Charles A. Lynch scite author profile

Charles A. Lynch

4Publications

26Citation Statements Received

53Citation Statements Given

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Affiliations

Georgia Institute of Technology, University of Central Florida, Rose–Hulman Institute of Technology

Publications

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Selective Determination of Isothermally Amplified Zika Virus RNA Using a Universal DNA-Hairpin Probe in Less than 1 Hour

et al. 2019

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The recent outbreak of the Zika virus (ZIKV) in the Americas and multiple studies that linked the virus to the cases of microcephaly and neurological complications have revealed the need for cost efficient and rapid ZIKV diagnostics tests. Here, a diagnostic platform relying on a four-way junction (4WJ)-based biosensor with electrochemical readout using a Universal DNA-Hairpin (UDH) probe for the selective recognition of an isothermally amplified ZIKV RNA fragment is developed. The 4WJ structure utilizes an electrode-immobilized stem-loop (DNA-hairpin) probe and two DNA adaptor strands complementary to both the stem-loop probe and the targeted fragment of a ZIKV amplicon. One of the adaptor strands is responsible for high selectivity of the target recognition, while another helps unwinding the target secondary structure. The first adaptor strand contains a redox label methylene blue to trigger the current change in response to the target-dependent formation of the 4WJ structure on the surface of the electrode. The amplicon can be analyzed directly from the amplification sample without the need for its purification. The proposed diagnostic methodology exhibits the limit of ZIKV RNA detection of 1.11 fg/μL (∼0.3 fM) and high selectivity that allows for reliable discrimination of ZIKV from West Nile virus and four dengue virus serotypes. Overall, the analysis of ZIKV RNA can be completed in less than 1 h, including amplification and electrochemical detection.

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Fully Inkjet Printed 60GHz Backscatter 5G RFID Modules for Sensing and Localization in Internet of Things (IoT) and Digital Twins Applications

Adeyeye

Lynch

et al. 2021

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Inkjet-/3D-/4D-Printed "Zero-Power" Flexible Wearable Wireless Modules for Smart Biomonitoring and Pathogen Sensing

Lynch

Eid

Fang

et al. 2021

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5G/mm-Wave Fully-Passive Dual Rotman Lens-Based Harmonic mmID for Long Range Microlocalization Over Wide Angular Ranges

Lynch

Adeyeye

Eid

et al. 2023

IEEE Trans. Microwave Theory Techn.

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Charles A. Lynch

Selective Determination of Isothermally Amplified Zika Virus RNA Using a Universal DNA-Hairpin Probe in Less than 1 Hour

Fully Inkjet Printed 60GHz Backscatter 5G RFID Modules for Sensing and Localization in Internet of Things (IoT) and Digital Twins Applications

Inkjet-/3D-/4D-Printed "Zero-Power" Flexible Wearable Wireless Modules for Smart Biomonitoring and Pathogen Sensing

5G/mm-Wave Fully-Passive Dual Rotman Lens-Based Harmonic mmID for Long Range Microlocalization Over Wide Angular Ranges

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