Total arterial inertance as the fourth element of the windkessel model

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Total arterial inertance as the fourth element of the windkessel model

Nikos Stergiopulos¹, Berend E. Westerhof², and Nico Westerhof³

¹ Biomedical Engineering Laboratory, Swiss Federal Institute of Technology, Parc Scientifique d'Ecublens, 1015 Lausanne, Switzerland; ² Biomedical Instrumentation, Institute of Applied Physics, Netherlands Organisation for Applied Scientific Research, Academic Medical Centre, 1015 AZ Amsterdam; and ³ Laboratory for Physiology, Institute for Cardiovascular Research, Free University of Amsterdam, 1081 BT Amsterdam, The Netherlands

In earlier studies we found that the three-element windkessel, although an almost perfect load for isolated heart studies,does not lead to accurate estimates of total arterial compliance.To overcome this problem, we introduce an inertial term in parallelwith the characteristic impedance. In seven dogs we found thatascending aortic pressure could be predicted better from aorticflow by using the four-element windkessel than by using the three-elementwindkessel: the root-mean-square errors and the Akaike informationcriterion and Schwarz criterion were smaller for the four-elementwindkessel. The three-element windkessel overestimated total arterialcompliance compared with the values derived from the area andthe pulse pressure method (P = 0.0047, paired t-test), whereasthe four-element windkessel compliance estimates were not different(P = 0.81). The characteristic impedance was underestimated usingthe three-element windkessel, whereas the four-element windkesselestimation differed marginally from the averaged impedance modulusat high frequencies (P = 0.0017 and 0.031, respectively). Whenapplied to the human, the four-element windkessel also was moreaccurate in these same aspects. Using a distributed model of thesystemic arterial tree, we found that the inertial term resultsfrom the proper summation of all local inertial terms, and wecall it total arterial inertance. We conclude that the fourelementwindkessel, with all its elements having a hemodynamic meaning,is superior to the three-element windkessel as a lumped-parametermodel of the entire systemic tree or as a model for parameterestimation of vascularproperties.

windkessels; total arterial compliance; aortic characteristic impedance; total arterial inertance; aortic pressure and flow; human; dog

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