Author
Listed:
- Evan Amalfitano
(University of Toronto)
- Margot Karlikow
(University of Toronto)
- Masoud Norouzi
(University of Toronto)
- Katariina Jaenes
(University of Toronto)
- Seray Cicek
(University of Toronto)
- Fahim Masum
(University of Toronto)
- Peivand Sadat Mousavi
(University of Toronto)
- Yuxiu Guo
(University of Toronto)
- Laura Tang
(University of Toronto)
- Andrew Sydor
(Peter Gilgan Center for Research and Learning)
- Duo Ma
(The Biodesign Institute and the School of Molecular Sciences)
- Joel D. Pearson
(Mt Sinai Hospital, Sinai Health System
University of Toronto
University of Toronto)
- Daniel Trcka
(Mt Sinai Hospital, Sinai Health System)
- Mathieu Pinette
(National Centre for Foreign Animal Disease)
- Aruna Ambagala
(National Centre for Foreign Animal Disease)
- Shawn Babiuk
(National Centre for Foreign Animal Disease)
- Bradley Pickering
(National Centre for Foreign Animal Disease
University of Manitoba
Iowa State University, College of Veterinary Medicine, Department of Veterinary Microbiology and Preventive Medicine)
- Jeff Wrana
(Mt Sinai Hospital, Sinai Health System
University of Toronto)
- Rod Bremner
(Mt Sinai Hospital, Sinai Health System
University of Toronto
University of Toronto)
- Tony Mazzulli
(University of Toronto
Sinai Health System/University Health Network)
- David Sinton
(University of Toronto)
- John H. Brumell
(Peter Gilgan Center for Research and Learning
University of Toronto
University of Toronto
Hospital for Sick Children)
- Alexander A. Green
(The Biodesign Institute and the School of Molecular Sciences
Boston University)
- Keith Pardee
(University of Toronto
University of Toronto)
Abstract
Recent advances in cell-free synthetic biology have given rise to gene circuit-based sensors with the potential to provide decentralized and low-cost molecular diagnostics. However, it remains a challenge to deliver this sensing capacity into the hands of users in a practical manner. Here, we leverage the glucose meter, one of the most widely available point-of-care sensing devices, to serve as a universal reader for these decentralized diagnostics. We describe a molecular translator that can convert the activation of conventional gene circuit-based sensors into a glucose output that can be read by off-the-shelf glucose meters. We show the development of new glucogenic reporter systems, multiplexed reporter outputs and detection of nucleic acid targets down to the low attomolar range. Using this glucose-meter interface, we demonstrate the detection of a small-molecule analyte; sample-to-result diagnostics for typhoid, paratyphoid A/B; and show the potential for pandemic response with nucleic acid sensors for SARS-CoV-2.
Suggested Citation
Evan Amalfitano & Margot Karlikow & Masoud Norouzi & Katariina Jaenes & Seray Cicek & Fahim Masum & Peivand Sadat Mousavi & Yuxiu Guo & Laura Tang & Andrew Sydor & Duo Ma & Joel D. Pearson & Daniel Tr, 2021.
"A glucose meter interface for point-of-care gene circuit-based diagnostics,"
Nature Communications, Nature, vol. 12(1), pages 1-10, December.
Handle:
RePEc:nat:natcom:v:12:y:2021:i:1:d:10.1038_s41467-020-20639-6
DOI: 10.1038/s41467-020-20639-6
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Citations
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Cited by:
- Margot Karlikow & Evan Amalfitano & Xiaolong Yang & Jennifer Doucet & Abigail Chapman & Peivand Sadat Mousavi & Paige Homme & Polina Sutyrina & Winston Chan & Sofia Lemak & Alexander F. Yakunin & Adam, 2023.
"CRISPR-induced DNA reorganization for multiplexed nucleic acid detection,"
Nature Communications, Nature, vol. 14(1), pages 1-11, December.
- Grace E. Vezeau & Lipika R. Gadila & Howard M. Salis, 2023.
"Automated design of protein-binding riboswitches for sensing human biomarkers in a cell-free expression system,"
Nature Communications, Nature, vol. 14(1), pages 1-13, December.
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