Abstract
AbstractCell-free biosensors are powerful platforms for monitoring human and environmental health. Here, we expand their capabilities by interfacing them with toehold-mediated strand displacement circuits, a dynamic DNA nanotechnology that enables molecular computation through programmable interactions between nucleic acid strands. We develop design rules for interfacing a small molecule sensing platform called ROSALIND with toehold-mediated strand displacement to construct hybrid RNA–DNA circuits that allow fine-tuning of reaction kinetics. We use these design rules to build 12 different circuits that implement a range of logic functions (NOT, OR, AND, IMPLY, NOR, NIMPLY, NAND). Finally, we demonstrate a circuit that acts like an analog-to-digital converter to create a series of binary outputs that encode the concentration range of the molecule being detected. We believe this work establishes a pathway to create ‘smart’ diagnostics that use molecular computations to enhance the speed and utility of biosensors.
Funder
Northwestern University’s Graduate School Cluster in Biotechnology, System, and Synthetic BiologyNorthwestern Ryan Fellowship Northwestern McCormick School of Engineering Terminal Year Fellowship
National Defense Science & Engineering Graduate (NDSEG) Fellowship
National Science Foundation
Crown Family Center for Jewish and Israel Studies at Northwestern UniversitySearle Funds at The Chicago Community Trust
Publisher
Springer Science and Business Media LLC
Subject
Cell Biology,Molecular Biology
Cited by
79 articles.
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