• DocumentCode
    2090999
  • Title

    Simulation of Microcirculation in Solid Tumors

  • Author

    Wu, J. ; Xu, S.X. ; Long, Q. ; Collins, M.W. ; Koenig, C.S. ; Zhao, G.P. ; Jiang, Y.P. ; Padhani, A.R.

  • Author_Institution
    Fudan Univ., Shanghai
  • fYear
    2007
  • fDate
    23-27 May 2007
  • Firstpage
    1555
  • Lastpage
    1562
  • Abstract
    In this paper, a numerical method is developed to investigate the microcirculation in solid tumors based on the mathematical models of tumor angiogenesis and tumor microcirculation. The 2D9P (2-dimensional 9-point) model of tumor angiogenesis used in this paper is an improvement on the 2D5P (2-dimensional 5-point) one of Anderson and Chaplain. The model of tumor microcirculation provides the link between the microvasculature and interstitial space perfusion through a matrix describing the local vascular density, and accordingly couples the intravascular and interstitial flow by vascular leaky terms. The intravascular, transvascular and interstitial flow are governed by the flux conservation equation, Starling´s law and Darcy´s law, respectively; compliance of tumor vessels is specified by the empirical equation from Netti et al., and blood rheology follows the formula proposed by Pries et al. with an extension of distribution rules of haematocrit at branches on the basis of Fung´s conclusions. We simulate the flows numerically. The results not only present the basic features and characteristics of tumor microcirculation, consisting with the corresponding experimental observations reported, but also predict an intimate relationship between the tumor intravascular and interstitial flow, among which the vascular leakiness is one key factor to govern the systemic flowing pattern, influence the tumor internal environment and contribute to the metastasis of tumor cells.
  • Keywords
    blood vessels; cancer; cellular biophysics; haemorheology; physiological models; tumours; 2D9P model; Darcy law; Fung conclusions; Starling law; blood rheology; flux conservation equation; haematocrit; interstitial space perfusion; microvasculature space perfusion; solid tumors; systemic flowing pattern; tumor angiogenesis; tumor cell metastasis; tumor microcirculation; tumor vessels compliance; vascular density; vascular leakiness; Blood; Design engineering; Equations; Hospitals; Mathematical model; Neoplasms; Numerical simulation; Rheology; Solid modeling; Tumors;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Complex Medical Engineering, 2007. CME 2007. IEEE/ICME International Conference on
  • Conference_Location
    Beijing
  • Print_ISBN
    978-1-4244-1077-4
  • Electronic_ISBN
    978-1-4244-1078-1
  • Type

    conf

  • DOI
    10.1109/ICCME.2007.4382008
  • Filename
    4382008