Impedimetric real-time monitoring of neural pluripotent stem cell differentiation process on microelectrode arrays

Seidel, Daniel; Obendorf, Janine; Englich, Beate; Jahnke, Heinz‐Georg; Semkova, Vesselina; Haupt, Simone; Girard, Mathilde; Peschanski, Marc; Brüstle, Oliver

doi:10.1016/j.bios.2016.06.056

Cited by 42 publications

(41 citation statements)

References 38 publications

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“…In order to analyze more in depth the impedance spectra variations, the impedance spectra were fitted based on an electronic circuit model (Supplementary material S2) . However, comparing cells cultured in GM and differentiation media, the circuit elements used to model the electrode/cell interface showed similar values.…”

Section: Resultsmentioning

confidence: 99%

Electrochemical Monitoring of Saos‐2 Cell Differentiation on Pyrolytic Carbon Electrodes

et al. 2018

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In this study we establish an electrochemical platform based on two dimensional (2D) pyrolytic carbon electrodes for in vitro analysis of osteoblast differentiation. Electrochemical impedance spectroscopy (EIS) was used to monitor cell adhesion and proliferation, while an electrochemical assay based on square wave voltammetry (SWV) was applied to measure the activity of the differentiation marker alkaline phosphatase (ALP). 2D pyrolytic carbon electrodes were fabricated and used to monitor Saos‐2 cell differentiation for a period of up to 21 days. With this method it was possible to detect a faster increase of ALP activity for cells cultured in medium supplemented with differentiation factors compared to cells cultured in growth medium. This was confirmed by the results obtained with Alizarin Red staining, showing that cells subjected to osteogenic medium went through the entire differentiation process, from proliferation to mineralization. Finally, for the first time, real‐time monitoring of ALP activity combined with continuous EIS monitoring of the same cell culture was achieved using the pyrolytic carbon electrodes.

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Section: Resultsmentioning

confidence: 99%

Electrochemical Monitoring of Saos‐2 Cell Differentiation on Pyrolytic Carbon Electrodes

et al. 2018

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“…Numerous studies based on impedance measurements of live biological cells enabled the technique to become widely accepted as a label free, non-invasive and quantitative analytical method to assess cell status. To show some examples, bioimpedance can be used to monitor proliferation [5], apoptosis [6], migration [7], degeneration [8], morphological changes [9] and also (neuronal) differentiation [10].…”

Section: Introductionmentioning

confidence: 99%

Bioimpedance Measurements on Human Neural Stem Cells as a Benchmark for the Development of Smart Mobile Biomedical Applications

et al. 2020

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Over the past 30 years, stem cell technologies matured from an attractive option to investigate neurodegenerative diseases to a possible paradigm shift in their treatment through the development of cell-based regenerative medicine (CRM). Implantable cell replacement therapies promise to completely restore function of neural structures possibly changing how we currently perceive the onset of these conditions. One of the major clinical hurdles facing the routine implementation of stem cell therapy is the limited and inconsistent benefit observed thus far. While unclear, numerous pre-clinical and a handful of clinical cell fate imaging studies point to poor cell retention and survival. Coupling the need to better understand these mechanisms while providing scalable approaches to monitor these treatments in both pre-clinical and clinical scenarios, we show a proof of concept bioimpedance electronic platform for the Agile development of smart and mobile biomedical applications like neural implants or highly portable monitoring devices.

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“…In this context, we published an actual work that demonstrates the feasibility of using impedance spectroscopy for monitoring and quantifying the initial differentiation process of neuronal differentiation. 7 Nevertheless, for late maturation and functional monitoring of finally differentiated and mature neuronal cultures, the monitoring of neuronal network electrophysiology is crucial, especially in safety assessment to identify the effect of active ingredients on human neuronal cell models. In contrast to traditional technologies such as patch clamp that are invasive and single cell-dependent and hinder scale-up, microelectrode array (MEA)-based field potential recording fulfills the demands of advanced neuronal network electrophysiology characterization.…”

Section: Introductionmentioning

confidence: 99%

In vitro field potential monitoring on a multi-microelectrode array for the electrophysiological long-term screening of neural stem cell maturation

Seidel

Jahnke

Englich

et al. 2017

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Due to the lack of appropriate cell models as well as automated electrophysiology monitoring technologies, the standardized identification of neurotoxic or protective effects in vitro remains a major problem in today's pharmaceutical ingredient development. Over the past few years, in vivo-like human pluripotent stem cell-derived neuronal networks have turned out to be a promising physiological cell source, if the establishment of robust and time-saving functional maturation strategies based on stable and expandable neural progenitor populations can be achieved. Here, we describe a multi-microelectrode array (MMEA)-based bioelectronics platform that was optimized for long-term electrophysiological activity monitoring of neuronal networks via field potential measurements. Differentiation of small molecule-based neuronal progenitors on MMEAs led to functional neurons within 15 days. More strikingly, these functional neuronal cultures could remain electrophysiologically stable on the MMEAs for more than four weeks. The observed electrophysiological properties correlated with the expression of typical neuron subtype markers and were further validated by specific neurotransmitter applications. With our established monitoring platform, we could show for the first time the long-term stability of the neural stem cell-like progenitor population to differentiate to electrophysiologically active dopaminergic neuronal networks for more than 80 passages. In conclusion, we provide a comprehensive long-term stable field potential monitoring platform based on stem cell-derived human neuronal networks that can be automated and up-scaled for standardized high-content screening applications e.g. in the field of neurotoxic and neuroprotective therapeutics identification.

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Impedimetric real-time monitoring of neural pluripotent stem cell differentiation process on microelectrode arrays

Cited by 42 publications

References 38 publications

Electrochemical Monitoring of Saos‐2 Cell Differentiation on Pyrolytic Carbon Electrodes

Electrochemical Monitoring of Saos‐2 Cell Differentiation on Pyrolytic Carbon Electrodes

Bioimpedance Measurements on Human Neural Stem Cells as a Benchmark for the Development of Smart Mobile Biomedical Applications

In vitro field potential monitoring on a multi-microelectrode array for the electrophysiological long-term screening of neural stem cell maturation

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