Determination of Manganese by Cathodic Stripping Voltammetry on a Microfabricated Platinum Thin–film Electrode

Kang, Wenjing; Rusinek, Cory A.; Bange, Adam; Haynes, Erin N.; Heineman, William R.; Papautsky, Ian

doi:10.1002/elan.201600679

Cited by 21 publications

(42 citation statements)

References 43 publications

(59 reference statements)

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“…Most research focuses on exploring the sensitivity of Mn detection with different working electrode materials. Materials such as mercury (Piech et al, 2008), carbon (Berg et al, 2016; Pei et al, 2021), platinum (Kang et al, 2017), indium tin oxide (Rusinek et al, 2016), and nanocomposite materials (Rocha et al, 2020) have been used for determining Mn. Even though mercury‐based electrodes provide sensitive determination of Mn in water (Piech et al, 2008), the toxicity of mercury is a concern and thus the stability of the electrode materials is critical, especially for in‐situ detection in water distribution systems.…”

Section: Emerging Methods For Field‐testingmentioning

confidence: 99%

“…Berg et al (2016) determined Mn using stencil‐printed carbon ink electrodes by square‐wave CSV. Kang et al (2017) microfabricated platinum thin‐film electrode for detection on Mn by CSV. Rusinek et al (2016) proved that bare and polymer‐coated indium tin oxide electrodes are effective for Mn detection using CSV in water.…”

Section: Emerging Methods For Field‐testingmentioning

confidence: 99%

“…The sensor was used to determine Mn in natural water samples (Kang et al, 2014). Kang et al (2017) also microfabricated a platinum thin‐film electrode for high sensitivity down to 16.3 nM.…”

Section: Emerging Methods For Field‐testingmentioning

confidence: 99%

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Considerations for new manganese analytical techniques for drinking water quality management

et al. 2022

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Manganese (Mn) is a contaminant of emerging concern in drinking water, as recent epidemiologic evidence suggests an association between Mn exposure in drinking water and negative neurodevelopmental effects. The nature of Mn events in distribution systems can be sporadic and difficult to predict, with conventional laboratory methods being limited in their ability to provide the flexible on-line Mn monitoring. Emerging methods such as colorimetric and electrochemical methods offer advantages for monitoring as they have potential to be less expensive, rapid, and readily deployed in the field. These emerging methods, however, face hurdles to adaptation and acceptance including demonstration of sufficient accuracy, precision, sensitivity and yet-to-be resolved issues with interfering agents. These hurdles are not insurmountable, and investment is warranted in these novel methods to address pressing needs by the water industry to protect human health. This review paper highlights the opportunities and advantages of advancing field-testing techniques for Mn management.

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Section: Emerging Methods For Field‐testingmentioning

confidence: 99%

Section: Emerging Methods For Field‐testingmentioning

confidence: 99%

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Considerations for new manganese analytical techniques for drinking water quality management

et al. 2022

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“…Electrochemical methods for manganese detection have been reported previously. 2,3,6,[12][13][14][18][19][20][21][22][23][24][25][26] For instance, Rusinek and colleagues 2 developed a new sensor based on polymercoated indium tin oxide for manganese detection in natural water samples. Kang et al 3 utilized a copper-based electrochemical sensor with a palladium electrode to determine manganese in water samples.…”

Section: Introductionmentioning

confidence: 99%

“…Saterlay and colleagues 20 developed a sono-cathodic stripping voltammetry method using as a working electrode a BDDE for manganese determination in instant tea reaching a very low detection limit of 10 −11 mol L −1 (2 min deposition). However, several procedures using modified electrodes 3,18,22 and/or high-cost electrodes, such as palladium, 3 platinum, 22 and BDDE, 6,20,25 present some drawbacks.…”

Section: Introductionmentioning

confidence: 99%

Trace manganese detection via differential pulse cathodic stripping voltammetry using disposable electrodes: additively manufactured nanographite electrochemical sensing platforms

Rocha

Foster

Muñoz

et al. 2020

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Determination of Mercury with a Miniature Sensor for Point‐of‐care Testing

Bassi

Forst

et al. 2022

Electroanalysis

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In developing countries, subsistence gold mining entails mixing metallic mercury with crushed sediments to extract gold. In this approach, the goldÀ mercury amalgam is heated to evaporate mercury and obtain gold. Thus, the highly volatile mercury can be absorbed through inhalation, resulting in adverse health effects. Urinalysis can be used to detect mercury, which is excreted in urine and feces, and correlate exposure with toxic effects. The current gold standard analytical methods are based on fluorescence or inductively coupled plasma mass spectrometry methods, but are expensive, time consuming, and are not easily accessible in countries where testing is needed. In this work, we report on a miniature electrochemical sensor that can rapidly detect mercury in urine at levels well below the US Biological Exposure Index (BEI) limit of 50 ppb (μg/L). The sensor is based on a thin-film gold electrode and anodic stripping voltammetry electroanalytical approach. The sensor successfully detected mercury at trace levels in urine, with a limit of detection of ~15 ppb Hg in the linear range of 20-80 ppb. With the low-cost disposable sensors and portable instrumentation, it is well suited for point-of-care applications.

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Determination of Manganese by Cathodic Stripping Voltammetry on a Microfabricated Platinum Thin–film Electrode

Cited by 21 publications

References 43 publications

Considerations for new manganese analytical techniques for drinking water quality management

Considerations for new manganese analytical techniques for drinking water quality management

Trace manganese detection via differential pulse cathodic stripping voltammetry using disposable electrodes: additively manufactured nanographite electrochemical sensing platforms

Determination of Mercury with a Miniature Sensor for Point‐of‐care Testing

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