In Vitro Model of Tumor Cell Extravasation

Jeon, Jessie S.; Zervantonakis, Ioannis K.; Chung, Seok; Kamm, Roger D.; Charest, Joseph L.

doi:10.1371/journal.pone.0056910

Cited by 209 publications

(223 citation statements)

References 45 publications

(56 reference statements)

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“…cancer cell migration, adhesion (23), and extravasation (24,25). Recently, our group presented a microfluidic model to investigate the specificity of breast cancer metastasis to bone, providing quantitative data on cancer cell extravasation rate and reproducing the effects of the CXCL5-CXCR2 interaction between bone cells and metastatic breast cancer cells observed in vivo (26).…”

Section: Significancementioning

confidence: 99%

Human 3D vascularized organotypic microfluidic assays to study breast cancer cell extravasation

Jeon

Bersini

Gilardi

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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617

538

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A key aspect of cancer metastases is the tendency for specific cancer cells to home to defined subsets of secondary organs. Despite these known tendencies, the underlying mechanisms remain poorly understood. Here we develop a microfluidic 3D in vitro model to analyze organ-specific human breast cancer cell extravasation into bone- and muscle-mimicking microenvironments through a microvascular network concentrically wrapped with mural cells. Extravasation rates and microvasculature permeabilities were significantly different in the bone-mimicking microenvironment compared with unconditioned or myoblast containing matrices. Blocking breast cancer cell A3 adenosine receptors resulted in higher extravasation rates of cancer cells into themyoblast-containingmatrices compared with untreated cells, suggesting a role for adenosine in reducing extravasation. These results demonstrate the efficacy of our model as a drug screening platform and a promising tool to investigate specific molecular pathways involved in cancer biology, with potential applications to personalized medicine

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Section: Significancementioning

confidence: 99%

Human 3D vascularized organotypic microfluidic assays to study breast cancer cell extravasation

Jeon

Bersini

Gilardi

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

617

538

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“…Recently, several studies using microfluidic platform have been reported that recreate the 3D context of each aspect of the TME and metastasis in vitro. [10][11][12][13] However, to our knowledge, no versatile in vitro experimental model that reconstitutes direct interplay between constituents of the TME during tumorigenesis has yet been reported. Here we describe a biomimetic TME model to mimic the complex inter actions of the tumor, stromal, and endothe lial cells, all of which are essential components of the TME that hinder the effective treatment of cancers.…”

mentioning

confidence: 99%

Biomimetic Model of Tumor Microenvironment on Microfluidic Platform

Chung

Ahn

Son

et al. 2017

Adv Healthcare Materials

107

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COMMUNICATION (1 of 7)© 2017 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim Biomimetic Model of Tumor Microenvironment on Microfluidic PlatformMinhwan Chung, Jungho Ahn, Kyungmin Son, Sudong Kim, and Noo Li Jeon* DOI: 10.1002/adhm.201700196 "cure." [4,5] The TME is a complex, inter acting system including the tumor itself, other noncancerous cell types such as immune, stromal and endothelial cells, and the extracellular matrix surrounding these cells. [6,7] This complexity has largely prevented a comprehensive understanding of TME in conventional in vitro models, which have been too simple to recapitulate the intricate interactions ( Figure 1A). [8,9] During recent decades, microfabrication technologies have been shown to be valu able tools in the exploration of tumor pro gression. Recently, several studies using microfluidic platform have been reported that recreate the 3D context of each aspect of the TME and metastasis in vitro. [10][11][12][13] However, to our knowledge, no versatile in vitro experimental model that reconstitutes direct interplay between constituents of the TME during tumorigenesis has yet been reported. Here we describe a biomimetic TME model to mimic the complex inter actions of the tumor, stromal, and endothe lial cells, all of which are essential components of the TME that hinder the effective treatment of cancers. [14][15][16] We used a micro fluidic platform from our previous studies. [17,18] Various effects of extracellular matrix (ECM) and the stroma on the physiology of tumor cells and angiogenesis were tested. Finally, we could mimic simultaneous angiogenesis and lymphangiogenesis in the TME with interactions between the tumor cells.Although the cancer stroma is well known for its many roles in multiple cancer stages, direct interactions between cancer and stromal cells have remained largely unknown. [19] Addition ally, cancer cell interaction with the ECM is another TME factor that regulates the behavior of the cancer cells and their resist ance to drugs. [20] Recently, in vitro activation of tumor stoma and corresponding ECM remodeling have been reported using a microfluidic platform. [21] However, single cell responses of the cancer cells in response to the stroma coculture and ECM composition has not yet been described. To examine cancer stromal cell interaction with a 3D ECM, we used a micro fluidic 3D cell culture platform previously reported from our group. [17,18] The array of microposts in the platform enabled straightforward micropatterning of the hydrogel which allowed flexible experimental configurations. We first cocultured cancer and stromal cells within fibrin gel in different microchannels, which still allowed the cells to interact with each other in a par acrine manner ( Figure 1B). Twice as many fibroblasts as cancer cells were patterned to exclude an autocrine or indirect effectThe "Tumor microenvironment" (TME) is a complex, interacting system of the tumor and its surrounding environment. The TME has drawn more attention recently in attempts to overcome current drug...

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“…The process consists of TC transport via the blood circulation, survival of the shear stress, arrest and attachment to a vessel wall and trans-endothelial invasion across the vessel wall and into the secondary metastatic site [54]. Two possible modes have been proposed…”

mentioning

confidence: 99%

“…The first, as described in the famous hypothesis by Paget, proposes that tumours of different organs show unique patterns of metastatic colonisation (seed) to other specific organ microenvironments (soil) through site-selective adhesion [45,54,55]. The second mode of extravasation hypothesises that due to the slightly larger size of TCs and their ability to aggregate with platelets, they become trapped in small vessels and capillary beds [56,57].…”

mentioning

confidence: 99%

“…The second mode of extravasation hypothesises that due to the slightly larger size of TCs and their ability to aggregate with platelets, they become trapped in small vessels and capillary beds [56,57]. Both modes have been observed during extravasation [58][59][60], however it is unclear as to which is the preferential mode and whether there are selective characteristics of TCs that promote a particular type of arrest [54].…”

mentioning

confidence: 99%

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The Role of EphB4 and Ephrin-B2 Interactions in Prostate Cancer Models of Intravasation and Extravasation

Protsenko¹

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In Vitro Model of Tumor Cell Extravasation

Cited by 209 publications

References 45 publications

Human 3D vascularized organotypic microfluidic assays to study breast cancer cell extravasation

Human 3D vascularized organotypic microfluidic assays to study breast cancer cell extravasation

Biomimetic Model of Tumor Microenvironment on Microfluidic Platform

The Role of EphB4 and Ephrin-B2 Interactions in Prostate Cancer Models of Intravasation and Extravasation

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