Integration of DNA and graphene oxide for the construction of various advanced logic circuits.

@article{Zhou2016IntegrationOD,
  title={Integration of DNA and graphene oxide for the construction of various advanced logic circuits.},
  author={Chunyan Zhou and Dali Liu and Changtong Wu and Yaqing Liu and Erkang Wang},
  journal={Nanoscale},
  year={2016},
  volume={8 40},
  pages={
          17524-17531
        }
}
Multiple advanced logic circuits including the full-adder, full-subtract and majority logic gate have been successfully realized on a DNA/GO platform for the first time. All the logic gates were implemented in an enzyme-free condition. The investigation provides a wider field of vision towards prototypical DNA-based algebra logical operations and promotes the development of advanced logic circuits. 
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Multifunctional Graphene/DNA-Based Platform for the Construction of Enzyme-Free Ternary Logic Gates.
In this work, we have successfully realized multivalued logic circuits including ternary INHIBIT and ternary OR logic gates in an enzyme-free condition by integration of graphene oxide and DNA for
A universal platform for multiple logic operations based on self-assembled a DNA tripod and graphene oxide
Construction of a Simple and Intelligent DNA-based Computing System for Multiplexing Logic Operations.
Implementation of cascade logic gates and majority logic gate on a simple and universal molecular platform
TLDR
It was found that DNA exhibits excellent peroxidase-like activity in a colorimetric system of TMB/H2O2/Hemin (TMB, 3,3′, 5,5′-Tetramethylbenzidine) in the presence of K+ and Cu2+, which is significantly inhibited by the addition of an antioxidant.
Designing logic gates based on 3-way DNAzyme complex
TLDR
This work proposes a 3-way DNAzyme complex composed of three E6 DNAzymes assembled using the biological characteristics of E6DNAzyme, and designs logic gates such as the OR gate, the AND gate, and the INHIBIT gate that will have a wide range of applications in DNA nanoscale programming, biological computing, and nanoscales medicine.
Versatile and Homogeneous DNA Tetraplex Platform for Constructing Label-Free Logic Devices: From Design to Application.
TLDR
By integrating two DNA tetraplex structures, a completely label-free logic platform with high scalability was established, with which a series of advanced functions were realized, including arithmetic (adders and subtractors) and nonarithmetic ones (majority and dual-transfer gates).
Design of DNA-based innovative computing system of digital comparison.
A DNA arithmetic logic unit for implementing data backtracking operations.
We present the application of redundant modules in the molecular cascade circuit, which can help trace the results of each logic gate. This provides a basis for finding the error position and judging
DNA-based digital comparator systems constructed by multifunctional nanoswitches.
TLDR
This work introduces a multi-input to multi-output DNA switch-based platform that can enable complex DC logical comparison and can inspire new designs and have intelligent digital comparator and in-field applications.
Multifunctional Biosensor Logic Gates Based on Graphene Oxide
TLDR
A YES gate and a AND gate are constructed by using the ability of graphene oxide to adsorb single strand and quench fluorescence and can be used not only as a logical element, but also to detect a specific target DNA.
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