Full range physiological mass transport control in 3D tissue cultures - Wikidata - awgldk - TriplyDB

Full range physiological mass transport control in 3D tissue cultures

Full range physiological mass transport control in 3D tissue cultures

http://www.wikidata.org/entity/Q36434466

about

An integrated in vitro model of perfused tumor and cardiac tissue 3D microtumors in vitro supported by perfused vascular networks.Engineering anastomosis between living capillary networks and endothelial cell-lined microfluidic channels.An ex vivo model for anti-angiogenic drug testing on intact microvascular networks Microfluidic device to control interstitial flow-mediated homotypic and heterotypic cellular communication Scaling and systems biology for integrating multiple organs-on-a-chip.Accelerating drug discovery via organs-on-chips.Mechanisms of tumor cell extravasation in an in vitro microvascular network platform Generation of 3D functional microvascular networks with human mesenchymal stem cells in microfluidic systems.Effects of shear stress pattern and magnitude on mesenchymal transformation and invasion of aortic valve endothelial cells An on-chip microfluidic pressure regulator that facilitates reproducible loading of cells and hydrogels into microphysiological system platforms On-chip human microvasculature assay for visualization and quantification of tumor cell extravasation dynamics.A strategy for integrating essential three-dimensional microphysiological systems of human organs for realistic anticancer drug screening.Techniques and assays for the study of angiogenesis.A contact line pinning based microfluidic platform for modelling physiological flows.A vascularized and perfused organ-on-a-chip platform for large-scale drug screening applications.Engineering challenges for instrumenting and controlling integrated organ-on-chip systems.In vitro perfused human capillary networks.A microfluidic platform for generating large-scale nearly identical human microphysiological vascularized tissue arrays.Clarifying intact 3D tissues on a microfluidic chip for high-throughput structural analysis.In Vitro Microvessel Growth and Remodeling within a Three-dimensional Microfluidic Environment.Advances in microfluidic cell culture systems for studying angiogenesis.In vitro microfluidic models of tumor microenvironment to screen transport of drugs and nanoparticles.Regulation of mesenchymal stem cell 3D microenvironment: From macro to microfluidic bioreactors.Low levels of physiological interstitial flow eliminate morphogen gradients and guide angiogenesis.Tissue culture on a chip: Developmental biology applications of self-organized capillary networks in microfluidic devices.Cell-microenvironment interactions and architectures in microvascular systems Microfluidic approaches to the study of angiogenesis and the microcirculation.Generation of Multi-Scale Vascular Network System within 3D Hydrogel using 3D Bio-Printing Technology.Creating perfused functional vascular channels using 3D bio-printing technology.Human, Tissue-Engineered, Skeletal Muscle Myobundles to Measure Oxygen Uptake and Assess Mitochondrial Toxicity.Microfluidic device to culture 3D in vitro human capillary networks.3D Anastomosed Microvascular Network Model with Living Capillary Networks and Endothelial Cell-Lined Microfluidic Channels.Interstitial flow regulates the angiogenic response and phenotype of endothelial cells in a 3D culture model.Design and validation of an osteochondral bioreactor for the screening of treatments for osteoarthritis.High-Throughput Blood- and Lymph-Capillaries with Open-Ended Pores Which Allow the Transport of Drugs and Cells.Engineering a 3D vascular network in hydrogel for mimicking a nephron.Microfluidic-Based 3D Engineered Microvascular Networks and Their Applications in Vascularized Microtumor Models

P2860

Q26822867-F781380C-CF04-4389-B020-1CBD56443E71 Q27317186-25EC0BEA-7A45-497E-98AD-BC075CC56EC6 Q27334397-EC6E5016-B7EE-4894-B109-378F3C6CB57B Q28543862-31B54205-C7D6-4930-91A7-818084F74E17 Q28833628-439ADB6E-1006-4C97-A152-580378A191D6 Q30410626-E29E3809-C722-4FCA-94D1-6D4BA3E93ACB Q30422679-BA5E5D70-5731-4A9D-9CDE-EDC5E5D8CE4D Q30579230-36D832B0-B121-480B-8753-6D1DB665AA64 Q30618514-9F285D2B-BE81-4867-BAA0-84621766D5D0 Q30654838-F88DA1D1-5124-468F-9E2E-B6ACC0E735A1 Q30773177-10E63A77-9227-4CAA-8DB6-B4E88479EEA0 Q33902543-5EA71C65-00D1-46F2-B6D4-2CB81851DFF5 Q34143251-543C0526-119C-4E41-98AF-1D1A4C3445C5 Q34438399-39312523-6804-45F7-851D-753FC0AFB2BE Q35861871-49C643B8-2C2F-428F-A140-27E0BCB05182 Q36250562-E87FEA09-F69F-441E-900E-8E9218F1C2F3 Q36968126-0BDB008A-7C72-4FCB-A71D-E160524F009E Q37035799-8FE6A9A0-3918-4E99-9B21-77F117E4589A Q37072155-72152FB6-B5CF-4602-8039-2BA5053486EC Q37549815-D9228063-8D73-4D78-A460-C8E30B065E1A Q37649429-E41DD8B7-FA06-4DDF-BCB7-E2DA83FD3ADD Q38119912-A8340F56-0213-4A45-BE71-474386996147 Q38405765-CCF2264D-FCF4-4203-9049-43210A6FF6FA Q38676887-F9B49D1C-70F6-4858-B1B0-E06614B50F36 Q38728427-28B510C4-5A53-453B-BCD3-3BF4A19C4AAB Q38858209-3E8FC706-910B-45CD-87FF-3EA01BC20344 Q38896900-18298CE5-544C-4773-92C7-348C1C6AA6CF Q39128311-C007AD94-16DA-4443-BB75-D4DB94516DFD Q41967498-DE286F1D-C73A-420F-AF7F-EB0371DB360A Q42176628-3C1F963D-C6E6-4E77-941A-A203E3C6950D Q42507596-D9EFF638-D3C4-48DB-A191-AE2DB0CD4651 Q42596550-EC837D5C-4E4D-435D-A2C7-55F0955B1B6B Q46624521-EB48993E-12F9-48A5-97C2-AD342A99B3DF Q48296700-A395F61B-2E35-4F68-A89E-80972F290FD3 Q49992154-70C430AA-DFD5-4EFC-A713-117024CBABE6 Q50242957-9092CA5B-D8F7-478E-8D6E-11F00FC9AF71 Q51533042-825D1C90-C24C-46B6-B20D-67BFAD29E0D4 Q59126788-A9845CC4-A20B-4D6D-9A4D-EE37464FB780

P2860

Full range physiological mass transport control in 3D tissue cultures

http://www.wikidata.org/entity/Q36434466

description

2012 nî lūn-bûn

@nan

2012年の論文

@ja

2012年学术文章

@wuu

2012年学术文章

@zh-cn

2012年学术文章

@zh-hans

2012年学术文章

@zh-my

2012年学术文章

@zh-sg

2012年學術文章

@yue

2012年學術文章

@zh

2012年學術文章

@zh-hant

name

Full range physiological mass transport control in 3D tissue cultures

@ast

Full range physiological mass transport control in 3D tissue cultures

@en

type

label

Full range physiological mass transport control in 3D tissue cultures

@ast

Full range physiological mass transport control in 3D tissue cultures

@en

prefLabel

Full range physiological mass transport control in 3D tissue cultures

@ast

Full range physiological mass transport control in 3D tissue cultures

@en

P1433

Q36434466-D3694F51-F68E-4522-8065-D92E4ACA828C

P1476

Q36434466-AB78EBE0-C692-43CE-A08A-F95830ADE282

P2093

Q36434466-41D88429-DA22-4B6F-9B97-60E30AA3643F

Q36434466-5858838D-0779-4E27-9291-E6A12BD508AB

Q36434466-5ECC6795-C42B-4046-A152-9EBB4EAE29C8

Q36434466-79C34580-8B98-4FEC-8EC2-676A82855D92

Q36434466-836C68F7-1512-4E52-A5CB-F39DF1D89828

Q36434466-85D08802-32BE-446B-9DCB-574B95FBFCA4

P2860

Q36434466-07BD3146-A8EF-41AD-80A1-3AC4F9958F71

Q36434466-18696913-0F19-4C2E-8979-078E4B98F546

Q36434466-1F662F44-1791-4982-B6D2-218877DE1BBD

Q36434466-241F71BD-17D8-4E91-83A7-FFA28D236C76

Q36434466-2622A0FB-4D05-419E-BBCA-FC4AEC50E521

Q36434466-2FEBB102-1702-406F-8BE9-E97975C4F79D

Q36434466-3BD44D02-EA34-4840-AE99-318E808EFB73

Q36434466-4A16FEE3-6EFB-47D2-BF47-242CEC20DE6D

Q36434466-4D139AEA-38E5-411A-B681-0EFCF9E92C16

Q36434466-4EFD2137-2BA0-4705-81C8-AC4F17EFBD98

P304

Q36434466-EC4A47C6-73E3-41F5-A9BF-A5FFF46802B4

P31

Q36434466-2481CC8A-D51B-4894-AB46-1F44C9D86A3B

P356

Q36434466-50F8E54C-F8D9-43BB-91FC-FF7B545CAEFB

P433

Q36434466-92C0F7C5-3BAF-4A84-875B-1874ECC7BFE5

P478

Q36434466-B1E60CD0-DAE3-4DB0-8348-749D17A319C8

P577

Q36434466-8D4658F6-3284-4FA1-A87A-F4D65EFF2584

P5875

Q36434466-767E30C4-D7AE-4FC2-A670-22B852686B9A

P698

Q36434466-428FD52B-0743-4EB3-ADFD-0E312CEB4ED6

P932

Q36434466-31866A34-A4C8-4FF5-B395-710DD6D948AA

P356

P1433

P1476

Full range physiological mass transport control in 3D tissue cultures

@en

P2093

Abraham P Lee

http://www.w3.org/2001/XMLSchema#string

Christopher C W Hughes

http://www.w3.org/2001/XMLSchema#string

Monica L Moya

http://www.w3.org/2001/XMLSchema#string

Parinaz Abiri

http://www.w3.org/2001/XMLSchema#string

Steven C George

http://www.w3.org/2001/XMLSchema#string

Yu-Hsiang Hsu

http://www.w3.org/2001/XMLSchema#string

P2860

Autologous chemotaxis as a mechanism of tumor cell homing to lymphatics via interstitial flow and autocrine CCR7 signaling

Heparan sulfate proteoglycans mediate interstitial flow mechanotransduction regulating MMP-13 expression and cell motility via FAK-ERK in 3D collagen

Tissue cells feel and respond to the stiffness of their substrate

Molecular regulation of angiogenesis and lymphangiogenesis

The third dimension bridges the gap between cell culture and live tissue

Regulation of angiogenesis by hypoxia: role of the HIF system

Dynamic contrast-enhanced magnetic resonance imaging of tumor-induced lymph flow.

Interstitial fluid flow intensity modulates endothelial sprouting in restricted Src-activated cell clusters during capillary morphogenesis.

Rapid anastomosis of endothelial progenitor cell-derived vessels with host vasculature is promoted by a high density of cotransplanted fibroblasts

Synergy between interstitial flow and VEGF directs capillary morphogenesis in vitro through a gradient amplification mechanism.

P304

81-89

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1039/C2LC40787F

http://www.w3.org/2001/XMLSchema#string

P433

1

http://www.w3.org/2001/XMLSchema#string

P478

13

http://www.w3.org/2001/XMLSchema#string

P577

2012-10-22T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

232610698

http://www.w3.org/2001/XMLSchema#string

P698

23090158

http://www.w3.org/2001/XMLSchema#string

P932

3510322

http://www.w3.org/2001/XMLSchema#string