3D tissue culture substrates produced by microthermoforming of pre-processed polymer films

Giselbrecht, Stefan; Gietzelt, Thomas; Gottwald, Eric; Trautmann, C.; Truckenmüller, Roman; Weibezahn, Karl-Friedrich; Welle, Alexander

doi:10.1007/s10544-006-8174-8

Cited by 107 publications

(114 citation statements)

References 26 publications

(22 reference statements)

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“…For co-culture with cortical tissue spheroids, a special membrane with thermo-formed micro-cavities was integrated for immobilization of the spheroids during perfusion of the endothelial layer in the lower part of the biochip (Figure 1). 16 Each micro-channel system is connected to a separate sampling port that allows sample collection without interruption of cell culture perfusion with medium ( Figure 1).…”

Section: Resultsmentioning

confidence: 99%

An integrative microfluidically supported in vitro model of an endothelial barrier combined with cortical spheroids simulates effects of neuroinflammation in neocortex development

et al. 2016

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The development of therapeutic substances to treat diseases of the central nervous system is hampered by the tightness and selectivity of the blood-brain barrier. Moreover, testing of potential drugs is time-consuming and cost-intensive. Here, we established a new microfluidically supported, biochip-based model of the brain endothelial barrier in combination with brain cortical spheroids suitable to detect effects of neuroinflammation upon disruption of the endothelial layer in response to inflammatory signals. Unilateral perfusion of the endothelial cell layer with a cytokine mix comprising tumor necrosis factor, IL-1b, IFNc, and lipopolysaccharide resulted in a loss of endothelial von Willebrand factor and VE-cadherin expression accompanied with an increased leakage of the endothelial layer and diminished endothelial cell viability. In addition, cytokine treatment caused a loss of neocortex differentiation markers Tbr1, Tbr2, and Pax6 in the cortical spheroids concomitant with reduced cell viability and spheroid integrity. From these observations, we conclude that our endothelial barrier/cortex model is suitable to specifically reflect cytokine-induced effects on barrier integrity and to uncover damage and impairment of cortical tissue development and viability. With all its limitations, the model represents a novel tool to study cross-communication between the brain endothelial barrier and underlying cortical tissue that can be utilized for toxicity and drug screening studies focusing on inflammation and neocortex formation. Published by AIP Publishing. [http://dx

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Section: Resultsmentioning

confidence: 99%

An integrative microfluidically supported in vitro model of an endothelial barrier combined with cortical spheroids simulates effects of neuroinflammation in neocortex development

et al. 2016

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“…and the fabrication process called SMART (Substrate Modification and Replication by Thermoforming), which allows the production of chips from thin polymer films [42,43] . SMART consists of a combination of microtechnical thermoforming or microthermoforming and various material modification techniques, and thus allows a site-specific functionalization of 3D cavities.…”

Section: D-matricesmentioning

confidence: 99%

The famousversusthe inconvenient - or the dawn and the rise of 3D-culture systems

Altmann

Welle²,

Giselbrecht³

et al. 2009

WJSC

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Author contributions: Altmann B performed bioreactor experiments and wrote the draft of the manuscript; Giselbrecht S and Truckenmüller R manufactured the KITChips and contributed substantially to the chapter 3D-matrices; Welle A and Giselbrecht S performed the surface modifications of the KITChips; Welle A performed the experiments with polylactic-co-glycolic acid and contributed substantially to the chapter 3D-matrices; Gottwald E performed bioreactor experiments and was responsible for the concept and final approval of the manuscript. Supported by AbstractOne of the greatest impacts on in vitro cell biology was the introduction of three-dimensional (3D) culture systems more than six decades ago and this era may be called the dawn of 3D-tissue culture. Although the advantages were obvious, this field of research was a "sleeping beauty" until the 1970s when multicellular spheroids were discovered as ideal tumor models. With this rebirth, organotypical culture systems became valuable tools and this trend continues to increase. While in the beginning, simple approaches, such as aggregation culture techniques, were favored due to their simplicity and convenience, now more sophisticated systems are used and are still being developed. One of the boosts in the development of new culture techniques arises from elaborate manufacturing and surface modification techniques, especially micro and nano system technologies that have either improved dramatically or have evolved very recently. With the help of these tools, it will soon be possible to generate even more sophisticated and more organotypic-like culture systems. Since 3D perfused or superfused systems are much more complex to set up and maintain compared to use of petri dishes and culture flasks, the added value of 3D approaches still needs to be demonstrated.

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“…Although the CVD process using parylene is used to fabricate 3-D membrane microstructures (Zhenga et al, 2007;Liua et al, 2008), the limitations caused by the unavailability of suitable materials and low production rates present significant problems. The microthermoforming process (Truckenmüller et al, 2002;Giselbrecht et al, 2006) can be applied to a wide variety of thermoplastic materials and is suitable for mass production; however, it cannot be applied to highly porous membranes because the pressurized fluid leaks through the pores. The MeME process (Fig.2) was developed to realize 3-D membrane microstructures from a wide variety of materials including porous materials (Ikeuchi & Ikuta, 2005;.…”

Section: Membrane Micro Emboss (Meme) Processmentioning

confidence: 99%

Membrane Micro Emboss (MeME) Process for 3-D Membrane Microdevice

Ikeuchi¹,

Ikuta²

2009

Micro Electronic and Mechanical Systems

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3D tissue culture substrates produced by microthermoforming of pre-processed polymer films

Cited by 107 publications

References 26 publications

An integrative microfluidically supported in vitro model of an endothelial barrier combined with cortical spheroids simulates effects of neuroinflammation in neocortex development

An integrative microfluidically supported in vitro model of an endothelial barrier combined with cortical spheroids simulates effects of neuroinflammation in neocortex development

The famousversusthe inconvenient - or the dawn and the rise of 3D-culture systems

Membrane Micro Emboss (MeME) Process for 3-D Membrane Microdevice

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