Stem cell colony interspacing effect on differentiation to neural cells

Joshi, Ramila; Fuller, Brendan; Mosadegh, Bobak; Tavana, Hossein

doi:10.1002/term.2739

Cited by 4 publications

(5 citation statements)

References 57 publications

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“…The first use was with noncontact printing of embryonic stem cells onto support cells that induce differentiation (13). This has since been expanded to show that spacing between cell colonies can have a profound effect on differentiation (134). Tissue constructs can be formed using ATPSs, in analogy to cell sheets used in tissue engineering.…”

Section: Cell Patterningmentioning

confidence: 99%

Aqueous Two-Phase Systems and Microfluidics for Microscale Assays and Analytical Measurements

Ahmed

Yamanishi

Kojima

et al. 2021

Annual Rev. Anal. Chem.

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Phase separation is a common occurrence in nature. Synthetic and natural polymers, salts, ionic liquids, surfactants, and biomacromolecules phase separate in water, resulting in an aqueous two-phase system (ATPS). This review discusses the properties, handling, and uses of ATPSs. These systems have been used for protein, nucleic acid, virus, and cell purification and have in recent years found new uses for small organics, polysaccharides, extracellular vesicles, and biopharmaceuticals. Analytical biochemistry applications such as quantifying protein–protein binding, probing for conformational changes, or monitoring enzyme activity have been performed with ATPSs. Not only are ATPSs biocompatible, they also retain their properties at the microscale, enabling miniaturization experiments such as droplet microfluidics, bacterial quorum sensing, multiplexed and point-of-care immunoassays, and cell patterning. ATPSs include coacervates and may find wider interest in the context of intracellular phase separation and origin of life. Recent advances in fundamental understanding and in commercial application are also considered. Expected final online publication date for the Annual Review of Analytical Chemistry, Volume 14 is August 2021. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.

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Section: Cell Patterningmentioning

confidence: 99%

Aqueous Two-Phase Systems and Microfluidics for Microscale Assays and Analytical Measurements

Ahmed

Yamanishi

Kojima

et al. 2021

Annual Rev. Anal. Chem.

View full text Add to dashboard Cite

show abstract

“…Alternatively, several studies have reported the use of PA6, a stromal cell line derived from mouse skull bone marrow, immersed in the PEG phase in which DEX droplets containing stem cells are printed to differentiate them into neural cells, demonstrating that by having direct contact with PA6 cells is sufficient to induce neural differentiation without the addition of external factors 21,30–33 …”

Section: Neuronal Cell Differentiation Using Atps‐3d Culturesmentioning

confidence: 99%

“…31 Alternatively, several studies have reported the use of PA6, a stromal cell line derived from mouse skull bone marrow, immersed in the PEG phase in which DEX droplets containing stem cells are printed to differentiate them into neural cells, demonstrating that by having direct contact with PA6 cells is sufficient to induce neural differentiation without the addition of external factors. 21,[30][31][32][33] Cell density, colony size and interconnectivity are geometrical parameters to consider during the construction of 3D cultures (Fig. 2) to enhance cell survival, migration, neurite outgrowth and lineage commitment.…”

Section: Neuronal Cell Differentiation Using Atps-3d Culturesmentioning

confidence: 99%

“…Hence, computational models could be designed to identify the regulatory roles of them at different stages of neural differentiation. 33 Studies have shown that a space of 9 mm between each cell colony modulates stem cell fate through paracrine signaling, and therefore had a positive effect on neural differentiation. 21 Taking all the aforementioned factors together during the construction of ATPS-3D cultures and considering the advantage of using traditional laboratory equipment, the efficiency of neural differentiation from stem cells has been compared using Petri dishes and 96-well plates.…”

Section: Neuronal Cell Differentiation Using Atps-3d Culturesmentioning

confidence: 99%

“…Interconnectivity of colonies is also essential to evaluate the exchange of soluble signaling factors. Hence, computational models could be designed to identify the regulatory roles of them at different stages of neural differentiation 33 . Studies have shown that a space of 9 mm between each cell colony modulates stem cell fate through paracrine signaling, and therefore had a positive effect on neural differentiation 21 …”

Section: Neuronal Cell Differentiation Using Atps‐3d Culturesmentioning

confidence: 99%

See 2 more Smart Citations

Novel approach for neuronal stem cell differentiation using aqueous two‐phase systems in 3D cultures

Chairez‐Cantu

Rito‐Palomares

2020

J of Chemical Tech & Biotech

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Stem cell therapy has emerged as a promising alternative for replacing lost cells involved in neurodegenerative diseases. High efficiency of differentiation and full cell viability are actual challenges to achieve the translation of cell therapies to the clinic. To address this, the construction of aqueous two-phase systems in three-dimensional (ATPS-3D) cultures has been proposed. This technique involves the combination of two polymers in which cells are confined in dextran droplets immersed over a substrate located in a poly(ethylene glycol) phase. The controlled placement of cells in a defined pattern promotes intercellular communication. This review aims to provide insight into the techniques used to enhance neural differentiation and current challenges to achieve the implementation of cell therapies. Cell density, colony size, interconnectivity and an appropriate substrate to modulate paracrine signaling are factors that determine neural differentiation efficiency during the construction of ATPS-3D cultures. Hence, this contact-free technique enables the design of neural niches to recapitulate in vivo environments more accurately.

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3D Printing of Multicomponent Hydrogels for Biomedical Applications

Zhou,

Wang,

Hert

et al. 2023

Multicomponent Hydrogels

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Hydrogels have attracted much attention in biomedical applications. A central focus of research has been advancing multicomponent hydrogels and engineering them into various forms and structures to yield desirable features for use in bio-related scenarios. 3D printing has served as a universal technology for processing hydrogels in a customized manner, which particularly suits the fabrication of multicomponent materials and heterogeneous structures. In this chapter, we overview the state-of-the-art of multicomponent hydrogels and their 3D printing for biomedical purposes, covering 3D printing technologies, multicomponent hydrogel materials, and biomedical applications. We have reviewed these aspects with careful classification, illustrated the progress with recent examples, and highlighted prominent trends in the field. This chapter aims to provide a comprehensive overview of the related topics and inspire researchers interested in this multidisciplinary field.

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Stem cell colony interspacing effect on differentiation to neural cells

Cited by 4 publications

References 57 publications

Aqueous Two-Phase Systems and Microfluidics for Microscale Assays and Analytical Measurements

Aqueous Two-Phase Systems and Microfluidics for Microscale Assays and Analytical Measurements

Novel approach for neuronal stem cell differentiation using aqueous two‐phase systems in 3D cultures

3D Printing of Multicomponent Hydrogels for Biomedical Applications

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