Cedric Hurth
Overview
Explore the profile of Cedric Hurth including associated specialties, affiliations and a list of published articles.
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Articles
12
Citations
49
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0
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Recent Articles
1.
Porta-de-la-Riva M, Carolina Gonzalez A, Sanfeliu-Cerdan N, Karimi S, Malaiwong N, Pidde A, et al.
Nat Methods
. 2023 Apr;
20(5):761-769.
PMID: 37024651
Neuronal computation is achieved through connections of individual neurons into a larger network. To expand the repertoire of endogenous cellular communication, we developed a synthetic, photon-assisted synaptic transmission (PhAST) system....
2.
Yang J, Kidd M, Nordquist A, Smith S, Hurth C, Modlin I, et al.
Infect Dis Rep
. 2021 Dec;
13(4):1061-1077.
PMID: 34940407
Since the outbreak of the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) pandemic in December 2019, the spread of SARS-CoV2 infection has been escalating rapidly around the world. In order...
3.
Sibilo R, Perez J, Tebbenjohanns F, Hurth C, Pruneri V
Biomed Opt Express
. 2019 Aug;
10(7):3698.
PMID: 31467799
[This corrects the article on p. 2101 in vol. 10, PMID: 31061773.].
4.
Sibilo R, Perez J, Hurth C, Pruneri V
Biomed Opt Express
. 2019 May;
10(4):2101-2116.
PMID: 31061773
Monitoring the early onset of bacterial film formation is critical in many clinical, environmental, and food quality control applications. We built a small inexpensive optical surface cytometer, in contrast with...
5.
Yang J, Hurth C, Nordquist A, Smith S, Zenhausern F
Methods Mol Biol
. 2018 Nov;
1906:207-224.
PMID: 30488395
A fully automated rapid DNA analysis system requires integrating several operational elements performing multiple steps onto one single microfluidic platform. The functions to include on the microfluidic platform consist of...
6.
Hurth C, Yang J, Barrett M, Brooks C, Nordquist A, Smith S, et al.
Biomed Microdevices
. 2014 Aug;
16(6):905-14.
PMID: 25106501
We report a microfluidic device and measurement method to perform real-time PCR (or qPCR) in a miniaturized configuration for on-chip implementation using reaction volumes of less than 20 μL. The...
7.
Estes M, Hurth C, Barrett M, Zenhausern F
Phys Chem Chem Phys
. 2013 May;
15(31):12805-14.
PMID: 23636584
We report an on-chip gradient generator that has been designed, modelled, fabricated, and characterized to facilitate temporal tuning of several unique gradients in parallel for multiple applications. This design allows...
8.
Direct loading of polymer matrices in plastic microchips for rapid DNA analysis: a comparative study
Hurth C, Gu J, Aboud M, Estes M, Nordquist A, McCord B, et al.
Electrophoresis
. 2012 Aug;
33(16):2604-11.
PMID: 22899270
We report the design and performance validation of microfluidic separation technologies for human identification using a disposable plastic device suitable for integration into an automated rapid DNA analysis system. A...
9.
Hurth C, Smith S, Nordquist A, Lenigk R, Duane B, Nguyen D, et al.
Electrophoresis
. 2010 Oct;
31(21):3510-7.
PMID: 20931618
The microfluidic integration of an entire DNA analysis workflow on a fully integrated miniaturized instrument is reported using lab-on-a-chip automation to perform DNA fingerprinting compatible with CODIS standard relevant to...
10.
Hopwood A, Hurth C, Yang J, Cai Z, Moran N, Lee-Edghill J, et al.
Anal Chem
. 2010 Aug;
82(16):6991-9.
PMID: 20704389
We demonstrate a conduit for the delivery of a step change in the DNA analysis process: A fully integrated instrument for the analysis of multiplex short tandem repeat DNA profiles...