Thank you for your interest in this product.
Please provide us with your contact information and your local representative
will contact you with a customized quote. Where appropriate, they can also assist you with a(n):
Estimated delivery time for your area
Product sample or exclusive offer
In-lab demonstration
By submitting this form, you are providing your consent to 海角破解版 Technologies Canada Inc. and its subsidiaries and affiliates (“海角破解版”) to collect and use your information, and send you newsletters and emails in accordance with our privacy policy. Please contact us with any questions that you may have. You can unsubscribe or change your email preferences at any time.
This site is protected by reCAPTCHA and the ?and??apply.
Isolate highly purified human CD4+ cells from fresh or previously frozen human peripheral blood mononuclear cells (PBMCs) or washed leukapheresis samples by immunomagnetic positive selection, with the EasySep? Human CD4 Positive Selection Kit II. 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? positive selection procedure, desired cells are labeled with antibody complexes recognizing CD4 and magnetic particles. Labeled cells are separated using an EasySep? magnet and by simply pouring or pipetting off the unwanted cells. The cells of interest remain in the tube. Following magnetic cell isolation in as little as 15 minutes, the desired CD4+ cells are ready for downstream applications such as flow cytometry, culture, or DNA/RNA extraction.
This product replaces the EasySep? Human CD4 Positive Selection Kit (Catalog #18052) for even faster cell isolations.
For large-scale isolation of CD4+ cells from leukapheresis samples, see the large-format (1x10^10 cells) kit (Catalog #100-0693).
Learn more about how immunomagnetic EasySep? technology works or how to fully automate immunomagnetic cell isolation with RoboSep?. Explore additional products optimized for your workflow, including culture media, supplements, antibodies, and more.
Figure 1. Typical EasySep? Human CD4 Positive Selection Profile
Starting with a single cell suspension of fresh human PBMCs, the CD4+ T cell content (CD3+CD4+) of the isolated fraction is typically 96.3 ± 3.0% (mean ± SD using the purple EasySep? magnet).
Figure 2. FACS Data for Anti-Human CD4 Antibody, Clone OKT4, Alexa Fluor? 488-Conjugated
(C) Flow cytometry analysis of human PBMCs isolated with the EasySep? Human CD4 Positive Selection Kit (Catalog #17852) and labeled with Anti-Human CD4 Antibody, Clone OKT4, Alexa Fluor? 488. Histograms show labeling of total PBMCs (Start) and isolated cells (Isolated). Labeling with Mouse IgG2b, kappa Isotype Control Antibody, Clone MPC-11, Alexa Fluor? 488 is shown in the bottom panel (solid line histogram).
Figure 3. Gene Expression Profiles of EasySep?-Isolated CD4+ T Cells Are Similar to PBMC Control
(A,B) tSNE plots were generated using data from (A) PBMC control or (B) cells isolated using the EasySep? Human CD4+ T Cell Enrichment Kit (Catalog #19052). CD4+ T cell clusters are colored as indicated in the legend.
(C,D) 500 genes were selected from a previously published list of CD4+ T cell signature markers (Zhang et al., 2018). Expression heatmaps were generated for CD4+ cells from (C) PBMC control and (D) cells isolated using the EasySep? Human CD4 Positive Selection Kit II (Catalog #17852), EasySep? Human CD4+ T Cell Enrichment Kit (Catalog #19052), or the EasySep? Release Human CD4 Positive Selection Kit (Catalog #17752). The average expression was calculated within each sample for three CD4+ T cell clusters identified by Seurat (na?ve, central memory, and effector memory CD4 T+ cells).
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.
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.
A semi‐automated ASC speck assay to evaluate pyrin inflammasome activation
P. Dai et al.
Clinical & Translational Immunology 2025 Oct
Abstract
Objective: To develop a rapid functional assay to validate variants of uncertain significance (VUS) in the MEFV gene. Methods: Overactivity of the pyrin inflammasome pathway and ASC speck oligomerisation in response to stimulation with low concentrations of Clostridium difficile toxin A was directly visualised by immunofluorescence microscopy. A semi‐automated algorithm was developed to count cells and ASC specks. Results: The semi‐automated ASC speck assay is able to discriminate between healthy controls and patients with familial Mediterranean fever (FMF) and pyrin inflammasome overactivity with high sensitivity. It is also able to discriminate pyrin inflammasome overactivity from other autoinflammatory disease controls with high specificity. Conclusion: The semi‐automated ASC speck assay may be a useful test to functionally validate VUS in the MEFV gene and screen for pyrin inflammasome overactivity. A semi‐automated ASC speck assay using machine learning is able to discriminate between healthy controls and patients with familial Mediterranean fever (FMF) with high sensitivity. It is also able to discriminate FMF from other autoinflammatory diseases with high specificity.
Identification and characterization of a ubiquitin E3 RING ligase of the Chlamydia-like bacterium Simkania negevensis
E-M. H?rner et al.
PLOS Pathogens 2025 Nov
Abstract
In the arms race between a pathogen and the host, the defense mechanisms of the host cell, including the ubiquitin system, are often counteracted by bacteria. Simkania negevensis (Sne), an obligate intracellular Chlamydia-like bacterium connected with respiratory diseases, possesses numerous deubiquitinases, but not much is known about its other ubiquitin-modifying enzymes. Sne infects a wide range of hosts, developing inside a tubular vacuole in close contact with the host endoplasmic reticulum (ER) and mitochondria. Our study describes an uncharacterized Sne ubiquitin E3 RING-ligase (SNE_A12920 or SneRING), which primarily generates K63- and K11-linked ubiquitin chains and preferentially interacts with UbcH5b and UBE2T E2 enzymes. SneRING is expressed upon infection of various human cell lines, as well as amoebae. We show that a portion of the expressed SneRING co-localizes with mitochondria and ER and that the SneRING interactome includes mitochondrial and ER proteins involved in organelle morphology and stress response. Our work offers an initial characterization of a bacterial RING ligase potentially involved in the host cell remodeling to accommodate the unique intracellular lifestyle of Sne. Author summaryUbiquitination is a protein modification system that regulates protein degradation, localization, or interactions. As such, ubiquitination has many important functions in cell signalling, and its dysregulation can lead to cancer and neurodegenerative diseases. Bacteria that live and develop inside human or other eukaryotic cells, such as Chlamydia, often modulate the ubiquitination system to ensure their own survival. Simkania negevensis is a Chlamydia-like bacterium connected to respiratory diseases in humans. We have discovered a novel enzyme expressed by these bacteria that can ubiquitinate other proteins and thus potentially modify host cell processes that would otherwise hinder infection. In this work, we explore the function of this enzyme and determine its possible cellular localization, as well as some of the proteins it interacts with. Our study provides new insights into how bacterial pathogens adapt to and manipulate host cells using one of the major cell function regulatory systems.
Modeling mesenchymal stromal cell support to hematopoiesis within a novel 3D artificial marrow organoid system
Scientific Reports 2025 Jul
Abstract
The human bone marrow (BM) microenvironment involves hematopoietic and non-hematopoietic cell subsets organized in a complex architecture. Tremendous efforts have been made to model it in order to analyze normal or pathological hematopoiesis and its stromal counterpart. Herein, we report an original, fully-human in vitro 3D model of the BM microenvironment dedicated to study interactions taking place between mesenchymal stromal cells (MSC) and hematopoietic stem and progenitor cells (HSPC) during the hematopoietic differentiation. This fully-human Artificial Marrow Organoid (AMO) model is highly efficient to recapitulate MSC support to myeloid differentiation and NK cell development from the immature CD34?+?HSPCs to the most terminally differentiated CD15?+?polymorphonuclear neutrophils, CD64?+?monocytes or NKG2A-KIR2D?+?CD57?+?NK subset. Lastly, our model is suitable for evaluating anti-leukemic NK cell function in presence of therapeutic agents. Overall, the AMO is a versatile, low cost and simple model able to recapitulate normal hematopoiesis and allowing more physiological drug testing by taking into account both immune and non-immune BM microenvironment interactions.Supplementary InformationThe online version contains supplementary material available at 10.1038/s41598-025-07717-9.
PRODUCTS ARE FOR RESEARCH USE ONLY AND NOT INTENDED FOR HUMAN OR ANIMAL DIAGNOSTIC OR THERAPEUTIC USES UNLESS OTHERWISE STATED. FOR ADDITIONAL INFORMATION ON QUALITY AT 海角破解版, REFER TO WWW.海角破解版.COM/COMPLIANCE.