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DNA- and RNA-Based Computing Systems


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5.5 Examples of combinatorial logic gates using half‐adder and full‐adder. (a) Half‐adder circuit diagram containing XOR and AND logic gates and its truth table. (b) Example of addition operation by the half‐adder that adds the two least significant bits highlighted in puncture/dashed line. (c) Circuit schematic and truth table for full‐adder. (d) Secondary structures demonstrating design principles for the Broccoli aptamer (XOR gate) and MG RNA aptamer (AND gate) and their fluorescence outputs in response to DNA inputs.

      Source: (Panel c) Adapted from Goldsworthy et al. [46]; (Panel d) From Goldsworthy et al. [46]. Licensed under CC by 4.0.

      The integration of advances in nucleic acid nanotechnology and in nucleic acid aptamer technologies makes it possible to build novel nanoparticles playing intermediate roles between electronic computers and biological systems. Programming with biological molecules, especially with nucleic acids (NA), is now becoming very attractive due to their potential of functions ranging from simple fluorescence emission to sophisticated gene regulation in vivo. The structural behavior encompassed within their sequences can be predicted and manipulated using 2D folding algorithms. The resulting nucleic acid biopolymers can then be used as logic‐gated nano‐agents for specific biomedical applications. Fluorogenic RNA aptamers can be designed to function as a simple circuit within individual binary logic gates. This demonstrates the great potential of nucleic acid nanotechnology and holds promise to develop cutting‐edge technologies, especially if synergistically combined with other computing and nanorobotic systems.

      This work was supported by the National Institute of Biomedical Imaging and Bioengineering of the National Institutes of Health under Award Number R03EB027910. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.

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