Generating pulsatility by pump speed modulation with continuous-flow total artificial heart in awake calves

Generating pulsatility by pump speed modulation with continuous-flow total artificial heart in awake calves

The purpose of this study was to evaluate the effects of sinusoidal pump speed modulation of the Cleveland Clinic continuous-flow total artificial heart (CFTAH) on hemodynamics and pump flow in an awake chronic calf model. The sinusoidal pump speed modulations, performed on the day of elective sacri...

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Bibliographic Details
Published in:Journal of artificial organs Vol. 20; no. 4; pp. 381 - 385
Main Authors: Fukamachi, Kiyotaka, Karimov, Jamshid H., Sunagawa, Gengo, Horvath, David J., Byram, Nicole, Kuban, Barry D., Dessoffy, Raymond, Sale, Shiva, Golding, Leonard A. R., Moazami, Nader
Format: Journal Article
Language:English
Published: Tokyo Springer Japan 01-12-2017
Springer Nature B.V
Subjects:
Artificial organs
Biomedical Engineering and Bioengineering
Brief Communication
Calves
Cardiac Surgery
Feasibility studies
Hemodynamics
Medicine
Medicine & Public Health
Modulation
Nephrology
Waveform
Implants, experimental
Hemodynamics
Pulsatile flow
Heart-assist devices
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Summary:The purpose of this study was to evaluate the effects of sinusoidal pump speed modulation of the Cleveland Clinic continuous-flow total artificial heart (CFTAH) on hemodynamics and pump flow in an awake chronic calf model. The sinusoidal pump speed modulations, performed on the day of elective sacrifice, were set at ±15 and ± 25% of mean pump speed at 80 bpm in four awake calves with a CFTAH. The systemic and pulmonary arterial pulse pressures increased to 12.0 and 12.3 mmHg (±15% modulation) and to 15.9 and 15.7 mmHg (±25% modulation), respectively. The pulsatility index and surplus hemodynamic energy significantly increased, respectively, to 1.05 and 1346 ergs/cm at ±15% speed modulation and to 1.51 and 3381 ergs/cm at ±25% speed modulation. This study showed that it is feasible to generate pressure pulsatility with pump speed modulation; the platform is suitable for evaluating the physiologic impact of pulsatility and allows determination of the best speed modulations in terms of magnitude, frequency, and profiles.
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Note: Coauthors LARG and DJH of the Department of Biomedical Engineering recently retired from the department.
ISSN:1434-7229
1619-0904
DOI:10.1007/s10047-017-0958-5