Biomolecular implementation of linear I/O systems

Author

Oishi, Kazuaki ; Klavins, E.

Author_Institution

Dept. of Electr. Eng., Univ. of Washington, Seattle, WA, USA

Volume

5

Issue

4

fYear

2011

fDate

7/1/2011 12:00:00 AM

Firstpage

252

Lastpage

260

Abstract

Linear I/O systems are a fundamental tool in systems theory, and have been used to design complex circuits and control systems in a variety of settings. Here we present a principled design method for implementing arbitrary linear I/O systems with biochemical reactions. This method relies on two levels of abstraction: first, an implementation of linear I/O systems using idealised chemical reactions, and second, an approximate implementation of the ideal chemical reactions with enzyme-free, entropy-driven DNA reactions. The ideal linear dynamics are shown to be closely approximated by the chemical reactions model and the DNA implementation. We illustrate the approach with integration, gain and summation as well as with the ubiquitous robust proportional-integral controller.

Keywords

DNA; biochemistry; biological techniques; chemical reactions; enzymes; molecular biophysics; DNA implementation; biochemical reactions; biomolecular implementation; chemical reactions; control systems; entropy-driven DNA reaction; enzyme-free reaction; linear I/O systems; principled design method; ubiquitous robust proportional-integral controller;

fLanguage

English

Journal_Title

Systems Biology, IET

Publisher

iet

ISSN

1751-8849

Type

jour

DOI

10.1049/iet-syb.2010.0056

Filename

5979221