Capture Every Detail of Biological Phenomena
Microscopic imaging continues to rapidly evolve together with such advances in digital technology as confocal microscopes and high-sensitivity, large field-of-view CMOS cameras. The newly developed CFI Plan Apochromat Lambda D is a high-performance objective series optimized for digital solutions that are essential for future life science research.
The Lambda D series objectives deliver high image quality across the large field of view of 25 mm and chromatic aberration correction over a wide wavelength range. They improve the accuracy of quantitative analysis and realize highly reliable data acquisition.
Key Features
Bright and Clear over a Large Field of View
Image flatness has been improved by adopting a newly-developed high-refractive index glass and correcting field curvature in the oil immersion objectives. Bright and clear images can be obtained right up to the edge of the 25 mm field of view.
This results in:
- Improvement accuracy of light intensity measurement
- Generation of seamless macro images in a short time
- Acquisition of a wide range of life phenomena with a single image
- Enhancement of high-content screening throughput
Reduced light intensity deterioration at the periphery of the field of view
The Lambda D series objectives minimize light intensity deterioration at the periphery of the field of view. This allows (DAPI stained) cell nuclei at the edges of the image to be observed brightly, even with confocal imaging.
High-precision image stitching
Since image acquisition time can be reduced thanks to a large 25 mm diagonal field of view and superior image quality up to the image periphery, seamless, high-quality stitched images can be efficiently obtained.
Large FOV enhances imaging efficiency
A 25 mm FOV is 30% more efficient than a 22 mm FOV because it requires less images for image stitching.
High refractive index glass achieves uniform brightness and image quality
Accurate Data Acquisition in All Wavelengths
Extra-low dispersion glass has been employed as a lens material, simultaneously correcting chromatic aberration over a wide wavelength range of 405 nm to 850 nm. Since deviation of the image plane for each wavelength is imperceptible, high-precision multicolor imaging is enhanced.
Highly reliable quantitative data can be obtained when measuring the light intensity of nuclear stains.
Extra-low dispersion glass corrects chromatic aberration
The Endless Pursuit of High Resolution
Using technology that processes the edge of lens elements to the minimum thickness, Nikon has maximized the use of the light rays that pass through the periphery of the lens diameter to increase numerical aperture, delivering high resolution of fine structures.
A clear fluorescent image with a high S/N ratio can be obtained.
High resolution images can be captured with a large field of view.
Gastric wall; Label: SMA antibody staining; Camera: Digital Sight 10; Objective: CFI Plan Apochromat Lambda D 40XC; Image courtesy of Nichirei Biosciences Inc.
Edge thinning technology that achieves high resolution
Anti-Reflective Nano Crystal Coat
Nano Crystal Coat is ultra-low refractive index thin film technology that applies a nanoparticle film used for the projection lens of Nikon’s semiconductor manufacturing equipment. An extremely high antireflection effect is achieved by forming a low-density film with particles of a few nanometers to a dozen nanometers. It also lowers the reflection of vertically incident light compared to conventional antireflection film, achieves extremely high transmittance in a wide wavelength range, has an unprecedented effect with respect to ghosting and flares caused by obliquely incident light.
Conventional anti-reflection multi-layer film | Nano Crystal Coat |
Conventional multi-layer film | Nano Crystal Coat |