Topic
Angiogenesis
About: Angiogenesis is a research topic. Over the lifetime, 58248 publications have been published within this topic receiving 3290129 citations. The topic is also known as: blood vessel formation from pre-existing blood vessels & GO:0001525.
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TL;DR: A new microfluidic platform that has the capability to control the biochemical and biomechanical forces within a three dimensional scaffold coupled with accessible image acquisition is developed and demonstrated to study cellular morphogenesis both qualitatively and quantitatively.
Abstract: Capillary morphogenesis is a complex cellular process that occurs in response to external stimuli. A number of assays have been used to study critical regulators of the process, but those assays are typically limited by the inability to control biochemical gradients and to obtain images on the single cell level. We have recently developed a new microfluidic platform that has the capability to control the biochemical and biomechanical forces within a three dimensional scaffold coupled with accessible image acquisition. Here, the developed platform is used to evaluate and quantify capillary growth and endothelial cell migration from an intact cell monolayer. We also evaluate the endothelial cell response when placed in co-culture with physiologically relevant cell types, including cancer cells and smooth muscle cells. This resulted in the following observations: cancer cells can either attract (MTLn3 cancer cell line) endothelial cells and induce capillary formation or have minimal effect (U87MG cancer cell line) while smooth muscle cells (10T 1/2) suppress endothelial activity. Results presented demonstrate the capabilities of this platform to study cellular morphogenesis both qualitatively and quantitatively while having the advantage of enhanced imaging and internal biological controls. Finally, the platform has numerous applications in the study of angiogenesis, or migration of other cell types including tumor cells, into a three-dimensional scaffold or across an endothelial layer under precisely controlled conditions of mechanical, biochemical and co-culture environments.
512 citations
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TL;DR: Pharmacologic manipulation of HIF-1 levels may provide a novel therapeutic approach to diseases that represent the most common causes of mortality in Western society, including cancer, chronic lung disease, and myocardial ischemia.
511 citations
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TL;DR: It is shown that hematopoietic stem cells (HSCs) play important roles for angiogenesis during embryogenesis and the role of HSCs in endothelial cell (EC) development is investigated.
511 citations
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TL;DR: It is demonstrated that the survival-promoting function is crucial for periostin to promote tumor metastasis of colon cancer.
511 citations
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TL;DR: The results suggest that FN controls capillary endothelial cell proliferation based on its ability to support tension-dependent alterations of cell shape--i.e., both by binding to cell-surface integrins and by resisting mechanical loads that are applied to these receptors.
Abstract: An in vitro system has been developed to study the mechanism by which fibronectin (FN) regulates capillary endothelial cell growth in the presence of soluble angiogenic mitogens. Endothelial cells were cultured in chemically defined medium containing a constant, saturating amount of basic fibroblast growth factor. Formation of cell-FN contacts was then varied in a controlled fashion by three different techniques: (i) nonadhesive, bacteriological dishes were precoated with increasing densities of FN; (ii) soluble RGD peptides were used to progressively inhibit binding of cell-surface integrin receptors to adsorbed FN; and (iii) FN-coated surfaces were covered with increasingly thick layers of polyhydroxyethylmethacrylate (a nonadhesive polymer) to physically restrict cell access to FN binding sites. Endothelial cells became more extended and proliferated more rapidly as FN coating concentrations were raised from approximately 250 to approximately 10,000 FN molecules per micron 2. Computerized morphometric analysis confirmed that cell shape (projected cell areas) was determined by the density of FN contacts and that DNA synthetic levels were tightly coupled to the extent of cell spreading, regardless of the method used to perturb cell adhesion. In contrast, neither soluble FN nor cell-surface binding of FN-coated microbeads (diameter, 4.5 microns) had any effect on growth when cells were grown in suspension and cell spreading was prohibited. These results suggest that FN controls capillary endothelial cell proliferation based on its ability to support tension-dependent alterations of cell shape--i.e., both by binding to cell-surface integrins and by resisting mechanical loads that are applied to these receptors.
511 citations