Facile one-step solid-phase synthesis of multitopic organic-DNA hybrids via "click" chemistry

Ryan V. Thaner; Ibrahim Eryazici; Omar K. Farha; Chad A. Mirkin; Sonbinh T. Nguyen

doi:10.1039/c3sc53206b

Facile one-step solid-phase synthesis of multitopic organic-DNA hybrids via "click" chemistry

Ryan V. Thaner, Ibrahim Eryazici^*, Omar K. Farha, Chad A. Mirkin, Sonbinh T. Nguyen

^*Corresponding author for this work

Chemistry

Research output: Contribution to journal › Article › peer-review

38 Scopus citations

Abstract

A broad range of synthetically challenging-to-access small molecule-DNA hybrids can be readily synthesized in "one pot" and in high yields by coupling multi-azide cores to alkyne-modified DNAs on a solid support using click chemistry. The multi-functional products can be obtained in pure forms and on large scales (1 μmol) in a facile fashion. In addition, the distribution of the products can be controlled by changing the concentration of the azide core in solution and the strand-loading density on the solid-supports.

Original language	English (US)
Pages (from-to)	1091-1096
Number of pages	6
Journal	Chemical Science
Volume	5
Issue number	3
DOIs	https://doi.org/10.1039/c3sc53206b
State	Published - Mar 2014

ASJC Scopus subject areas

Chemistry(all)

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10.1039/c3sc53206b

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abstract = "A broad range of synthetically challenging-to-access small molecule-DNA hybrids can be readily synthesized in {"}one pot{"} and in high yields by coupling multi-azide cores to alkyne-modified DNAs on a solid support using click chemistry. The multi-functional products can be obtained in pure forms and on large scales (1 μmol) in a facile fashion. In addition, the distribution of the products can be controlled by changing the concentration of the azide core in solution and the strand-loading density on the solid-supports.",

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AU - Thaner, Ryan V.

AU - Eryazici, Ibrahim

AU - Farha, Omar K.

AU - Mirkin, Chad A.

AU - Nguyen, Sonbinh T.

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AB - A broad range of synthetically challenging-to-access small molecule-DNA hybrids can be readily synthesized in "one pot" and in high yields by coupling multi-azide cores to alkyne-modified DNAs on a solid support using click chemistry. The multi-functional products can be obtained in pure forms and on large scales (1 μmol) in a facile fashion. In addition, the distribution of the products can be controlled by changing the concentration of the azide core in solution and the strand-loading density on the solid-supports.

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