Nonlinear Dynamics Modeling of Mechanical Periodicity of End Diastolic Volume of Left Ventricle

XU Shi-xiong; MAO Xiao-chun

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XU Shi-xiong, MAO Xiao-chun. Nonlinear Dynamics Modeling of Mechanical Periodicity of End Diastolic Volume of Left Ventricle[J]. Applied Mathematics and Mechanics, 2001, (10): 1067-1074.

Citation:

XU Shi-xiong, MAO Xiao-chun. Nonlinear Dynamics Modeling of Mechanical Periodicity of End Diastolic Volume of Left Ventricle[J]. Applied Mathematics and Mechanics, 2001, (10): 1067-1074.

Citation:

XU Shi-xiong, MAO Xiao-chun. Nonlinear Dynamics Modeling of Mechanical Periodicity of End Diastolic Volume of Left Ventricle[J]. Applied Mathematics and Mechanics, 2001, (10): 1067-1074.

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Nonlinear Dynamics Modeling of Mechanical Periodicity of End Diastolic Volume of Left Ventricle

Mechanics and Engineering Science Department, Fudan University, Shanghai 200433, P R China

Received Date: 2000-10-16
Rev Recd Date: 2001-05-08
Publish Date: 2001-10-15

Abstract

Abstract

The cardiovascular system with a lumped parameter model is treated,in which the Starling model is used to simulate left ventricle and the four-element Burattini & Gnudi model is used in the description of arterial system.Moreover,the feedback action of arterial pressure on cardiac cycle is taken into account.The phenomenon of mechanical periodicity (MP) of end diastolic volume (EDV) of left ventricle is successfully simulated by solving a series of one-dimensional discrete nonlinear dynamical equations.The effects of cardiovascular parameters on MP is also discussed.
- left ventricle,
- end diastolic volume,
- mechanical periodicity,
- nonlinear dynamics

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References(30)

References

[1]	Goldberger A L.Is the normal heartbeat chaotic or homeostatic?[J].News Physical Sci,1991,6(2):87-91.
[2]	Gleason W L,Braunwald E.Studies on Slarling's law of the heart-Ⅳ relationship between left ventricular end-diastolic volume and stroke volume in man,with observation on the mechanism of pulsus alternans[J].Circulation,1962,25(5):841-848.
[3]	Noble E I,Nutter D O.The demonstration of alternating contractile state in pulsus alternans[J].J Clin Invest,1970,49(5):1166-1177.
[4]	Ritzenberg A L,Adam D R,Cohen R J.Period multiplying:evidence for nonlinear behavior of canine heart[J].Nature Lond,1984,307(5947):159-161.
[5]	Goldberger A L,Bhargara V,West B J.Nonlinear dynamics of the heartbeat-Ⅱ Subharmonic bifurcates of the cardiac interbeat internal in sinus mode disease[J].Physica,1985,17D(2):201-214.
[6]	Hada Y,Wolfe C,Craige E.Pulsus alternans determined by birentricular simultaneous time intervals[J].Circulation,1982,65(3):617-626.
[7]	Lee Y C,Sutton S J.Pulsus alternans:echocardiographic evidence of reduced venous return and alternating end-diastolic fiber length as causative factors[J].Chest,1981,80(6):756-759.
[8]	Cannon R O,Schenke W H,Bonow R O,et al.Left Ventricular pulsus alternans in patiens with hypertrophic cardiomyopathy and severe obstruction to left ventricular outflow[J].Circulation,1986,73(2):276-285.
[9]	Cohn K E,Sandler H,Hancock E N.Mechanism of pulsus alternans[J].Circulation,1967,36(2):372-380.
[10]	Depace N L,Iskandrian A S,Hakki A H.Pulsus alternans after valve replacement for aortic regurgitation[J].Am J Cardial,1983,52(2):211-213.
[11]	Hess O M,Surber E P,Ritter M,et al.Pulsus alternans:its influence on systolic and diastolic function in aortic valve disease[J].J Am Coll Cardiol,1984,4(1):1-7.
[12]	Guntheroth W G.Pulsus alternans[J].Circulation,1982,66(2):479-480.
[13]	Laskey W K,John Sutton M S,Unterker W J,et al.Mechanics of Pulsus alternans in aortic valve stenosis[J].Am J Cardiol,1983,52(7):809-812.
[14]	McGaugher M D,Maughan W L,Sunagawa K,et al.Alternating contractility in Pulsus alternans studied in the isolated canice heart[J].Circulation,1985,71(2):357-362.
[15]	Adler D,Wong A Y K,Klassen G A.Model of calcium movements in the mammalian myocardium,interval-strength relationship[J].J Theor Biol,1985,113(3):379-394.
[16]	Adler D,Wong A Y K,Mahler Y.Model of mechanical alternans in the mammalian myocardium[J].J Theor Biol,1985,117(4):563-577.
[17]	Winfree A T.The Geometry of Biological Time[M].New York:Springer-Verlag,1980.
[18]	Winfree A T.The Timing of Biological Clock[M].New York:Freeman,1987.
[19]	Othmer H G.Nonlinear Oscillations in Biology and Chemistry[M].Berlin:Springer-Verlag,1986.
[20]	Kanters Jorgen K,Hojgaare Michael V,Agner Erik,et al.Short and long term variations in nonlinear dynamics of heart rate variability[J].Cardiovascular Research,1996,31(2):400-409.
[21]	Vila J,Palacios F,Presedo J,et al.Time-frequency analysis of heart-rate variability[J].IEEE Engineering in Medicine and Biology,1997,16(5):119-126.
[22]	Ben-Haim Shlomo A,Frucher Gila,Hayam Gal,et al.Periodicity's of cardiac mechanics[J].Am J Physiol,1991,261(2):H424-H433.
[23]	Frucher Cila,Ben-Ham Shlomo.Stability analysis of one-dimensional systems applied to an isolate beating heart[J].J Theor Biol,1991,148(2):175-192.
[24]	Patterson H.The regulation of the heart beat[J].Am J Physiol,1914,48(2):465.
[25]	冯忠刚,吴望一,孙东宁.心血管系统体循环后负荷的集中参数模型[J].中国生物医学工程学报,1997,16(3):212-218.
[26]	Burattini,Gnudi.Computer identification of models for the arterial tree input impedance:comparison between two new simple models and first experimental results[J].Med Biol Eng Comput,1982,20(2):134-144.
[27]	Campell K B,Ringo J A,Neti C,et al.Informational analysis of left ventricle-systemic arterial interaction[J].Ann Biomed Eng,1984,12(3):209-231.
[28]	Stergiopulos Nikos,Westerhoff Berend E,Westerhoof Nico.Total arterial inertance as the fourth element of the Windkessel model[J].Am J Physiol,1999,276(1):H81-H88.
[29]	Kroner P I,Show M J,Other J B.Steady-state properties of barorecepto-heart rate reflex in essential hypertension in man[J].Clin Exp Pharamacol Physiol,1974,1(1):65-76.
[30]	Westerhoof N,Elginga G,Sipkema I.An artificial arterial system for pumping hearts[J].J Appl Physiol,1971,31(5):776-781.