EasySep™ Mouse CD11b Positive Selection Kit II

Immunomagnetic positive selection cell isolation kit

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EasySep™ Mouse CD11b Positive Selection Kit II

Immunomagnetic positive selection cell isolation kit

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Immunomagnetic positive selection cell isolation kit
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Product Advantages


  • Fast and easy-to-use

  • Up to 95% purity (for bone marrow, purity can be up to 99%)

  • No columns required

  • Isolated cells are not fluorochrome-labeled

What's Included

  • EasySep™ Mouse CD11b Positive Selection Kit II (Catalog #18970)
    • EasySep™ Mouse CD11b Positive Selection II Component A, 0.5 mL
    • EasySep™ Mouse CD11b Positive Selection II Component B, 0.5 mL
    • EasySep™ Dextran RapidSpheres™ 50100, 2 x 1 mL
    • Rat Serum, 2 mL
  • RoboSep™ Mouse CD11b Positive Selection Kit II (Catalog #18970RF)
    • EasySep™ Mouse CD11b Positive Selection II Component A, 0.5 mL
    • EasySep™ Mouse CD11b Positive Selection II Component B, 0.5 mL
    • EasySep™ Dextran RapidSpheres™ 50100, 2 x 1 mL
    • Rat Serum, 2 mL
    • Empty Vial for use with RoboSep™
    • RoboSep™ Buffer (Catalog #20104)
    • RoboSep™ Filter Tips (Catalog #20125)

Overview

The EasySep™ Mouse CD11b Positive Selection Kit II isolates highly purified CD11b+ cells from mouse splenocytes, bone marrow, lungs, brains or other tissues by immunomagnetic positive selection. Desired cells are targeted with antibodies and magnetic particles, and isolated without columns using an EasySep™ magnet. Unwanted cells are simply poured off, while desired cells remain in the tube. Isolated cells are immediately ready for downstream applications such as flow cytometry, culture, and cell-based experiments.

This product replaces the EasySep™ Mouse CD11b Positive Selection Kit (Catalog #18770) for even faster cell isolations and does not result in the labeling of isolated cells with PE.
Magnet Compatibility
• EasySep™ Magnet (Catalog #18000)
• “The Big Easy” EasySep™ Magnet (Catalog #18001)
• EasyEights™ EasySep™ Magnet (Catalog #18103)
• RoboSep™-S (Catalog #21000)
Subtype
Cell Isolation Kits
Cell Type
Monocytes, Myeloid Cells
Species
Mouse
Sample Source
Bone Marrow, Lung, Other, Spleen
Selection Method
Positive
Application
Cell Isolation
Brand
EasySep, RoboSep
Area of Interest
Immunology

Data Figures

Typical EasySep™ Mouse CD11b Positive Selection Profile from Mouse Spleen and Bone Marrow

Figure 1. Typical EasySep™ Mouse CD11b Positive Selection Profile from Mouse Spleen and Bone Marrow

Starting with mouse splenocytes and bone marrow samples, the CD11b+ cell content of the isolated fraction is typically 92.6 ± 3.0% and 98.4 ± 2.3%, respectively (gated on viable singlet cells, mean ± SD using the purple EasySep™ Magnet).

Typical EasySep™ Mouse CD11b Positive Selection Profile from Mouse Lung Tissue

Figure 2. Typical EasySep™ Mouse CD11b Positive Selection Profile from Mouse Lung Tissue

Starting with mouse lung single-cell suspension, the CD11b+ cell content of the isolated fraction is typically 86.9 ± 7.6% (mean ± SD using the purple EasySep™ Magnet).

Typical EasySep™ Mouse CD11b Positive Selection Profile from Mouse Brain Tissue

Figure 3. Typical EasySep™ Mouse CD11b Positive Selection Profile from Mouse Brain Tissue

Starting with a single-cell suspension of mouse brain cells, the CD11b+ cell content of the isolated fraction is typically 94.2 ± 4.0% (mean ± SD using the purple EasySep™ Magnet). In the above example, the purities of the start and final isolated fractions are 32.5% and 94.5%, respectively.

Protocols and Documentation

Find supporting information and directions for use in the Product Information Sheet or explore additional protocols below.

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Applications

This product is designed for use in the following research area(s) as part of the highlighted workflow stage(s). Explore these workflows to learn more about the other products we offer to support each research area.

Resources and Publications

Frequently Asked Questions

Can EasySep™ be used for either positive or negative selection?

Yes. The EasySep™ kits use either a negative selection approach by targeting and removing unwanted cells or a positive selection approach targeting desired cells. Depletion kits are also available for the removal of cells with a specific undesired marker (e.g. GlyA).

How does the separation work?

Magnetic particles are crosslinked to cells using Tetrameric Antibody Complexes (TAC). When placed in the EasySep™ Magnet, labeled cells migrate to the wall of the tube. The unlabeled cells are then poured off into a separate fraction.

Which columns do I use?

The EasySep™ procedure is column-free. That's right - no columns!

How can I analyze the purity of my enriched sample?

The Product Information Sheet provided with each EasySep™ kit contains detailed staining information.

Can EasySep™ separations be automated?

Yes. RoboSep™, the fully automated cell separator, automates all EasySep™ labeling and cell separation steps.

Can EasySep™ be used to isolate rare cells?

Yes. We recommend a cell concentration of 2x108 cells/mL and a minimum working volume of 100 µL. Samples containing 2x107 cells or fewer should be suspended in 100 µL of buffer.

Are the EasySep™ magnetic particles FACS-compatible?

Yes, the EasySep™ particles are flow cytometry-compatible, as they are very uniform in size and about 5000X smaller than other commercially available magnetic beads used with column-free systems.

Can the EasySep™ magnetic particles be removed after enrichment?

No, but due to the small size of these particles, they will not interfere with downstream applications.

Can I alter the separation time in the magnet?

Yes; however, this may impact the kit's performance. The provided EasySep™ protocols have already been optimized to balance purity, recovery and time spent on the isolation.

For positive selection, can I perform more than 3 separations to increase purity?

Yes, the purity of targeted cells will increase with additional rounds of separations; however, cell recovery will decrease.

How does the binding of the EasySep™ magnetic particle affect the cells? is the function of positively selected cells altered by the bound particles?

Hundreds of publications have used cells selected with EasySep™ positive selection kits for functional studies. Our in-house experiments also confirm that selected cells are not functionally altered by the EasySep™ magnetic particles.

If particle binding is a key concern, we offer two options for negative selection. The EasySep™ negative selection kits can isolate untouched cells with comparable purities, while RosetteSep™ can isolate untouched cells directly from whole blood without using particles or magnets.

Publications (4)

Bioluminescence for in vivo detection of cell-type-specific inflammation in a mouse model of uveitis. S. John et al. Scientific reports 2020 jul

Abstract

This study reports the use of cell-type-specific in vivo bioluminescence to measure intraocular immune cell population dynamics during the course of inflammation in a mouse model of uveitis. Transgenic lines expressing luciferase in inflammatory cell subsets (myeloid cells, T cells, and B cells) were generated and ocular bioluminescence was measured serially for 35 days following uveitis induction. Ocular leukocyte populations were identified using flow cytometry and compared to the ocular bioluminescence profile. Acute inflammation is neutrophilic (75{\%} of ocular CD45 + cells) which is reflected by a significant increase in ocular bioluminescence in one myeloid reporter line on day 2. By day 7, the ocular T cell population increases to 50{\%} of CD45 + cells, leading to a significant increase in ocular bioluminescence in the T cell reporter line. While initially negligible ({\textless} 1{\%} of CD45 + cells), the ocular B cell population increases to {\textgreater} 4{\%} by day 35. This change is reflected by a significant increase in the ocular bioluminescence of the B cell reporter line starting on day 28. Our data demonstrates that cell-type-specific in vivo bioluminescence accurately detects changes in multiple intraocular immune cell populations over time in experimental uveitis. This assay could also be useful in other inflammatory disease models.
Tuning isoform selectivity and bortezomib sensitivity with a new class of alkenyl indene PDI inhibitor. R. M. Robinson et al. European journal of medicinal chemistry 2020 jan

Abstract

Protein disulfide isomerase (PDI, PDIA1) is an emerging therapeutic target in oncology. PDI inhibitors have demonstrated a unique propensity to selectively induce apoptosis in cancer cells and overcome resistance to existing therapies, although drug candidates have not yet progressed to the stage of clinical development. We recently reported the discovery of lead indene compound E64FC26 as a potent pan-PDI inhibitor that enhances the cytotoxic effects of proteasome inhibitors in panels of Multiple Myeloma (MM) cells and MM mouse models. An extensive medicinal chemistry program has led to the generation of a diverse library of indene-containing molecules with varying degrees of proteasome inhibitor potentiating activity. These compounds were generated by a novel nucleophilic aromatic ring cyclization and dehydration reaction from the precursor ketones. The results provide detailed structure activity relationships (SAR) around this indene pharmacophore and show a high degree of correlation between potency of PDI inhibition and bortezomib (Btz) potentiation in MM cells. Inhibition of PDI leads to ER and oxidative stress characterized by the accumulation of misfolded poly-ubiquitinated proteins and the induction of UPR biomarkers ATF4, CHOP, and Nrf2. This work characterizes the synthesis and SAR of a new chemical class and further validates PDI as a therapeutic target in MM as a single agent and in combination with proteasome inhibitors.
Clearance of senescent glial cells prevents tau-dependent pathology and cognitive decline. T. J. Bussian et al. Nature 2018 SEP

Abstract

Cellular senescence, which is characterized by an irreversible cell-cycle arrest1 accompanied by a distinctive secretory phenotype2, can be induced through various intracellular and extracellular factors. Senescent cells that express the cell cycle inhibitory protein p16INK4A have been found to actively drive naturally occurring age-related tissue deterioration3,4 and contribute to several diseases associated with ageing, including atherosclerosis5 and osteoarthritis6. Various markers of senescence have been observed in patients with neurodegenerative diseases7-9; however, a role for senescent cells in the aetiology of these pathologies is unknown. Here we show a causal link between the accumulation of senescent cells and cognition-associated neuronal loss. We found that the MAPTP301SPS19 mouse model of tau-dependent neurodegenerative disease10 accumulates p16INK4A-positive senescent astrocytes and microglia. Clearance of these cells as they arise using INK-ATTAC transgenic mice prevents gliosis, hyperphosphorylation of both soluble and insoluble tau leading to neurofibrillary tangle deposition, and degeneration of cortical and hippocampal neurons, thus preserving cognitive function. Pharmacological intervention with a first-generation senolytic modulates tau aggregation. Collectively, these results show that senescent cells have a role in the initiation and progression of tau-mediated disease, and suggest that targeting senescent cells may provide a therapeutic avenue for the treatment of these pathologies.
New look, same high quality and support! You may notice that your instrument or reagent packaging looks slightly different from images displayed on the website, or from previous orders. We are updating our look but rest assured, the products themselves and how you should use them have not changed. Learn more