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Thermal Regulation of Colloidal Materials Architecture through Orthogonal Functionalizable Patchy Particles
Abstract
This contribution presents a sol–gel based cluster encapsulation methodology to produce bifunctional patchy particles. The particles possess azide moieties on the surfaces of the patch and carboxylic acids on the shell. Two types of DNA with distinct terminal sequences are site-specifically conjugated to the particle patches or the shell employing two orthogonal coupling strategies: strain-promoted alkyne–azide cycloaddition and carbodiimide-mediated amidation. We can activate and deactivate assembly on the patches and/or the shell through thermal control, demonstrating reversible and stepwise self-assembly- Dataset
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- Biophysics
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- Genetics
- Molecular Biology
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- Developmental Biology
- Cancer
- Inorganic Chemistry
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- Environmental Sciences not elsewhere classified
- Chemical Sciences not elsewhere classified
- Physical Sciences not elsewhere classified
- terminal sequences
- carboxylic acids
- deactivate assembly
- bifunctional patchy particles
- DNA
- particle patches
- Colloidal Materials Architecture
- Thermal Regulation
- azide moieties
- Orthogonal Functionalizable Patchy Particles
- cluster encapsulation methodology
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Last time updated on 12/02/2018
This paper was published in The Francis Crick Institute.
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