In
this work, we report the first copper-based point-of-care sensor
for electrochemical measurements demonstrated by zinc determination
in blood serum. Heavy metals require careful monitoring, yet current
methods are too complex for a point-of-care system. Electrochemistry
offers a simple approach to metal detection on the microscale, but
traditional carbon, gold (Au), or platinum (Pt) electrodes are difficult
or expensive to microfabricate, preventing widespread use. Our sensor
features a new low-cost electrode material, copper, which offers simple
fabrication and compatibility with microfabrication and PCB processing,
while maintaining competitive performance in electrochemical detection.
Anodic stripping voltammetry of zinc using our new copper-based sensors
exhibited a 140 nM (9.0 ppb) limit of detection (calculated) and sensitivity
greater than 1 μA/μM in the acetate buffer. The sensor
was also able to determine zinc in a bovine serum extract, and the
results were verified with independent sensor measurements. These
results demonstrate the advantageous qualities of this lab-on-a-chip
electrochemical sensor for clinical applications, which include a
small sample volume (μL scale), reduced cost, short response
time, and high accuracy at low concentrations of analyte.
This work demonstrates determination of lead (Pb) in surface water samples using a low-cost copper (Cu)-based electrochemical sensor. Heavy metals require careful monitoring due to their toxicity, yet current methods are too complex or bulky for point-of-care (POC) use. Electrochemistry offers a convenient alternative for metal determination, but the traditional electrodes, such as carbon or gold/platinum, are costly and difficult to microfabricate. Our Cu-based sensor features a low-cost electrode material – copper – that offers simple fabrication and competitive performance in electrochemical detection. For anodic stripping voltammetry (ASV) of Pb, our sensor shows 21 nM (4.4 ppb) limit of detection, resistance to interfering metals such as cadmium (Cd) and zinc (Zn), and stable response in natural water samples with minimum sample pretreatment. These results suggest this electrochemical sensor is suitable for environmental and potentially biological applications, where accurate and rapid, yet inexpensive on-site monitoring is necessary.
Though an essential metal in the body, manganese (Mn) has a number of health implications when found in excess that are magnified by chronic exposure. These health complications include neurotoxicity, memory loss, infertility in males, and development of a neurologic psychiatric disorder- manganism. Thus, trace detection in environmental samples is increasingly important. Few electrode materials are able to reach the negative reductive potential of Mn required for anodic stripping voltammetry (ASV), so cathodic stripping voltammetry (CSV) has been shown to be a viable alternative. We demonstrate Mn CSV using an indium tin oxide (ITO) working electrode both bare and coated with a sulfonated charge selective polymer film, polystyrene-block-poly(ethylene-ran-butylene)-block-polystyrene-sulfonate (SSEBS). ITO itself proved to be an excellent electrode material for Mn CSV, achieving a calculated detection limit of 5 nM (0.3 ppb) with a deposition time of 3 min. Coating the ITO with the SSEBS polymer was found to increase the sensitivity and lower the detection limit to 1 nM (0.06 ppb). This polymer modified electrode offers excellent selectivity for Mn as no interferences were observed from other metal ions tested (Zn2+, Cd2+, Pb2+, In3+, Sb3+, Al3+, Ba2+, Co2+, Cu2+, Ni3+, Bi3+, and Sn2+) except Fe2+, which was found to interfere with the analytical signal for Mn2+ at a ratio 20:1 (Fe2+:Mn2+). The applicability of this procedure to the analysis of tap, river, and pond water samples was demonstrated. This simple, sensitive analytical method using ITO and SSEBS-ITO could be applied to a number of electroactive transition metals detectable by CSV.
In
this work, we report on the development of a palladium-based,
microfabricated point-of-care electrochemical sensor for the determination
of manganese using square wave cathodic stripping voltammetry. Heavy
metals require careful monitoring, yet current methods are too complex
for a point-of-care system. Voltammetry offers an attractive approach
to metal detection on the microscale, but traditional carbon, gold,
or platinum electrodes are difficult or expensive to microfabricate,
preventing widespread use. Our sensor uses palladium working and auxiliary
electrodes and integrates them with a copper-based reference electrode
for simple fabrication and compatibility with microfabrication and
printed circuit board processing, while maintaining competitive performance
in electrochemical detection. Copper electrodes were prepared on glass
substrate using a combination of microfabrication procedures followed
by electrodeposition of palladium. The disposable sensor system was
formed by bonding a poly(dimethylsiloxane) (PDMS) well to the glass
substrate. Cathodic stripping voltammetry of manganese using our new
disposable palladium-based sensors exhibited 334 nM (18.3 ppb) limit
of detection in borate buffer. The sensor was used to demonstrate
manganese determination in natural water samples from a pond in Burnet
Woods, located in Cincinnati, OH, and the Ohio River.
In this work, we report on the determination of trace manganese (Mn) using cathodic stripping voltammetry (CSV) using a microfabricated sensor with a Pt thin-film working electrode. While an essential trace metal for human health, prolonged exposure to Mn tends to gradually impair our neurological system. The potential sources of Mn exposure make it necessary to monitor the concentration in various sample matrices. Previous work by us and others suggested CSV as an effective method for measuring trace Mn. The analytical performance metrics were characterized and optimized, leading to a calculated limit of detection (LOD) of 16.3 nM (0.9 ppb) in pH 5.5, 0.2 M acetate buffer. Further, we successfully validated Mn determination in surface water with ~90% accuracy and >97% precision as compared with ICP-MS “gold standard” measurement. Ultimately, with stable, accurate and precise electrochemical performance, this Pt sensor permits rapid monitoring of Mn in environmental samples, and could potentially be used for point-of-use measurements if coupled with portable instrumentation
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