• DocumentCode
    1525424
  • Title

    Kinematics of Specifically Captured Circulating Tumor Cells in Bio-Functionalized Microchannels

  • Author

    Cheung, Luthur Siu-Lun ; Zheng, Xiangjun ; Wang, Lian ; Guzman, Roberto ; Schroeder, Joyce A. ; Heimark, Ronald L. ; Baygents, James C. ; Zohar, Yitshak

  • Author_Institution
    Dept. of Aerosp. & Mech. Eng., Univ. of Arizona, Tucson, AZ, USA
  • Volume
    19
  • Issue
    4
  • fYear
    2010
  • Firstpage
    752
  • Lastpage
    763
  • Abstract
    The attachment kinematics of cancer cells under hydrodynamic loading in antibody-functionalized microchannels has been studied. Epithelial-cell-adhesion-molecule antibodies are immobilized on the microchannel surface for specific capture of the target cancer cells from homogeneous cell suspensions. The specific interaction between the cancer cell receptors and the immobilized antibodies under static conditions is demonstrated. The capture efficiency of the target cells from homogeneous suspensions under applied hydrodynamic flow field has been investigated, revealing a characteristic shear stress. Applying a lower stress allows the capture of most target cells, while the capture efficiency drops sharply with an increasing shear stress. The captured cells are spatially distributed along the microchannel; both the velocity and the distance travelled by cells prior to capture are measured. The characteristic time and length scales for cell capture are determined, and a log-normal statistical distribution is proposed to describe the observations. Furthermore, a first-order kinetic model for receptor-ligand bond formation provides a rough estimate of the cell adhesion rate constant. Under a low shear stress, the on-rate is much higher than the off-rate, allowing capture of most loaded cells. The off-rate constant increases exponentially with an increasing shear stress, such that above the characteristic stress level, most loaded cells avoid capture.
  • Keywords
    adhesion; bioMEMS; biological fluid dynamics; cancer; cellular biophysics; hydrodynamics; microchannel flow; physiological models; shear flow; statistical distributions; tumours; applied hydrodynamic flow; biofunctionalized microchannels; cancer cell receptors; capture efficiency; cell adhesion rate constant; characteristic shear stress; circulating tumor cells; epithelial-cell-adhesion-molecule antibodies; first-order kinetic model; hydrodynamic loading; log-normal statistical distribution; receptor-ligand bond formation; Bio-functional microchannels; cell-capture kinetics; circulating tumor cells (CTCs);
  • fLanguage
    English
  • Journal_Title
    Microelectromechanical Systems, Journal of
  • Publisher
    ieee
  • ISSN
    1057-7157
  • Type

    jour

  • DOI
    10.1109/JMEMS.2010.2052021
  • Filename
    5497059