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cell suspensions  (MedChemExpress)


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    MedChemExpress cell suspensions
    Cell Suspensions, supplied by MedChemExpress, used in various techniques. Bioz Stars score: 97/100, based on 935 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/cell suspensions/product/MedChemExpress
    Average 97 stars, based on 935 article reviews
    cell suspensions - by Bioz Stars, 2026-05
    97/100 stars

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    k562 suspension cells  (ATCC)
    99
    ATCC k562 suspension cells
    ( A ) Working principle of STAT. (i) Two orthogonal standing SAW fields with slightly detuned frequencies, ω x and ω y , pattern PACPs (red) and NACPs (blue) in distinct pressure regions; inset: photo of the STAT chip. (ii) Pressure-field evolution over one detuning cycle (0 to 2π/Δω), showing dynamic shifts of pressure nodes and antinodes induced by the frequency difference Δω. (iii) Schematic of the dynamic, static, and drag forces acting on PACPs and NACPs. ( B ) (i) High-throughput, low-frequency, shear-like oscillation of PACPs under the dynamic force field distribution. (ii) Time-lapse images over one oscillation cycle with 10-μm polystyrene beads in water. ( C ) (i) High-throughput, low-frequency, longitudinal-like oscillation of NACPs within patterned PACPs. Time-lapse images over one oscillation cycle with PDMS clusters within an arrayed pattern of 10 μm polystyrene beads. (ii) Experimental demonstration of selective navigation of a PDMS cluster through a locally stationary polystyrene-bead lattice. ( D ) Schematics and experiments showing that STAT enables (i) gentle oscillation of biological cells and (ii) controllable transport of NACPs while maintaining cells in a patterned lattice. In (B) to (D), the polystyrene beads, PDMS clusters, and <t>K562</t> cells are highlighted in red, blue, and light green, respectively. Oscillation was captured at ω x /2π = 20.094 MHz and ω y /2π = 20.094 MHz − 1 Hz, corresponding to Δω = 1 × 2π Hz, when P x > P y . In (C) and (D), black and green arrows represent transport and oscillation directions, respectively. Scale bars, 45 μm.
    K562 Suspension Cells, supplied by ATCC, used in various techniques. Bioz Stars score: 99/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/k562 suspension cells/product/ATCC
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    recombinant rbd protein production suspension hek293f cells  (CLS Cell Lines Service GmbH)
    94
    CLS Cell Lines Service GmbH recombinant rbd protein production suspension hek293f cells
    ( A ) Working principle of STAT. (i) Two orthogonal standing SAW fields with slightly detuned frequencies, ω x and ω y , pattern PACPs (red) and NACPs (blue) in distinct pressure regions; inset: photo of the STAT chip. (ii) Pressure-field evolution over one detuning cycle (0 to 2π/Δω), showing dynamic shifts of pressure nodes and antinodes induced by the frequency difference Δω. (iii) Schematic of the dynamic, static, and drag forces acting on PACPs and NACPs. ( B ) (i) High-throughput, low-frequency, shear-like oscillation of PACPs under the dynamic force field distribution. (ii) Time-lapse images over one oscillation cycle with 10-μm polystyrene beads in water. ( C ) (i) High-throughput, low-frequency, longitudinal-like oscillation of NACPs within patterned PACPs. Time-lapse images over one oscillation cycle with PDMS clusters within an arrayed pattern of 10 μm polystyrene beads. (ii) Experimental demonstration of selective navigation of a PDMS cluster through a locally stationary polystyrene-bead lattice. ( D ) Schematics and experiments showing that STAT enables (i) gentle oscillation of biological cells and (ii) controllable transport of NACPs while maintaining cells in a patterned lattice. In (B) to (D), the polystyrene beads, PDMS clusters, and <t>K562</t> cells are highlighted in red, blue, and light green, respectively. Oscillation was captured at ω x /2π = 20.094 MHz and ω y /2π = 20.094 MHz − 1 Hz, corresponding to Δω = 1 × 2π Hz, when P x > P y . In (C) and (D), black and green arrows represent transport and oscillation directions, respectively. Scale bars, 45 μm.
    Recombinant Rbd Protein Production Suspension Hek293f Cells, supplied by CLS Cell Lines Service GmbH, used in various techniques. Bioz Stars score: 94/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/recombinant rbd protein production suspension hek293f cells/product/CLS Cell Lines Service GmbH
    Average 94 stars, based on 1 article reviews
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    cell suspensions  (Qiagen)
    92
    Qiagen cell suspensions
    ( A ) Working principle of STAT. (i) Two orthogonal standing SAW fields with slightly detuned frequencies, ω x and ω y , pattern PACPs (red) and NACPs (blue) in distinct pressure regions; inset: photo of the STAT chip. (ii) Pressure-field evolution over one detuning cycle (0 to 2π/Δω), showing dynamic shifts of pressure nodes and antinodes induced by the frequency difference Δω. (iii) Schematic of the dynamic, static, and drag forces acting on PACPs and NACPs. ( B ) (i) High-throughput, low-frequency, shear-like oscillation of PACPs under the dynamic force field distribution. (ii) Time-lapse images over one oscillation cycle with 10-μm polystyrene beads in water. ( C ) (i) High-throughput, low-frequency, longitudinal-like oscillation of NACPs within patterned PACPs. Time-lapse images over one oscillation cycle with PDMS clusters within an arrayed pattern of 10 μm polystyrene beads. (ii) Experimental demonstration of selective navigation of a PDMS cluster through a locally stationary polystyrene-bead lattice. ( D ) Schematics and experiments showing that STAT enables (i) gentle oscillation of biological cells and (ii) controllable transport of NACPs while maintaining cells in a patterned lattice. In (B) to (D), the polystyrene beads, PDMS clusters, and <t>K562</t> cells are highlighted in red, blue, and light green, respectively. Oscillation was captured at ω x /2π = 20.094 MHz and ω y /2π = 20.094 MHz − 1 Hz, corresponding to Δω = 1 × 2π Hz, when P x > P y . In (C) and (D), black and green arrows represent transport and oscillation directions, respectively. Scale bars, 45 μm.
    Cell Suspensions, supplied by Qiagen, used in various techniques. Bioz Stars score: 92/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/cell suspensions/product/Qiagen
    Average 92 stars, based on 1 article reviews
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    cell suspension buffer  (Bio-Rad)
    98
    Bio-Rad cell suspension buffer
    ( A ) Working principle of STAT. (i) Two orthogonal standing SAW fields with slightly detuned frequencies, ω x and ω y , pattern PACPs (red) and NACPs (blue) in distinct pressure regions; inset: photo of the STAT chip. (ii) Pressure-field evolution over one detuning cycle (0 to 2π/Δω), showing dynamic shifts of pressure nodes and antinodes induced by the frequency difference Δω. (iii) Schematic of the dynamic, static, and drag forces acting on PACPs and NACPs. ( B ) (i) High-throughput, low-frequency, shear-like oscillation of PACPs under the dynamic force field distribution. (ii) Time-lapse images over one oscillation cycle with 10-μm polystyrene beads in water. ( C ) (i) High-throughput, low-frequency, longitudinal-like oscillation of NACPs within patterned PACPs. Time-lapse images over one oscillation cycle with PDMS clusters within an arrayed pattern of 10 μm polystyrene beads. (ii) Experimental demonstration of selective navigation of a PDMS cluster through a locally stationary polystyrene-bead lattice. ( D ) Schematics and experiments showing that STAT enables (i) gentle oscillation of biological cells and (ii) controllable transport of NACPs while maintaining cells in a patterned lattice. In (B) to (D), the polystyrene beads, PDMS clusters, and <t>K562</t> cells are highlighted in red, blue, and light green, respectively. Oscillation was captured at ω x /2π = 20.094 MHz and ω y /2π = 20.094 MHz − 1 Hz, corresponding to Δω = 1 × 2π Hz, when P x > P y . In (C) and (D), black and green arrows represent transport and oscillation directions, respectively. Scale bars, 45 μm.
    Cell Suspension Buffer, supplied by Bio-Rad, used in various techniques. Bioz Stars score: 98/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/cell suspension buffer/product/Bio-Rad
    Average 98 stars, based on 1 article reviews
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    cell suspensions  (MedChemExpress)
    97
    MedChemExpress cell suspensions
    ( A ) Working principle of STAT. (i) Two orthogonal standing SAW fields with slightly detuned frequencies, ω x and ω y , pattern PACPs (red) and NACPs (blue) in distinct pressure regions; inset: photo of the STAT chip. (ii) Pressure-field evolution over one detuning cycle (0 to 2π/Δω), showing dynamic shifts of pressure nodes and antinodes induced by the frequency difference Δω. (iii) Schematic of the dynamic, static, and drag forces acting on PACPs and NACPs. ( B ) (i) High-throughput, low-frequency, shear-like oscillation of PACPs under the dynamic force field distribution. (ii) Time-lapse images over one oscillation cycle with 10-μm polystyrene beads in water. ( C ) (i) High-throughput, low-frequency, longitudinal-like oscillation of NACPs within patterned PACPs. Time-lapse images over one oscillation cycle with PDMS clusters within an arrayed pattern of 10 μm polystyrene beads. (ii) Experimental demonstration of selective navigation of a PDMS cluster through a locally stationary polystyrene-bead lattice. ( D ) Schematics and experiments showing that STAT enables (i) gentle oscillation of biological cells and (ii) controllable transport of NACPs while maintaining cells in a patterned lattice. In (B) to (D), the polystyrene beads, PDMS clusters, and <t>K562</t> cells are highlighted in red, blue, and light green, respectively. Oscillation was captured at ω x /2π = 20.094 MHz and ω y /2π = 20.094 MHz − 1 Hz, corresponding to Δω = 1 × 2π Hz, when P x > P y . In (C) and (D), black and green arrows represent transport and oscillation directions, respectively. Scale bars, 45 μm.
    Cell Suspensions, supplied by MedChemExpress, used in various techniques. Bioz Stars score: 97/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/cell suspensions/product/MedChemExpress
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    cell suspensions - by Bioz Stars, 2026-05
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    cell suspension  (Elabscience Biotechnology)
    94
    Elabscience Biotechnology cell suspension
    ( A ) Working principle of STAT. (i) Two orthogonal standing SAW fields with slightly detuned frequencies, ω x and ω y , pattern PACPs (red) and NACPs (blue) in distinct pressure regions; inset: photo of the STAT chip. (ii) Pressure-field evolution over one detuning cycle (0 to 2π/Δω), showing dynamic shifts of pressure nodes and antinodes induced by the frequency difference Δω. (iii) Schematic of the dynamic, static, and drag forces acting on PACPs and NACPs. ( B ) (i) High-throughput, low-frequency, shear-like oscillation of PACPs under the dynamic force field distribution. (ii) Time-lapse images over one oscillation cycle with 10-μm polystyrene beads in water. ( C ) (i) High-throughput, low-frequency, longitudinal-like oscillation of NACPs within patterned PACPs. Time-lapse images over one oscillation cycle with PDMS clusters within an arrayed pattern of 10 μm polystyrene beads. (ii) Experimental demonstration of selective navigation of a PDMS cluster through a locally stationary polystyrene-bead lattice. ( D ) Schematics and experiments showing that STAT enables (i) gentle oscillation of biological cells and (ii) controllable transport of NACPs while maintaining cells in a patterned lattice. In (B) to (D), the polystyrene beads, PDMS clusters, and <t>K562</t> cells are highlighted in red, blue, and light green, respectively. Oscillation was captured at ω x /2π = 20.094 MHz and ω y /2π = 20.094 MHz − 1 Hz, corresponding to Δω = 1 × 2π Hz, when P x > P y . In (C) and (D), black and green arrows represent transport and oscillation directions, respectively. Scale bars, 45 μm.
    Cell Suspension, supplied by Elabscience Biotechnology, used in various techniques. Bioz Stars score: 94/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/cell suspension/product/Elabscience Biotechnology
    Average 94 stars, based on 1 article reviews
    cell suspension - by Bioz Stars, 2026-05
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    Image Search Results


    ( A ) Working principle of STAT. (i) Two orthogonal standing SAW fields with slightly detuned frequencies, ω x and ω y , pattern PACPs (red) and NACPs (blue) in distinct pressure regions; inset: photo of the STAT chip. (ii) Pressure-field evolution over one detuning cycle (0 to 2π/Δω), showing dynamic shifts of pressure nodes and antinodes induced by the frequency difference Δω. (iii) Schematic of the dynamic, static, and drag forces acting on PACPs and NACPs. ( B ) (i) High-throughput, low-frequency, shear-like oscillation of PACPs under the dynamic force field distribution. (ii) Time-lapse images over one oscillation cycle with 10-μm polystyrene beads in water. ( C ) (i) High-throughput, low-frequency, longitudinal-like oscillation of NACPs within patterned PACPs. Time-lapse images over one oscillation cycle with PDMS clusters within an arrayed pattern of 10 μm polystyrene beads. (ii) Experimental demonstration of selective navigation of a PDMS cluster through a locally stationary polystyrene-bead lattice. ( D ) Schematics and experiments showing that STAT enables (i) gentle oscillation of biological cells and (ii) controllable transport of NACPs while maintaining cells in a patterned lattice. In (B) to (D), the polystyrene beads, PDMS clusters, and K562 cells are highlighted in red, blue, and light green, respectively. Oscillation was captured at ω x /2π = 20.094 MHz and ω y /2π = 20.094 MHz − 1 Hz, corresponding to Δω = 1 × 2π Hz, when P x > P y . In (C) and (D), black and green arrows represent transport and oscillation directions, respectively. Scale bars, 45 μm.

    Journal: Science Advances

    Article Title: Space-time acoustofluidic tweezers for dynamic and selective manipulation of microparticles

    doi: 10.1126/sciadv.aee2983

    Figure Lengend Snippet: ( A ) Working principle of STAT. (i) Two orthogonal standing SAW fields with slightly detuned frequencies, ω x and ω y , pattern PACPs (red) and NACPs (blue) in distinct pressure regions; inset: photo of the STAT chip. (ii) Pressure-field evolution over one detuning cycle (0 to 2π/Δω), showing dynamic shifts of pressure nodes and antinodes induced by the frequency difference Δω. (iii) Schematic of the dynamic, static, and drag forces acting on PACPs and NACPs. ( B ) (i) High-throughput, low-frequency, shear-like oscillation of PACPs under the dynamic force field distribution. (ii) Time-lapse images over one oscillation cycle with 10-μm polystyrene beads in water. ( C ) (i) High-throughput, low-frequency, longitudinal-like oscillation of NACPs within patterned PACPs. Time-lapse images over one oscillation cycle with PDMS clusters within an arrayed pattern of 10 μm polystyrene beads. (ii) Experimental demonstration of selective navigation of a PDMS cluster through a locally stationary polystyrene-bead lattice. ( D ) Schematics and experiments showing that STAT enables (i) gentle oscillation of biological cells and (ii) controllable transport of NACPs while maintaining cells in a patterned lattice. In (B) to (D), the polystyrene beads, PDMS clusters, and K562 cells are highlighted in red, blue, and light green, respectively. Oscillation was captured at ω x /2π = 20.094 MHz and ω y /2π = 20.094 MHz − 1 Hz, corresponding to Δω = 1 × 2π Hz, when P x > P y . In (C) and (D), black and green arrows represent transport and oscillation directions, respectively. Scale bars, 45 μm.

    Article Snippet: K562 suspension cells and B16-F10 adherent melanoma cells were cultured in RPMI 1640 [American Type Culture Collection (ATCC), 30-2001] and Dulbecco’s modified Eagle’s medium (ATCC, 30-2002), respectively.

    Techniques: High Throughput Screening Assay, Shear, Gentle

    ( A ) Images of K562 cells, showing a half-cycle oscillation with ζ x and ζ y denoting oscillation displacements in x and y . ( B ) Measured cell oscillation displacements as functions of frequency detuning Δω. Green bars show ζ x , while blue bars indicate ζ y . ( C ) Measured cell oscillation displacements as functions of driving voltage amplitudes V x when V y = 11 V pp and V y when V x = 11 V pp . ( D ) Schematics illustrating how tuning Δ P and Δω controls the transport of a PDMS cluster between a lattice pattern of K562 cells, showing gentle oscillations around stable pressure nodes. ( E ) Time-elapse images of tuning Δω and Δ P to selectively manipulate a PDMS cluster through an effectively stationary K562 cell pattern.

    Journal: Science Advances

    Article Title: Space-time acoustofluidic tweezers for dynamic and selective manipulation of microparticles

    doi: 10.1126/sciadv.aee2983

    Figure Lengend Snippet: ( A ) Images of K562 cells, showing a half-cycle oscillation with ζ x and ζ y denoting oscillation displacements in x and y . ( B ) Measured cell oscillation displacements as functions of frequency detuning Δω. Green bars show ζ x , while blue bars indicate ζ y . ( C ) Measured cell oscillation displacements as functions of driving voltage amplitudes V x when V y = 11 V pp and V y when V x = 11 V pp . ( D ) Schematics illustrating how tuning Δ P and Δω controls the transport of a PDMS cluster between a lattice pattern of K562 cells, showing gentle oscillations around stable pressure nodes. ( E ) Time-elapse images of tuning Δω and Δ P to selectively manipulate a PDMS cluster through an effectively stationary K562 cell pattern.

    Article Snippet: K562 suspension cells and B16-F10 adherent melanoma cells were cultured in RPMI 1640 [American Type Culture Collection (ATCC), 30-2001] and Dulbecco’s modified Eagle’s medium (ATCC, 30-2002), respectively.

    Techniques: Gentle