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3. On-Chip Electrokinetic Micropumping for Nanoparticle Impact Electrochemistry

Author

Lennart J. K. Weiß, Emir Music, Philipp Rinklin, Marko Banzet, Dirk Mayer, and Bernhard Wolfrum

Subjects
Electrolytes, Silver, Electrochemistry, Metal Nanoparticles, Microelectrodes, Oxidation-Reduction, Analytical Chemistry
Abstract

Single-entity electrochemistry is a powerful technique to study the interactions of nanoparticles at the liquid-solid interface. In this work, we exploit Faradaic (background) processes in electrolytes of moderate ionic strength to evoke electrokinetic transport and study its influence on nanoparticle impacts. We implemented an electrode array comprising a macroscopic electrode that surrounds a set of 62 spatially distributed microelectrodes. This configuration allowed us to alter the global electrokinetic transport characteristics by adjusting the potential at the macroscopic electrode, while we concomitantly recorded silver nanoparticle impacts at the microscopic detection electrodes. By focusing on temporal changes of the impact rates, we were able to reveal alterations in the macroscopic particle transport. Our findings indicate a potential-dependent micropumping effect. The highest impact rates were obtained for strongly negative macroelectrode potentials and alkaline solutions, albeit also positive potentials lead to an increase in particle impacts. We explain this finding by reversal of the pumping direction. Variations in the electrolyte composition were shown to play a critical role as the macroelectrode processes can lead to depletion of ions, which influences both the particle oxidation and the reactions that drive the transport. Our study highlights that controlled on-chip micropumping is possible, yet its optimization is not straightforward. Nevertheless, the utilization of electro- and diffusiokinetic transport phenomena might be an appealing strategy to enhance the performance in future impact-based sensing applications.

Published
2022
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4. Single-Impact Electrochemistry in Paper-Based Microfluidics

Author

Lennart J. K. Weiß, Georg Lubins, Emir Music, Philipp Rinklin, Marko Banzet, Hu Peng, Korkut Terkan, Dirk Mayer, and Bernhard Wolfrum

Subjects
Fluid Flow and Transfer Processes, Silver, SARS-CoV-2, Process Chemistry and Technology, Microfluidics, COVID-19, Metal Nanoparticles, Bioengineering, Pregnancy, Electrochemistry, Humans, Female, Microelectrodes, Instrumentation
Abstract

Microfluidic paper-based analytical devices (μPADs) have experienced an unprecedented story of success. In particular, as of today, most people have likely come into contact with one of their two most famous examples─the pregnancy or the SARS-CoV-2 antigen test. However, their sensing performance is constrained by the optical readout of nanoparticle agglomeration, which typically allows only qualitative measurements. In contrast, single-impact electrochemistry offers the possibility to quantify species concentrations beyond the pM range by resolving collisions of individual species on a microelectrode. Within this work, we investigate the integration of stochastic sensing into a μPAD design by combining a wax-patterned microchannel with a microelectrode array to detect silver nanoparticles (AgNPs) by their oxidative dissolution. In doing so, we demonstrate the possibility to resolve individual nanoparticle collisions in a reference-on-chip configuration. To simulate a lateral flow architecture, we flush previously dried AgNPs along a microchannel toward the electrode array, where we are able to record nanoparticle impacts. Consequently, single-impact electrochemistry poses a promising candidate to extend the limits of lateral flow-based sensors beyond current applications toward a fast and reliable detection of very dilute species on site.

Published
2022
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7. Determination of Stiffness and the Elastic Modulus of 3D-Printed Micropillars with Atomic Force Microscopy–Force Spectroscopy

Author

Giorgio Cortelli, Leroy Grob, Luca Patruno, Tobias Cramer, Dirk Mayer, Beatrice Fraboni, Bernhard Wolfrum, and Stefano de Miranda

Subjects
General Materials Science, ddc:600
Abstract

Nowadays, many applications in diverse fields are taking advantage of micropillars such as optics, tribology, biology, and biomedical engineering. Among them, one of the most attractive is three-dimensional microelectrode arrays for in vivo and in vitro studies, such as cellular recording, biosensors, and drug delivery. Depending on the application, the micropillar’s optimal mechanical response ranges from soft to stiff. For long-term implantable devices, a mechanical mismatch between the micropillars and the biological tissue must be avoided. For drug delivery patches, micropillars must penetrate the skin without breaking or bending. The accurate mechanical characterization of the micropillar is pivotal in the fabrication and optimization of such devices, as it determines whether the device will fail or not. In this work, we demonstrate an experimental method based only on atomic force microscopy–force spectroscopy that allows us to measure the stiffness of a micropillar and the elastic modulus of its constituent material. We test our method with four different types of 3D inkjet-printed micropillars: silver micropillars sintered at 100 and 150 °C and polyacrylate microstructures with and without a metallic coating. The estimated elastic moduli are found to be comparable with the corresponding bulk values. Furthermore, our findings show that neither the sintering temperature nor the presence of a thin metal coating plays a major role in defining the mechanical properties of the micropillar.

Published
2023
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8. Filtration-processed biomass nanofiber electrodes for flexible bioelectronics

Author

Daiki Ando, Tetsuhiko F. Teshima, Francisco Zurita, Hu Peng, Kota Ogura, Kenji Kondo, Lennart Weiß, Ayumi Hirano-Iwata, Markus Becherer, Joe Alexander, and Bernhard Wolfrum

Subjects
Silver, Nanotubes, Carbon, Nanowires, Nanofibers, Biomedical Engineering, Pharmaceutical Science, Molecular Medicine, Medicine (miscellaneous), Bioengineering, Biomass, Electrodes, Applied Microbiology and Biotechnology
Abstract

An increasing demand for bioelectronics that interface with living systems has driven the development of materials to resolve mismatches between electronic devices and biological tissues. So far, a variety of different polymers have been used as substrates for bioelectronics. Especially, biopolymers have been investigated as next-generation materials for bioelectronics because they possess interesting characteristics such as high biocompatibility, biodegradability, and sustainability. However, their range of applications has been restricted due to the limited compatibility of classical fabrication methods with such biopolymers. Here, we introduce a fabrication process for thin and large-area films of chitosan nanofibers (CSNFs) integrated with conductive materials. To this end, we pattern carbon nanotubes (CNTs), silver nanowires, and poly (3,4-ethylenedioxythiophene):poly (styrenesulfonate) (PEDOT:PSS) by a facile filtration process that uses polyimide masks fabricated via laser ablation. This method yields feedlines of conductive material on nanofiber paper and demonstrates compatibility with conjugated and high-aspect-ratio materials. Furthermore, we fabricate a CNT neural interface electrode by taking advantage of this fabrication process and demonstrate peripheral nerve stimulation to the rapid extensor nerve of a live locust. The presented method might pave the way for future bioelectronic devices based on biopolymer nanofibers.

Published
2022
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9. Recent developments and future perspectives on neuroelectronic devices

Author

Philipp Rinklin and Bernhard Wolfrum

Subjects
Electrical recording, Materials science, Neurology, Nanotechnology, Neurology (clinical), Microfabrication
Abstract

Neuroscientific discoveries and the development of recording and stimulation tools are deeply connected. Over the past decades, the progress in seamlessly integrating such tools in the form of neuroelectronic devices has been tremendous. Here, we review recent advances and key aspects of this goal. Firstly, we illustrate improvements with respect to the coupling between cells/tissue and recording/stimulation electrodes. Thereafter, we cover attempts to mitigate the foreign body response by reducing the devices’ invasiveness. We follow up with a description of specialized electronic hardware aimed at the needs of bioelectronic applications. Lastly, we outline how additional modalities such as optical techniques or ultrasound could in the future be integrated into neuroelectronic implants.

Published
2021
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11. A Cost-Effective, Impediometric Na+-Sensor in Fluids

Author

Franz Kreupl, Bernhard Wolf, Christian Pfeffer, Markus Hefele, Bernhard Wolfrum, Sabine Zips, Yue Liang, Ernst Muellner, and Ralf Brederlow

Subjects
Fabrication, Materials science, business.industry, Dynamic range, 010401 analytical chemistry, 02 engineering and technology, Dielectric, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Electrochemical gas sensor, Dielectric spectroscopy, Membrane, Electrode, Optoelectronics, Sensitivity (control systems), Electrical and Electronic Engineering, 0210 nano-technology, business, Instrumentation
Abstract

A crucial parameter in the body-fluid analysis is Na+-ions. Preferably realized as a small wearable, mostly the fabrication method, size, and costs prevented ion-selective devices to enter the big realm of IoT applications. This letter reports a printed, electrochemical sensor system for measuring Na+-ions in liquids. We designed, simulated, optimized, fabricated, and experimentally evaluated the sensor structures. Employing electrochemical impedance spectroscopy on a printable, dielectric ion-selective membrane, reproducible 2-electrode-measurement results are achieved in a biological-relevant mM-range. The cross-sensitivity toward K+-ions, dynamic range, and drift are investigated, and a robust measurement scheme is derived. The flexible, low-cost approach can enable new Internet-of-Things and point-of-care applications in biomedicine such as sweat analysis and environmental monitoring.

Published
2021
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12. Prototype Digital Lateral Flow Sensor Using Impact Electrochemistry in a Competitive Binding Assay

Author

Lennart J. K. Weiß, Philipp Rinklin, Bhawana Thakur, Emir Music, Heike Url, Inola Kopic, Darius Hoven, Marko Banzet, Tassilo von Trotha, Dirk Mayer, and Bernhard Wolfrum

Subjects
Fluid Flow and Transfer Processes, Silver, Process Chemistry and Technology, Electrochemistry, Biotin, Metal Nanoparticles, Bioengineering, Biosensing Techniques, Instrumentation, Binding, Competitive
Abstract

This work demonstrates a lateral flow assay concept on the basis of stochastic-impact electrochemistry. To this end, we first elucidate requirements to employ silver nanoparticles as redox-active labels. Then, we present a prototype that utilizes nanoimpacts from biotinylated silver nanoparticles as readouts to detect free biotin in solution based on competitive binding. The detection is performed in a membrane-based microfluidic system, where free biotin and biotinylated particles compete for streptavidin immobilized on embedded latex beads. Excess nanoparticles are then registered downstream at an array of detection electrodes. In this way, we establish a proof of concept that serves as a blueprint for future "digital" lateral flow sensors.

Published
2022

13. In vivo closed-loop control of a locust’s leg using nerve stimulation

Author

Francisco Zurita, Fulvia Del Duca, Tetsuhiko Teshima, Lukas Hiendlmeier, Michael Gebhardt, Harald Luksch, and Bernhard Wolfrum

Subjects
Neurons, Multidisciplinary, Animals, Grasshoppers, Algorithms, Electric Stimulation, Feedback
Abstract

Activity of an innervated tissue can be modulated based on an acquired biomarker through feedback loops. How to convert this biomarker into a meaningful stimulation pattern is still a topic of intensive research. In this article, we present a simple closed-loop mechanism to control the mean angle of a locust’s leg in real time by modulating the frequency of the stimulation on its extensor motor nerve. The nerve is interfaced with a custom-designed cuff electrode and the feedback loop is implemented online with a proportional control algorithm, which runs solely on a microcontroller without the need of an external computer. The results show that the system can be controlled with a single-input, single-output feedback loop. The model described in this article can serve as a primer for young researchers to learn about neural control in biological systems before applying these concepts in advanced systems. We expect that the approach can be advanced to achieve control over more complex movements by increasing the number of recorded biomarkers and selective stimulation units.

Published
2022
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14. Biocompatible, Flexible, and Oxygen-Permeable Silicone-Hydrogel Material for Stereolithographic Printing of Microfluidic Lab-On-A-Chip and Cell-Culture Devices

Author

Markus Eblenkamp, Sabine Zips, Heike Url, L Weiß, Petra Mela, Richard Schmid, Lukas Hiendlmeier, Tetsuhiko Teshima, and Bernhard Wolfrum

Subjects
chemistry.chemical_classification, Materials science, Polymers and Plastics, Process Chemistry and Technology, Organic Chemistry, Microfluidics, Nanotechnology, Silicone hydrogel, Polymer, Lab-on-a-chip, Biocompatible material, law.invention, chemistry, law, Self-healing hydrogels, Hybrid material
Abstract

We present a photocurable, biocompatible, and flexible silicone-hydrogel hybrid material for stereolithographic (SLA) printing of biomedical devices. The silicone-hydrogel polymer is similar to mix...

Published
2020
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15. Opportunities and challenges of translating direct single impact electrochemistry to high-throughput sensing applications

Author

Philipp Rinklin, L Weiß, and Bernhard Wolfrum

Subjects
Computer science, Sensing applications, Microfluidics, Nanotechnology, 02 engineering and technology, Single impact, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Analytical Chemistry, Electrochemistry, 0210 nano-technology, Electrolyte composition, Throughput (business)
Abstract

In this review, we address the opportunities and challenges of single impact electrochemistry as a detection framework applicable beyond the research laboratory. Focusing on the direct detection of nanoparticles, we discuss several aspects essential to the transfer of this technique into applications for ultralow concentration sensing. We cover particle size–dependent sensor performance and engineering approaches for improving mass transfer via microfluidics. Furthermore, we address interfering phenomena such as aggregation, adsorption, and the effect of electrolyte composition.

Published
2020
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17. 4D‐Printed Soft and Stretchable Self‐Folding Cuff Electrodes for Small‐Nerve Interfacing

Author

Lukas Hiendlmeier, Francisco Zurita, Jonas Vogel, Fulvia Del Duca, George Al Boustani, Hu Peng, Inola Kopic, Marta Nikić, Tetsuhiko F. Teshima, and Bernhard Wolfrum

Subjects
Mechanics of Materials, Mechanical Engineering, General Materials Science, Research Article, Research Articles, 4D printing, cuff electrodes, hydrogels, nerve interfaces, self-folding, small nerves, stretchable materials, ddc
Abstract

Peripheral nerve interfacing (PNI) has a high clinical potential for treating various diseases, like obesity or diabetes. However, currently existing electrodes present challenges to the interfacing procedure, which limits their clinical application, in particular, when targeting small peripheral nerves (200 μm). To improve the electrode handling and implantation, we fabricate a nerve interface that can fold itself to a cuff around a small nerve, triggered by the body moisture during insertion. We achieve this folding by printing a bilayer of a flexible polyurethane printing resin and a highly swelling sodium acrylate hydrogel using photopolymerization. When immersed in an aqueous liquid, the hydrogel swells and folds the electrode softly around the nerve. Furthermore, the electrodes are robust, can be stretched (20%), and bend to facilitate the implantation due to the use of soft and stretchable printing resins as substrates and a microcracked gold film as conductive layer. We demonstrate the straightforward implantation and extraction of the electrode as well as stimulation and recording capabilities on a small peripheral nerve in vivo. We believe that such simple and robust to use self-folding electrodes will pave the way for bringing PNI to a broader clinical application. This article is protected by copyright. All rights reserved.

Published
2023
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18. Polarity and chirality control of an active fluid by passive nematic defects

Author

Alfredo Sciortino, Lukas J. Neumann, Timo Krüger, Ivan Maryshev, Tetsuhiko F. Teshima, Bernhard Wolfrum, Erwin Frey, and Andreas R. Bausch

Subjects
Mechanics of Materials, Mechanical Engineering, General Materials Science, General Chemistry, Condensed Matter Physics
Abstract

Much like passive materials, active systems can be affected by the presence of imperfections in their microscopic order, called defects, that influence macroscopic properties. This suggests the possibility to steer collective patterns by introducing and controlling defects in an active system. Here we show that a self-assembled, passive nematic is ideally suited to control the pattern formation process of an active fluid. To this end, we force microtubules to glide inside a passive nematic material made from actin filaments. The actin nematic features self-assembled half-integer defects that steer the active microtubules and lead to the formation of macroscopic polar patterns. Moreover, by confining the nematic in circular geometries, chiral loops form. We find that the exact positioning of nematic defects in the passive material deterministically controls the formation and the polarity of the active flow, opening the possibility of efficiently shaping an active material using passive defects.

Published
2022

20. Influence of Auditory Cues on the Neuronal Response to Naturalistic Visual Stimuli in a Virtual Reality Setting

Author

George Al Boustani, Lennart Jakob Konstantin Weiß, Hongwei Li, Svea Marie Meyer, Lukas Hiendlmeier, Philipp Rinklin, Bjoern Menze, Werner Hemmert, Bernhard Wolfrum, University of Zurich, and Wolfrum, Bernhard

Subjects
610 Medicine & health, ddc, 3206 Neuropsychology and Physiological Psychology, 2738 Psychiatry and Mental Health, Behavioral Neuroscience, Psychiatry and Mental health, Neuropsychology and Physiological Psychology, Neurology, 2808 Neurology, 2802 Behavioral Neuroscience, Human Neuroscience, brain computer interface, event-related potential (ERP), combinational audio-visual stimulus, visual evoked potential (VEP), virtual reality, support vector machine (SVM), 11493 Department of Quantitative Biomedicine, 2803 Biological Psychiatry, Biological Psychiatry
Abstract

Virtual reality environments offer great opportunities to study the performance of brain-computer interfaces (BCIs) in real-world contexts. As real-world stimuli are typically multimodal, their neuronal integration elicits complex response patterns. To investigate the effect of additional auditory cues on the processing of visual information, we used virtual reality to mimic safety-related events in an industrial environment while we concomitantly recorded electroencephalography (EEG) signals. We simulated a box traveling on a conveyor belt system where two types of stimuli – an exploding and a burning box – interrupt regular operation. The recordings from 16 subjects were divided into two subsets, a visual-only and an audio-visual experiment. In the visual-only experiment, the response patterns for both stimuli elicited a similar pattern – a visual evoked potential (VEP) followed by an event-related potential (ERP) over the occipital-parietal lobe. Moreover, we found the perceived severity of the event to be reflected in the signal amplitude. Interestingly, the additional auditory cues had a twofold effect on the previous findings: The P1 component was significantly suppressed in the case of the exploding box stimulus, whereas the N2c showed an enhancement for the burning box stimulus. This result highlights the impact of multisensory integration on the performance of realistic BCI applications. Indeed, we observed alterations in the offline classification accuracy for a detection task based on a mixed feature extraction (variance, power spectral density, and discrete wavelet transform) and a support vector machine classifier. In the case of the explosion, the accuracy slightly decreased by –1.64% p. in an audio-visual experiment compared to the visual-only. Contrarily, the classification accuracy for the burning box increased by 5.58% p. when additional auditory cues were present. Hence, we conclude, that especially in challenging detection tasks, it is favorable to consider the potential of multisensory integration when BCIs are supposed to operate under (multimodal) real-world conditions.

Published
2021

22. Temperature profile characterization with fluorescence lifetime imaging microscopy in a thermophoretic chip

Author

Bernhard Wolfrum, Namkyu Lee, Philipp Rinklin, Dzmitry Afanasenkau, and Simone Wiegand

Subjects
Fluorescence-lifetime imaging microscopy, Microscope, Materials science, Biophysics, Thermal diffusivity, law.invention, chemistry.chemical_compound, law, Refractive index contrast, ddc:530, General Materials Science, Regular Article - Soft Matter, Thermal non-equilibrium phenomena in fluid mixtures, Soft and Granular Matter, Complex Fluids and Microfluidics, Biological and Medical Physics, Biophysics, Surfaces and Interfaces, Thin Films, Nanotechnology, Polymer Sciences, Complex Systems, Microscopy, business.industry, Temperature, Surfaces and Interfaces, General Chemistry, ddc, Characterization (materials science), Regular Article – Soft Matter, Temperature gradient, chemistry, Optoelectronics, Polystyrene, business, Joule heating, Biotechnology
Abstract

Abstract This study introduces a thermophoretic lab-on-a-chip device to measure the Soret coefficient. We use resistive heating of a microwire on the chip to induce a temperature gradient, which is measured by fluorescence lifetime imaging microscopy (FLIM). To verify the functionality of the device, we used dyed polystyrene particles with a diameter of 25 nm. A confocal microscope is utilized to monitor the concentration profile of colloidal particles in the temperature field. Based on the measured temperature and concentration differences, we calculate the corresponding Soret coefficient. The same particles have been recently investigated with thermal diffusion forced Rayleigh scattering (TDFRS) and we find that the obtained Soret coefficients agree with literature results. This chip offers a simple way to study the thermophoretic behavior of biological systems in multicomponent buffer solutions quantitatively, which are difficult to study with optical methods solely relying on the refractive index contrast. Graphic abstract

Published
2021
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23. Fully 3D‐Printed Cuff Electrode for Small Nerve Interfacing

Author

Francisco Zurita, Leroy Grob, Amelie Erben, Fulvia Del Duca, Hauke Clausen‐Schaumann, Stefanie Sudhop, Oliver Hayden, and Bernhard Wolfrum

Subjects
Mechanics of Materials, General Materials Science, Industrial and Manufacturing Engineering, ddc, Research Article, Research Articles, 3D printing, implantable electrode, nerve cuff
Published
2022
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24. Impedance scaling for gold and platinum microelectrodes

Author

Bo Fan, Bernhard Wolfrum, and Jacob T. Robinson

Subjects
Neurons, Materials science, business.industry, Biomedical Engineering, Radius, Signal, Article, Electrodes, Implanted, Diffusion layer, Cellular and Molecular Neuroscience, Microelectrode, Electrode, Electric Impedance, Optoelectronics, Gold, Diffusion (business), business, Electrical impedance, Scaling, Microelectrodes, Platinum
Abstract

Objective. Electrical measurement of the activity of individual neurons is a primary goal for many invasive neural electrodes. Making these ‘single unit’ measurements requires that we fabricate electrodes small enough so that only a few neurons contribute to the signal, but not so small that the impedance of the electrode creates overwhelming noise or signal attenuation. Thus, neuroelectrode design often must strike a balance between electrode size and electrode impedance, where the impedance is often assumed to scale linearly with electrode area. Approach and main results. Here we study how impedance scales with neural electrode area and find that the 1 kHz impedance of Pt electrodes (but not Au electrodes) transitions from scaling with area (r −2) to scaling with perimeter (r −1) when the electrode radius falls below 10 µm. This effect can be explained by the transition from planar to spherical diffusion behavior previously reported for electrochemical microelectrodes. Significance. These results provide important intuition for designing small, single unit recording electrodes. Specifically, for materials where the impedance is dominated by a pseudo-capacitance that is associated with a diffusion limited process, the total impedance will scale with perimeter rather than area when the electrode size becomes comparable with the diffusion layer thickness. For Pt electrodes this transition occurs around 10 µm radius electrodes. At even lower frequencies (1 Hz) impedance approaches a constant. This transition to r −1 scaling implies that electrodes with a pseudo-capacitance can be made smaller than one might expect before thermal noise or voltage division limits the ability to acquire high-quality single-unit recordings.

Published
2021

25. Lab-on-a-chip based mechanical actuators and sensors for single-cell and organoid culture studies

Author

Da Yang, Jaan Männik, Tetsuhiko Teshima, and Bernhard Wolfrum

Subjects
010302 applied physics, Medical diagnostic, Magnetic tweezers, Computer science, General Physics and Astronomy, Nanotechnology, 02 engineering and technology, Lab-on-a-chip, 021001 nanoscience & nanotechnology, Molecular resolution, 01 natural sciences, law.invention, Molecular network, law, 0103 physical sciences, Organoid, 0210 nano-technology, Actuator, Throughput (business), Perspectives
Abstract

All living cells constantly experience and respond to mechanical stresses. The molecular networks that activate in cells in response to mechanical stimuli are yet not well-understood. Our limited knowledge stems partially from the lack of available tools that are capable of exerting controlled mechanical stress to individual cells and at the same time observing their responses at subcellular to molecular resolution. Several tools such as rheology setups, micropipetes, and magnetic tweezers have been used in the past. While allowing to quantify short-time viscoelastic responses, these setups are not suitable for long-term observations of cells and most of them have low throughput. In this Perspective, we discuss lab-on-a-chip platforms that have the potential to overcome these limitations. Our focus is on devices that apply shear, compressive, tensile, and confinement derived stresses to single cells and organoid cultures. We compare different design strategies for these devices and highlight their advantages, drawbacks, and future potential. While the majority of these devices are used for fundamental research, some of them have potential applications in medical diagnostics and these applications are also discussed.

Published
2021

26. Inkjet-Printed and Electroplated 3D Electrodes for Recording Extracellular Signals in Cell Culture

Author

Philipp Rinklin, Sabine Zips, Korkut Terkan, L Weiß, Bernhard Wolfrum, Andreas Offenhäusser, Dirk Mayer, Leroy Grob, Sabrina Weidlich, and Nouran Adly

Subjects
Materials science, Silver, Cell Culture Techniques, Metal Nanoparticles, Nanotechnology, TP1-1185, 02 engineering and technology, bioelectronics, 010402 general chemistry, 01 natural sciences, Biochemistry, Silver nanoparticle, Article, Analytical Chemistry, Electrical and Electronic Engineering, Electroplating, Instrumentation, Bioelectronics, inkjet printing, impedance spectroscopy, Inkwell, Chemical technology, 021001 nanoscience & nanotechnology, Atomic and Molecular Physics, and Optics, cyclic voltammetry, 0104 chemical sciences, 3D electrodes, Microelectrode, Dielectric Spectroscopy, Electrode, electrodeposition, ddc:620, Cyclic voltammetry, 0210 nano-technology, Microelectrodes, Microfabrication
Abstract

Recent investigations into cardiac or nervous tissues call for systems that are able to electrically record in 3D as opposed to 2D. Typically, challenging microfabrication steps are required to produce 3D microelectrode arrays capable of recording at the desired position within the tissue of interest. As an alternative, additive manufacturing is becoming a versatile platform for rapidly prototyping novel sensors with flexible geometric design. In this work, 3D MEAs for cell-culture applications were fabricated using a piezoelectric inkjet printer. The aspect ratio and height of the printed 3D electrodes were user-defined by adjusting the number of deposited droplets of silver nanoparticle ink along with a continuous printing method and an appropriate drop-to-drop delay. The Ag 3D MEAs were later electroplated with Au and Pt in order to reduce leakage of potentially cytotoxic silver ions into the cellular medium. The functionality of the array was confirmed using impedance spectroscopy, cyclic voltammetry, and recordings of extracellular potentials from cardiomyocyte-like HL-1 cells.

Published
2021
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27. Impedance scaling for gold and platinum microelectrodes

Author

Jacob T. Robinson, Bo Fan, and Bernhard Wolfrum

Subjects
Diffusion layer, Microelectrode, Materials science, business.industry, Electrode, Optoelectronics, Radius, business, Signal, Electrical impedance, Scaling, Pseudocapacitance
Abstract

ObjectiveElectrical measurement of the activity of individual neurons is a primary goal for many invasive neural electrodes. Making these “single unit” measurements requires that we fabricate electrodes small enough so that only a few neurons contribute to the signal, but not so small that the impedance of the electrode creates overwhelming noise or signal attenuation. Thus, neuroelectrode design often must strike a balance between electrode size and electrode impedance, where the impedance is often assumed to scale linearly with electrode area.Approach and main resultsHere we study how impedance scales with neural electrode area and find that the 1 kHz impedance of Pt electrodes (but not Au electrodes) transitions from scaling with area (r-2) to scaling with perimeter (r-1) when the electrode radius falls below 10 microns. This effect can be explained by the transition from planar to spherical diffusion behavior previously reported for electrochemical microelectrodes. Significance: These results provide important intuition for designing small, single unit recording electrodes. Specifically, for materials where the impedance is dominated by a pseudo-capacitance that is associated with a diffusion limited process, the total impedance will scale with perimeter rather than area when the electrode size becomes comparable with the diffusion layer thickness. For Pt electrodes this transition occurs around 10 um radius electrodes. At even lower frequencies (1 Hz) impedance approaches a constant. This transition to r-1 scaling implies that electrodes with a pseudo-capacitance can be made smaller than one might expect before thermal noise or voltage division limits the ability to acquire high-quality single-unit recordings.

Published
2021
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29. (Digital Presentation) Stochastic Impact Electrochemistry in a Lateral-Flow Sensor Architecture

Author

Lennart Jakob Konstantin Weiß, Georg Lubins, Emir Music, Philipp Rinklin, Hu Peng, Korkut Terkan, Dirk Mayer, and Bernhard Wolfrum

Abstract

During the recent SARS-CoV-2 pandemic, lateral flow assays (LFAs) have written an indescribable story of success, as they provide means for decentralized, low-cost, and easy-to-use testing. However, LFAs in their most common form support only qualitative results and their sensitivity and limit of detection is significantly limited by the colorimetric readout method. In contrast, single-impact electrochemistry offers the possibility to quantify species beyond picomolar concentrations by recording individual species collisions with a biased microelectrode. Within this work, we investigate the integration of stochastic sensing into a LFA-architecture by combining a wax-patterned microchannel with a microelectrode array in order to detect silver nanoparticles by their oxidative dissolution. Here, we demonstrate the possibility to resolve individual nanoparticle collisions in a paper-based microchannel using a simplified reference-on-chip setup. Furthermore, we simulated a lateral-flow sensor, by flushing previously dried silver nanoparticles towards the electrode array, where the particles are subsequently detected. This proof-of-principle illustrates that single-impact electrochemistry might be a promising technique to extend the capability of LFAs. Especially, the integration of functionalized nanoparticle labels could enable the rapid and on-site detection of very dilute species with exceptional sensitivity.

Published
2022
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30. Upscaling of pneumatic membrane valves for the integration of 3D cell cultures on chip

Author

Nina Compera, Scott Atwell, Johannes Wirth, Matthias Meier, and Bernhard Wolfrum

Subjects
Materials science, Stereolithography, Microfluidics, Induced Pluripotent Stem Cells, Biomedical Engineering, Cell Culture Techniques, 3D printing, Bioengineering, Nanotechnology, 02 engineering and technology, Biochemistry, Soft lithography, law.invention, 03 medical and health sciences, 3D cell culture, chemistry.chemical_compound, Mice, law, Microtechnology, Animals, Humans, 030304 developmental biology, 0303 health sciences, Polydimethylsiloxane, business.industry, General Chemistry, 021001 nanoscience & nanotechnology, Chip, ddc, Chemistry, chemistry, Printing, Three-Dimensional, NIH 3T3 Cells, 0210 nano-technology, business
Abstract

Microfluidic large-scale integration (mLSI) technology enables the automation of two-dimensional (2D) cell culture processes in a highly parallel manner. Despite the wide range of biological applications of mLSI chips, manufacturing limitations of the central functional element, the pneumatic membrane valve (PMV), make the technology inaccessible for integrating tissue cultures and organoids with dimensions larger than tens of microns. In this study, we developed microtechnology processes to upscale PMVs for mLSI chips by combining 3D printing and soft lithography. Therefore, we developed a robust soft lithography protocol for the production of polydimethylsiloxane chips with PMVs from 3D-printed acrylate and wax molds. While scaled-up PMVs manufactured from acrylate-printed molds exhibited channel profiles with staircases, owing to the inherent 3D stereolithography printing process, PMVs manufactured from reflowed wax molds exhibited a semi-half-rounded channel profile. PMVs with different channel profiles showed closing pressures between 130 and 22.5 kPa, respectively. We demonstrated the functionality of the scaled-up PMVs by forming and maintaining 3D cell cultures from mouse fibroblasts (NIH3T3), human induced pluripotent stem cells (hiPSCs), and human adipose-derived adult stem cells (hASCs), with a narrow size distribution between 124 and 136 μm. Further, parallel and serial design of PMVs on an mLSI chip is used to first form and culture 3D cell cultures before fusing them within a defined flow process. Unit cell designs with upscaled PMVs enabled parallel formation, culturing, trapping, retrieval, and fusion of 3D cell cultures. Thus, the presented additive manufacturing strategy for mLSI chips will foster new developments for highly parallel 3D cell culture screening applications., For integration of 3D cell cultures on microfluidic large-scale integration chips, we upscaled pneumatic membrane valves using 3D-printed replica molds. Unit cell operations for 3D cell culture formation, culture, retrieval, and fusion are designed.

Published
2021

31. An Investigation into the Intrinsic Peroxidase‐Like Activity of Fe‐MOFs and Fe‐MOFs/Polymer Composites

Author

Daniel T. Sun, Vikram V. Karve, L Weiß, Bhawana Thakur, Roland A. Fischer, Leroy Grob, A. Lisa Semrau, Wendy L. Queen, and Bernhard Wolfrum

Subjects
Conductive polymer, Materials science, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Industrial and Manufacturing Engineering, 0104 chemical sciences, ddc, Chemical engineering, Mechanics of Materials, Peroxidase like, Polymer composites, General Materials Science, Metal-organic framework, 0210 nano-technology
Published
2020

32. 3D Printing of Implants Composed of Nanjing Tamasudare‐Inspired Flexible Shape Transformers

Author

Francisco Zurita, Bernhard Wolfrum, Leroy Grob, Philipp Rinklin, Sabine Zips, Tetsuhiko Teshima, Korkut Terkan, and Lukas Hiendlmeier

Subjects
Materials science, Mechanics of Materials, law, business.industry, Mechanical engineering, 3D printing, General Materials Science, Shape transformation, Transformer, business, Industrial and Manufacturing Engineering, law.invention, ddc
Published
2020

33. Printed microelectrode arrays on soft materials: from PDMS to hydrogels

Author

Nouran Adly, Sabrina Weidlich, Silke Seyock, Fabian Brings, Alexey Yakushenko, Andreas Offenhäusser, and Bernhard Wolfrum

Subjects
TK7800-8360, ddc:621.3, lcsh:Electronics, TA401-492, food and beverages, lcsh:TK7800-8360, Electronics, Materials of engineering and construction. Mechanics of materials
Abstract

Microelectrode arrays (MEAs) provide promising opportunities to study electrical signals in neuronal and cardiac cell networks, restore sensory function, or treat disorders of the nervous system. Nevertheless, most of the currently investigated devices rely on silicon or polymer materials, which neither physically mimic nor mechanically match the structure of living tissue, causing inflammatory response or loss of functionality. Here, we present a new method for developing soft MEAs as bioelectronic interfaces. The functional structures are directly deposited on PDMS-, agarose-, and gelatin-based substrates using ink-jet printing as a patterning tool. We demonstrate the versatility of this approach by printing high-resolution carbon MEAs on PDMS and hydrogels. The soft MEAs are used for in vitro extracellular recording of action potentials from cardiomyocyte-like HL-1 cells. Our results represent an important step toward the design of next-generation bioelectronic interfaces in a rapid prototyping approach.

Published
2018
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34. Fabrication of ultrathin and flexible graphene-based devices for in vivo neuroprosthetics

Author

Viviana Rincón Montes, Mathis Ernst, Dmitry Kireev, Bernhard Wolfrum, Pegah Shokoohimehr, Andreas Offenhäusser, Kagithiri Srikantharajah, and Vanessa Maybeck

Subjects
Fabrication, Materials science, Silicon, Transconductance, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, law.invention, law, Microelectronics, General Materials Science, Wafer, Bioelectronics, Graphene, business.industry, Mechanical Engineering, Transistor, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 0104 chemical sciences, chemistry, Mechanics of Materials, Optoelectronics, 0210 nano-technology, business
Abstract

Graphene based devices have already proven to be extremely sensitive and very useful in a wide spectrum of bioelectronics research. In the manuscript we describe a method to fabricate arrays of graphene-based probes, requiring minimal number of fabrication steps, while maintaining overall device functionality. These polyimide-based probes are approximately 6 μm thick, therefore ultraflexible, yet robust and stable. Devices, such as graphene field effect transistors (GFETs) and graphene multielectrode arrays (GMEAs) have been designed, fabricated and tested for their performance. The flexible GFETs exhibit sensitivity, i.e. transconductance up to 700 μS/V, which an order of magnitude larger compared to typical silicon transistors. Multiple probe per wafer design allows us to fabricate different kinds of devices on one 4-inch wafer, consequently increasing a possible range of applications from e.g. retinal to cortical neuroprosthetics.

Published
2018
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35. On-Chip Stochastic Detection of Silver Nanoparticles without a Reference Electrode

Author

Kay J. Krause, Leroy Grob, Pedro G. Figueiredo, Bernhard Wolfrum, and Philipp Rinklin

Subjects
Silver, Materials science, Metal Nanoparticles, Nanoparticle, Bioengineering, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Reference electrode, Silver nanoparticle, Lab-On-A-Chip Devices, Electrodes, Instrumentation, Fluid Flow and Transfer Processes, Open-circuit voltage, Process Chemistry and Technology, Electrochemical Techniques, Equipment Design, Multielectrode array, 021001 nanoscience & nanotechnology, Chip, Ascorbic acid, 0104 chemical sciences, Microelectrode, 0210 nano-technology, Microelectrodes, Oxidation-Reduction
Abstract

We report the electrochemical detection of 20 nm silver nanoparticles at a chip-based microelectrode array (MEA) without the need for a conventional reference electrode. This is possible due to the system's open-circuit potential allowing the oxidation of silver nanoparticles in the presence of phosphate-buffered saline (PBS). The hypothesis is confirmed by modulating the open-circuit potential via addition of ascorbic acid in solution, effectively inhibiting the detection of silver nanoparticle events. Employing the reference-free detection concept, we observe a linear relationship between the nanoparticle impact frequency at the microelectrodes and the nanoparticle concentration. This allows for viable quantification of silver nanoparticle concentrations in situ. The presented concept is ideal for the development of simple lab-on-a-chip or point-of-use systems enabling fast and low-cost screening of nanoparticles.

Published
2018
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37. Fully Printed μ-Needle Electrode Array from Conductive Polymer Ink for Bioelectronic Applications

Author

Dirk Mayer, Korkut Terkan, Bernhard Wolfrum, Nouran Adly, Leroy Grob, Sabine Zips, L Weiß, and Philipp Rinklin

Subjects
Materials science, Polymers, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Mice, PEDOT:PSS, Electrochemistry, Animals, General Materials Science, Conductive polymer, Bioelectronics, business.industry, Nanotubes, Carbon, Electric Conductivity, 021001 nanoscience & nanotechnology, Bridged Bicyclo Compounds, Heterocyclic, 0104 chemical sciences, Dielectric spectroscopy, Microelectrode, Needles, Printed electronics, Electrode, Optoelectronics, Polystyrenes, Ink, Cyclic voltammetry, Electronics, 0210 nano-technology, business, Microelectrodes
Abstract

Microelectrode arrays (MEAs) are widely used platforms in bioelectronics to study electrogenic cells. In recent years, the processing of conductive polymers for the fabrication of three-dimensional electrode arrays has gained increasing interest for the development of novel sensor designs. Here, additive manufacturing techniques are promising tools for the production of MEAs with three-dimensional electrodes. In this work, a facile additive manufacturing process for the fabrication of MEAs that feature needle-like electrode tips, so-called μ-needles, is presented. To this end, an aerosol-jet compatible PEDOT:PSS and multiwalled carbon nanotube composite ink with a conductivity of 323 ± 75 S m-1 is developed and used in a combined inkjet and aerosol-jet printing process to produce the μ-needle electrode features. The μ-needles are fabricated with a diameter of 10 ± 2 μm and a height of 33 ± 4 μm. They penetrate an inkjet-printed dielectric layer to a height of 12 ± 3 μm. After successful printing, the electrochemical properties of the devices are assessed via cyclic voltammetry and impedance spectroscopy. The μ-needles show a capacitance of 242 ± 70 nF at a scan rate of 5 mV s-1 and an impedance of 128 ± 22 kΩ at 1 kHz frequency. The stability of the μ-needle MEAs in aqueous electrolyte is demonstrated and the devices are used to record extracellular signals from cardiomyocyte-like HL-1 cells. This proof-of-principle experiment shows the μ-needle MEAs' cell-culture compatibility and functional integrity to investigate electrophysiological signals from living cells.

Published
2019

38. Tuning Channel Architecture of Interdigitated Organic Electrochemical Transistors for Recording the Action Potentials of Electrogenic Cells

Author

Andrij Pich, Andreas Offenhäusser, Sven Ingebrandt, Yuan-Ying Liang, Bernhard Wolfrum, Fabian Brings, Dirk Mayer, Vanessa Maybeck, Biobased Materials, RS: FSE Biobased Materials, RS: FSE AMIBM, AMIBM, Sciences, and RS: FSE Sciences

Subjects
Materials science, business.industry, Transistor, Cardiac action potential, Condensed Matter Physics, Electrochemistry, organic electrochemical transistors, channel resistance, Electronic, Optical and Magnetic Materials, law.invention, ARRAYS, Biomaterials, source-drain series resistance, Action (philosophy), cardiac action potentials, law, interdigitated electrode arrays, TRANSCONDUCTANCE, Optoelectronics, business, RESISTANCE, Communication channel
Abstract

Organic electrochemical transistors (OECTs) have emerged as versatile electrophysiological sensors due to their high transconductance, biocompatibility, and transparent channel material. High maximum transconductances are demonstrated facilitating the extracellular recording of signals from electrogenic cells. However, this requires large channel dimensions and thick polymer films. These large channel dimensions lead to low transistor densities. Here, interdigitated OECTs (iOECTs) are introduced, which feature high transconductances at small device areas. A superior device performance is achieved by systematically optimizing the electrode layout regarding channel length, number of electrode fingers and electrode width. Interestingly, the maximum transconductance (g(max)) does not straightforwardly scale with the channel width-to-length ratio, which is different from planar OECTs. This deviation is caused by the dominating influence of the source-drain series resistance R-sd for short channel devices. Of note, there is a critical channel length (15 mu m) above which the channel resistance R-ch becomes dominant and the device characteristics converge toward those of planar OECTs. Design rules for engineering the performance of iOECTs are proposed and tested by recording action potentials of cardiomyocyte-like HL-1 cells with high signal-to-noise ratios. These results demonstrate that interdigitated OECTs meet two requirements of bioelectronic applications, namely, high device performance and small channel dimensions.

Published
2019
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39. Ultrasoft Silicone Gel as a Biomimetic Passivation Layer in Inkjet-Printed 3D MEA Devices

Author

Bernhard Wolfrum, Kazuhiro Oiwa, Takuma Sumi, Leroy Grob, Ayumi Hirano-Iwata, and Hideaki Yamamoto

Subjects
Fabrication, Materials science, Passivation, Primary Cell Culture, Biomedical Engineering, Nanotechnology, Biosensing Techniques, General Biochemistry, Genetics and Molecular Biology, Biomaterials, Rats, Sprague-Dawley, Silicone Gels, chemistry.chemical_compound, Silicone, Biomimetic Materials, Animals, Dimethylpolysiloxanes, Fluorescent Dyes, Cerebral Cortex, Neurons, Bioelectronics, Polydimethylsiloxane, Optical Imaging, technology, industry, and agriculture, Electrochemical Techniques, Embryo, Mammalian, Fluoresceins, Electric Stimulation, Rats, Coupling (electronics), chemistry, Electrode, Printing, Three-Dimensional, Calcium, Gold, Layer (electronics), Microelectrodes
Abstract

Multielectrode arrays (MEAs) are versatile tools that are used for chronic recording and stimulation of neural cells and tissues. Driven by the recent progress in understanding of how neuronal growth and function respond to scaffold stiffness, development of MEAs with a soft cell-to-device interface has gained importance not only for in vivo but also for in vitro applications. However, the passivation layer, which constitutes the majority of the cell-device interface, is typically prepared with stiff materials. Herein, a fabrication of an MEA device with an ultrasoft passivation layer is described, which takes advantage of inkjet printing and a polydimethylsiloxane (PDMS) gel with a stiffness comparable to that of the brain. The major challenge in using the PDMS gel is that it cannot be patterned to expose the sensing area of the electrode. This issue is resolved by printing 3D micropillars at the electrode tip. Primary cortical neurons are grown on the fabricated device, and effective stimulation of the culture confirms functional cell-device coupling. The 3D MEA device with an ultrasoft interface provides a novel platform for investigating evoked activity and drug responses of living neuronal networks cultured in a biomimetic environment for both fundamental research and pharmaceutical applications.

Published
2019

40. Observation of chemically protected polydimethylsiloxane: towards crack-free PDMS

Author

Bernhard Wolfrum, Dirk Mayer, Alexey Yakushenko, Nouran Adly, M. Balski, Anh Quang Tran, Andreas Offenhäusser, and Hossein Hassani

Subjects
Materials science, Polydimethylsiloxane, Chemical treatment, technology, industry, and agriculture, Chemical modification, macromolecular substances, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Crack free, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Polymer chemistry, Oxygen plasma, Composite material, 0210 nano-technology, Nanoscopic scale
Abstract

The current modification of polydimethylsiloxane (PDMS) substrates via oxygen plasma treatment causes surface cracks. Here, we demonstrate a method to prevent crack formation by chemical treatment. Chemical modification renders the surface hydrophilic for several days and is effective in preserving the elasticity of the PDMS surface at the nanoscale level.

Published
2017
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41. High throughput transfer technique: Save your graphene

Author

Dario Sarik, Andreas Offenhäusser, Dmitry Kireev, Tongshun Wu, Xiaoming Xie, and Bernhard Wolfrum

Subjects
Materials science, Fabrication, Graphene, Process (computing), Nanotechnology, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, law.invention, law, Hardware_INTEGRATEDCIRCUITS, General Materials Science, Wafer, 0210 nano-technology, Throughput (business)
Abstract

The development rate of graphene-related research is tremendous. New methods of graphene growth and transfer are reported on a regular basis, trending towards large-scale. Nevertheless, the fabrication of high-yield and low-cost graphene devices is still challenging. In this work, we approach this problem from a technological point of view and propose a new, so-called “high-throughput transfer technique”. The technique allows a semi-automatic transfer of graphene films right at the desired places on a wafer. We demonstrate the applicability of our method by aligning 52 graphene devices on a 4-inch wafer using only 4 cm2 of graphene. The overall yield of this process is over 90%.

Published
2016
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42. Inkjet printing of UV-curable adhesive and dielectric inks for microfluidic devices

Author

Andreas Offenhäusser, Daniel S. Correa, Eyad M. Hamad, Bernhard Wolfrum, Nouran Adly, Alexey Yakushenko, Michael J. Schöning, and S. E. R. Bilatto

Subjects
Fabrication, Materials science, Polymers, Ultraviolet Rays, Microfluidics, Biomedical Engineering, Bioengineering, Nanotechnology, 02 engineering and technology, Dielectric, 01 natural sciences, Biochemistry, Adhesives, Lab-On-A-Chip Devices, Curing (chemistry), Inkjet printing, chemistry.chemical_classification, Inkwell, 010401 analytical chemistry, General Chemistry, Polymer, Microfluidic Analytical Techniques, 021001 nanoscience & nanotechnology, 0104 chemical sciences, chemistry, Printing, Ink, Adhesive, 0210 nano-technology
Abstract

Bonding of polymer-based microfluidics to polymer substrates still poses a challenge for Lab-On-a-Chip applications. Especially, when sensing elements are incorporated, patterned deposition of adhesives with curing at ambient conditions is required. Here, we demonstrate a fabrication method for fully printed microfluidic systems with sensing elements using inkjet and stereolithographic 3D-printing.

Published
2016
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43. CMOS-compatible silicon nanowire field-effect transistor biosensor: technology development toward commercialization

Author

Andreas Offenhäusser, Duy Tran, Bernhard Wolfrum, Benjamin Thierry, Thuy Thi Thanh Pham, Tran, Duy Phu, Pham, Thuy Thi Thanh, Wolfrum, Bernhard, Offenhäusser, Andreas, and Thierry, Benjamin

Subjects
Fabrication, Materials science, Field effect, diagnostic, Nanotechnology, Review, 02 engineering and technology, Hardware_PERFORMANCEANDRELIABILITY, 010402 general chemistry, biosensor, 01 natural sciences, Commercialization, lcsh:Technology, field effect transistor, Hardware_INTEGRATEDCIRCUITS, General Materials Science, silicon nanowire, Silicon nanowires, lcsh:Microscopy, commercialization, lcsh:QC120-168.85, lcsh:QH201-278.5, lcsh:T, micro/nanofabrication, CMOS, 021001 nanoscience & nanotechnology, 0104 chemical sciences, lcsh:TA1-2040, Field-effect transistor, lcsh:Descriptive and experimental mechanics, lcsh:Electrical engineering. Electronics. Nuclear engineering, 0210 nano-technology, lcsh:Engineering (General). Civil engineering (General), Biosensor, lcsh:TK1-9971, ddc:600, Cmos compatible, Hardware_LOGICDESIGN
Abstract

Owing to their two-dimensional confinements, silicon nanowires display remarkable optical, magnetic, and electronic properties. Of special interest has been the development of advanced biosensing approaches based on the field effect associated with silicon nanowires (SiNWs). Recent advancements in top-down fabrication technologies have paved the way to large scale production of high density and quality arrays of SiNW field effect transistor (FETs), a critical step towards their integration in real-life biosensing applications. A key requirement toward the fulfilment of SiNW FETs' promises in the bioanalytical field is their efficient integration within functional devices. Aiming to provide a comprehensive roadmap for the development of SiNW FET based sensing platforms, we critically review and discuss the key design and fabrication aspects relevant to their development and integration within complementary metal-oxide-semiconductor (CMOS) technology. Refereed/Peer-reviewed

Published
2018
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44. Nanostructured cavity devices for extracellular stimulation of HL-1 cells

Author

Philipp Rinklin, Sabrina Ullmann, Bernhard Wolfrum, Ulrike Derra, Anna Czeschik, Andreas Offenhäusser, Siegfried Steltenkamp, and Peter Holik

Subjects
Materials science, Noise (signal processing), Nanotechnology, Stimulation, Signal, Nanostructures, Coupling (electronics), Microelectrode, Sensor array, Electrode, Electric Impedance, Humans, General Materials Science, Microelectrodes, ddc:600, Electrical impedance, Biomedical engineering
Abstract

Microelectrode arrays (MEAs) are state-of-the-art devices for extracellular recording and stimulation on biological tissue. Furthermore, they are a relevant tool for the development of biomedical applications like retina, cochlear and motor prostheses, cardiac pacemakers and drug screening. Hence, research on functional cell-sensor interfaces, as well as the development of new surface structures and modifications for improved electrode characteristics, is a vivid and well established field. However, combining single-cell resolution with sufficient signal coupling remains challenging due to poor cell-electrode sealing. Furthermore, electrodes with diameters below 20 µm often suffer from a high electrical impedance affecting the noise during voltage recordings. In this study, we report on a nanocavity sensor array for voltage-controlled stimulation and extracellular action potential recordings on cellular networks. Nanocavity devices combine the advantages of low-impedance electrodes with small cell-chip interfaces, preserving a high spatial resolution for recording and stimulation. A reservoir between opening aperture and electrode is provided, allowing the cell to access the structure for a tight cell-sensor sealing. We present the well-controlled fabrication process and the effect of cavity formation and electrode patterning on the sensor's impedance. Further, we demonstrate reliable voltage-controlled stimulation using nanostructured cavity devices by capturing the pacemaker of an HL-1 cell network.

Published
2015
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45. MEAs and 3D nanoelectrodes: electrodeposition as tool for a precisely controlled nanofabrication

Author

Kay J. Krause, Jan Schnitker, Andreas Offenhäusser, Bernhard Wolfrum, and Sabrina Weidlich

Subjects
Single chip, Materials science, Fabrication, Mechanical Engineering, Bioengineering, Nanotechnology, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Coupling (electronics), Microelectrode, Nanolithography, Mechanics of Materials, Electrode, General Materials Science, Electrical and Electronic Engineering, 0210 nano-technology
Abstract

Microelectrode arrays (MEAs) are gaining increasing importance for the investigation of signaling processes between electrogenic cells. However, efficient cell–chip coupling for robust and long-term electrophysiological recording and stimulation still remains a challenge. A possible approach for the improvement of the cell–electrode contact is the utilization of three-dimensional structures. In recent years, various 3D electrode geometries have been developed, but we are still lacking a fabrication approach that enables the formation of different 3D structures on a single chip in a controlled manner. This, however, is needed to enable a direct and reliable comparison of the recording capabilities of the different structures. Here, we present a method for a precisely controlled deposition of nanoelectrodes, enabling the fabrication of multiple, well-defined types of structures on our 64 electrode MEAs towards a rapid-prototyping approach to 3D electrodes.

Published
2017

46. The influence of supporting ions on the electrochemical detection of individual silver nanoparticles: Understanding the shape and frequency of current transients in nano-impacts

Author

Andreas Offenhäusser, Bernhard Wolfrum, Philipp Rinklin, Jan Schnitker, Fabian Brings, Serge G. Lemay, Dirk Mayer, Enno Kätelhön, Richard G. Compton, Kay J. Krause, and Bio electronics

Subjects
oxidation, Analytical chemistry, Nanoparticle, 02 engineering and technology, Electrolyte, 010402 general chemistry, 01 natural sciences, Chloride, Catalysis, Silver nanoparticle, Silver chloride, chemistry.chemical_compound, medicine, silver, Chemistry, Organic Chemistry, General Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Microelectrode, electrochemistry, Standard electrode potential, ddc:540, 2023 OA procedure, nanoparticles, 0210 nano-technology, medicine.drug, Electrode potential
Abstract

We report the influence of electrolyte composition and concentration on the stochastic amperometric detection of individual silver nanoparticles at microelectrode arrays and show that the sensor response at certain electrode potentials is dependent on both the conductivity of the electrolyte and the concentration of chloride ions. We further demonstrate that the chloride concentration in solution heavily influences the characteristic current spike shape of recorded nanoparticle impacts: While typically too short to be resolved in the measured current, the spike widths are significantly broadened at low chloride concentrations below 10 mM and range into the millisecond regime. The analysis of more than 25.000 spikes reveals that this effect can be explained by the diffusive mass transport of chloride ions to the nanoparticle, which limits the oxidization rate of individual silver nanoparticles to silver chloride at the chosen electrode potential.

Published
2017
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47. Correction: Tantalum(<scp>v</scp>) 1,3-propanediolate β-diketonate solution as a precursor to sol–gel derived, metal oxide thin films

Author

Stefanie Hamacher, Elmar Neumann, Alexander Shkurmanov, Gregor Mussler, Sören Möller, Guillermo Beltramo, Alexey Yakushenko, Oumaima Bensaid, Heinrich Hartmann, Christopher Beale, Sabine Willbold, Dirk Mayer, Bernhard Wolfrum, and Andreas Offenhäusser

Subjects
Materials science, General Chemical Engineering, Tantalum, chemistry.chemical_element, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Metal oxide thin films, 0104 chemical sciences, chemistry, 0210 nano-technology, Nuclear chemistry, Sol-gel
Abstract

Correction for ‘Tantalum(v) 1,3-propanediolate β-diketonate solution as a precursor to sol–gel derived, metal oxide thin films’ by Christopher Beale et al., RSC Adv., 2020, 10, 13737–13748, DOI: 10.1039/D0RA02558E.

Published
2020
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48. Brownian motion in electrochemical nanodevices

Author

Klaus Mathwig, Bernhard Wolfrum, Serge G. Lemay, and Kay J. Krause

Subjects
Physics, Mass transport, Micrometer scale, Reversible adsorption, Brownian dynamics, General Physics and Astronomy, General Materials Science, Nanotechnology, Physical and Theoretical Chemistry, Diffusion (business), Nanoscopic scale, Brownian motion
Abstract

Diffusion dominates mass transport in most electrochemical systems. In classical experimental systems on the micrometer scale or larger, this is adequately described at the mean-field level. However, nanoscale detection devices are being developed in which a handful or even single molecules can be detected. Brownian dynamics become manifest in these systems via the associated fluctuations in electrochemical signals. Here we describe the state of the art of these electrochemical nanodevices, paying particular attention to the role of Brownian dynamics and emphasizing areas in which theoretical understanding remains limited.

Published
2014
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49. Nanocavity crossbar arrays for parallel electrochemical sensing on a chip

Author

Bernhard Wolfrum, Dirk Mayer, Andreas Offenhäusser, Enno Kätelhön, and Marko Banzet

Subjects
Materials science, Passivation, Bar (music), General Physics and Astronomy, Nanotechnology, lcsh:Chemical technology, lcsh:Technology, Full Research Paper, Sensor array, Perpendicular, lcsh:TP1-1185, General Materials Science, Wafer, Electrical and Electronic Engineering, lcsh:Science, nanoelectrochemistry, Nanoelectrochemistry, lcsh:T, redox cycling, lcsh:QC1-999, Nanoscience, Electrode, lcsh:Q, electrochemical imaging, ddc:620, Crossbar switch, lcsh:Physics
Abstract

Beilstein Journal of Nanotechnology 5, 1137-1143 (2014). doi:10.3762/bjnano.5.124, Published by Beilstein-Institut zur Förderung der Chemischen Wissenschaften, Frankfurt, M.

Published
2014
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50. On-chip fast scan cyclic voltammetry for selective detection of redox active neurotransmitters

Author

Volker Schöps, Andreas Offenhäusser, Alexey Yakushenko, Dirk Mayer, and Bernhard Wolfrum

Subjects
Chemistry, Fast-scan cyclic voltammetry, Analytical chemistry, Surfaces and Interfaces, Condensed Matter Physics, Chip, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Microelectrode, Electrode, Materials Chemistry, Biophysics, Degradation (geology), Redox active, Electrical and Electronic Engineering, Cyclic voltammetry, Selectivity
Abstract

Fast scan cyclic voltammetry is a powerful technique for selective detection of biogenic amines in vivo and in vitro. Here we investigate this technique for multichannel spatiotemporal detection of neurotransmitter concentrations on a chip, using metal microelectrode arrays. The array-based approach allows monitoring concentration gradients of redox-active species at multiple highly localized (3 µm) positions simultaneously, while maintaining selectivity from the characteristic voltammogram shapes. We demonstrate that concentration fluctuations at individual electrode locations are resolved after spatially confined neurotransmitter injections. Furthermore, we discuss effects of microelectrode degradation caused by electrode sweeping during long-term experiments.

Published
2014
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