Abstract

The Microfabrication Core will be established to support the investigators in the Cancer Physics Center, specifically to provide resources for microfabrication and soft-lithography. The Core will mainly support Projects 2 and 3 in the Center. For example, adhesive micropatterned surfaces will be used to study the influence of geometry on motility. In another example, microfluidic-based devices will be fabricated to study the influence of steric forces, extracellular matrix, cell compliance, and adhesiveness on tumor cell migration. These experiments will provide new insight into the process of intravasation and extravasation. The core will be located at the Hopkins'Homewood campus in 600 sq. ft. of dedicated laboratory space. The Core will be managed and administered as a user facility with well established protocols for: scheduling, managing and maintaining equipment, training, providing oversight of users, and billing and cost recovery. Two post-doctoral associates will be responsible for the day-to-day operation, including fabrication of devices and platforms for researchers in the Center, the training of researchers in microfabrication, and the oversight of self-users in the facility.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Specialized Center--Cooperative Agreements (U54)
Project #
5U54CA143868-04
Application #
8381714
Study Section
Special Emphasis Panel (ZCA1-SRLB-9)
Project Start
Project End
Budget Start
2012-08-01
Budget End
2013-07-31
Support Year
4
Fiscal Year
2012
Total Cost
$67,154
Indirect Cost

  Institution

Name
Johns Hopkins University
Department
Type
DUNS #
001910777
City
Baltimore
State
MD
Country
United States
Zip Code
21218

  Publications

Lan, Tian; Hung, Shen-Hsiu; Su, Xudong et al. (2018) Integrating transient cellular and nuclear motions to comprehensively describe cell migration patterns. Sci Rep 8:1488
Jayatilaka, Hasini; Giri, Anjil; Karl, Michelle et al. (2018) EB1 and cytoplasmic dynein mediate protrusion dynamics for efficient 3-dimensional cell migration. FASEB J 32:1207-1221
Jayatilaka, Hasini; Umanzor, Fatima G; Shah, Vishwesh et al. (2018) Tumor cell density regulates matrix metalloproteinases for enhanced migration. Oncotarget 9:32556-32569
Kim, Jeong-Ki; Louhghalam, Arghavan; Lee, Geonhui et al. (2017) Nuclear lamin A/C harnesses the perinuclear apical actin cables to protect nuclear morphology. Nat Commun 8:2123
Ju, Julia A; Godet, InĂªs; Ye, I Chae et al. (2017) Hypoxia Selectively Enhances Integrin ?5?1 Receptor Expression in Breast Cancer to Promote Metastasis. Mol Cancer Res 15:723-734
He, Lijuan; Sneider, Alexandra; Chen, Weitong et al. (2017) Mammalian Cell Division in 3D Matrices via Quantitative Confocal Reflection Microscopy. J Vis Exp :
Lan, Tian; Cheng, Kai; Ren, Tina et al. (2016) Displacement correlations between a single mesenchymal-like cell and its nucleus effectively link subcellular activities and motility in cell migration analysis. Sci Rep 6:34047
Lee, Pilhwa; Wolgemuth, Charles W (2016) Physical Mechanisms of Cancer in the Transition to Metastasis. Biophys J 111:256-66
Semenza, Gregg L (2016) The hypoxic tumor microenvironment: A driving force for breast cancer progression. Biochim Biophys Acta 1863:382-391
Zhang, Kun; Grither, Whitney R; Van Hove, Samantha et al. (2016) Mechanical signals regulate and activate SNAIL1 protein to control the fibrogenic response of cancer-associated fibroblasts. J Cell Sci 129:1989-2002

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