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Aplicações
For Cell Biology ResearchCell biology requires a high-sensitivity imaging system to minimize phototoxicity to live organisms such as zebrafish and C. elegans. Imaging large pieces of tissue and small organisms may also require both high speeds as well as large fields of view to see the entire organism in context, requiring precise automation and excellent optics. The FV3000 system is designed to image large tissues and small organisms with accurate stage control, image stitching, and an optical design that facilitates very low to high magnification (1.25X up to 150X). To facilitate the removal of autofluorescence from the detection signal, the fully-spectral system comes equipped with advanced spectral unmixing software, enabling separation of autofluorescence and overlapping spectra (e.g. GFP/YFP). |
Blood flow imaging and velocity measurements by cellSens software kymograph analysis. | For Cancer ResearchThe FV3000 series incorporates the technologies necessary for powerful cancer research imaging studies. In live cell cancer studies, sensitive fluorescence detection, optimized optics, and analytical tools such as cell counting and segmentation analysis are essential. With the emergence of microfluidics and a focus on circulating tumor cells, high-speed acquisitions can make the difference between success and failure in an experiment. |
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For Stem Cell ResearchStem cell imaging requires increased levels of automation and long-term time-lapse capabilities. The FV3000 system is designed to image cells over multiple days with accurate timing, low phototoxicity, and accurate focus. To maintain focus during multipoint time-lapse imaging in microplates, the system can be enhanced with a Z-drift compensator (IX3-ZDC2). For long experiments, add the laser power monitor to maintain consistent laser exposure for excellent laser stability. | MatTek EpiDermFT Tissue Model: Immunofluorescence labeled with 6 targets of interest. 1. Abcam DRAQ5 ab108410, 2. Abcam Anti-GAPDH (Alexa Fluor 405) ab206372, 3. Abcam Anti-Tubulin (Alexa Fluor 488) ab1955883, 4. Abcam Anti-Fibrillarin (Alexa Fluor 568) ab202540, 5. Abcam Anti-Vimentin (Alexa Fluor 594) ab154207, 6. Abcam Anti-Ki67 (Alexa Fluor 647) ab 194724. Sample courtesy MatTek. |
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For Neuroscience ResearchThe FV3000 confocal laser scanning microscope is compatible with a variety of objectives from 1.25x to 150x, enabling both macro overviews as well as high-resolution image acquisition. Obtain images of whole brain tissue sections to get easily identify areas of interest, and then switch to a high magnification objective to acquire high-resolution images of target neurons. You can even observe the fine structure of dendritic spines using Olympus super resolution technology. With the system’s TruSpectal detection technology, it’s possible to image neurons labeled with multiple colors and clearly separate the individual spectra. FV3000 Upright System — Electrophysiology ConfigurationThis configuration offers a larger working space, so there’s more room around the objective for electrophysiology equipment. You can add additional space by lowering the height of the stage to accommodate experiments that involve large samples. Fast phenomena, such as calcium ion dynamics related to neuronal signal transmission, can be captured at up to 438 frames per second with the available resonant scanner. |
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For Advanced ApplicationsBoth the FV3000 and FV3000RS microscopes have a range of standard and optional advanced application features, including Olympus Super Resolution (FV-OSR), photostimulation, spectral unmixing, and an external beam combiner. With precise laser control and our patented super resolution method, the FV3000 can acquire images with a resolution down to 120 nm, similar to structured illumination methods. Spectral unmixing is robust for a range of applications, while photoconversion and photostimulation are efficient and precise, enabling high-speed targeted path scanning and stimulation mapping studies. |
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