Continuous-flow Pump Model Study: the Effect on Pump Performance of Pump Characteristics and Cardiovascular Conditions

Overview

Journal J Artif Organs

Specialty Biomedical Engineering

Date 2013 Mar 7

PMID 23463355

Citations 2

Authors

Gianfranco Ferrari

Maciej Kozarski

Libera Fresiello

Arianna Di Molfetta

Krzysztof Zielinski

Krystyna Gorczynska

Krzysztof J Palko

Marek Darowski

Affiliations

Soon will be listed here.

Abstract

This model study evaluates the effect of pump characteristics and cardiovascular data on hemodynamics in atrio-aortic VAD assistance. The model includes a computational circulatory sub-model and an electrical sub-model representing two rotary blood pumps through their pressure-flow characteristics. The first is close to a pressure generator-PG (average flow sensitivity to pressure variations, -0.047 l mmHg(-1)); the second is closer to a flow generator-FG (average flow sensitivity to pressure variations, -0.0097 l mmHg(-1)). Interaction with VAD was achieved by means of two interfaces, behaving as impedance transformers. The model was verified by use of literature data and VAD onset conditions were used as a control for the experiments. Tests compared the two pumps, at constant pump speed, in different ventricular and circulatory conditions: maximum ventricular elastance (0.44-0.9 mmHg cm(-3)), systemic peripheral resistance (781-1200 g cm(-4) s(-1)), ventricular diastolic compliance C p (5-10-50 cm(3) mmHg(-1)), systemic arterial compliance (0.9-1.8 cm(3) mmHg(-1)). Analyzed variables were: arterial and venous pressures, flows, ventricular volume, external work, and surplus hemodynamic energy (SHE). The PG pump generated the highest SHE under almost all conditions, in particular for higher C p (+50 %). PG pump flow is also the most sensitive to E max and C p changes (-26 and -33 %, respectively). The FG pump generally guarantees higher external work reduction (54 %) and flow less dependent on circulatory and ventricular conditions. The results are evidence of the importance of pump speed regulation with changing ventricular conditions. The computational sub-model will be part of a hydro-numerical model, including autonomic controls, designed to test different VADs.

Citing Articles

Hemodynamic effects of various support modes of continuous flow LVADs on the cardiovascular system: a numerical study.

Song Z, Gu K, Gao B, Wan F, Chang Y, Zeng Y Med Sci Monit. 2014; 20:733-41.

PMID: 24793178 PMC: 4020910. DOI: 10.12659/MSM.890824.

Journal of Artificial Organs 2013: the year in review : Journal of Artificial Organs Editorial Committee.

Sawa Y, Tatsumi E, Tsukiya T, Matsuda K, Fukunaga K, Kishida A J Artif Organs. 2014; 17(1):1-8.

PMID: 24569884 DOI: 10.1007/s10047-014-0759-z.

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