Morphine electrochemical determination using SnO2 nanostructure-modified glassy carbon electrode in the presence of diclofenac

Morphine electrochemical determination using SnO2 nanostructure-modified glassy carbon electrode in the presence of diclofenac

In the present work, SnO2 nanostructures were synthesized and a sensitive voltammetric sensor on a glassy carbon electrode (GCE) was constructed to estimate morphine (MP) in the presence of diclofenac (DLF). Background and purpose: Because diclofenac (DLF) is an NSAID, its administration can reduce...

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Bibliographic Details
Main Authors: Isam Ngaimesh Taeb, Zainab S. Hadawi, Rasha N. Alibabery
Format: Article
Language:English
Published: International Association of Physical Chemists (IAPC) 2025-07-01
Series:ADMET and DMPK
Subjects:
Electrochemical sensor
voltammetric determinationž
modified electrodes
voltammetry
chronoamperometry
Online Access:https://pub.iapchem.org/ojs/index.php/admet/article/view/2803
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Summary:In the present work, SnO2 nanostructures were synthesized and a sensitive voltammetric sensor on a glassy carbon electrode (GCE) was constructed to estimate morphine (MP) in the presence of diclofenac (DLF). Background and purpose: Because diclofenac (DLF) is an NSAID, its administration can reduce postoperative morphine (MP) requirements in adults; for example, standard DLF dosing has been shown to decrease MP use after abdominal surgery. Hence, devising a simple, cost-effective, and swift assay for these compounds in biological and pharmaceutical specimens is indispensable.  Experimental approach: SnO2 nanostructures were synthesized, and a sensitive voltammetric sensor on a glassy carbon electrode (GCE) was constructed to estimate MP in the presence of DLF. Cyclic voltammetry was employed to evaluate the electrochemical response of the SnO2 nanostructures/GCE towards MP. Key results: The SnO2 nanostructures exhibited a significant effect on the electrochemical reaction of the electrode toward the MP oxidation. The SnO2 nanostructures/GCE further exhibited a more sensitive detection platform for MP determination with a limit of detection of 0.006 μM using differential pulse voltammetry in a linear range of 0.01 to 340.0 μM. Conclusion: The SnO2 nanostructures/GCE exhibited extremely high electrochemical activities towards the simultaneous oxidation of MP and DLF. Moreover, the SnO2 nanostructures/GCE provided reproducible and stable responses for MP quantitation. The platform prepared showed successful performance for MP and DLF determination in real samples. SnO2 nanostructures exhibited a significant effect on the electrochemical reaction of the electrode toward the MP oxidation. The SnO2 nanostructures/GCE further exhibited a more sensitive detection platform for MP determination with a limit of detection of 0.006 μM using differential pulse voltammetry in a linear range of 0.01 to 340.0 μM. Additionally, the SnO2 nanostructures/GCE exhibited extremely high electrochemical activities towards the simultaneous oxidation of MP and DLF. Moreover, the SnO2 nanostructures/GCE provided reproducible and stable responses for MP quantitation. The platform prepared showed successful performance for MP and DLF determination in real samples.
ISSN:1848-7718

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