Patterning of cell-instructive hydrogels by hydrodynamic flow focusing

Cosson, Steffen; Allazetta, Simone

doi:10.1039/c3lc50219h

Cited by 21 publications

(19 citation statements)

References 22 publications

(39 reference statements)

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“…This developed microfluidic method opens a new avenue for intercellular signaling studies (e.g., probing the different existing mechanisms and even how they operate) and drug screening (e.g., screening different potential drugs for more effective agonist or inhibitor) [6,8]. In addition, we anticipate this new method also has other potential applications, such as the study of neurochemistry (e.g., single cell recording) or neuroregeneration [46], the investigation of spatial-temporal dynamics of collective chemosensing [47] and the microfluidic patterning of proteins [48].…”

Section: Discussionmentioning

confidence: 98%

Investigating intercellular calcium waves by microfluidic gated pinched-flow

Chen

Feng

Chen

et al. 2016

Sensors and Actuators B: Chemical

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Section: Discussionmentioning

confidence: 98%

Investigating intercellular calcium waves by microfluidic gated pinched-flow

Chen

Feng

Chen

et al. 2016

Sensors and Actuators B: Chemical

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“…Cosson et al [75]. In this work, poly(ethylene glycol) (PEG) hydrogels containing PEG-tethered NeutrAvidin/ProteinA could be on-demand patterned by various gradient profiles of biomolecules, including the formation of surface-bound overlapping gradients.…”

Section: Surface-bound Gradientsmentioning

confidence: 94%

“…Schematic of 2-step patterning process (i); stitched micrographs of a four-by-four gradient array of fluorescent-BSA-biotin (vertical) and fluorescent Alexa488-hIgG (horizontal) gradients patterned on PEG gel using hydrodynamic flow focusing, magnification details and respective intensity profile graphs (scale bar = 900 lm). Adapted from Ref [75]. with permission of The Royal Society of Chemistry.…”

mentioning

confidence: 99%

High-throughput screening approaches and combinatorial development of biomaterials using microfluidics

2016

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Microfluidics, being a technology characterized by the engineered manipulation of fluids at the submillimeter scale, offers some interesting tools that can advance biomedical research and development. Screening platforms based on microfluidic technologies that allow high-throughput and combinatorial screening may lead to breakthrough discoveries not only in basic research but also relevant to clinical application. This is further strengthened by the fact that reliability of such screens may improve, since microfluidic systems allow close mimicking of physiological conditions. Finally, microfluidic systems are also very promising as micro factories of a new generation of natural or synthetic biomaterials and constructs, with finely controlled properties.

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“…We recently introduced a platform for the rapid generation of protein gradients of arbitrary size and shape tethered on the surface of soft hydrogels using hydrodynamic flow focusing and bioconjugation strategies (see Glossary, Box 1) (Cosson et al, 2013). We used this technique to explore how gradients of leukemia inhibitory factor (LIF) influence ESC behavior.…”

Section: D Spatial and Temporal Patterning Of Biochemical Signalsmentioning

confidence: 99%

Bioengineering approaches to guide stem cell-based organogenesis

2014

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During organogenesis, various molecular and physical signals are orchestrated in space and time to sculpt multiple cell types into functional tissues and organs. The complex and dynamic nature of the process has hindered studies aimed at delineating morphogenetic mechanisms in vivo, particularly in mammals. Recent demonstrations of stem cell-driven tissue assembly in culture offer a powerful new tool for modeling and dissecting organogenesis. However, despite the highly organotypic nature of stem cell-derived tissues, substantial differences set them apart from their in vivo counterparts, probably owing to the altered microenvironment in which they reside and the lack of mesenchymal influences. Advances in the biomaterials and microtechnology fields have, for example, afforded a high degree of spatiotemporal control over the cellular microenvironment, making it possible to interrogate the effects of individual microenvironmental components in a modular fashion and rapidly identify organ-specific synthetic culture models. Hence, bioengineering approaches promise to bridge the gap between stem cell-driven tissue formation in culture and morphogenesis in vivo, offering mechanistic insight into organogenesis and unveiling powerful new models for drug discovery, as well as strategies for tissue regeneration in the clinic. We draw on several examples of stem cellderived organoids to illustrate how bioengineering can contribute to tissue formation ex vivo. We also discuss the challenges that lie ahead and potential ways to overcome them.

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Patterning of cell-instructive hydrogels by hydrodynamic flow focusing

Cited by 21 publications

References 22 publications

Investigating intercellular calcium waves by microfluidic gated pinched-flow

Investigating intercellular calcium waves by microfluidic gated pinched-flow

High-throughput screening approaches and combinatorial development of biomaterials using microfluidics

Bioengineering approaches to guide stem cell-based organogenesis

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