In-mold patterning and actionable axo-somatic compartmentalization for on-chip neuron culture

Yamada, Ayako; Vignes, Maéva; Bureau, Cécile; Mamane, Alexandre; Venzac, Bastien; Descroix, Stéphanie; Viovy, Jean‐Louis; Villard, Catherine; Peyrin, Jean Michel; Malaquin, Laurent

doi:10.1039/c6lc00414h

Cited by 31 publications

(24 citation statements)

References 43 publications

(67 reference statements)

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“…In the present study, we developed polydimethylsiloxane (PDMS) microstructured substrates of various topographies using photolithography and molding. Coated PDMS surfaces have been validated for the culture of various cell types [65], including primary neurons [66]. The final culture coverslip is composed of a thin layer of microstructured PDMS strongly attached on a glass coverslip (Fig.1A).…”

Section: Design Of Microstructured Substrates To Study the Migration mentioning

confidence: 99%

Topographical cues control the morphology and dynamics of migrating cortical interneurons

et al. 2019

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In mammalian embryos, cortical interneurons travel long distances among complex threedimensional tissues before integrating into cortical circuits. Several molecular guiding cues involved in this migration process have been identified, but the influence of physical parameters remains poorly understood. In the present study, we have investigated in vitro the influence of the topography of the microenvironment on the migration of primary cortical interneurons released from mouse embryonic explants. We found that arrays of PDMS micro-pillars of 10µm size and spacing, either round or square, influenced both the morphology and the migratory behavior of interneurons. Strikingly, most interneurons exhibited a single and long leading process oriented along the diagonals of the square pillared array, whereas leading processes of interneurons migrating inbetween round pillars were shorter, often branched and oriented in all available directions. Accordingly, dynamic studies revealed that growth cone divisions were twice more frequent in round than in square pillars. Both soma and leading process tips presented forward directed movements within square pillars, contrasting with the erratic trajectories and more dynamic movements observed among round pillars. In support of these observations, long interneurons migrating in square pillars displayed tight bundles of stable microtubules aligned in the direction of migration. Overall, our results show that micron-sized topography provides global spatial constraints promoting the establishment of different morphological and migratory states. Remarkably, these different states belong to the natural range of migratory behaviors of cortical interneurons, highlighting the potential importance of topographical cues in the guidance of these embryonic neurons, and more generally in brain development.

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Section: Design Of Microstructured Substrates To Study the Migration mentioning

confidence: 99%

Topographical cues control the morphology and dynamics of migrating cortical interneurons

et al. 2019

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“…Noteworthy, when using such cotton threads, the device should be thoroughly sterilized with ethanol before use, not to compromise cell viability during the experiments. Building up on previously developed technology making use of removable filaments in a microfluidic device to create hydrogel structures [56,57] we first confined our 3D cell-hydrogel construct using Nylon filaments (VARIVAS Fluoro carbon Super tippet 2XN 0.235-mm diameter, Morris, Saitama, Japan) inserted in 200-µm high guiding channels through vertical inlets and outlets before bonding of the device. However, those large filaments were not deformable enough to bend and conform with the sharp angle existing at the inlets and outlets of the guiding channels, which significantly hampered bonding of the device with the glass slide, which was not the case for smaller height channels (80 µm) and thinner Nylon fibers (95-µm diameter) in the original paper introducing this technique.…”

Section: Design and Fabrication Of The Microfluidic Systemsmentioning

confidence: 99%

Metabolic Switching of Tumor Cells under Hypoxic Conditions in a Tumor-on-a-chip Model

et al. 2020

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Hypoxia switches the metabolism of tumor cells and induces drug resistance. Currently, no therapeutic exists that effectively and specifically targets hypoxic cells in tumors. Development of such therapeutics critically depends on the availability of in vitro models that accurately recapitulate hypoxia as found in the tumor microenvironment. Here, we report on the design and validation of an easy-to-fabricate tumor-on-a-chip microfluidic platform that robustly emulates the hypoxic tumor microenvironment. The tumor-on-a-chip model consists of a central chamber for 3D tumor cell culture and two side channels for medium perfusion. The microfluidic device is fabricated from polydimethylsiloxane (PDMS), and oxygen diffusion in the device is blocked by an embedded sheet of polymethyl methacrylate (PMMA). Hypoxia was confirmed using oxygen-sensitive probes and the effect on the 3D tumor cell culture investigated by a pH-sensitive dual-labeled fluorescent dextran and a fluorescently labeled glucose analogue. In contrast to control devices without PMMA, PMMA-containing devices gave rise to decreases in oxygen and pH levels as well as an increased consumption of glucose after two days of culture, indicating a rapid metabolic switch of the tumor cells under hypoxic conditions towards increased glycolysis. This platform will open new avenues for testing anti-cancer therapies targeting hypoxic areas.

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“…In recent years, numerous studies have reported the application of compartmentalized microfluidic platforms for neurobiological research 133–135 . The ability to observe the different parts of neurons (axons and cell bodies) in compartmentalized microfluidic devices can be useful for studying neurodegenerative diseases.…”

Section: Stem Cells In Microfluidic-based Neural Tissue Engineeringmentioning

confidence: 99%

Microfluidic systems for stem cell-based neural tissue engineering

et al. 2016

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Neural tissue engineering aims at developing novel approaches for the treatment of diseases of the nervous system, by providing a permissive environment for the growth and differentiation of neural cells. Three-dimensional (3D) cell culture systems provide a closer biomimetic environment, and promote better cell differentiation and improved cell function, than could be achieved by conventional two-dimensional (2D) culture systems. With the recent advances in the discovery and introduction of different types of stem cells for tissue engineering, microfluidic platforms have provided an improved microenvironment for the 3D-culture of stem cells. Microfluidic systems can provide more precise control over the spatiotemporal distribution of chemical and physical cues at the cellular level compared to traditional systems. Various microsystems have been designed and fabricated for the purpose of neural tissue engineering. Enhanced neural migration and differentiation, and monitoring of these processes, as well as understanding the behavior of stem cells and their microenvironment have been obtained through application of different microfluidic-based stem cell culture and tissue engineering techniques. As the technology advances it may be possible to construct a “brain-on-a-chip”. In this review, we describe the basics of stem cells and tissue engineering as well as microfluidics-based tissue engineering approaches. We review recent testing of various microfluidic approaches for stem cell-based neural tissue engineering.

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In-mold patterning and actionable axo-somatic compartmentalization for on-chip neuron culture

Cited by 31 publications

References 43 publications

Topographical cues control the morphology and dynamics of migrating cortical interneurons

Topographical cues control the morphology and dynamics of migrating cortical interneurons

Metabolic Switching of Tumor Cells under Hypoxic Conditions in a Tumor-on-a-chip Model

Microfluidic systems for stem cell-based neural tissue engineering

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