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Density gradient medium for the isolation of mononuclear cells

³¢²ā³¾±č³ó“Ē±č°ł±š±čā„¢

Density gradient medium for the isolation of mononuclear cells

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Density gradient medium for the isolation of mononuclear cells
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Overview

Reliably isolate mononuclear cells from peripheral blood, cord blood, or bone marrow with ³¢²ā³¾±č³ó“Ē±č°ł±š±č™—a cost-effective alternative to Ficoll-Paqueā„¢. Use this density gradient medium for rapid, simple, and reliable cell isolation from most blood samples obtained from normal individuals and patients. You can substitute ³¢²ā³¾±č³ó“Ē±č°ł±š±čā„¢ for Ficoll-Paqueā„¢ without changing your existing protocols and achieve similar cell purity and recovery rates. This medium is fully compatible with both SepMateā„¢ and RosetteSepā„¢. Formulated with Diatrizoic acid dihydate (9.1% w/v) and polysaccharide (5.7% w/v), ³¢²ā³¾±č³ó“Ē±č°ł±š±čā„¢ has a density of 1.077 g/ml.
Contains

• Diatrizoic acid dihydrate (9.1% w/v)

• Polysaccharide (5.7% w/v)

• Other ingredients

Subtype
Density Gradient Media
Cell Type
Mononuclear Cells
Species
Human
Sample Source
Bone Marrow, Cord Blood, Whole Blood
Selection Method
Negative
Application
Cell Isolation
Brand
Lymphoprep
Area of Interest
Immunology

Data Figures

Figure 1. Purity and Recovery of Cells from Whole Blood When Using Cost-Effective ³¢²ā³¾±č³ó“Ē±č°ł±š±čā„¢ is Comparable to Using Ficoll-Paqueā„¢ PLUS

(A) Density gradient centrifugation of peripheral whole blood using ³¢²ā³¾±č³ó“Ē±č°ł±š±čā„¢ results in similar cell purity of mononuclear cells including T cells, B cells, NK cells and monocytes compared to Ficoll-Paqueā„¢ PLUS. (B) The recovery of total mononuclear cells and CD45+ cells is also similar. (n = 5, Mean ± SD).

Figure 2. Purity and Recovery of Cells from Cord Blood When Using Cost-Effective ³¢²ā³¾±č³ó“Ē±č°ł±š±čā„¢ is Comparable to Using Ficoll-Paqueā„¢ PLUS

(A) Density Gradient centrifugation of cord blood using ³¢²ā³¾±č³ó“Ē±č°ł±š±čā„¢ results in similar cell purity of mononuclear cells including T cells, B cells, NK cells and monocytes compared to Ficoll-Paqueā„¢ PLUS. (B) The recovery of total mononuclear cells and CD45+ cells is also similar. (n = 4, Mean ± SD).

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 #
07861, 18061, 18060, 07811
Lot #
All
Language
Multi
Document Type
Product Name
Catalog #
07861, 18061, 18060, 07811
Lot #
All
Language
English
Document Type
Product Name
Catalog #
07861, 07811
Lot #
All
Language
English
Document Type
Product Name
Catalog #
18061, 18060
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.

Research Area
Workflow Stages

Resources and Publications

Publications (367)

A viral noncoding RNA is a master regulator of gene expression that defines host cell identity and function C. Gorbea et al. Nucleic Acids Research 2026 May

Abstract

AbstractViruses extensively reprogram the host cell to promote infection and persistence, yet the contribution of noncoding RNAs (ncRNAs) to this viral reengineering remains largely unknown. Here, we show that HSUR1, a viral Sm-class ncRNA abundantly expressed by the oncogenic Herpesvirus saimiri, functions as a master regulator of host gene expression. HSUR1 interacts with hundreds of cellular messenger RNAs (mRNAs) that encode factors involved in RNA metabolism, immune cell differentiation, and apoptosis, thereby rewiring the host transcriptome to control both cell survival and fate. Mechanistically, we show that HSUR1 acts as an RNA adaptor that coordinates the recruitment of the host microRNA miR-142-3p and AU-rich element–binding proteins to target mRNA 3′ untranslated regions, redirecting post-transcriptional regulation. These findings reveal that a single viral ncRNA can orchestrate global remodeling of host gene expression, uncovering an RNA-based strategy for viral control of cell identity and function. Graphical Abstract Graphical AbstractFor image description, please refer to the figure legend and surrounding text.
Proof-of-Concept Evaluation of Primary Human FAP-CAR-NK Cells Targeting Activated Fibroblasts in Pulmonary Fibrosis G. Wu et al. International Journal of Molecular Sciences 2026 May

Abstract

In recent years, the feasibility of immunotherapy targeting activated fibroblasts in pulmonary fibrosis has received further support. Recent studies have shown that transient FAP-targeted immunotherapy can alleviate pulmonary fibrosis by eliminating excessively activated fibroblasts, improving the aberrant extracellular matrix environment, and promoting alveolar cell lineage remodeling, suggesting that FAP-associated pathological stromal cells are amenable to therapeutic intervention. Based on this, research on FAP-centered engineered cell therapies is being gradually extended from settings such as myocardial fibrosis to pulmonary fibrosis. In this context, primary human NK cells represent a promising effector cell platform, as they are generally associated with a lower risk of severe treatment-related toxicities and relatively limited in vivo persistence, which may confer a more controllable therapeutic window. This feature is particularly important in fibrotic diseases, because long-term and continuous depletion of fibroblast populations may disrupt tissue homeostasis and injury repair. In addition, current studies of FAP-targeted CAR-NK therapy have mainly relied on NK cell lines such as NK-92, but these systems may not fully reflect the functional characteristics, receptor signaling, or clinical potential of primary human NK cells. Based on these considerations, it is necessary to develop a FAP-targeted cell therapy platform with greater clinical relevance for pulmonary fibrosis. In this study, we established a primary human FAP-CAR-NK-cell platform and conducted a proof-of-concept evaluation in pulmonary fibrosis-related models, including in vitro systems, a human pulmonary fibrosis-like organoid model, and an acute in vivo observation model. The main novelty of this study lies in the use of primary human NK cells for FAP-targeted intervention in pulmonary fibrosis-related models. We focused on whether these engineered cells could selectively target and eliminate FAP-positive activated fibroblasts, retain effector function in a fibrotic microenvironment, and show short-term feasibility after adoptive transfer. The study was not intended to assess long-term therapeutic efficacy or systemic safety, but rather to examine the feasibility of FAP-directed fibroblast targeting by primary human CAR-NK cells in pulmonary fibrosis and to provide a basis for further preclinical investigation.
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.