Olympus recently unveiled the new FLUOVIEW FV3000 confocal laser scanning microscope, that combines high-performance imaging capabilities along with ease of use so researchers in such fields as cancer research, cell biology and stem cell research can collect relevant imaging data easily and quickly.
This new FV3000 series is bright fluorescent imaging of even dim samples made possible through a highly efficient spectroscopic mechanism and high-sensitivity detector. It also improved observation reliability achieved through precise spectroscopy and newly developed time management system.
This new FLUOVIEW FV3000 built for stable, accurate and fast measurements of biological reactions within living cells and tissues, Olympus new FV3000 offers flexibility for all live-cell imaging applications, providing high-resolution pictures of structures and dynamic intracellular processes.
The Olympus TruSpectral detection system is optimized for maximum efficiency and performance when delivering emission light to detectors. Users have the freedom to select the accurate wavelength range they wish to capture in every detection channel at nanometer precision.
Succeeding the well-established FV1200 and the FV3000 is controlled via a intuitive software interface so even novice users can generate high-quality images and data. Meeting today’s application demands the system’s new optical design offers unique macro to micro imaging capabilities along with objectives ranging from 1.25X to 150X magnification. Users can choose either the FV3000 with galvanometer scanner or FV3000RS with a hybrid resonant / galvanometer scanner. The high-speed resonant scanner offers users to acquire high-resolution images at up to 438 frames per second so scientists can observe fast-changing processes.
FLUOVIEW software has been designed with an intuitive interface that can be tailored to adapt to the way an individual works. Users can also create and save workflows and customise the interface’s layout for easy access to commonly used applications. A new sys architecture enables researchers to execute a variety of observation procedures, like, changing the laser light or scanning range midway through an experiment with millisecond precision.