The reaction mechanism of p-hydroxystyryl-substituted BODIPY with ABTS•+ and Fe3+ in solutions and in liposomes

The reaction mechanism of p-hydroxystyryl-substituted BODIPY with ABTS•+ and Fe3+ in solutions and in liposomes

The reaction mechanism of p-hydroxystyryl-substituted BODIPY (BOH) with two oxidative cations, namely ABTS•+ and Fe3+, was investigated in a water–ethanol mixed solution and in liposome suspensions, respectively, using different spectroscopic methods. In solution, the oxidation of BOH (with orange f...

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Bibliographic Details
Main Authors: Qinhai Xu, Kang Li, Peng Wang
Format: Article
Language:English
Published: Elsevier 2025-01-01
Series:Arabian Journal of Chemistry
Subjects:
BODIPY derivatives
Antioxidant fluorescent probe
Reaction mechanism
Small unilamella vesicle
Water-soluble oxidants
Online Access:http://www.sciencedirect.com/science/article/pii/S187853522400443X
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Summary:The reaction mechanism of p-hydroxystyryl-substituted BODIPY (BOH) with two oxidative cations, namely ABTS•+ and Fe3+, was investigated in a water–ethanol mixed solution and in liposome suspensions, respectively, using different spectroscopic methods. In solution, the oxidation of BOH (with orange fluorescence) by the two cations occurred at the ethylene group (CC) locating between the dipyrrole and phenol groups and resulted in conjugation-truncated products exhibiting characteristic green fluorescence emission. In heterogeneous small unilamellar vesicles (SUV), water soluble ABTS•+ was evidenced to oxidize BOH embedded in the lipid bilayers of SUV, while Fe3+ did not. The lack of reaction between Fe3+ and BOH was attributed to the complexation between Fe3+ and the phenolic hydroxyl group of BOH on the surface of the SUV. The reaction kinetics results indicated that, in homogeneous solution, the oxidation rate of Fe3+ was three orders of magnitude slower than that of ABTS•+ for BOH. The location and orientation of BOH within the SUV were discussed based on the reaction phenomena. BOH could be as a good antioxidant fluorescent prober for ABTS•+ detection with a detection limit of 1.5 * 10−7 M and a linear rang of 0–4.93 μM. What’s more, the amphiphilic BOH dispersed in the round GUV (BOH + GUV) could show the bright red fluorescence. This research suggests the significant potential of BOH as an antioxidant fluorescent probe for in situ bioimaging.
ISSN:1878-5352

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