The challenges in using DNA origami are twofold, said Majikes. First, researchers are fabricating 3D structures using a foreign language -- the base pairs A, G, T and C. In addition, they're using those base-pair staples to twist and untwist the familiar double helix of DNA molecules so that the strands bend into specific shapes. That can be difficult to design and visualize. Majikes and Liddle urge researchers to strengthen their design intuition by building 3D mock-ups, such as sculptures made with bar magnets, before they start fabrication. These models, which can reveal which aspects of the folding process are critical and which ones are less important, should then be "flattened" into 2D to be compatible with computer-aided design tools for DNA origami, which typically use two-dimensional representations.DNA folding can be accomplished in a variety of ways, some less efficient than others, noted Majikes. Some strategies, in fact, may be doomed to failure.

"Pointing out things like 'You could do this, but it's not a good idea' -- that type of perspective isn't in a traditional journal article, but because NIST is focused on driving the state of technology in the nation, we're able to publish this work in the NIST journal," Majikes said. "I don't think there's anywhere else that would have given us the leeway and the time and the person hours to put all this together." Liddle and Majikes plan to follow up their work with several additional manuscripts detailing how to successfully fabricate nanoscale devices with DNA.

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