Christoph Grün scite author profile

To date, tissue engineering and organ‐on‐a‐chip devices become more powerful as replacements for animal testings in high throughput drug screenings. However, the majority of the devices are either based on static 2D or 3D cell cultures or on microfluidic channel systems that are usually rectangular and do not fit to the geometry of natural blood vessels. Therefore, a semicircular microfluidic blood vessel scaffold (vasQchip) with a surrounding microfluidic compartment for vascularized 3D cell culture was developed, which resembles the curvature of natural blood vessels. vasQchip is composed of a porous microchannel which is produced by micro‐thermoforming of polycarbonate membranes. The pores generated by ion track technology allow for the support of nutrients and gases as well as for the exchange of growth factors or immune cells with the surrounding compartment. Eventually the surrounding compartment can be used for the establishment of 3D cell cultures in order to reconstruct vascularized tissues. Here, the vasQchip for its biocompatibility is characterized to somatic primary cells, the diffusion of molecules through the artificial blood vessels and its suitability for 3D cell culture. In addition, shear stress and flow regimes are simulated in order to mimic the natural environment of vascularized tissues.

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Advanced 3D Cell Culture Techniques in Micro-Bioreactors, Part II: Systems and Applications

Altmann

Grün

Nies

et al. 2020

Processes

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In this second part of our systematic review on the research area of 3D cell culture in micro-bioreactors we give a detailed description of the published work with regard to the existing micro-bioreactor types and their applications, and highlight important results gathered with the respective systems. As an interesting detail, we found that micro-bioreactors have already been used in SARS-CoV research prior to the SARS-CoV2 pandemic. As our literature research revealed a variety of 3D cell culture configurations in the examined bioreactor systems, we defined in review part one “complexity levels” by means of the corresponding 3D cell culture techniques applied in the systems. The definition of the complexity is thereby based on the knowledge that the spatial distribution of cell-extracellular matrix interactions and the spatial distribution of homologous and heterologous cell–cell contacts play an important role in modulating cell functions. Because at least one of these parameters can be assigned to the 3D cell culture techniques discussed in the present review, we structured the studies according to the complexity levels applied in the MBR systems.

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Advanced 3D Cell Culture Techniques in Micro-Bioreactors, Part I: A Systematic Analysis of the Literature Published between 2000 and 2020

2020

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Bioreactors have proven useful for a vast amount of applications. Besides classical large-scale bioreactors and fermenters for prokaryotic and eukaryotic organisms, micro-bioreactors, as specialized bioreactor systems, have become an invaluable tool for mammalian 3D cell cultures. In this systematic review we analyze the literature in the field of eukaryotic 3D cell culture in micro-bioreactors within the last 20 years. For this, we define complexity levels with regard to the cellular 3D microenvironment concerning cell–matrix-contact, cell–cell-contact and the number of different cell types present at the same time. Moreover, we examine the data with regard to the micro-bioreactor design including mode of cell stimulation/nutrient supply and materials used for the micro-bioreactors, the corresponding 3D cell culture techniques and the related cellular microenvironment, the cell types and in vitro models used. As a data source we used the National Library of Medicine and analyzed the studies published from 2000 to 2020.

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O2-sensitive microcavity arrays: A new platform for oxygen measurements in 3D cell cultures

Grün

Pfeifer

Liebsch

et al. 2023

Front. Bioeng. Biotechnol.

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Oxygen concentration plays a crucial role in (3D) cell culture. However, the oxygen content in vitro is usually not comparable to the in vivo situation, which is partly due to the fact that most experiments are performed under ambient atmosphere supplemented with 5% CO2, which can lead to hyperoxia. Cultivation under physiological conditions is necessary, but also fails to have suitable measurement methods, especially in 3D cell culture. Current oxygen measurement methods rely on global oxygen measurements (dish or well) and can only be performed in 2D cultures. In this paper, we describe a system that allows the determination of oxygen in 3D cell culture, especially in the microenvironment of single spheroids/organoids. For this purpose, microthermoforming was used to generate microcavity arrays from oxygen-sensitive polymer films. In these oxygen-sensitive microcavity arrays (sensor arrays), spheroids cannot only be generated but also cultivated further. In initial experiments we could show that the system is able to perform mitochondrial stress tests in spheroid cultures to characterize mitochondrial respiration in 3D. Thus, with the help of sensor arrays, it is possible to determine oxygen label-free and in real-time in the immediate microenvironment of spheroid cultures for the first time.

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Christoph Grün

Gallic acid induces mitotic catastrophe and inhibits centrosomal clustering in HeLa cells

vasQchip: A Novel Microfluidic, Artificial Blood Vessel Scaffold for Vascularized 3D Tissues

Advanced 3D Cell Culture Techniques in Micro-Bioreactors, Part II: Systems and Applications

Advanced 3D Cell Culture Techniques in Micro-Bioreactors, Part I: A Systematic Analysis of the Literature Published between 2000 and 2020

O2-sensitive microcavity arrays: A new platform for oxygen measurements in 3D cell cultures

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