Angiogenesis plays a fundamental role in development of circulation system, reorganization of reproductive system, wound healing. Pathological angiogenesis is deeply involved in a variety of diseases, particularly solid tumor growth and metastasis. However, it is not easy to study the mechanism of angiogenesis because endothelial cells proceed complex differentiation by interaction with extracellular matrix proteins and growth factors. However, human umbilical vein endothelial cells (HUVEC) form polygonal networks of capillary-like tubes in 3D Matrigel cultures. Differentiation of endothelial cells will be observed accurately by application of videomicroscopy. Thrombospondin-1 is secreted by a wide variety of cells including endothelial cells and is incorporated into their matrix. Thrombospondin-1 can modulate differentiation of endothelial cells by increasing cell-cell interactions as well as cell-substrate interactions. The current study was undertaken to determine which mechanism is involved in inhibition of angiogenesis by Thrombospondin-1. They was secreted from HUVEC during the process of angiogenesis in 3D Matrigel culture. When applied to endothelial cells attachment to the surface of Matrigel was not decreased, but spreading was decreased. In addition, bigger clusters was formed by enhancement of cell to cell binding by Thrombospondin-1. They inhibit cord and tube formation of HUVEC by inhibition of migration. These results suggest that Thrombospondin-1 inhibits angiogenesis by blocking differentiation of endothelial cells to motile phenotype in 3D Matrigel culture.
Cell Culture Techniques* ; Endothelial Cells* ; Extracellular Matrix Proteins ; Human Umbilical Vein Endothelial Cells ; Intercellular Signaling Peptides and Proteins ; Microscopy, Video ; Neoplasm Metastasis ; Neovascularization, Pathologic ; Phenotype ; Wound Healing

BACKGROUND: The nonsurgical treatment of chest wall deformity by a vacuum bell or external brace is gradual, with correction taking place over months. Monitoring the progress of nonsurgical treatment of chest wall deformity has relied on the ancient methods of measuring the depth of the excavatum and the protrusion of the carinatum. Patients, who are often adolescent, may become discouraged and abandon treatment. METHODS: Optical scanning was utilized before and after the intervention to assess the effectiveness of treatment. The device measured the change in chest shape at each visit. In this pilot study, patients were included if they were willing to undergo scanning before and after treatment. Both surgical and nonsurgical treatment results were assessed. RESULTS: Scanning was successful in 7 patients. Optical scanning allowed a visually clear, precise assessment of treatment, whether by operation, vacuum bell (for pectus excavatum), or external compression brace (for pectus carinatum). Millimeter-scale differences were identified and presented graphically to patients and families. CONCLUSION: Optical scanning with the digital subtraction of images obtained months apart allows a comparison of chest shape before and after treatment. For nonsurgical, gradual methods, this allows the patient to more easily appreciate progress. We speculate that this will increase adherence to these methods in adolescent patients.
Adolescent ; Braces ; Congenital Abnormalities* ; Funnel Chest ; Humans ; Pectus Carinatum ; Pilot Projects* ; Thoracic Wall* ; Thorax* ; Vacuum