PURPOSE: To eliminate the variable of tumor heterogeneity from a novel in vivo model of tumor angiogenesis. EXPERIMENTAL DESIGN: We developed a method to navigate tumor neovasculature in a living tissue microenvironment, enabling relocation of a cell- or microregion-of-interest, for serial in vivo imaging. Orthotopic melanoma was grown, in immunocompetent Tie2GFP mice. Intravital multiphoton fluorescence and confocal reflectance imaging was performed, on a custom microscope with motorized stage and coordinate navigation software. A point within a Tie2GFP+ microvessel was selected for relocation. Custom software predicted target coordinates based upon reference points (tissue-embedded polystyrene beads) and baseline target coordinates. Mice were removed from the stage to make previously-obtained target coordinates invalid in subsequent imaging. RESULTS: Coordinate predictions always relocated target points, in vivo, to within 10-200 microm (within a single 40x field-of-view). The model system provided a virtual living histology of tumor neovascularization and microenvironment, with subcellular spatial resolution and hemodynamic information. CONCLUSIONS: The navigation procedure, termed in vivo microcartography, permits control of tissue heterogeneity, as a variable. Tie2 may be the best reporter gene identified, to-date, for intravital microscopy of tumor angiogenesis. This novel model system should strengthen intravital microscopy in its historical role as a vital tool in oncology, angiogenesis research, and angiotherapeutic drug development.
PURPOSE: To eliminate the variable of tumor heterogeneity from a novel in vivo model of tumor angiogenesis. EXPERIMENTAL DESIGN: We developed a method to navigate tumor neovasculature in a living tissue microenvironment, enabling relocation of a cell- or microregion-of-interest, for serial in vivo imaging. Orthotopic melanoma was grown, in immunocompetent Tie2GFP mice. Intravital multiphoton fluorescence and confocal reflectance imaging was performed, on a custom microscope with motorized stage and coordinate navigation software. A point within a Tie2GFP+ microvessel was selected for relocation. Custom software predicted target coordinates based upon reference points (tissue-embedded polystyrene beads) and baseline target coordinates. Mice were removed from the stage to make previously-obtained target coordinates invalid in subsequent imaging. RESULTS: Coordinate predictions always relocated target points, in vivo, to within 10-200 microm (within a single 40x field-of-view). The model system provided a virtual living histology of tumor neovascularization and microenvironment, with subcellular spatial resolution and hemodynamic information. CONCLUSIONS: The navigation procedure, termed in vivo microcartography, permits control of tissue heterogeneity, as a variable. Tie2 may be the best reporter gene identified, to-date, for intravital microscopy of tumor angiogenesis. This novel model system should strengthen intravital microscopy in its historical role as a vital tool in oncology, angiogenesis research, and angiotherapeutic drug development.
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Authors: Wei Du; Christian Adkisson; Xianjun Ye; Camille L Duran; Benson Chellakkan Selvanesan; Claudia Gravekamp; Maja H Oktay; John C McAuliffe; John S Condeelis; Nicole C Panarelli; Robert J Norgard; Yogev Sela; Ben Z Stanger; David Entenberg Journal: Open Biol Date: 2022-06-15 Impact factor: 7.124