Effect of Buffer Capacity and Ascorbic Acid on the Cyclization Reaction of Electrochemically Oxidized Dopamine, Levodopa, and Adrenaline on the Glassy Carbon Electrode

Xu, Xiaokun; Zhu, Ziling; Liu, Na; Li, Yanfang; Xiao, Li; Liu, Lian; Lin, Mi; Wang, Jianguo

doi:10.1149/2.0371609jes

J. Electrochem. Soc.

2016

DOI: 10.1149/2.0371609jes

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Effect of Buffer Capacity and Ascorbic Acid on the Cyclization Reaction of Electrochemically Oxidized Dopamine, Levodopa, and Adrenaline on the Glassy Carbon Electrode

Xiaokun Xu

Ziling Zhu

Na Liu

et al.

Abstract: The intramolecular cyclization step of oxidized catecholamines is crucial for neuromelanin (NM) and polydopamine (PDA). The product of the cyclization reaction of catecholamines has electrochemical activity, and its anodic and cathodic peaks occur at a more negative position than that of catecholamines. Moreover, in low pH, the amine group is protonated to a considerable extent; thus, the cyclization reaction is precluded. Our cyclic voltammetric results show that, in dilute buffer solution, the buffer concent… Show more

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Investigation of the Electron Transfer between Levodopa and Zinc Porphyrins at Bionic Interface

Yue¹

2018

International Journal of Electrochemical Science

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In this paper, the interface between two immiscible electrolyte solutions (ITIES) is adopted as the bionic interface model to investigate the interfacial electron transfer (ET) process of levodopa by using thin-layer cyclic voltammetry. Three zinc porphyrins with a systematic variation in structure are used as the reactants in the organic phase for the supply of varied overall driving forces at the ITIES. The consecutive two-step ET reactions between levodopa and three zinc porphyrins with the corresponding ET rate constants are evaluated precisely. The relationship between the interfacial ET rate constants and the overall driving force are also studied. It is found that the ET kinetics of the bimolecular reactions at the ITIES obeys the Marcus theory in a wide potential region. The results of this work will assist in our understanding of the interfacial electron-transfer process of levodopa in vivo.

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Investigation of the Electron Transfer between Levodopa and Zinc Porphyrins at Bionic Interface

Yue¹

2018

International Journal of Electrochemical Science

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Effect of Buffer Capacity and Ascorbic Acid on the Cyclization Reaction of Electrochemically Oxidized Dopamine, Levodopa, and Adrenaline on the Glassy Carbon Electrode

Cited by 1 publication

References 39 publications

Investigation of the Electron Transfer between Levodopa and Zinc Porphyrins at Bionic Interface

Investigation of the Electron Transfer between Levodopa and Zinc Porphyrins at Bionic Interface

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