Olympus FV1000 manual Laser Light Stimulation, FLIP-Fluorescence Loss in Photobleaching

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Laser Light Stimulation

The SIM scanner system combines the main scanner with a laser light stimulation scanner.

Control of the two independent beams enables simultaneous stimulation and imaging, to capture reactions during stimulation.

Multi-stimulation software is used to continuously stimulate multiple points with laser light for simultaneous imaging of the effects of stimulation on the cell.

FLIP—Fluorescence Loss in Photobleaching

Fluorescence loss in photobleaching (FLIP) combines imaging with continuous bleaching of a specific region to observe the diffusion of a target protein within a cell. The changes in the image over time make it possible to observe the location of structural bodies that inhibit the diffusion of the molecule.

 

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Time (ms)

Specimen: HeLa cell, GFP (free), 488 nm excitation (multi-argon laser)

Image acquisition time: 100 ms/ bleach time: 100 s continuously, 405 nm bleaching

FRAP—Fluorescence Recovery after Photobleaching

Exposure of fluorescent-labeled target proteins to strong laser light causes their fluorescence to fade locally. Fluorescence recovery after photobleaching (FRAP) is used to observe the gradual recovery of fluorescence intensity caused by protein diffusion from the area surrounding the bleached region. By examining the resulting images, it is possible to characterize the diffusion speed of the molecule, and the speed of binding and release between the molecule and cell structures.

intensity

 

Example: Fluorescence recovery without interactions

 

its fluorescence at a high speed due to Brownian motion.

 

 

If the protein can freely diffuse, the bleached region recovers

Fluorescent

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Specimen: Hippocampal neurons, Shank-GFP stain, 488 nm excitation (multi-argon laser)

Image acquisition time: 100 ms Bleach time: 80 ms, 488 nm excitation (Sapphire 488 laser)

Data courtesy of: Dr. Shigeo Okabe

Department of Anatomy and Cell Biology, Tokyo Medical and Dental University

Fluorescent intensity

Time

Example: Fluorescence recovery with interactions

If the protein is strongly bound to a structure or forms part of a large protein complex, the bleached region recovers its fluorescence at a slower rate relative to the unbound state.

 

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Contents FV1000 FLUOVIEW--From Olympus is OpenImaging to Analysis Ing up New WorldsAdvanced Fluoview Systems Enhance the Power of Your Research Page Excellent Precision, Sensitivity and Stability Laser combiner/FiberScanners/Detection Icity Optical SystemSamples and Specimens Spectral Based Detection Filter Based DetectionWide Choice of Bleaching Modes SIM Simultaneous Scanner UnitSimultaneous Laser Light Stimulation and Imaging Multi-Purpose Laser CombinerBest Reliability for Colocalization Analysis Improved Flatness and Resolution at 405 nmNEW Low Chromatic Aberration Objective Flatness Comparison Image at 1x ZoomFV1000MPE Multiphoton Excitation System User-Friendly Software to Support Your Research Multi Stimulation Software Re-Use FunctionHelp Guide Multi-Area Time-Lapse SoftwareFret Measurement Multi-Dimensional Time-Lapse3D/4D Volume Rendering Light StimulationPoint FCS-Point scan Fluorescence Correlation Spectroscopy Diffusion Measurement PackageRICS-Raster Imaging Correlation Spectroscopy Frap AnalysisRics Analysis Method Rics Application and PrinciplesRics Principle Spatial Correlation AlgorithmFRAP-Fluorescence Recovery after Photobleaching Laser Light StimulationFLIP-Fluorescence Loss in Photobleaching Photoconversion UncagingMulti-Point Laser Light Stimulation Focal Drift Compensation for Long Time-Lapse Imaging Multi-Dimensional Time-LapseSignificantly Improved Long Time-Lapse Throughput Maintain Cell Activity Over a Long Period3D Mosaic Imaging Mosaic Imaging for 3D XYZ ConstructionAutomated from 3D Image Acquisition to Mosaic Imaging Expandability to Support Diverse Application AnalysisNHeNe Ree MCherry405 Ulti 458 473 488 515Laser Systems Optional Upgrade Equipments for FV1000Scanning Units Illumination UnitsFV1000 System Diagram CO2 IncubatorHigh-Precision Motorized Stage/ Prior H117 Using WI-UCD, WI-DICTHRA2 Main SpecificationsUsing U-UCD8A-2, IX2-LWUCDA2 and U-DICTS Objectives for BX2Dimensions, Weight and Power Consumption Recommended FV1000 system setup IX81, BX61, BX61WIImages are courtesy of the following institutions Fluoview website Olympus Corpoaration is ISO9001/ISO14001 certified