Gold Nanoparticle-Modified Carbon-Fiber Microelectrodes for the Electrochemical Detection of Cd[sup.2+] via Fast-Scan Cyclic Voltammetry

Neurotoxic heavy metals, such as Cd[sup.2+] , pose a significant global health concern due to their increased environmental contamination and subsequent detrimental health hazards they pose to human beings. These metal ions can breach the blood-brain barrierblood–brain barrier, leading to severe and...

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Bibliographic Details
Published in:Micromachines (Basel) 2024-03, Vol.15 (3)
Main Authors: Manring, Noel, Strini, Miriam, Koifman, Gene, Smeltz, Jessica L, Pathirathna, Pavithra
Format: Article
Language:English
Subjects:
Cadmium
Design and construction
Electric properties
Electrodes, Carbon
Gold
Measurement
Methods
Nanoparticles
Testing
Voltammetry
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Summary:Neurotoxic heavy metals, such as Cd[sup.2+] , pose a significant global health concern due to their increased environmental contamination and subsequent detrimental health hazards they pose to human beings. These metal ions can breach the blood-brain barrierblood–brain barrier, leading to severe and often irreversible damage to the central nervous system and other vital organs. Therefore, developing a highly sensitive, robust, and rapid in vivo detection method for these hazardous heavy metal ions is of the utmost importance for early detection, thus initiating timely therapeutics. Detecting ultra-low levels of toxic metal ions in vivo and obtaining accurate speciation information remains a challenge with conventional analytical techniques. In this study, we fabricated a novel carbon carbon-fiber microelectrode (CFM)-based sensor that can detect Cd[sup.2+] ions using fast-scan cyclic voltammetry by electrodepositing gold nanoparticles (AuNP). We optimized electrochemical parameters that generate a unique cyclic voltammogram (CV) of Cd[sup.2+] at a temporal resolution of 100 ms with our novel sensor. All our experiments were performed in tris buffer that mimics the artificial cerebellum fluid. We established a calibration curve resulting in a limit of detection (LOD) of 0.01 µM with a corresponding sensitivity of 418.02 nA/ µM. The sensor’s selectivity was evaluated in the presence of other metal ions, and it was noteworthy to observe that the sensor retained its ability to produce the distinctive Cd[sup.2+] CV, even when the concentration of other metal ions was 200 times higher than that of Cd[sup.2+] . We also found that our sensor could detect free Cd[sup.2+] ions in the presence of complexing agents. Furthermore, we analyzed the solution chemistry of each of those Cd[sup.2+] –ligand solutions using a geochemical model, PHREEQC. The concentrations of free Cd[sup.2+] ions determined through our electrochemical data align well with geochemical modeling data, thus validating the response of our novel sensor. Furthermore, we reassessed our sensor’s LOD in tris buffer based on the concentration of free Cd[sup.2+] ions determined through PHREEQC analysis, revealing an LOD of 0.00132 µM. We also demonstrated the capability of our sensor to detect Cd[sup.2+] ions in artificial urine samples, showcasing its potential for application in actual biological samples. To the best of our knowledge, this is the first AuNP-modified, CFM-based Cd[sup.2+] sensor capable of
ISSN:2072-666X
2072-666X
DOI:10.3390/mi15030294