In Situ Mapping of H2, O2, and H2O2 in Microreactors: A Parallel, Selective Multianalyte Detection Method

Urban, Sebastian; Deschner, Benedikt J.; Trinkies, Laura L.; Kieninger, Jochen; Kraut, Manfred; Dittmeyer, Roland; Urban, G.; Weltin, Andreas

doi:10.1021/acssensors.0c02509

Cited by 12 publications

(10 citation statements)

References 52 publications

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“…This data shows excellent performance of the sensor for GLY measurements and the appropriate method application leading to reproducible and stable electrochemical properties of the electrode. Hereby, we achieved sensitivities for GLY comparable to highly electroactive substances such as hydrogen peroxide . A lower concentration of H 2 SO 4 led to higher sensitivity but increasingly non-linear behavior.…”

Section: Resultsmentioning

confidence: 75%

Electrochemical Microsensor for Microfluidic Glyphosate Monitoring in Water Using MIP-Based Concentrators

et al. 2021

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Glyphosate (GLY) is a broad-spectrum herbicide and is the most used pesticide worldwide. This vast usage has raised strong interest in the ecotoxicological impacts and human risks, with contamination of water being a major concern. Decentralized analytical techniques for water monitoring are of high importance. In this work, we present a small, low-cost, and time-effective electrochemical, chip-based microfluidic device for direct electrochemical detection of GLY downstream of a molecularly imprinted polymer (MIP) concentrator. We studied the electrochemical behavior of GLY and its metabolite aminomethylphosphonic acid (AMPA) using cyclic voltammetry with noble metal electrodes in acidic, neutral, and basic media. A chronoamperometric sensor protocol was developed for sensitive and selective GLY measurements on gold electrodes. The optimized protocol was transferred to a chip-based microsensor platform for online and real-time detection of GLY in a microfluidic setup. The results in the range from 0 to 50 μM GLY in 0.5 M H 2 SO 4 show high linearity and a sensitivity of 10.3 ± 0.6 μA mm −2 mM −1 for the chip-based microfluidic platform. Successful recovery of GLY concentrated from untreated tap water and its precise detection from low volumes demonstrates the advantages of our system.

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Section: Resultsmentioning

confidence: 75%

Electrochemical Microsensor for Microfluidic Glyphosate Monitoring in Water Using MIP-Based Concentrators

et al. 2021

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“…Next to optical fiber sensors, also electrochemical microsensors can be used with the system. For example, label-free electrochemical immunobiosensors could be employed for continual in situ monitoring of soluble biomarkers secreted by the cells. ,, The minimally invasive and label-free microphysiometry approach enables the repeated screening of multiple time points using a single sample facilitating the study of kinetics and recovery effects of metabolic parameters after drug exposure and, thereby, overcomes the limitations of end-point assays. This approach does not only reduce the overall sample number required for long-term studies with multiple time points but is also advantageous for studies with expensive biomaterials and drugs or where low cell numbers are limiting the number of technical replicates.…”

Section: Discussionmentioning

confidence: 99%

Automated 3D Microphysiometry Facilitates High-Content and Highly Reproducible Oxygen Measurements within 3D Cell Culture Models

et al. 2021

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Microphysiometry is a powerful technique to study metabolic parameters and detect changes to external stimuli. However, applying this technique for automated label-free and real-time measurements within cell-laden three-dimensional (3D) cell culture constructs remains a challenge. Herein, we present an entirely automated microphysiometry setup that combines needle-type microsensors with motorized sample and sensor positioning systems inside a standard tissue-culture incubator. The setup records dissolved oxygen as a metabolic parameter along the z-direction within cell-laden 3D constructs in a minimally invasive manner. The microphysiometry setup was applied to characterize the spatial oxygen distribution within thick cell-laden 3D constructs, study the time-dependent changes on the oxygen tension within 3D breast cancer models following a chemotherapeutic treatment, and identify kinetics and recovery effects after drug exposure over 5 weeks. Our data suggest that the microphysiometry setup enables highly reproducible measurements without human intervention, due to the high degree of automation and positional accuracy. The results demonstrate the applicability of the setup to provide valuable long-term insights into oxygenation within 3D models using minimally invasive, label-free, and entirely automated analysis methods.

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“…The H 2 O 2 oxidation current is seen at 800 mV, and is not dependent on oxygen (figure 5(B) blue vs green curve). In the cathodic part, if both O 2 and H 2 O 2 , their reduction currents superimpose linearly [26], and the highest reduction current can be observed (figure 5(B) green curve).…”

Section: Effect Of Hydrogen Peroxidementioning

confidence: 97%

Electrochemical methods for neural interface electrodes

Weltin

Kieninger

2021

J. Neural Eng.

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Objective. Neural interfaces often rely on charge transfer processes between electrodes and the tissue or electrolyte. Electrochemical processes are at the core of electrode function and, therefore, the key to neural interface stability, electrode performance characterization, and utilization of electrodes as chemical sensors. Electrochemical techniques offer a variety of options to investigate the charge transfer and electrocatalytic properties of electrodes. Approach. In this tutorial, we present various experiments to illustrate the power of electrochemical methods, serve as a reference and guideline, and stimulate deeper understanding of the subject. Main results. As a basis for the following experiments, we discuss the platinum cyclic voltammogram and focus on understanding surface processes and roughness determination. We highlight the importance of appropriate instrumentation using potentiostats and how strongly it can influence results. We then discuss a number of potential-controlled and current-controlled methods for electrode characterization, including chronocoulometry, chronoamperometry, (active) potentiometry, and chronopotentiometry. They illustrate charge transfer caused by both electrode surface processes and the presence of redox-active species, such as dissolved oxygen and hydrogen, or hydrogen peroxide. We also discuss the electrode potential with respect to a reference electrode under various conditions and how it affects its electrochemical properties like surface state, catalytic properties and capability to transfer charge. Significance. Electrochemical methods are still underutilized in neural engineering, and valuable information is therefore often not accessed. Many studies on electrode characterization would benefit from a more consistent and target-oriented electrochemical methodology and instrumentation. That ranges from the investigation of new materials and processes, over electrode performance assessment to the development of more long-term stable and biocompatible neural interfaces. Ultimately, standardization, consistency and comparability will play a key role in the translation of microtechnology into biomedical and clinical applications.

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In Situ Mapping of H₂, O₂, and H₂O₂ in Microreactors: A Parallel, Selective Multianalyte Detection Method

Cited by 12 publications

References 52 publications

Electrochemical Microsensor for Microfluidic Glyphosate Monitoring in Water Using MIP-Based Concentrators

Electrochemical Microsensor for Microfluidic Glyphosate Monitoring in Water Using MIP-Based Concentrators

Automated 3D Microphysiometry Facilitates High-Content and Highly Reproducible Oxygen Measurements within 3D Cell Culture Models

Electrochemical methods for neural interface electrodes

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