1. Quantifying Intracellular Single Vesicular Catecholamine Concentration with Open Carbon Nanopipettes to Unveil the Effect of L‐DOPA on Vesicular Structure
- Author
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Kim Long Le Vo, Andrew G. Ewing, Keke Hu, and Amir Hatamie
- Subjects
010405 organic chemistry ,Vesicle ,Kinetics ,chemistry.chemical_element ,Intracellular vesicle ,General Chemistry ,General Medicine ,010402 general chemistry ,01 natural sciences ,Carbon ,Catalysis ,Exocytosis ,0104 chemical sciences ,Levodopa ,Catecholamines ,chemistry ,Biophysics ,Catecholamine ,medicine ,Nanoparticles ,Cytometry ,Intracellular ,medicine.drug - Abstract
Understanding the regulatory mechanisms of exocytosis is essential for uncovering the pathologies of neuronal disorders and developing related pharmaceuticals. In this work intracellular vesicle impact electrochemical cytometry (IVIEC) measurements with different-sized (50-500 nm radius) open carbon nanopipettes (CNPs) were performed to quantify the vesicular content and release kinetics of specific vesicle populations grouped by orifice sizes. Intracellular vesicles with radius below 100 nm were captured and narrowed between 50 and 100 nm. On the basis of this, single vesicular catecholamine concentrations in the intracellular environment were quantified as 0.23-1.1 M. Our results with L-3,4-dihydroxyphenylalanine (L-DOPA)-exposure indicate that L-DOPA regulates exocytosis by increasing the dense core size and vesicular content while catecholamine concentrations didn't show obvious alterations. These were all achieved simultaneously and relatively noninvasively with open CNPs, and this methodology is applicable to the mechanistic study of the drugs in exocytosis modulation inside single cells as well as small living organisms.
- Published
- 2021
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