The importance of being a lumen

Bischel, Lauren L.; Sung, Kyung Eun; Jiménez-Torres, José A.; Mader, Brianah R.; Keely, Patricia J.; Beebe, David J.

doi:10.1096/fj.13-243733

Cited by 61 publications

(57 citation statements)

References 45 publications

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“…This may be due to concentration gradients of soluble factors, cell adhesion, and mechanical forces . Similarly, we have observed a considerable change in cytokine secretion by both endothelial cells and epithelial cells when cultured in an in vivo‐like structure (i.e., a lumen) compared to 2D and 3D cultures . Lumens (i.e., tubular structures) are ubiquitous in vivo being present in blood vessels, mammary ducts, and the lymphatic system.…”

mentioning

confidence: 51%

LumeNEXT: A Practical Method to Pattern Luminal Structures in ECM Gels

Jiménez-Torres

Peery

Sung

et al. 2015

Adv Healthcare Materials

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104

102

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In vitro biomimetic modeling of physiological structures bridges the gap between 2D in vitro culture and animal models. Lumens (tubular structures) are ubiquitous in vivo, being present in blood vessels, mammary ducts, and the lymphatic system. A method ‘LumeNEXT' is presented here that allows the fabrication of 3D embedded lumens where size, structure, distance, and configuration can be controlled using standard polydimethylsiloxane micromolding methods.

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mentioning

confidence: 51%

LumeNEXT: A Practical Method to Pattern Luminal Structures in ECM Gels

Jiménez-Torres

Peery

Sung

et al. 2015

Adv Healthcare Materials

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104

102

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“…Organotypic design is more than cosmetic: the importance of cell–cell interactions and structure/function relationships is well established . It has even been demonstrated that structure and geometry alone alters endothelial and epithelial cell soluble factor signaling and phenotype . In the study of the innate immune response, for example, it has been shown that multiculture, cell–cell signaling, and cell–matrix interactions alter neutrophil transendothelial migration, chemotaxis behavior, and surface marker expression .…”

Section: Introductionmentioning

confidence: 99%

An Accessible Organotypic Microvessel Model Using iPSC‐Derived Endothelium

Ingram

Hind

Jiminez-Torres

et al. 2017

Adv Healthcare Materials

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While organotypic approaches promise increased relevance through the inclusion of increased complexity (e.g., 3D extracellular microenvironment, structure/function relationships, presence of multiple cell types), cell source is often overlooked. Induced pluripotent stem cell (iPSC)-derived cells are potentially more physiologically relevant than cell lines, while also being less variable than primary cells, and recent advances have made them commercially available at costs similar to cell lines. Here, the use of induced pluripotent stem cell-derived endothelium for the generation of a functional microvessel model is demonstrated. High precision structural and microenvironmental control afforded by the design approach synergizes with the advantages of iPSC to produce microvessels for modeling endothelial biology in vitro. iPSC microvessels show endothelial characteristics, exhibit barrier function, secrete angiogenic and inflammatory mediators, and respond to changes in the extracellular microenvironment by altering vessel phenotype. Importantly, when deployed in the investigation of neutrophils during innate immune recruitment, the presence of the iPSC endothelial vessel facilitates neutrophil extravasation and migration toward a chemotactic source. Relevant cell sources, such as iPSC, combine with organotypic models to open the way for improved and increasingly accessible in vitro tissue, disease, and patient-specific models.

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“…Misalignment and seams will lead to discontinuities in the wall, disturbing the flow and adhesion of endothelium. The layer-by-layer fabrication also results in predominantly square shaped channels that do not resemble the in vivo round lumen shape that is critical for normal functioning [52]. Either high resolution techniques are required to create round channels on the micrometre scale of the vasculature or post processing must be applied to reshape the square channels into round ones.…”

Section: Layer-by-layer Compositionmentioning

confidence: 99%

Recapitulating the Vasculature Using Organ-On-Chip Technology

Pollet

Toonder

2020

Bioengineering

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The development of Vasculature-on-Chip has progressed rapidly over the last decade and recently, a wealth of fabrication possibilities has emerged that can be used for engineering vessels on a chip. All these fabrication methods have their own advantages and disadvantages but, more importantly, the capability of recapitulating the in vivo vasculature differs greatly between them. The first part of this review discusses the biological background of the in vivo vasculature and all the associated processes. We then evaluate the biological relevance of different fabrication methods proposed for Vasculature-on-Chip, we indicate their possibilities and limitations, and we assess which fabrication methods are capable of recapitulating the intrinsic complexity of the vasculature. This review illustrates the complexity involved in developing in vitro vasculature and provides an overview of fabrication methods for Vasculature-on-Chip in relation to the biological relevance of such methods.

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The importance of being a lumen

Cited by 61 publications

References 45 publications

LumeNEXT: A Practical Method to Pattern Luminal Structures in ECM Gels

LumeNEXT: A Practical Method to Pattern Luminal Structures in ECM Gels

An Accessible Organotypic Microvessel Model Using iPSC‐Derived Endothelium

Recapitulating the Vasculature Using Organ-On-Chip Technology

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