Design of DNA origami

Author

Rothemund, Paul W K

Author_Institution

Comput. Sci. & Comput. & Neural Syst., California Inst. of Technol., Pasadena, CA, USA

fYear

2005

fDate

6-10 Nov. 2005

Firstpage

471

Lastpage

478

Abstract

The generation of arbitrary patterns and shapes at very small scales is at the heart of our effort to miniaturize circuits and is fundamental to the development of nanotechnology. Here I review a recently developed method for folding long single strands of DNA into arbitrary two-dimensional shapes using a raster fill technique - ´scaffolded DNA origami´. Shapes up to 100 nanometers in diameter can be approximated with a resolution of 6 nanometers and decorated with patterns of roughly 200 binary pixels at the same resolution. Experimentally verified by the creation of a dozen shapes and patterns, the method is easy, high yield, and lends itself well to automated design and manufacture. So far, CAD tools for scaffolded DNA origami are simple, require hand-design of the folding path, and are restricted to two dimensional designs. If the method gains wide acceptance, better CAD tools will be required.

Keywords

DNA; biomolecular electronics; integrated circuit design; integrated circuit manufacture; nanopatterning; 100 nm; 6 nm; CAD tools; DNA origami; automated design; automated manufacture; folding path; raster fill technique; Atomic force microscopy; DNA; Design automation; Hamming distance; Lithography; Nanostructures; Scanning electron microscopy; Self-assembly; Sequences; Shape;

fLanguage

English

Publisher

ieee

Conference_Titel

Computer-Aided Design, 2005. ICCAD-2005. IEEE/ACM International Conference on

Print_ISBN

0-7803-9254-X

Type

conf

DOI

10.1109/ICCAD.2005.1560114

Filename

1560114