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polyclonal mouse anti cd166 antibody  (R&D Systems)


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    R&D Systems polyclonal mouse anti cd166 antibody
    CSCs sorting process. A . Flow cytometry was used to detect CD133 + , <t>CD166</t> + , and CD133 + /CD166 + CSCs populations within mixed cells, with the R2 gate serving as the target cell population. B . Sorting of CSCs from three tissue classes using the cartridge of the MACSQuant Tyto system, with the cartridge and microchip on the left and cell sorting through the microchip on the right. C . Real-time visualization of CSCs obtained by FlowSight imaging flow cytometer. Bright field and cell fluorescence image are presented, with Ch01: light field, Ch03: CD133-PE, and Ch11: CD166-BV421; scale bar = 20 μm. Flow cytometric analysis was performed on the sorted negative cells
    Polyclonal Mouse Anti Cd166 Antibody, supplied by R&D Systems, used in various techniques. Bioz Stars score: 93/100, based on 39 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/polyclonal mouse anti cd166 antibody/product/R&D Systems
    Average 93 stars, based on 39 article reviews
    polyclonal mouse anti cd166 antibody - by Bioz Stars, 2026-03
    93/100 stars

    Images

    1) Product Images from "Comparison of functional characterization of cancer stem cells in different tumor tissues of pseudomyxoma peritonei"

    Article Title: Comparison of functional characterization of cancer stem cells in different tumor tissues of pseudomyxoma peritonei

    Journal: Journal of Translational Medicine

    doi: 10.1186/s12967-024-05730-6

    CSCs sorting process. A . Flow cytometry was used to detect CD133 + , CD166 + , and CD133 + /CD166 + CSCs populations within mixed cells, with the R2 gate serving as the target cell population. B . Sorting of CSCs from three tissue classes using the cartridge of the MACSQuant Tyto system, with the cartridge and microchip on the left and cell sorting through the microchip on the right. C . Real-time visualization of CSCs obtained by FlowSight imaging flow cytometer. Bright field and cell fluorescence image are presented, with Ch01: light field, Ch03: CD133-PE, and Ch11: CD166-BV421; scale bar = 20 μm. Flow cytometric analysis was performed on the sorted negative cells
    Figure Legend Snippet: CSCs sorting process. A . Flow cytometry was used to detect CD133 + , CD166 + , and CD133 + /CD166 + CSCs populations within mixed cells, with the R2 gate serving as the target cell population. B . Sorting of CSCs from three tissue classes using the cartridge of the MACSQuant Tyto system, with the cartridge and microchip on the left and cell sorting through the microchip on the right. C . Real-time visualization of CSCs obtained by FlowSight imaging flow cytometer. Bright field and cell fluorescence image are presented, with Ch01: light field, Ch03: CD133-PE, and Ch11: CD166-BV421; scale bar = 20 μm. Flow cytometric analysis was performed on the sorted negative cells

    Techniques Used: Flow Cytometry, MicroChIP Assay, FACS, Imaging, Fluorescence

    Cell culture and marker identification. A . Observation of cell growth using a light microscope revealed the morphology, size, and adherence of cells in the logarithmic growth phase, with a scale bar indicating 100 μm. B . Immunofluorescence staining was performed to detect markers. Nuclei are stained blue, CD133 + appears as green fluorescence, CD166 + appears as red fluorescence, and CD133 + /CD166 + appears as yellow fluorescence. Scale bar indicates 200 μm. C . Marker detection was also conducted using flow cytometry, where each colored point represents a cell. The target cell population is enclosed by a black box for clarity, with brighter colors indicating a higher cell density
    Figure Legend Snippet: Cell culture and marker identification. A . Observation of cell growth using a light microscope revealed the morphology, size, and adherence of cells in the logarithmic growth phase, with a scale bar indicating 100 μm. B . Immunofluorescence staining was performed to detect markers. Nuclei are stained blue, CD133 + appears as green fluorescence, CD166 + appears as red fluorescence, and CD133 + /CD166 + appears as yellow fluorescence. Scale bar indicates 200 μm. C . Marker detection was also conducted using flow cytometry, where each colored point represents a cell. The target cell population is enclosed by a black box for clarity, with brighter colors indicating a higher cell density

    Techniques Used: Cell Culture, Marker, Light Microscopy, Immunofluorescence, Staining, Fluorescence, Flow Cytometry



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    CSCs sorting process. A . Flow cytometry was used to detect CD133 + , <t>CD166</t> + , and CD133 + /CD166 + CSCs populations within mixed cells, with the R2 gate serving as the target cell population. B . Sorting of CSCs from three tissue classes using the cartridge of the MACSQuant Tyto system, with the cartridge and microchip on the left and cell sorting through the microchip on the right. C . Real-time visualization of CSCs obtained by FlowSight imaging flow cytometer. Bright field and cell fluorescence image are presented, with Ch01: light field, Ch03: CD133-PE, and Ch11: CD166-BV421; scale bar = 20 μm. Flow cytometric analysis was performed on the sorted negative cells
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    CSCs sorting process. A . Flow cytometry was used to detect CD133 + , <t>CD166</t> + , and CD133 + /CD166 + CSCs populations within mixed cells, with the R2 gate serving as the target cell population. B . Sorting of CSCs from three tissue classes using the cartridge of the MACSQuant Tyto system, with the cartridge and microchip on the left and cell sorting through the microchip on the right. C . Real-time visualization of CSCs obtained by FlowSight imaging flow cytometer. Bright field and cell fluorescence image are presented, with Ch01: light field, Ch03: CD133-PE, and Ch11: CD166-BV421; scale bar = 20 μm. Flow cytometric analysis was performed on the sorted negative cells
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    Image Search Results


    Hepatocyte apical domains appear abnormal and expanded in sav1−/− larvae. (A-B‴) Examples of wild-type (A) and sav1−/− (B-B‴) 8 dpf larvae whole-mount immunostaining for Alcam. n=5 wild type, n=6 sav1−/−. Scale bar: 100 μm. (C,D) Single plane images of intrahepatic biliary ducts stained for annexin A4 in wild-type and sav1−/− 8 dpf larvae respectively. Red arrow in C indicates one annexin A4+ biliary epithelial cell. (C′,D′) Single plane images of aPKC staining in wild-type and sav1−/− 8 dpf larvae, respectively. Yellow arrow in C′ indicates one canaliculus. (C″,D″) Merged images with green representing aPKC and magenta representing annexin A4. Scale bar: 25 μm. (E-F″) Examples of wild-type and sav1−/− gallbladder stained for aPKC and annexin A4, following the same labeling conventions as in C-D″. (G,G′) Z-projections of whole-mount staining for annexin A4 and aPKC in wild-type larvae at 8 dpf. Scale bar: 25 μm. (H,H′,I,I′,J,J′) Z-projections of whole-mount staining for annexin A4 and aPKC in sav1−/− larvae at 8 dpf. (G″,H″,I″,J″) Merged images with green representing aPKC and magenta representing annexin A4 (n=7 wild type; n=5 sav1−/−). Scale bar: 100 μm. (K-K″) Z-projections of whole-mount staining for annexin A4 and Cdh2 in wild-type larvae at 8 dpf. (L,L′,M,M′,N,N′) Z-projections of whole-mount staining for annexin A4 and Cdh2 in sav1−/− larvae at 8 dpf. Yellow arrowheads in N′ indicate examples of high intensity cytoplasmic punctate Cdh2 staining, suggesting cadherin junction collapse. (L″,M″,N″) Merged images of Cdh2 (green) and annexin A4 (magenta) (n=7 wild type; n=6 sav1−/−). Scale bar: 100 μm.

    Journal: Development (Cambridge, England)

    Article Title: Core Hippo pathway components act as a brake on Yap and Taz in the development and maintenance of the biliary network

    doi: 10.1242/dev.184242

    Figure Lengend Snippet: Hepatocyte apical domains appear abnormal and expanded in sav1−/− larvae. (A-B‴) Examples of wild-type (A) and sav1−/− (B-B‴) 8 dpf larvae whole-mount immunostaining for Alcam. n=5 wild type, n=6 sav1−/−. Scale bar: 100 μm. (C,D) Single plane images of intrahepatic biliary ducts stained for annexin A4 in wild-type and sav1−/− 8 dpf larvae respectively. Red arrow in C indicates one annexin A4+ biliary epithelial cell. (C′,D′) Single plane images of aPKC staining in wild-type and sav1−/− 8 dpf larvae, respectively. Yellow arrow in C′ indicates one canaliculus. (C″,D″) Merged images with green representing aPKC and magenta representing annexin A4. Scale bar: 25 μm. (E-F″) Examples of wild-type and sav1−/− gallbladder stained for aPKC and annexin A4, following the same labeling conventions as in C-D″. (G,G′) Z-projections of whole-mount staining for annexin A4 and aPKC in wild-type larvae at 8 dpf. Scale bar: 25 μm. (H,H′,I,I′,J,J′) Z-projections of whole-mount staining for annexin A4 and aPKC in sav1−/− larvae at 8 dpf. (G″,H″,I″,J″) Merged images with green representing aPKC and magenta representing annexin A4 (n=7 wild type; n=5 sav1−/−). Scale bar: 100 μm. (K-K″) Z-projections of whole-mount staining for annexin A4 and Cdh2 in wild-type larvae at 8 dpf. (L,L′,M,M′,N,N′) Z-projections of whole-mount staining for annexin A4 and Cdh2 in sav1−/− larvae at 8 dpf. Yellow arrowheads in N′ indicate examples of high intensity cytoplasmic punctate Cdh2 staining, suggesting cadherin junction collapse. (L″,M″,N″) Merged images of Cdh2 (green) and annexin A4 (magenta) (n=7 wild type; n=6 sav1−/−). Scale bar: 100 μm.

    Article Snippet: The following primary antibodies and concentrations were used: 1:200 dilution rabbit monoclonal Yap (ab81183, Abcam), 1:200 dilution rabbit monoclonal Yap and Taz (D24E4, Cell Signaling, 8418), 1:500 dilution rabbit monoclonal GFP ( {"type":"entrez-nucleotide","attrs":{"text":"G10362","term_id":"942211","term_text":"G10362"}} G10362 , ABfinity), 1:100 dilution mouse polyclonal Alcam (zn-8, DSHB), 1:200 dilution mouse monoclonal AnnexinA4/2F11 [ab71286, Zebrafish Gut Secretory Cell Epitope (FIS2F11/2)], 1:500 dilution rabbit polyclonal aPKC λ and ξ (C-20 and sc-216, Santa Cruz Biotech), 1:200 dilution rabbit polyclonal Cdh2 (GTX125962, GeneTex) and 1:500 dilution rabbit polyclonal Prox1 (AB5475, EMD Millipore).

    Techniques: Immunostaining, Staining, Labeling

    CSCs sorting process. A . Flow cytometry was used to detect CD133 + , CD166 + , and CD133 + /CD166 + CSCs populations within mixed cells, with the R2 gate serving as the target cell population. B . Sorting of CSCs from three tissue classes using the cartridge of the MACSQuant Tyto system, with the cartridge and microchip on the left and cell sorting through the microchip on the right. C . Real-time visualization of CSCs obtained by FlowSight imaging flow cytometer. Bright field and cell fluorescence image are presented, with Ch01: light field, Ch03: CD133-PE, and Ch11: CD166-BV421; scale bar = 20 μm. Flow cytometric analysis was performed on the sorted negative cells

    Journal: Journal of Translational Medicine

    Article Title: Comparison of functional characterization of cancer stem cells in different tumor tissues of pseudomyxoma peritonei

    doi: 10.1186/s12967-024-05730-6

    Figure Lengend Snippet: CSCs sorting process. A . Flow cytometry was used to detect CD133 + , CD166 + , and CD133 + /CD166 + CSCs populations within mixed cells, with the R2 gate serving as the target cell population. B . Sorting of CSCs from three tissue classes using the cartridge of the MACSQuant Tyto system, with the cartridge and microchip on the left and cell sorting through the microchip on the right. C . Real-time visualization of CSCs obtained by FlowSight imaging flow cytometer. Bright field and cell fluorescence image are presented, with Ch01: light field, Ch03: CD133-PE, and Ch11: CD166-BV421; scale bar = 20 μm. Flow cytometric analysis was performed on the sorted negative cells

    Article Snippet: To identify the CSC population by immunofluorescence staining, a polyclonal rabbit anti-CD133 antibody (1:200, Cat. #SAB5701045, Sigma-Aldrich, St. Louis, Missouri, USA) and polyclonal mouse anti-CD166 antibody (1:50, Cat. #AF1172, R&D Systems, Minneapolis, Minnesota, USA), were employed.

    Techniques: Flow Cytometry, MicroChIP Assay, FACS, Imaging, Fluorescence

    Cell culture and marker identification. A . Observation of cell growth using a light microscope revealed the morphology, size, and adherence of cells in the logarithmic growth phase, with a scale bar indicating 100 μm. B . Immunofluorescence staining was performed to detect markers. Nuclei are stained blue, CD133 + appears as green fluorescence, CD166 + appears as red fluorescence, and CD133 + /CD166 + appears as yellow fluorescence. Scale bar indicates 200 μm. C . Marker detection was also conducted using flow cytometry, where each colored point represents a cell. The target cell population is enclosed by a black box for clarity, with brighter colors indicating a higher cell density

    Journal: Journal of Translational Medicine

    Article Title: Comparison of functional characterization of cancer stem cells in different tumor tissues of pseudomyxoma peritonei

    doi: 10.1186/s12967-024-05730-6

    Figure Lengend Snippet: Cell culture and marker identification. A . Observation of cell growth using a light microscope revealed the morphology, size, and adherence of cells in the logarithmic growth phase, with a scale bar indicating 100 μm. B . Immunofluorescence staining was performed to detect markers. Nuclei are stained blue, CD133 + appears as green fluorescence, CD166 + appears as red fluorescence, and CD133 + /CD166 + appears as yellow fluorescence. Scale bar indicates 200 μm. C . Marker detection was also conducted using flow cytometry, where each colored point represents a cell. The target cell population is enclosed by a black box for clarity, with brighter colors indicating a higher cell density

    Article Snippet: To identify the CSC population by immunofluorescence staining, a polyclonal rabbit anti-CD133 antibody (1:200, Cat. #SAB5701045, Sigma-Aldrich, St. Louis, Missouri, USA) and polyclonal mouse anti-CD166 antibody (1:50, Cat. #AF1172, R&D Systems, Minneapolis, Minnesota, USA), were employed.

    Techniques: Cell Culture, Marker, Light Microscopy, Immunofluorescence, Staining, Fluorescence, Flow Cytometry