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EasySep? Human CD8+ T Cell Isolation Kit

Immunomagnetic negative isolation of untouched human CD8+ T cells

EasySep? Human CD8+ T Cell Isolation Kit

Immunomagnetic negative isolation of untouched human CD8+ T cells

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Immunomagnetic negative isolation of untouched human CD8+ T cells
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Product Advantages


  • Fast, easy-to-use and column-free

  • Up to 91% purity with high recovery

  • Untouched, viable cells

What's Included

  • EasySep? Human CD8+ T Cell Isolation Kit (Catalog #17953)
    • EasySep? Human CD8+ T Cell Isolation Cocktail, 1 mL
    • EasySep? Dextran RapidSpheres?, 1 mL
  • EasySep? Human CD8+ T Cell Isolation Kit (Catalog #100-0710)
    • EasySep? Human CD8+ T Cell Isolation Cocktail, 1 x 10 mL
    • EasySep? Dextran RapidSpheres?, 1 x 10 mL
  • RoboSep? Human CD8+ T Cell Isolation Kit (Catalog #17953RF)
    • EasySep? Human CD8+ T Cell Isolation Cocktail, 1 mL
    • EasySep? Dextran RapidSpheres?, 1 mL
    • RoboSep? Buffer (Catalog #20104)
    • RoboSep? Filter Tips (Catalog #20125)
Products for Your Protocol
To see all required products for your protocol, please consult the Protocols and Documentation.

Overview

Easily and efficiently isolate highly purified human CD8+ T cells from fresh or previously frozen human peripheral blood mononuclear cells (PBMCs) or washed leukapheresis samples by immunomagnetic negative selection, with the EasySep? Human CD8+ T Cell Isolation Kit. Widely used in published research for more than 20 years, EasySep? combines the specificity of monoclonal antibodies with the simplicity of a column-free magnetic system.

In this EasySep? negative selection procedure, unwanted cells are labeled with antibody complexes and magnetic particles. Unwanted cells expressing the following markers are targeted for removal: CD4, CD14, CD16, CD19, CD20, CD36, CD56, CD66b, CD123, GlyA, and TCRgd. The magnetically labeled cells are then separated from the untouched desired CD8+ T cells by using an EasySep? magnet and simply pouring or pipetting the desired cells into a new tube. Following magnetic cell isolation in as little as 8 minutes, the desired CD8+ T cells are ready for downstream applications such as flow cytometry, culture, or DNA/RNA extraction.

This product replaces EasySep? Human CD8+ T Cell Enrichment Kit (Catalog #19053) for even faster cell isolations.

For large-scale isolation of human CD8+ T cells from leukapheresis samples, see the large-format (1x10^10 cells) kit (Catalog #100-0710).

Learn more about how immunomagnetic EasySep? technology works or how to fully automate immunomagnetic cell isolation with RoboSep?. Alternatively, choose ready-to-use, ethically sourced, primary Human Peripheral Blood CD8+ T Cells, Frozen isolated with EasySep? Human CD8+ T Cell Isolation Kit. Explore additional products optimized for your workflow, including culture media, supplements, antibodies, and more.
Magnet Compatibility
? EasySep? Magnet (Catalog #18000)
? “The Big Easy” EasySep? Magnet (Catalog #18001)
? Easy 50 EasySep? Magnet (Catalog #18002)
? EasyPlate? EasySep? Magnet (Catalog 18102)
? EasyEights? EasySep? Magnet (Catalog #18103)
? RoboSep?-S (Catalog #21000)
? Easy 250 EasySep? Magnet (Catalog #100-0821)
Subtype
Cell Isolation Kits
Cell Type
T Cells, T Cells, CD8+
Species
Human
Sample Source
Leukapheresis, PBMC
Selection Method
Negative
Application
Cell Isolation
Brand
EasySep, RoboSep
Area of Interest
Immunology

Data Figures

EasySep™ Human CD8+ T Cell Isolation Kit

Figure 1. EasySep™ Human CD8+ T Cell Isolation Kit

Starting with human peripheral blood mononuclear cells (PBMCs), the CD8+ T cell content (CD3+CD8+) of the isolated fraction is typically 85.6 ± 4.9% (mean ± SD for the purple EasySep™ Magnet).

Experimental Workflow: DC/T Cell Co-Culture Protocol for the Activation and Expansion of Antigen-Induced CD8+ T Cells

Figure 2. Experimental Workflow: DC/T Cell Co-Culture Protocol for the Activation and Expansion of Antigen-Induced CD8+ T Cells

The EasySep? Human CD8+ T Cell Isolation Kit (Catalog #17953) can be used as a part of a workflow to assess antigen-specific T cell functionality by co-culturing dendritic cells (DCs) and CD8+ T cells. (1) Isolate monocytes from Human Peripheral Blood Leukopak, Fresh (Catalog #70500) or from Human Peripheral Blood Mononuclear Cells (PBMCs), Fresh or Frozen (Catalog #70025), using EasySep? Human Monocyte Isolation Kit (Catalog #19359). (2) Culture monocytes to generate monocyte-derived dendritic cells (Mo-DCs) using ImmunoCult? Dendritic Cell Culture Kit (Catalog #10985) and the peptide(s) of interest. (3) Isolate CD8+ T cells from the same donor’s blood or PBMCs using EasySep? Human CD8+ T Cell Isolation Kit. (4) Co-culture DCs and CD8+ T cells in ImmunoCult?-XF T Cell Expansion Medium (Catalog #10981). (5) For short-term co-culture, isolate CD8+ T cells using EasySep? Human CD8+ Cell Isolation Kit and label the isolated CD8+ T cells with a cell proliferation tracking dye. Set up co-culture by seeding peptide-pulsed dendritic cell suspension with the CD8+ T cell suspension at a 1:4 ratio. Harvest the co-cultures and quantify the antigen-specific CD8+ T cells with tetramer staining after 6 days. (6) For long-term co-culture, expand antigen-specific CD8+ T cells with additional supplements. Analyze the phenotype and function of expanded CD8+ T cells by assessing surface markers or cytokine production. Alternatively, enrich antigen-specific CD8+ T cells with EasySep?, rest the cells for 2 days, and then assess killing activity.

Protocols and Documentation

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

Document Type
Product Name
Catalog #
Lot #
Language
Document Type
Product Name
Catalog #
17953
Lot #
All
Language
English
Document Type
Product Name
Catalog #
100-0710
Lot #
All
Language
English
Document Type
Product Name
Catalog #
17953RF
Lot #
All
Language
English
Document Type
Product Name
Catalog #
17953
Lot #
All
Language
English
Document Type
Product Name
Catalog #
17953
Lot #
All
Language
English
Document Type
Product Name
Catalog #
100-0710
Lot #
All
Language
English
Document Type
Product Name
Catalog #
17953RF
Lot #
All
Language
English
Document Type
Product Name
Catalog #
17953RF
Lot #
All
Language
English
Document Type
Product Name
Catalog #
17953RF
Lot #
All
Language
English

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 (49)

SLA2 is Associated With Immune evasion and Exhaustion of CD8 + T Cells in Gastric Cancer Y. Zhang et al. Journal of Cellular and Molecular Medicine 2026 May

Abstract

ABSTRACTThe Src‐like adaptor 2 (SLA2) functions as a negative regulator of T cell receptor signalling. However, its involvement in the tumour microenvironment (TME) of gastric cancer (GC) remains unexplored. In this study, we found that SLA2 expression was significantly elevated in GC tissues, and a high level of SLA2 was associated with poor prognosis in GC patients. Bioinformatics analyses revealed a close association between SLA2 and TME in GC. Single‐cell RNA sequencing analysis indicated that SLA2 was significantly enriched in CD8+ T cells in GC tissues. Functional validation demonstrated that SLA2 overexpression contributed to the exhaustion of CD8+ T cells by suppressing their proliferation, upregulating the expression of exhaustion markers, reducing the secretion of effector cytokines (IFN‐γ and TNF‐α) and impairing cytotoxic function. SLA2 knockdown in in vitro‐generated exhausted CD8 T cells significantly alleviated T cell exhaustion. Mechanistically, we found that inverse promoter methylation and active histone marks (H3K27ac, H3K4me3 and H3K4me1) may regulate SLA2 expression. Our findings suggest that SLA2 may modulate the TME and promote immune evasion via CD8+ T cell exhaustion in GC.
Hyaluronic acid-CD44 signaling defines therapeutic resistance and immunosuppressive microenvironment in peritoneal metastasis of gastric cancer J. Zhao et al. Journal for Immunotherapy of Cancer 2026 Mar

Abstract

AbstractBackgroundPeritoneal metastasis (PM) is one of the most challenging clinical problems in gastric cancer (GC), largely due to its high recurrence rate and poor response to current therapies. Increasing evidence indicates that remodeling of the extracellular matrix (ECM) plays an important role in therapeutic failure. However, how specific stromal–immune interactions contribute to PM heterogeneity and immunotherapy resistance remains unclear. In this study, we investigated how ECM composition—particularly the accumulation of hyaluronic acid (HA)—influences the immune microenvironment and therapeutic responses in GC-associated PM.MethodsWe combined histopathological assessment, analyses of patient-derived specimens, single-cell transcriptomic profiling, and murine models of PM to delineate ECM remodeling patterns and immune cell dynamics in therapy-sensitive and therapy-resistant lesions. In addition, functional assays and pharmacological approaches were used to examine HA–CD44 signaling and its impact on CD4+ T cell differentiation and responsiveness to immune checkpoint blockade.ResultsTherapy-sensitive PM lesions were characterized by enrichment of elastic fibers, whereas therapy-resistant lesions showed collagen accumulation. Notably, HA deposition emerged as a key feature distinguishing these ECM states and was closely associated with differential therapeutic outcomes. Elevated HA levels activated CD44-dependent signaling in CD4+ T cells, driving regulatory T cell (Treg) differentiation through a CD44–IQGAP1–RAC1–SMAD3 signaling pathway and thereby establishing an immunosuppressive microenvironment. Importantly, pharmacological inhibition of CD44 reduced Treg expansion and markedly enhanced the antitumor efficacy of anti-PD-1 therapy in murine PM models.ConclusionsOur findings identify HA–CD44 signaling as a critical link between ECM remodeling and immune evasion in GC PM. Targeting ECM-driven immunosuppressive mechanisms may represent a promising strategy to overcome therapeutic resistance and improve the efficacy of immunotherapy in this aggressive disease.
RIG-I Stimulation Enhances the Effector Function and Proliferation of Primary Human CD8+ T Cells. A. Mohamed et al. International journal of molecular sciences 2026 Mar

Abstract

Cytotoxic CD8 T lymphocytes are crucial in antiviral immune responses. However, their recruitment to infection sites renders them at risk of viral infection, which could affect their effector activity. CD8 T lymphocytes express RIG-I, which detects cytosolic viral RNA and subsequently induces antiviral gene expression. We investigated how Influenza A virus infection and synthetic triphosphorylated double-stranded RNA, a specific RIG-I ligand, influence TCR-dependent effector responses in primary human CD8 T cells. Cells were isolated from healthy donors and either infected with the reassortant virus RG-PR8-Brazil78 (H1N1) or transfected with the synthetic RNA. Proliferation, degranulation, and cytokine production upon anti-CD3/CD28 stimulation were assessed using flow cytometry and intracellular cytokine staining. Type I IFN production and downstream signaling were measured using IFN-I reporter assay and Western blotting. CRISPR/Cas9 gene editing was employed to knock out RIG-I and STAT2 to evaluate their roles in antiviral responses. Influenza A virus infection of CD8 T cells stimulated RIG-I and activated downstream pathways, including TBK1 and NF-κB, resulting in type-I interferon secretion. Transfection of cytotoxic CD8 T lymphocytes with synthetic RIG-I ligands not only stimulated these pathways but also enhanced the proliferation of CD8 T cells in vitro and protected them from influenza A virus infection. In line with a positive effect on CD8 effector function, both influenza A virus infection and RIG-I ligand transfection enhanced CD8 T cell degranulation and cytokine secretion. Conversely, activation of CD8 T lymphocytes via CD3/CD28 crosslinking increased their susceptibility to influenza A virus infection. We demonstrated that RIG-I stimulation by virus infection or RIG-I ligand transfection promotes intrinsic antiviral pathways and enhances CD8 T-cell effector functions and proliferation. This suggests that RIG-I agonists could enhance and prolong the effector function of cytotoxic CD8 T lymphocytes in immunotherapy.