Formation of microvascular networks in vitro

Morgan, John P.; DelNero, Peter; Zheng, Ying; Verbridge, Scott S.; Chen, Junmei; Craven, Michael; Choi, Nakwon; Diaz-Santana, Anthony; Kermani, Pouneh; Hempstead, Barbara; López, José A.; Corso, Thomas N.; Fischbach, Claudia; Stroock, Abraham D.

doi:10.1038/nprot.2013.110

Cited by 162 publications

(137 citation statements)

References 47 publications

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“…The possibility of creating pre-vascularized tissue constructs is an exciting application of vascular engineering and regeneration. Biomimetic models to simulate angiogenic sprouting morphogenesis in vivo have also been developed using a tissue-molding technique (Morgan et al, 2013;Nguyen et al, 2013). The development of highly organized in vitro vascular constructs also presents a powerful screening platform for studying the effects of different angiogenic factors.…”

Section: Defining Vasculature Architecture In Vitromentioning

confidence: 99%

“…The microfabrication technique has been widely used to create artificial tissue constructs, including microvascularized networks embedded within a 3D hydrogel, which can be applied as a platform to mimic in vivo vascular microenvironments. Fischbach-Teschel and colleagues recently developed a novel approach to create fully enclosed and perfusable blood vessels in collagen I hydrogels using microfabrication, which allows the control of nutrients and oxygen transfer, and of blood flow rate and pressure (Zheng et al, 2012;Morgan et al, 2013). This technique can be used to study vascular function across multiple parameters, such as mass transfer, which is the transfer of nutrients and oxygen across the vessel wall, physical parameters, such as blood flow and pressure, and drug screening (Rodriguez-Rodriguez et al, 2012;Griep et al, 2013;Westein et al, 2013).…”

Section: Defining Vasculature Architecture In Vitromentioning

confidence: 99%

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Harnessing developmental processes for vascular engineering and regeneration

Park

Gerecht

2014

Development

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The formation of vasculature is essential for tissue maintenance and regeneration. During development, the vasculature forms via the dual processes of vasculogenesis and angiogenesis, and is regulated at multiple levels: from transcriptional hierarchies and protein interactions to inputs from the extracellular environment. Understanding how vascular formation is coordinated in vivo can offer valuable insights into engineering approaches for therapeutic vascularization and angiogenesis, whether by creating new vasculature in vitro or by stimulating neovascularization in vivo. In this Review, we will discuss how the process of vascular development can be used to guide approaches to engineering vasculature. Specifically, we will focus on some of the recently reported approaches to stimulate therapeutic angiogenesis by recreating the embryonic vascular microenvironment using biomaterials for vascular engineering and regeneration.

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Section: Defining Vasculature Architecture In Vitromentioning

confidence: 99%

Section: Defining Vasculature Architecture In Vitromentioning

confidence: 99%

Harnessing developmental processes for vascular engineering and regeneration

Park

Gerecht

2014

Development

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“…Other variations of such models have been to create tube channels artificially in 3D matrixes to enable user-defined geometries of the vascular network and then seed the channels with ECs for the creation of tube networks in the absence of EC-driven tubulogenesis and vascular guidance tunnel formation. 22,23 Of note, these systems have so far not been tested by many laboratories, and the robustness and practicability at a larger scale remain to be established.…”

Section: Microfluidic Flow Modelsmentioning

confidence: 99%

State-of-the-Art Methods for Evaluation of Angiogenesis and Tissue Vascularization

Simons¹,

Alitalo²,

Annex³

et al. 2015

Circulation Research

110

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“…Using microfluidic technology, capillary lumen structures have been fabricated to mimic the microvasculature in tissues [94]. Common methods to create capillary lumen structures as microvasculatures include moulding the capillaries in hydrogels by needles or rods [95][96][97][98], by photoresists [99][100][101], by sacrificial carbohydrates [102] or creating lumens based on viscous fingering instabilities [103,104]. Alternatively, an endothelial vascular network as the microvasculature can be formed by endothelial sprouting in hydrogels [105][106][107][108][109][110][111][112], monolayer on ECM hydrogel [113][114][115] or on a porous membrane [116,117], and monolayer in microchannels [118,119] (figure 2l ).…”

Section: Microfluidic Tumour -Microvascular Modelmentioning

confidence: 99%

Tumour-on-a-chip: microfluidic models of tumour morphology, growth and microenvironment

Tsai

Trubelja

Shen

et al. 2017

J. R. Soc. Interface.

158

133

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Cancer remains one of the leading causes of death, albeit enormous efforts to cure the disease. To overcome the major challenges in cancer therapy, we need to have a better understanding of the tumour microenvironment (TME), as well as a more effective means to screen anti-cancer drug leads; both can be achieved using advanced technologies, including the emerging tumour-on-a-chip technology. Here, we review the recent development of the tumour-on-a-chip technology, which integrates microfluidics, microfabrication, tissue engineering and biomaterials research, and offers new opportunities for building and applying functional three-dimensional in vitro human tumour models for oncology research, immunotherapy studies and drug screening. In particular, tumour-on-a-chip microdevices allow well-controlled microscopic studies of the interaction among tumour cells, immune cells and cells in the TME, of which simple tissue cultures and animal models are not amenable to do. The challenges in developing the next-generation tumour-on-a-chip technology are also discussed.

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Formation of microvascular networks in vitro

Cited by 162 publications

References 47 publications

Harnessing developmental processes for vascular engineering and regeneration

Harnessing developmental processes for vascular engineering and regeneration

State-of-the-Art Methods for Evaluation of Angiogenesis and Tissue Vascularization

Tumour-on-a-chip: microfluidic models of tumour morphology, growth and microenvironment

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