Lukas Wunderlich scite author profile

Lukas Wunderlich

5Publications

48Citation Statements Received

72Citation Statements Given

How they've been cited

How they cite others

177

Affiliations

University of Regensburg

Publications

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Electrochemical multi-analyte point-of-care perspiration sensors using on-chip three-dimensional graphene electrodes

et al. 2020

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Multi-analyte sensing using exclusively laser-induced graphene (LIG)-based planar electrode systems was developed for sweat analysis. LIG provides 3D structures of graphene, can be manufactured easier than any other carbon electrode also on large scale, and in form of electrodes: hence, it is predestinated for affordable, wearable point-of-care sensors. Here, it is demonstrated that LIG facilitates all three electrochemical sensing strategies (voltammetry, potentiometry, impedance) in a multi-analyte system for sweat analysis. A potentiometric potassium-ion-selective electrode in combination with an electrodeposited Ag/AgCl reference electrode (RE) enabled the detection of potassium ions in the entire physiologically relevant range (1 to 500 mM) with a fast response time, unaffected by the presence of main interfering ions and sweat-collecting materials. A kidney-shaped interdigitated LIG electrode enabled the determination of the overall electrolyte concentration by electrochemical impedance spectroscopy at a fixed frequency. Enzyme-based strategies with amperometric detection share a common RE and were realized with Prussian blue as electron mediator and biocompatible chitosan for enzyme immobilization and protection of the electrode. Using glucose and lactate oxidases, lower limits of detection of 13.7 ± 0.5 μM for glucose and 28 ± 3 μM for lactate were obtained, respectively. The sensor showed a good performance at different pH, with sweat-collecting tissues, on a model skin system and furthermore in synthetic sweat as well as in artificial tear fluid. Response time for each analytical cycle totals 75 s, and hence allows a quasi-continuous and simultaneous monitoring of all analytes. This multi-analyte all-LIG system is therefore a practical, versatile, and most simple strategy for point-of-care applications and has the potential to outcompete standard screen-printed electrodes.

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Current challenges in nanomaterial-based sensors for online monitoring of drinking water by surface plasmon resonance

Wunderlich

Hirsch

2022

Current Opinion in Environmental Science & Health

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Nanoparticle Determination in Water by LED-Excited Surface Plasmon Resonance Imaging

et al. 2021

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The increasing popularity of nanoparticles in many applications has led to the fact that these persistent materials pollute our environment and threaten our health. An online sensor system for monitoring the presence of nanoparticles in fresh water would be highly desired. We propose a label-free sensor based on SPR imaging. The sensitivity was enhanced by a factor of about 100 by improving the detector by using a high-resolution camera. This revealed that the light source also needed to be improved by using LED excitation instead of a laser light source. As a receptor, different self-assembled monolayers have been screened. It can be seen that the nanoparticle receptor interaction is of a complex nature. The best system when taking sensitivity as well as reversibility into account is given by a dodecanethiol monolayer on the gold sensor surface. Lanthanide-doped nanoparticles, 29 nm in diameter and with a similar refractive index to the most common silica nanoparticles were detected in water down to 1.5 µg mL−1. The sensor can be fully regenerated within one hour without the need for any washing buffer. This sensing concept is expected to be easily adapted for the detection of nanoparticles of different size, shape, and composition, and upon miniaturization, suitable for long-term applications to monitor the quality of water.

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Surface plasmon resonance imaging for detection of drug metabolites in water

Hausler

Wunderlich

Fischer

et al. 2019

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Two-Dimensional Carbon Nanomaterials for Electrochemical and Plasmonic Sensing Applications

Kirchner

Genslein

Wunderlich

et al. 2017

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Two-dimensional carbon nanomaterials are very popular in chemo-and biosensor development. The high surface area and the outstanding electrochemical and electronical properties make them attractive candidates as sensing material. To date, it is still challenging to prepare well-defined, defect-free 2D-nanomaterials in a reproducible way. Here, chemical and mechanical methods for the fabrication of colloidal stable graphene dispersions with focus on the flake-size distribution, the number of defects and the physicochemical properties are discussed. A method is proposed to transfer the graphene materials on electrodes and nanostructured gold surfaces for sensor development. As one example for a feasibility study, amperometric sensors were constructed with various types of graphene using glucose as the model analyte. Selectivity was introduced by electrochemical deposition of Nickel nanoparticles on top of the 2D-nanomaterial. For plasmonic sensing, graphene is shown to enhance surface plasmon resonance sensitivity, especially for small molecules such as plastisizers or purine-based biomarkers when combining nanostructured gold substrates with 2D-nanomaterials.

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