• DocumentCode
    2819246
  • Title

    Computational method to model flow through the mitral valve and early diastolic filling of the left ventricle

  • Author

    Hunt, A.C.

  • Author_Institution
    Musgrove Park Hosp., Taunton, UK
  • fYear
    2000
  • fDate
    2000
  • Firstpage
    223
  • Lastpage
    226
  • Abstract
    This model uses a finite difference Euler equation to recursively calculate the axial midline mitral outlet flow velocity (mfv) from given atrio-ventricular pressure gradients (avpgs). Published data of canine in-vivo avpgs and their mfvs applied to the computer algorithm enabled successful validation. The model simulated 16 early mfvs generated by avpgs produced by different combinations of atrial and left ventricular (lv) loading. The algorithm generated mvf profiles showed the same changes in configuration as observed in in-vivo load altering mfv studies. Index PolyT, derived from a 5th order polynomial in time representing mfvs, showed a 0.99 correlation with the time contstant of IV active relaxation (talc). For taus of 20 and 55 ms, the mean PolyTs were 19.2(SD=0.78)(Cl=18.7-19.7) ms and 54.5 (SD=3.8/(CI=51.8-57.7) ms respectively
  • Keywords
    cardiology; finite difference methods; haemodynamics; physiological models; polynomials; 20 ms; 55 ms; 5th order polynomial; active relaxation; atrioventricular pressure gradients; axial midline mitral outlet flow velocity; canine in-vivo pressure gradients; finite difference Euler equation; haemodynamic modelling; recursive calculation; Acceleration; Computational modeling; Difference equations; Filling; Finite difference methods; Fluid dynamics; Hospitals; Polynomials; Valves; Volume relaxation;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Computers in Cardiology 2000
  • Conference_Location
    Cambridge, MA
  • ISSN
    0276-6547
  • Print_ISBN
    0-7803-6557-7
  • Type

    conf

  • DOI
    10.1109/CIC.2000.898497
  • Filename
    898497