D
Dylan W. Domaille
Researcher at Colorado School of Mines
Publications - 47
Citations - 5959
Dylan W. Domaille is an academic researcher from Colorado School of Mines. The author has contributed to research in topics: Self-healing hydrogels & Catalysis. The author has an hindex of 21, co-authored 43 publications receiving 5328 citations. Previous affiliations of Dylan W. Domaille include University of California, San Diego & University of California, Berkeley.
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Metals in Neurobiology: Probing Their Chemistry and Biology with Molecular Imaging
TL;DR: The brain is a singular organ of unique biological complexity that serves as the command center for cognitive and motor function and has requirements for the highest concentrations of metal ions in the body and the highest per-weight consumption of body oxygen.
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Synthetic fluorescent sensors for studying the cell biology of metals
TL;DR: A review of available synthetic small-molecule sensor types for fluorescence detection of cellular metals presents a host of emerging opportunities for visualizing, in real time, aspects of metal accumulation, trafficking, and function or toxicity in living systems.
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An ICT-Based Approach to Ratiometric Fluorescence Imaging of Hydrogen Peroxide Produced in Living Cells
TL;DR: Two-photon confocal microscopy experiments in live macrophages show that PL1 can ratiometrically visualize localized hydrogen peroxide bursts generated in living cells at immune response levels.
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Bacterial Killing by Dry Metallic Copper Surfaces
Christophe Espírito Santo,Christophe Espírito Santo,Ee Wen Lam,Christian Elowsky,Davide Quaranta,Dylan W. Domaille,Christopher J. Chang,Gregor Grass +7 more
TL;DR: These findings are important first steps for revealing the molecular sensitive targets in cells lethally challenged by exposure to copper surfaces and provide a scientific explanation for the use of copper surfaces as antimicrobial agents for supporting public hygiene.
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Visualizing ascorbate-triggered release of labile copper within living cells using a ratiometric fluorescent sensor.
TL;DR: Live-cell confocal microscopy experiments show that RCS1 is membrane-permeable and can sense changes in the levels of labile Cu(+) pools within living cells by ratiometric imaging, including expansion of endogenous stores of exchangeable intracellular Cu(+ triggered by ascorbate stimulation in kidney and brain cells.