Supports multicolor fluorescent studies for imaging of living, whole mount or thickly sliced specimens. Dynamic biological processes can be imaged hundreds of micrometers within living cells and tissues. Provides support for applications where phototoxicity/photobleaching are a concern such as time course studies of living cells and tissues. Low magnification lens and long working distance stage allow imaging of large samples, embryos, and animals. A range of microprobe objectives are available for minimally invasive in vivo imaging of deep tissues. This microscope also offers conventional confocal laser scanning of samples on slide.

Features

• Conventional laser scanning fluorescence microscopy of fixed and live samples with visible lasers and DIC imaging.
• Multiphoton laser scanning with IR lasers.
• Independent grating and slit for precise spectral imaging of dyes with similar emission wavelength.
• Z-series for 3D image.
• Time series for time-lapse imaging (high-speed imaging up to at 16 frames/second)
• FRAP (fluorescence recovery after photobleaching), FRET (fluorescence resonance energy transfer) and photoactivation.

Specifications

• Objective lenses
  • 4x U Plan APO 0.16 N.A.
  • 5x M Plan N 0.10 N.A.
  • 10x U Plan APO 0.40 N.A.  
  • 20x LUC Plan FLN 0.45 N.A.
  • 25x XL Plan N 1.05 N.A. Water immersion
  • 40x LUM Plan Fl/IR 0.8 N.A. Water immersion
  • 40x U Plan FLN 1.30 N.A. Oil immersion
  • 60x LUM Plan Fl/IR 0.9 N.A. Water immersion
  • 60x U Plan APO 1.42 N.A. Oil immersion
    
    
• Fluorescent filters (excitation/emission) for fluorescent viewing. 
  • DAPI (330-385 nm/420 nm; violet DNA dyes such as DAPI and Hoechst)
  • NIBA (470-495 nm/510-550 nm; fluorophores from blue to yellow range, such as CFP, YFP, GFP, Alexa-488, FITC)
  • WIG (530-550 nm/ 575 nm for redish fluorophores, like Cy-3, TRITC, DsRED)
    

Excitation Lasers

 

Laser source	Excitation wavelength	Dyes & Fluorophores	Emission color
405 Diode	405 nm	DAPI, Hoechst	Violet
Multi-line Argon	457 nm	CFP	Cyan
	488 nm	Alexa 488, Oregon Green, FITC, GFP, EGFP, DiO, Cy2	Green
	514 nm	YFP, EYFP	Yellow
Green HeNe	543 nm	Cy3, TRITC, mCherry,  Alexa 543, Alexa 594	Orange-red
Red HeNe	633 nm	Alexa 633, Alexa 647, Cy5, TO-PRO3,	Far red

 

 

Fluorochrome excitation with multi-photon IR laser.

Emission color	Dye	Excitation (FV1000-tested)
Blue/cyan	Alexa 350	780-800 nm
	Hoechst	780-800 nm, 900-1100 nm
	DAPI	780-800 nm, 900-1100 nm
	CFP	800-900 nm
Green	Oregon Green	800-860 nm
	Alexa 488	800-830 nm, (860 nm, 910-920 nm)
	EGFP	920-990 nm
	Bodipy	900-950 nm
	FITC	750-800 nm, (860 nm, 910-920 nm)
	DiO	780-830 nm
Yellow / Orange	YFP	890-950 nm
	DiA	800-860 nm
Red	DiI	830-920 nm
	Rhodamine B	800-860 nm
	Alexa 568	780-840 nm

 

Download and view Olympus FV1000 User Guide.

 

For viewing and basic image handling, a free viewer software (FV10-ASW viewer) is available.

 

For more information on FV1000MPE system, click on http://microscope.olympus-global.com/en/ga/product/fv1000mpe/index.cfm

 

Images   Multiphoton vs. Single-photon laser scanning. One of the main advantage of multiphoton laser scanning microscopy comes from the use of infra-red (IR) lasers and signal detection without pinhole.  IR lasers seem to penetrate more deeply than shorter-wavelength visible lasers and, with no need for pinhole, more light signals are collected, consequently increasing the resolution and contrast of image from deep and thick sample.  This enhancement is well demonstrated by the figure below, in which a Drosophila embryo (~200 µm thick) stained with FITC-conjugated anti-a-tubulin antibody was imaged with 488nm visible laser (single photon) or 800nm IR laser (multiphoton) on Olympus FV1000 confocal microscope.

 

Multiphoton laser scanning image.

3T3 cells are stained with DAPI and anti-tubulin (green) antibody and imaged with 800 nm to 920 nm laser to visualize both DAPI and green Alexa fluoro 488 antibody. As seen in the figures, DAPI and Alexa 488 exhibit different excitation and emission profiles over various wavelength; DAPI is excited well with 820~840 nm laser, whereas Alexa 488 shows better exciation with 880~920 nm laser. It is noticeable that some DAPI emissions appear to be detected in Alexa 488 (green) channel at shorter wavelength (i.e. 800 nm), about which one needs to be careful during double immunofluorescence imaging.