G
Gerald Urban
Researcher at University of Freiburg
Publications - 420
Citations - 9679
Gerald Urban is an academic researcher from University of Freiburg. The author has contributed to research in topics: Electrode & Biosensor. The author has an hindex of 45, co-authored 408 publications receiving 7871 citations. Previous affiliations of Gerald Urban include University of Vienna & IMTEK.
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A Real-Time Thermal Sensor System for Quantifying the Inhibitory Effect of Antimicrobial Peptides on Bacterial Adhesion and Biofilm Formation.
Tobias Wieland,Julia Assmann,Astrid Bethe,Christian Fidelak,Helena Gmoser,Traute Janßen,Krishan Kotthaus,Antina Lübke-Becker,Lothar H. Wieler,Lothar H. Wieler,Gerald Urban +10 more
TL;DR: In this paper, a thermal sensor was used to monitor the effect of two potent AMPs, protamine and OH-CATH-30, on surface colonization of bovine mastitis-associated Escherichia (E.) coli and Staphylococcus (S.) aureus.
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Highly Sensitive Electrochemical Glutamate Microsensors for Food Analysis
TL;DR: A disposable electrochemical microsensor platform with multiple integrated, highly sensitive (detection limit <150 nM) and selective enzyme-based glutamate biosensors is developed and successfully demonstrated the capabilities of electrochemical biosensor in food monitoring, analysis and quality control.
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Simulation model validation of two common i-line photoresists
TL;DR: It is demonstrated that with the data provided by a Dissolution Rate Monitor (DRM) the quality of lithography simulation results can improve and can speed up process development and optimization.
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In-vivo monitoring of infection via implantable microsensors: a pilot study.
Andrej Ring,Heiko Sorg,Andreas Weltin,Daniel J. Tilkorn,Jochen Kieninger,Gerald Urban,Jörg Hauser +6 more
TL;DR: The given results in this study are the first hints on a promising new tool and should be interpreted as a proof of the principle to show the functionality of the microsensors in an in vivo setting.
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Fenton fragmentation for faster electrophoretic on chip purification of amplifiable genomic DNA.
TL;DR: This work introduces on-chip lysis and non-enzymatic DNA cleavage directly followed by a purifying step for receiving amplifiable DNA fragments from bacteria in less than 25 min and enables electrophoretic extraction methods to unspecifically process long genomic DNA in a short time frame.