Confocal Laser Scanning Microscope – QNCF1000

Confocal Laser Scanning Microscope – QNCF1000

Confocal Laser Scanning Microscope – QNCF1000 is crafted to meet the advanced imaging needs of modern biological research. Offering high-throughput and high-resolution imaging, it is perfect for studying tissues, organs, and live model organisms. With a 25mm field of view and an industry-leading scanning resolution of 8192 x 8192 pixels, the QNCF1000 delivers exceptional clarity and efficiency in large-scale sample imaging.

Craftsmanship Masterpiece Pursuing Perfection

Building on the success of the QNCF930 and QNCF950 confocal microscopes, we are excited to introduce the next-generation QNCF1000 confocal microscope!

This latest model brings groundbreaking improvements in optical performance, resolution, and speed, while also incorporating enhanced intelligent features and motorized design. These advancements streamline complex experimental workflows, meeting the rigorous demands of advanced research across various fields.

Refined through dedicated innovation and precision, the QNCF1000 represents a new standard in quality. Qualitest is proud to support your scientific pursuits, guiding you in exploring uncharted territories and pushing the boundaries of discovery.

Super Vision

Achieve a broad observation field and gather detailed information across the entire sample quickly and efficiently.

• To extract more data from the sample: The QNCF1000 confocal microscope features a cutting-edge 25mm field of view, allowing seamless imaging of large samples in a single scan with 1.5 times the data throughput of earlier models. With a scanning resolution of up to 8192x8192 pixels, it meets the increasing demands of life science research, providing precise analysis of tissues, organs, and live model organisms while delivering critical biological data with exceptional clarity and efficiency.

• Requires fewer total images for large and high-resolution image stitching: When combined with the QNIB1000 inverted microscope, the QNCF1000 delivers high-quality confocal images with a 25mm field of view (FOV). This expansive FOV minimizes the need for image stitching, significantly reducing acquisition time. The result is uniform brightness, enhanced efficiency, and high-throughput imaging for large specimens.

Super Resolution

Enhance image clarity with a higher signal-to-noise ratio and superior resolution.

• High-performance objectives for confocal imaging: The NIS series objectives feature high numerical apertures, extended working distances, and superior chromatic aberration correction. With advanced multi-layer coating technology, they provide exceptional image quality and resolution. Perfect for traditional optical microscopes and essential for confocal microscopy systems, these objectives empower researchers to reveal previously unseen fine structures and dynamic processes, driving deeper exploration and visualization of the microscopic world.
• NIS Apochromat TIRF 100X Oil: With an ultra-high resolution and a numerical aperture (NA) of up to 1.49, this objective lens represents the pinnacle of the NIS series. Expertly engineered, it minimizes spherical aberrations across imaging temperatures of 23°C and 37°C, ensuring optimal performance and precision.

• NIS Apochromat 20× C WI: An ideal solution for observing cultured cells and specimens in culture medium, this lens closely matches the refractive index of both, minimizing spherical aberration and reducing light loss from refractive index differences for exceptional imaging clarity.

• NIS Plan Apochromat series: Setting a new standard for professional-grade objectives, these lenses achieve exceptional numerical apertures and extended working distances. They deliver flawless aberration correction across the entire field of view, providing imaging quality that surpasses conventional objectives.

• High-efficiency scanning heads and detectors: The QNCF1000 features a high-precision scanning galvanometer system integrated within its scanning head, paired with a continuously adjustable electric pinhole. This combination delivers low-noise, high-contrast confocal imaging with outstanding quality. Its 8192x8192 pixel scanning resolution surpasses the optical diffraction limit, even with low magnification objectives, enabling exceptional high-resolution sampling and precise capture of intricate micro details.

Super Speed

Reduced acquisition times enable high-frequency confocal imaging, enhancing efficiency and throughput.

• Faster scanning speed: With a high-speed imaging capability of up to 60 frames per second (fps) at 8*256 pixels, the QNCF1000 reduces exposure time under high light intensities, significantly lowering phototoxicity. This rapid imaging speed supports high-frequency data acquisition, enabling the real-time capture of dynamic events and extended sample changes, meeting the demanding imaging needs of the life sciences field.

• Real-time four-channel synchronized imaging: The QNCF1000 confocal microscope features advanced four-channel fluorescence merging technology, enabling researchers to perform real-time, synchronized multi-channel observations and captures. It facilitates simultaneous detection and analysis of four distinct fluorescent labels within the same field of view, seamlessly integrating multiple signals. Combined with precise spectral unmixing imaging, this technology provides vivid, three-dimensional visualization of complex, multi-layered sample data, significantly enhancing experimental throughput and data accuracy.

Nomis Pro X-C

A robust and integrated software platform designed for advanced analysis and visualization. 

Nomis Pro X-C is a confocal microscope adaptation software developed by Qualitest, offering seamless integration and control over the confocal system's hardware and core microscope functions. It combines these controls with advanced imaging analysis, providing a high-performance, user-friendly, all-in-one solution for experiments. Designed to handle complex application scenarios and specific research needs, Nomis Pro X-C ensures a smooth workflow, eliminating the hassle of cumbersome microscope operations and allowing users to focus on the core of their experiments and innovative exploration.

• High-speed hardware control: It offers users unmatched ease of use, streamlining operation and digital management while providing precise control over various electronic components of the microscope, including objective lens switching, focusing, condenser lens adjustments, and fluorescence module transitions.

• Multi-dimensional imaging and image display: It can memorize custom observation modes and supports the combined use of X, Y, Z, λ, and T scanning functions. With a variety of flexible imaging modes—including multi-channel fluorescence imaging, time-lapse scanning, multi-position acquisition, Z-axis stacking, and panoramic stitching—users can freely combine these modes to meet specific needs, adapting to a wide range of complex experimental scenarios.

• Deconvolution: This feature enables the deblurring of two-dimensional images through multiple iterations of deconvolution, effectively removing out-of-focus noise, or speckle noise, from confocal images. Additionally, 3D deconvolution can be applied to multidimensional images, further improving clarity and resolution across multiple axes.