Briana N. Vogen scite author profile

Structural DNA nanotechnology, and specifically scaffolded DNA origami, is rapidly developing as a versatile method for bottom-up fabrication of novel nanometer-scale materials and devices. However, lengths of conventional single-stranded scaffolds, for example, 7,249-nucleotide circular genomic DNA from the M13mp18 phage, limit the scales of these uniquely addressable structures. Additionally, increasing DNA origami size generates the cost burden of increased staple-strand synthesis. We addressed this 2-fold problem by developing the following methods: (1) production of the largest to-date biologically derived single-stranded scaffold using a λ/M13 hybrid virus to produce a 51 466-nucleotide DNA in a circular, single-stranded form and (2) inexpensive DNA synthesis via an inkjet-printing process on a chip embossed with functionalized micropillars made from cyclic olefin copolymer. We have experimentally demonstrated very efficient assembly of a 51-kilobasepair origami from the λ/M13 hybrid scaffold folded by chip-derived staple strands. In addition, we have demonstrated two-dimensional, asymmetric origami sheets with controlled global curvature such that they land on a substrate in predictable orientations that have been verified by atomic force microscopy.

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Biocatalytic Microcontact Printing

Snyder

Johannes

Vogen

et al. 2007

J. Org. Chem.

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Soft-Lithographic Approach to Functionalization and Nanopatterning Oxide-Free Silicon

et al. 2011

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We report a simple, reliable high-throughput method for patterning passivated silicon with reactive organic monolayers and demonstrate selective functionalization of the patterned substrates with both small molecules and proteins. The approach completely protects silicon from chemical oxidation, provides precise control over the shape and size of the patterned features in the 100 nm domain, and gives rapid, ready access to chemically discriminated patterns that can be further functionalized with both organic and biological molecules.

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Self-assembling DNA templates for programmed artificial biomineralization

Sámano¹,

Pilo‐Pais²,

Goldberg³

et al. 2011

Soft Matter

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Briana N. Vogen

Toward Larger DNA Origami

Biocatalytic Microcontact Printing

Soft-Lithographic Approach to Functionalization and Nanopatterning Oxide-Free Silicon

Self-assembling DNA templates for programmed artificial biomineralization

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