally, plasmonic AuNRs not only serve as a carrier of cationic polymers via the Au-S bond to form PDMA brushes, but also play multifunctional roles that are essential for improving antimicrobial activity by photothermal conversion and elucidating the working mechanism of the caged antimicrobial nanoparticles by scattering-based dark-field imaging.…”
Section: Introductionmentioning
confidence: 99%
“…Therefore, the active PDMA could be exposed after the degradation and detachment of PCM-b-PEG under selected bacteria-associated microenvironment. [20][21][22][23][24][25] Moreover, our design allows traceable monitoring of the enzymatic degradation of the caging polymers by using dye-labeled PCM-b-PEG with fluorescence signals, which is quenched in the caged nanoparticles by AuNRs and recovers once being released from the AuNR surface. Finally, plasmonic AuNRs not only serve as a carrier of cationic polymers via the Au-S bond to form PDMA brushes, but also play multifunctional roles that are essential for improving antimicrobial activity by photothermal conversion and elucidating the working mechanism of the caged antimicrobial nanoparticles by scattering-based dark-field imaging.…”
Section: Introductionmentioning
confidence: 99%