Cell survival and proliferation after encapsulation in a chemically modified Pluronic® F127 hydrogel

Lippens, Evi; Swennen, Ives; Gironès, Jordi; Declercq, Heidi; Vertenten, Geert; Vlaminck, Lieven; Gasthuys, Frank; Schacht, Etienne; Cornelissen, Ria

doi:10.1177/0885328211427774

Cited by 37 publications

(24 citation statements)

References 31 publications

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“…Synthetic polymer hydrogels are typically polymerized as a 3D network that presents a 2D culture substrate as they are often composed of cytotoxic components that upon polymerization become inert. However, cells can now be mixed in situ in liquid gels that can be polymerized by temperature, chemical or photo induced polymerization 82 . Novel techniques to encapsulate cells in gels in a highly controlled manner are emerging from microfluidics community by leveraging the control over fluid flow of polymer gels 83,84 .…”

Section: Co-regulation Of Stem Cell Function By Multi-variant Mechmentioning

confidence: 99%

Control of stem cell fate and function by engineering physical microenvironments

Kshitiz

Park

Kim

et al. 2012

Integrative Biology

234

135

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The phenotypic expression and function of stem cells are regulated by their integrated response to variable microenvironmental cues, including growth factors and cytokines, matrix-mediated signals, and cell-cell interactions. Recently, growing evidence suggests that matrix-mediated signals include mechanical stimuli such as strain, shear stress, substrate rigidity and topography, and these stimuli have a more profound impact on stem cell phenotypes than had previously been recognized, e.g. self-renewal and differentiation through the control of gene transcription and signaling pathways. Using a variety of cell culture models enabled by micro and nanoscale technologies, we are beginning to systematically and quantitatively investigate the integrated response of cells to combinations of relevant mechanobiological stimuli. This paper reviews recent advances in engineering physical stimuli for stem cell mechanobiology and discusses how micro-and nanoscale engineered platforms can be used to control stem cell niche environments and regulate stem cell fate and function.

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Section: Co-regulation Of Stem Cell Function By Multi-variant Mechmentioning

confidence: 99%

Control of stem cell fate and function by engineering physical microenvironments

Kshitiz

Park

Kim

et al. 2012

Integrative Biology

234

135

View full text Add to dashboard Cite

show abstract

“…Also, a covalent modification of insulin as recently performed by Chou et al(28) prior to its encapsulation into the micelles is another possible approach. Regarding SOLbased formulations, future studies are required to deeply analyze the effect of glucose concentration of the release properties of SOL and to explore the possible stimuli-responsive properties of the polymer for future applications.Pluronic ® are considered biocompatible and biodegradable polymers used in many biomedical applications including cell's encapsulation(29,30). Thus, as expected, no significant signs of toxicity to both pulmonary cell lines and macrophages were observed in the in vitro experimental setting used as determined by MTT and LDH leakage assays.…”

mentioning

confidence: 52%

Biological assessment of self-assembled polymeric micelles for pulmonary administration of insulin

Andrade

Neves

Gener

et al. 2015

Nanomedicine: Nanotechnology, Biology and Medicine

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“…The typical pore size ranges typically from 100-1000 µm. More recently, the focus has shifted from thermoplastic biodegradable polymers to hydrogels, as several research groups have now succeeded to mix cells within the polymer feed [36,37]. This generates hybrid scaffolds that are composed of both dead and living species.…”

Section: Rapid Prototypingmentioning

confidence: 99%

Plasma Science and Technology - Progress in Physical States and Chemical Reactions

Mieno¹

2016

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Non-thermal plasma technology is one of those techniques that suffer relatively little from diffusion limits, slow kinetics, and complex geometries compared to more traditional liquid-based chemical surface modification techniques. Combined with a lack of solvents, preservation of the bulk properties, and fast treatment times; it is a well-liked technique for the treatment of materials for biomedical applications. In this book chapter, a review will be given on what the scientific community determined to be essential to obtain appropriate scaffolds for tissue engineering and how plasma scientists have used non-thermal plasma technology to accomplish this. A distinction will be made depending on the scaffold fabrication technique, as each technique has its own set of specific problems that need to be tackled. Fabrication techniques will include traditional fabrication methods, rapid prototyping, and electrospinning. As for the different plasma techniques, both plasma activation and grafting/polymerization will be included in the review and linked to the in-vitro/in-vivo response to these treatments. The literature review itself is preceded by a more general overview on cell communication, giving useful insights on how surface modification strategies should be developed.

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Cell survival and proliferation after encapsulation in a chemically modified Pluronic® F127 hydrogel

Cited by 37 publications

References 31 publications

Control of stem cell fate and function by engineering physical microenvironments

Control of stem cell fate and function by engineering physical microenvironments

Biological assessment of self-assembled polymeric micelles for pulmonary administration of insulin

Plasma Science and Technology - Progress in Physical States and Chemical Reactions

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