Abstract
We present an implementation of an in vitro signal recorder based on DNA assembly and strand displacement. The signal recorder implements a stack data structure in which both data as well as operators are represented by single stranded DNA “bricks”. The stack grows by adding push and write bricks and shrinks in last-in-first-out manner by adding pop and read bricks. We report the design of the signal recorder and its mode of operations and give experimental results from capillary electrophoresis as well as transmission electron microscopy that demonstrate the capability of the device to store and later release several successive signals. We conclude by discussing potential future improvements of our current results.
H. Fellermann and A. Lopiccolo—Contributed equally to this work.
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Acknowledgments
This work has been supported by EPSRC grant agreements no EP/J004111/1, EP/J004111/2, EP/L001489/1, EP/L001489/2. We thank Chien-yi Chang, Christoph Flamm, Alessandro Ceccarelli, Omer Markovitch, and Ben Shirt-Ediss for helpful discussions.
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Fellermann, H., Lopiccolo, A., Kozyra, J., Krasnogor, N. (2016). In Vitro Implementation of a Stack Data Structure Based on DNA Strand Displacement. In: Amos, M., CONDON, A. (eds) Unconventional Computation and Natural Computation. UCNC 2016. Lecture Notes in Computer Science(), vol 9726. Springer, Cham. https://doi.org/10.1007/978-3-319-41312-9_8
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