Our broad portfolio consists of multiplex panels that allow you to choose, within the panel, analytes that best meet your needs. On a separate tab you can choose the premixed cytokine format or a single plex kit.
Cell Signaling Kits & MAPmates™
Choose fixed kits that allow you to explore entire pathways or processes. Or design your own kits by choosing single plex MAPmates™, following the provided guidelines.
The following MAPmates™ should not be plexed together:
-MAPmates™ that require a different assay buffer
-Phospho-specific and total MAPmate™ pairs, e.g. total GSK3β and GSK3β (Ser 9)
-PanTyr and site-specific MAPmates™, e.g. Phospho-EGF Receptor and phospho-STAT1 (Tyr701)
-More than 1 phospho-MAPmate™ for a single target (Akt, STAT3)
-GAPDH and β-Tubulin cannot be plexed with kits or MAPmates™ containing panTyr
.
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Select A Species, Panel Type, Kit or Sample Type
To begin designing your MILLIPLEX® MAP kit select a species, a panel type or kit of interest.
Custom Premix Selecting "Custom Premix" option means that all of the beads you have chosen will be premixed in manufacturing before the kit is sent to you.
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96-Well Plate
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Add Additional Reagents (Buffer and Detection Kit is required for use with MAPmates)
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48-602MAG
Buffer Detection Kit for Magnetic Beads
1 Kit
Space Saver Option Customers purchasing multiple kits may choose to save storage space by eliminating the kit packaging and receiving their multiplex assay components in plastic bags for more compact storage.
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Classical biochemical techniques are often employed to measure location and co-location of molecules, tasks ideally suited for Amnis® imaging flow cytometry system. Examples include molecular translocation of transcription factors from the cytoplasm to the nucleus, trafficking of molecules to sub-cellular organelles, co-localization of proteins on, in, or between cells, just to name a few. The Amnis® imaging flow cytometry's ability to obtain statistically robust per-cell measurements of probe location and co-localization within highly heterogenous samples provides significant advances that complement and extend traditional biochemical research.
Measurement of NFκB translocation in transgenic T cells which are in contact with antigen presenting cells (APC) and specific peptide. Specific T cell:APC conjugates are identified and translocation of NFκB from the cytoplasm to the nucleus specifically within the T cells is measured in the presence (shown) or absence of peptide. See the application note for more details.
Co-Localization of an Antibody-Drug Conjugate to Endosomes or Lysosomes
In this experiment we use the capabilities of the Imagestream®x system to measure the transit of a fluorescently labeled antibody-drug conjugate (ADC) through the cellular endocytic pathway. The high spatial resolution afforded by the Imagestream®x system allowed accurate measurement of ADC co-localization to endosomes and lysosomes. See the application note for more details.
FRET Using the Imagestream®x for Detection of Protein-Protein Interactions
In fluorescence microscopy, light at one wavelength is absorbed by a fluorophore and emitted at a longer wavelength. FRET (Fluorescence or Forster Resonance Energy Transfer) can occur when a second fluorophore is in very close contact such that it can accept the energy from the first fluorophore and emit the light at an even longer wavelength. The efficiency of the transfer is extremely sensitive to the separation distance between the fluorophores and therefore when the emission is detected at the longer wavelength the conclusion is that the fluorophores were within approximately 10 nanometers of each other. When two fluorophores (a donor and acceptor pair) are used to label two different proteins, the close proximity of the two proteins are inferred by the measurement of the FRET from the donor to the acceptor fluorophore. The combination of high speed image acquisition and automated quantitative image analysis with FRET on the Imagestream®x allows measurement of the spatial location of the protein interaction within the cell or between cell conjugates even for rare subpopulations. Distinguishing intracelluar location of FRET vs. location of the proteins when not exhibiting FRET behavior offers a major advancement in understanding signaling pathways.
In this experiment receptor 1 is labeled with PE (donor) and receptor 2 is labeled with AF647 (acceptor). Cells were stimulated or not-stimulated and images collected with 488nm laser excitation. The graph shows that FRET to the AF647 fluorophore can be detected in the stimulated sample.
Classical biochemical techniques are often employed to measure location and co-location of molecules, tasks ideally suited for Amnis® imaging flow cytometry system. Examples include molecular translocation of transcription factors from the cytoplasm to the nucleus, trafficking of molecules to sub-cellular organelles, co-localization of proteins on, in, or between cells, just to name a few. The Amnis® imaging flow cytometry's ability to obtain statistically robust per-cell measurements of probe location and co-localization within highly heterogenous samples provides significant advances that complement and extend traditional biochemical research.
