Differential arrest and adhesion of tumor cells and microbeads in the microvasculature

Peng Guo, Bin Cai, Ming Lei, Yang Liu, Bingmei M. Fu

Research output: Journal article publicationJournal articleAcademic researchpeer-review

23 Citations (Scopus)


To investigate the mechanical mechanisms behind tumor cell arrest in the microvasculature, we injected fluorescently labeled human breast carcinoma cells or similarly sized rigid beads into the systemic circulation of a rat. Their arrest patterns in the microvasculature of mesentery were recorded and quantified. We found that 93 % of rigid beads were arrested either at arteriolecapillary intersections or in capillaries. Only 3 % were at the capillary-postcapillary venule intersections and in postcapillary venules. In contrast, most of the flexible tumor cells were either entrapped in capillaries or arrested at capillary or postcapillary venule-postcapillary venule intersections and in postcapillary venules. Only 12 % of tumor cells were arrested at the arteriole-capillary intersections. The differential arrest and adhesion of tumor cells and microbeads in the microvasculature was confirmed by a χ<sup>2</sup> test (p < 0.001). These results demonstrate that mechanical trapping was responsible for almost all the arrest of beads and half the arrest of tumor cells. Based on the measured geometry and blood flow velocities at the intersections, we also performed a numerical simulation using commercial software (ANSYS CFX 12.01) to depict the detailed distribution profiles of the velocity, shear rate, and vorticity at the intersections where tumor cells preferred to arrest and adhere. Simulation results reveal the presence of localized vorticity and shear rate regions at the turning points of the microvessel intersections, implying that hemodynamic factors play an important role in tumor cell arrest in the microcirculation. Our study helps elucidate long-debated issues related to the dominant factors in earlystage tumor hematogenous metastasis.
Original languageEnglish
Pages (from-to)537-550
Number of pages14
JournalBiomechanics and Modeling in Mechanobiology
Issue number3
Publication statusPublished - 1 Jan 2014


  • Cell deformability
  • Hemodynamic factors
  • Mechanical trapping
  • Rat mesenteric microvasculature
  • Shear rate
  • Vorticity

ASJC Scopus subject areas

  • Biotechnology
  • Modelling and Simulation
  • Mechanical Engineering


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