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      A Novel High-resolution In vivo Imaging Technique to Study the Dynamic Response of Intracranial Structures to Tumor Growth and Therapeutics

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          Abstract

          We have successfully integrated previously established Intracranial window (ICW) technology 1-4 with intravital 2-photon confocal microscopy to develop a novel platform that allows for direct long-term visualization of tissue structure changes intracranially. Imaging at a single cell resolution in a real-time fashion provides supplementary dynamic information beyond that provided by standard end-point histological analysis, which looks solely at 'snap-shot' cross sections of tissue.

          Establishing this intravital imaging technique in fluorescent chimeric mice, we are able to image four fluorescent channels simultaneously. By incorporating fluorescently labeled cells, such as GFP+ bone marrow, it is possible to track the fate of these cells studying their long-term migration, integration and differentiation within tissue. Further integration of a secondary reporter cell, such as an mCherry glioma tumor line, allows for characterization of cell:cell interactions. Structural changes in the tissue microenvironment can be highlighted through the addition of intra-vital dyes and antibodies, for example CD31 tagged antibodies and Dextran molecules.

          Moreover, we describe the combination of our ICW imaging model with a small animal micro-irradiator that provides stereotactic irradiation, creating a platform through which the dynamic tissue changes that occur following the administration of ionizing irradiation can be assessed.

          Current limitations of our model include penetrance of the microscope, which is limited to a depth of up to 900 μm from the sub cortical surface, limiting imaging to the dorsal axis of the brain. The presence of the skull bone makes the ICW a more challenging technical procedure, compared to the more established and utilized chamber models currently used to study mammary tissue and fat pads 5-7. In addition, the ICW provides many challenges when optimizing the imaging.

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          Most cited references18

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          Dynamic imaging of collagen and its modulation in tumors in vivo using second-harmonic generation.

          The content and structure of collagen is essential in governing the delivery of therapeutic molecules in tumors. Thus, simple histological staining of tumor tissue biopsies for collagen could be used to assess the accessibility of molecular therapeutics in tumors. Here we show that it is possible to optically image fibrillar collagen in tumors growing in mice using second-harmonic generation (SHG). Using this noninvasive technique, we estimated relative diffusive hindrance, quantified the dynamics of collagen modification after pharmacologic intervention and provided mechanistic insight into improved diffusive transport induced by the hormone relaxin. This technology could offer basic scientists and clinicians an enhanced ability to estimate the relative penetrabilities of molecular therapeutics.
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            Intravital imaging of metastatic behavior through a mammary imaging window.

            We report a technique to evaluate the same tumor microenvironment over multiple intravital imaging sessions in living mice. We optically marked individual tumor cells expressing photoswitchable proteins in an orthotopic mammary carcinoma and followed them for extended periods through a mammary imaging window. We found that two distinct microenvironments in the same orthotopic mammary tumor affected differently the invasion and intravasation of tumor cells.
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              The hypoxic response of tumors is dependent on their microenvironment.

              To reveal the functional significance of hypoxia and angiogenesis in astrocytoma progression, we created genetically engineered transformed astrocytes from murine primary astrocytes and deleted the hypoxia-responsive transcription factor HIF-1alpha or its target gene, the angiogenic factor VEGF. Growth of HIF-1alpha- and VEGF-deficient transformed astrocytes in the vessel-poor subcutaneous environment results in severe necrosis, reduced growth, and vessel density, whereas when the same cells are placed in the vascular-rich brain parenchyma, the growth of HIF-1alpha knockout, but not VEGF knockout tumors, is reversed: tumors deficient in HIF-1alpha grow faster, and penetrate the brain more rapidly and extensively. These results demonstrate that HIF-1alpha has differential roles in tumor progression, which are greatly dependent on the extant microenvironment of the tumor.
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                Author and article information

                Journal
                J Vis Exp
                J Vis Exp
                JoVE
                Journal of Visualized Experiments : JoVE
                MyJove Corporation
                1940-087X
                2013
                16 June 2013
                16 June 2013
                : 76
                : 50363
                Affiliations
                Brain Tumor Research Centre, Hospital for Sick Children, Toronto Medical Discovery Tower
                Ontario Cancer Institute, Princess Margaret Hospital
                Neurosurgery, Toronto Western Hospital
                Author notes

                Correspondence to: Kelly Burrell at Kelly.burrell@ 123456sickkids.ca

                Article
                50363
                10.3791/50363
                3727480
                23793043
                b91af032-cac5-4bc0-bb15-b8073ba70a16
                Copyright © 2013, Journal of Visualized Experiments

                This is an open-access article distributed under the terms of the Creative Commons Attribution-NonCommercial License, which permits non-commercial use, distribution, and reproduction, provided the original work is properly cited.

                History
                Categories
                Cancer Biology

                Uncategorized
                cancer biology,issue 76,medicine,biomedical engineering,cellular biology,molecular biology,genetics,neuroscience,neurobiology,biophysics,anatomy,physiology,surgery,intracranial window, in vivo imaging,stereotactic radiation,bone marrow derived cells,confocal microscopy,two-photon microscopy,drug-cell interactions,drug kinetics,brain,imaging,tumors,animal model

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