Facility

Trifoil InSyTe FLECT/CT™ (3D NIR optical imaging with CT)

3D NIR tomographic optical imaging system (InSyTe FLECT/CT™, TriFoil Imaging) is an innovative instrument that offers 3D NIR optical imaging with high-quality anatomical reference in a single platform. The InSyTe™ platform, based on Fluorescence Emission Computed Tomography (FLECT), provides unparalleled capability for whole body imaging and in vivo characterization of preclinical, small animal models. It integrates two 3D imaging modalities into a single instrument by enabling co-registered FLECT and X-ray CT. It utilizes a patented, rotating gantry design to collect optical and X-ray-based projections of the animal. When combined with NIR probes and laser excitation, this allows for enhanced sensitivity (up to the picoM range) and accurate 3D data acquisition, especially when looking for low-level and/or deep signals during fluorescence detection. Image reconstruction algorithms utilize segmented X-ray CT data to assess changes in optical properties within the animal, providing accurate reconstruction visualizations.

Figure. Schematic diagram and photograph of fluorescence emission computed tomography (FLECT) system (InSyTe, Trifoil Imaging), and images of a mouse injected with NIR probes.

Video. Operation of 3D NIR tomographic optical imaging system (InSyTe FLECT/CT™, TriFoil Imaging)

Cytation5

Optical Imaging core has Cytation 5 (BioTek, Winooski, VT), which is a combination of automated digital microscopy and conventional microplate detection. This imaging suite allows for capturing both well-based quantitative data and phenotypic information on a single platform.

Gen5™ microplate reader and imager software provide complete control over all imaging and data capture, plus image and data analysis to create publication-ready images and data.

1. The multi-mode readers offer a plate reader functions with the multi-mode detection modules including filter- and monochromator-based fluorescence detection, luminescence and UV-Vis absorbance detection, and time resolved fluorescence (secondary mode):

Tunable wavelength monochromator optical systems for selecting specific wavelengths

2. A micro-volume analysis system with Take3 module allows for 16 samples in one run to save a lot of time compared to single-sample devices:

Gen5 is pre-programmed for ssDNA, dsDNA, RNA and protein quantification in 2 μL.
Spectrophotometric determination of dsDNA, ssDNA, RNA at A260
Fluorometric determination of dsDNA with fluorescent dyes, for example, PicoGreen
Determination of purity based on A260/A280 ratios

3. The microscopy module offers a full range of microscopy resolution in fluorescence covering 250-900 nm for visible and near-infrared compatible fluorescence imaging, brightfield, fluorescence, high contrast brightfield, color brightfield and phase contrast imaging in microplates and a wide variety of labware, from slides to cell culture flasks:

Full range of microscopy resolution (the highest quality objectives 4x, 10x, 20x, 60x)
Up to four choices of full range of fluorescence filter cubes available (DAPI, GFP, RFP, CY5, CY7)
Up to four choices of excitation LED available (365, 465, 523, 623, 655, 740 nm)
Temperature control, including the condensation control gradient
Labware adapters for microscope slides, cell culture dishes, chamber slides, microplates, T75 flasks and hemocytometers.
Auto focus capabilities: Imaging based autofocus, user trained, laser autofocus for high reproducibility and accuracy for automated imaging and long-term kinetics.
The High Contrast (HC) cell counting application uses modified brightfield imaging to generate a bright point of light for each cell that is easily identified and counted by Gen5™ software without the use of labels

Figure. Cytation5 imaging suite with automated digital microscopy and conventional microplate readers. (Upper right), ID8 ovarian cancer cells stained for near-infrared targeted fluorophore (red), mitotracker green (green), nuclei (blue) at a magnification of 20x. (Bottom right), Cell count on Gen5. Bar = 100 µm.

JuLi Stage

JuLI Stage Real-Time Cell History Recorder (NanoenTek Inc., South Korea) is designed to support cell biology researchers to approach kinetic images and data from the start to the end so that they can save their time and can focus on more advanced and valuable work for their research. JuLi Stage is a fully automated real-time cell history recorder that directly acquires cell images from numerous cell culture plates (6 to 384 wells) and dishes in an incubator. JuLi Stage supports the multi-channel fluorescent colors and multiple objective lens, and the sensitive filter-based optics are optimized for live cell assays. It also enables users to obtain the quantified cell confluence results with low variation and the growth curve using images based analysis with a bright field.

Main Features

Incubator-compatible
Fully automated X-Y-Z stage
Interchangeable objective lens (4x, 10x, 20x)
Manual & auto focusing
Compatible with various plates & vessels
Data management with all-in-one PC

Figure. Photo of Juli stage in the cell incubator and real-time images of U2 OS cell with GFP/RFP expressions.

Figure. Real time cell growth curves. Cell confluence analyzed for cytotoxicity assays.

Page updated

Google Sites

Report abuse