Neural tube morphogenesis in synthetic 3D microenvironments

Ranga, Adrian; Girgin, Mehmet; Meinhardt, Andrea; Eberle, Dominic; Caiazzo, Massimiliano; Tanaka, Elly M.; Lütolf, Matthias P.

doi:10.1073/pnas.1603529113

Cited by 196 publications

(182 citation statements)

References 32 publications

(44 reference statements)

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“…[197,200,201] Modular synthetic matrices have been used to control early neural morphogenesis and to explore the role of ECM in the development of 3D neuroepithelial organoids. [200,201] A recent study used a 3D microarray platform based on cross-linked multi-arm PEG, to probe the effect of factors including matrix elasticity, degradability, and signaling proteins on mouse embryonic stem cells (Figure 7D). [201] Current approaches to study the neural tube morphogenesis also rely on commercial animal derived matrices, such as Matrigel.…”

Section: Designing Synthetic Matrices For Recapitulating the Extramentioning

confidence: 99%

“…[200,201] A recent study used a 3D microarray platform based on cross-linked multi-arm PEG, to probe the effect of factors including matrix elasticity, degradability, and signaling proteins on mouse embryonic stem cells (Figure 7D). [201] Current approaches to study the neural tube morphogenesis also rely on commercial animal derived matrices, such as Matrigel. However, Matrigel leads to heterogeneities, whereas well defined synthetic matrices lead to more homogeneous and defined populations.…”

Section: Designing Synthetic Matrices For Recapitulating the Extramentioning

confidence: 99%

“…New insights are emerging into the role of biophysical factors in neural morphogenesis and multifactorial cell-matrix interactions are key to control the growth and differentiation of stem cells in vitro. [201] …”

Section: Designing Synthetic Matrices For Recapitulating the Extramentioning

confidence: 99%

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Three‐Dimensional Models of the Human Brain Development and Diseases

Jorfi

D’Avanzo

Kim

et al. 2017

Adv Healthcare Materials

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Deciphering the human brain pathophysiology remains one of the greatest challenges of the 21st century. Neurological disorders represent a significant proportion of diseases burden; however, the complexity of the brain physiology makes it challenging to model its diseases. Simple in vitro models have been very useful for precise measurements in controled conditions. However, existing models are limited in their ability to replicate complex interactions between various cells in the brain. Studying human brain requires sophisticated models to reconstitute the tangled architecture and functions of brain cells. Recently, advances in the development of three-dimensional (3D) brain cell culture models have begun to recapitulate various aspects of the human brain physiology in vitro and replicate basic disease processes of Alzheimer’s disease, amyotrophic lateral sclerosis, and microcephaly. In this review, we discuss the progress, advantages, limitations, and future directions of 3D cell culture systems for modeling the human brain development and diseases.

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Section: Designing Synthetic Matrices For Recapitulating the Extramentioning

confidence: 99%

Section: Designing Synthetic Matrices For Recapitulating the Extramentioning

confidence: 99%

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Three‐Dimensional Models of the Human Brain Development and Diseases

Jorfi

D’Avanzo

Kim

et al. 2017

Adv Healthcare Materials

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“…Embryonic and extraembryonic stem cells have been shown to self-organize in 3D culture (45)(46)(47)(48)(49). When ESCs are cultured in a 3D gel supplemented with ECM, they form an apicalbasal polarized shell that eliminates the boundaries of micropattern culture, allowing control of substrate mechanics and chemistry.…”

Section: Self-organization In Embryonic Stem Cellsmentioning

confidence: 99%

357 Occupational exposure to selenium compounds, its effect on biological parameters and markers of diabetes

Greiner

Feltes

Hildebrand

et al. 2018

Occupational Toxicology

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Embryonic development is orchestrated by robust and complex regulatory mechanisms acting at different scales of organization. In vivo studies are particularly challenging for mammals after implantation, owing to the small size and inaccessibility of the embryo. The generation of stem cell models of the embryo represents a powerful system with which to dissect this complexity. Control of geometry, modulation of the physical environment, and priming with chemical signals reveal the intrinsic capacity of embryonic stem cells to make patterns. Adding the stem cells for the extraembryonic lineages generates three-dimensional models that are more autonomous from the environment and recapitulate many features of the pre-and postimplantation mouse embryo, including gastrulation. Here, we review the principles of self-organization and how they set cells in motion to create an embryo.

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“…Recently, hydrogels have been used to investigate the role of the ECM on the formation of self-organized multi-cellular aggregates. [2] By tuning matrix stiffness, degradability, and type and amount of biologically active ligand, the optimal conditions for proliferation, differentiation, and self-organization can be identified. Interestingly, the optimal hydrogel compositions vary significantly for different cell types, reflecting the advantage of specifically bioengineered matrices over Matrigel.…”

Section: Introductionmentioning

confidence: 99%

Dynamic bioengineered hydrogels as scaffolds for advanced stem cell and organoid culture

2017

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Bioengineered hydrogels enable systematic variation of mechanical and biochemical properties, resulting in the identification of optimal in vitro three-dimensional culture conditions for individual cell types. As the scientific community attempts to mimic and study more complex biologic processes, hydrogel design has become multi-faceted. To mimic organ and tissue heterogeneity in terms of spatial arrangement and temporal changes, hydrogels with spatiotemporal control over mechanical and biochemical properties are needed. In this prospective article, we present studies that focus on the development of hydrogels with dynamic mechanical and biochemical properties, highlighting the discoveries made using these scaffolds.

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Neural tube morphogenesis in synthetic 3D microenvironments

Cited by 196 publications

References 32 publications

Three‐Dimensional Models of the Human Brain Development and Diseases

Three‐Dimensional Models of the Human Brain Development and Diseases

357 Occupational exposure to selenium compounds, its effect on biological parameters and markers of diabetes

Dynamic bioengineered hydrogels as scaffolds for advanced stem cell and organoid culture

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