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RosetteSep™人间充质干细胞富集抗体混合物

为血浆和密度梯度离心液的交界界面中高度富集的细胞。

产品号 #(选择产品)

产品号 #15128_C

为血浆和密度梯度离心液的交界界面中高度富集的细胞。

产品优势

  • 快捷、操作简单
  • 不需要特殊设备或额外培训
  • 获得的活细胞无标记

产品组分包括

  • RosetteSep™人间充质干细胞富集抗体混合物(产品号#15128)          
    • RosetteSep™人间充质干细胞富集抗体混合物,2mL
  • RosetteSep™人间充质干细胞富集抗体混合物(产品号#15168)          
    • RosetteSep™人间充质干细胞富集抗体混合物操作流程,5x2mL
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总览

RosetteSep™人间充质干细胞富集抗体混合物通过负选从新鲜骨髓分离间充质干细胞。四聚体抗体复合物可识别CD3、CD14、CD19、CD38、CD66b以及红细胞(RBC)上的糖蛋白A,从而靶向去除非目的细胞。使用密度梯度离心液如Lymphoprep™(产品号 #18060)离心后 ,非目的细胞会与红细胞一起沉淀。纯化的间充质干细胞为血浆和密度梯度离心液的交界界面中高度富集的细胞。

亚型
细胞分选试剂盒
 
细胞类型
间充质干/祖细胞
 
种属

 
样本来源
Bone Marrow
 
筛选方法
Negative
 
应用
细胞分选
 
品牌
RosetteSep
 
研究领域
干细胞生物学
 

产品说明书及文档

请在《产品说明书》中查找相关支持信息和使用说明,或浏览下方更多实验方案。

Document Type
Product Name
Catalog #
Lot #
Language
Catalog #
15168, 15128
Lot #
All
Language
English
Document Type
Safety Data Sheet
Catalog #
15168, 15128
Lot #
All
Language
English

应用领域

本产品专为以下研究领域设计,适用于工作流程中的高亮阶段。探索这些工作流程,了解更多我们为各研究领域提供的其他配套产品。

相关材料与文献

技术资料 (4)

常见问题

What is RosetteSep™?

RosetteSep™ is a rapid cell separation procedure for the isolation of purified cells directly from whole blood, without columns or magnets.

How does RosetteSep™ work?

The antibody cocktail crosslinks unwanted cells to red blood cells (RBCs), forming rosettes. The unwanted cells then pellet with the free RBCs when centrifuged over a density centrifugation medium (e.g. Ficoll-Paque™ PLUS, Lymphoprep™).

What factors affect cell recovery?

The temperature of the reagents can affect cell recovery. All reagents should be at room temperature (sample, density centrifugation medium, PBS, centrifuge) before performing the isolations. Layering can also affect recovery so be sure to carefully layer the sample to avoid mixing with the density centrifugation medium as much as possible. Be sure to collect the entire enriched culture without disturbing the RBC pellet. A small amount of density centrifugation medium can be collected without worry.

Which cell samples can RosetteSep™ be used with?

RosetteSep™ can be used with leukapheresis samples, bone marrow or buffy coat, as long as: the concentration of cells does not exceed 5 x 107 per mL (can dilute if necessary); and there are at least 100 RBCs for every nucleated cell (RBCs can be added if necessary).

Can RosetteSep™ be used with previously frozen or cultured cells?

Yes. Cells should be re-suspended at 2 - 5 x 107 cells / mL in PBS + 2% FBS. Fresh whole blood should be added at 250 µL per mL of sample, as a source of red cells.

Can RosetteSep™ be used to enrich progenitors from cord blood?

Yes. Sometimes cord blood contains immature nucleated red cells that have a lower density than mature RBCs. These immature red cells do not pellet over Ficoll™, which can lead to a higher RBC contamination than peripheral blood separations.

Does RosetteSep™ work with mouse cells?

No, but we have developed EasySep™, a magnetic-based cell isolation system which works with mouse and other non-human species.

Which anticoagulant should be used with RosetteSep™?

Peripheral blood should be collected in heparinized Vacutainers. Cord blood should be collected in ACD.

Should the anticoagulant be washed off before using RosetteSep™?

No, the antibody cocktail can be added directly to the sample.

文献 (8)

Auranofin Protects Intestine against Radiation Injury by Modulating p53/p21 Pathway and Radiosensitizes Human Colon Tumor. D. Nag et al. Clinical cancer research : an official journal of the American Association for Cancer Research 2019 aug

Abstract

PURPOSE The radiosensitivity of the normal intestinal epithelium is the major limiting factor for definitive radiotherapy against abdominal malignancies. Radiosensitizers, which can be used without augmenting radiation toxicity to normal tissue, are still an unmet need. Inhibition of proteosomal degradation is being developed as a major therapeutic strategy for anticancer therapy as cancer cells are more susceptible to proteasomal inhibition-induced cytotoxicity compared with normal cells. Auranofin, a gold-containing antirheumatoid drug, blocks proteosomal degradation by inhibiting deubiquitinase inhibitors. In this study, we have examined whether auranofin selectively radiosensitizes colon tumors without promoting radiation toxicity in normal intestine. EXPERIMENTAL DESIGN The effect of auranofin (10 mg/kg i.p.) on the radiation response of subcutaneous CT26 colon tumors and the normal gastrointestinal epithelium was determined using a mouse model of abdominal radiation. The effect of auranofin was also examined in a paired human colonic organoid system using malignant and nonmalignant tissues from the same patient. RESULTS Both in the mouse model of intestinal injury and in the human nonmalignant colon organoid culture, auranofin pretreatment prevented radiation toxicity and improved survival with the activation of p53/p21-mediated reversible cell-cycle arrest. However, in a mouse model of abdominal tumor and in human malignant colonic organoids, auranofin inhibited malignant tissue growth with inhibition of proteosomal degradation, induction of endoplasmic reticulum stress/unfolded protein response, and apoptosis. CONCLUSIONS Our data suggest that auranofin is a potential candidate to be considered as a combination therapy with radiation to improve therapeutic efficacy against abdominal malignancies.
New approach to isolate mesenchymal stem cell (MSC) from human umbilical cord blood. Hussain I et al. Cell biology international 2012 JUL

Abstract

HUCB (human umbilical cord blood) has been frequently used in clinical allogeneic HSC (haemopoietic stem cell) transplant. However, HUCB is poorly recognized as a rich source of MSC (mesenchymal stem cell). The aim of this study has been to establish a new method for isolating large number of MSC from HUCB to recognize it as a good source of MSC. HUCB samples were collected from women following their elective caesarean section. The new method (Clot Spot method) was carried out by explanting HUCB samples in mesencult complete medium and maintained in 37°C, in a 5% CO2 and air incubator. MSC presence was established by quantitative and qualitative immunophenotyping of cells and using FITC attached to MSC phenotypic markers (CD29, CD73, CD44 and CD105). Haematopoietic antibodies (CD34 and CD45) were used as negative control. MSC differentiation was examined in neurogenic and adipogenic media. Immunocytochemistry was carried out for the embryonic markers: SOX2 (sex determining region Y-box 2), OLIG-4 (oligodendrocyte-4) and FABP-4 (fatty acid binding protein-4). The new method was compared with the conventional Rosset Sep method. MSC cultures using the Clot Spot method showed 3-fold increase in proliferation rate compared with conventional method. Also, the cells showed high expression of MSC markers CD29, CD73, CD44 and CD105, but lacked the expression of specific HSC markers (CD34 and CD45). The isolated MSC showed some differentiation by expressing the neurogenic (SOX2 and Olig4) and adipogenic (FABP-4) markers respectively. In conclusion, HUCB is a good source of MSC using this new technique.
Gene expression analysis in osteoblastic differentiation from peripheral blood mesenchymal stem cells. Valenti MT et al. Bone 2008 DEC

Abstract

MSCs are known to have an extensive proliferative potential and ability to differentiate in various cell types. Osteoblastic differentiation from mesenchymal progenitor cells is an important step of bone formation, though the pattern of gene expression during differentiation is not yet well understood. Here, to investigate the possibility to obtain a model for in vitro bone differentiation using mesenchymal stem cells (hMSCs) from human subjects non-invasively, we developed a method to obtain hMSCs-like cells from peripheral blood by a two step method that included an enrichment of mononuclear cells followed by depletion of unwanted cells. Using these cells, we analyzed the expression of transcription factor genes (runt-related transcription factor 2 (RUNX2) and osterix (SP7)) and bone related genes (osteopontin (SPP1), osteonectin (SPARC) and collagen, type I, alpha 1 (COLIA1)) during osteoblastic differentiation. Our results demonstrated that hMSCs can be obtained from peripheral blood and that they are able to generate CFU-F and to differentiate in osteoblast and adipocyte; in this study, we also identified a possible gene expression timing during osteoblastic differentiation that provided a powerful tool to study bone physiology.

更多信息

更多信息
种属 Human
样本来源 Bone Marrow
Selection Method Negative
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