Vascular resistance at low frequencies may explain the physiological role of Mayer waves: A fractal arterial tree model study

Author

Buchner, Teodor ; Sobiech, Tomasz

Author_Institution

Fac. of Phys., Warsaw Univ. of Technol., Warsaw, Poland

fYear

2014

fDate

25-28 May 2014

Firstpage

173

Lastpage

174

Abstract

We numerically investigate a 1-D mathematical model of blood flow related with harmonic blood pressure modes (BP) in the fractal model of a human arterial tree [1]. We calculated the model admittance: inverse of the Total Peripheral Resistance (TPR) as a function of frequency. We show that the peak of admittance (maximum flow) may appear at low frequency, below 1 Hz. Total flow in presence of such low frequency oscillations is higher than without it. Introduction of these oscillations by cardiovascular regulatory loops may provide a supplementary mechanism which can increase the total blood flow (venous return) in situations of increased demand. The result may add new value to the analysis of the Mayer waves.

Keywords

blood; blood vessels; cardiovascular system; flow simulation; fluid oscillations; fractals; 1D mathematical model; Mayer waves; cardiovascular regulatory loops; fractal arterial tree model; frequency oscillations; harmonic blood pressure modes; human arterial tree; low-frequency vascular resistance; model admittance; physiological role; total blood flow; total peripheral resistance; venous return; Admittance; Blood; Blood pressure; Fractals; Mathematical model; Oscillators; Vegetation; Mayer waves; blood pressure oscillations; fractal geometry; mathematical model; numerical simulation;

fLanguage

English

Publisher

ieee

Conference_Titel

Cardiovascular Oscillations (ESGCO), 2014 8th Conference of the European Study Group on

Conference_Location

Trento

Type

conf

DOI

10.1109/ESGCO.2014.6847575

Filename

6847575