Design of a physiologic pulsatile flow cardiopulmonary bypass system for neonates and infants

A. Ündar; T. M. Runge; O. L. Miller; M. C. Felger; R. Lansing; D. L. Korvick; F. O. Bohls; S. E. Ottmers; B. J. O'Dell; J. R. Ybarra; R. V. Howelton; R. Z. Mireles; C. K. Benson; M. C. Holland; J. H. Calhoon

doi:10.1177/039139889601900306

Design of a physiologic pulsatile flow cardiopulmonary bypass system for neonates and infants

A. Ündar, T. M. Runge, O. L. Miller, M. C. Felger, R. Lansing, D. L. Korvick, F. O. Bohls, S. E. Ottmers, B. J. O'Dell, J. R. Ybarra, R. V. Howelton, R. Z. Mireles, C. K. Benson, M. C. Holland, J. H. Calhoon

Department of Cardiothoracic Surgery

Producción científica: Article › revisión exhaustiva

12 Citas (Scopus)

Resumen

Cardiopulmonary bypass surgical techniques that allow a surgeon to operate on the infant's heart use an extracorporeal circuit consisting of a pump, oxygenator, arterial and venous reservoirs, cannulae, an arterial filter, and tubing. The extracorporeal technique currently used in infants and neonates is sometimes associated with neurologic damage. We are developing a modified cardiopulmonary bypass system for neonates that has been tested in vitro and in one animal in vivo. Unlike other extracorporeal circuits which use steady flow, this system utilizes pulsatile flow, a low prime volume (500 ml) and a closed circuit. During in vitro experiments, the pseudo patient's mean arterial pressure was kept constant at 40 mmHg and the extracorporeal circuit pressure did not exceed a mean pressure of 200 mmHg. In our single in vivo experiment, the primary objective was to determine whether physiologic pulsatility with a 1OF (3.3 mm) aortic cannula could be achieved. The results suggest that this is possible.

Idioma original	English (US)
Páginas (desde-hasta)	170-176
Número de páginas	7
Publicación	International Journal of Artificial Organs
Volumen	19
N.º	3
DOI	https://doi.org/10.1177/039139889601900306
Estado	Published - 1996

ASJC Scopus subject areas

Bioengineering
Biomedical Engineering
Medicine (miscellaneous)
Biomaterials

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Ündar, A., Runge, T. M., Miller, O. L., Felger, M. C., Lansing, R., Korvick, D. L., Bohls, F. O., Ottmers, S. E., O'Dell, B. J., Ybarra, J. R., Howelton, R. V., Mireles, R. Z., Benson, C. K., Holland, M. C., & Calhoon, J. H. (1996). Design of a physiologic pulsatile flow cardiopulmonary bypass system for neonates and infants. International Journal of Artificial Organs, 19(3), 170-176. https://doi.org/10.1177/039139889601900306

Ündar, A, Runge, TM, Miller, OL, Felger, MC, Lansing, R, Korvick, DL, Bohls, FO, Ottmers, SE, O'Dell, BJ, Ybarra, JR, Howelton, RV, Mireles, RZ, Benson, CK, Holland, MC & Calhoon, JH 1996, 'Design of a physiologic pulsatile flow cardiopulmonary bypass system for neonates and infants', International Journal of Artificial Organs, vol. 19, n.º 3, pp. 170-176. https://doi.org/10.1177/039139889601900306

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abstract = "Cardiopulmonary bypass surgical techniques that allow a surgeon to operate on the infant's heart use an extracorporeal circuit consisting of a pump, oxygenator, arterial and venous reservoirs, cannulae, an arterial filter, and tubing. The extracorporeal technique currently used in infants and neonates is sometimes associated with neurologic damage. We are developing a modified cardiopulmonary bypass system for neonates that has been tested in vitro and in one animal in vivo. Unlike other extracorporeal circuits which use steady flow, this system utilizes pulsatile flow, a low prime volume (500 ml) and a closed circuit. During in vitro experiments, the pseudo patient's mean arterial pressure was kept constant at 40 mmHg and the extracorporeal circuit pressure did not exceed a mean pressure of 200 mmHg. In our single in vivo experiment, the primary objective was to determine whether physiologic pulsatility with a 1OF (3.3 mm) aortic cannula could be achieved. The results suggest that this is possible.",

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AU - Korvick, D. L.

AU - Bohls, F. O.

AU - Ottmers, S. E.

AU - O'Dell, B. J.

AU - Ybarra, J. R.

AU - Howelton, R. V.

AU - Mireles, R. Z.

AU - Benson, C. K.

AU - Holland, M. C.

AU - Calhoon, J. H.

PY - 1996

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N2 - Cardiopulmonary bypass surgical techniques that allow a surgeon to operate on the infant's heart use an extracorporeal circuit consisting of a pump, oxygenator, arterial and venous reservoirs, cannulae, an arterial filter, and tubing. The extracorporeal technique currently used in infants and neonates is sometimes associated with neurologic damage. We are developing a modified cardiopulmonary bypass system for neonates that has been tested in vitro and in one animal in vivo. Unlike other extracorporeal circuits which use steady flow, this system utilizes pulsatile flow, a low prime volume (500 ml) and a closed circuit. During in vitro experiments, the pseudo patient's mean arterial pressure was kept constant at 40 mmHg and the extracorporeal circuit pressure did not exceed a mean pressure of 200 mmHg. In our single in vivo experiment, the primary objective was to determine whether physiologic pulsatility with a 1OF (3.3 mm) aortic cannula could be achieved. The results suggest that this is possible.

AB - Cardiopulmonary bypass surgical techniques that allow a surgeon to operate on the infant's heart use an extracorporeal circuit consisting of a pump, oxygenator, arterial and venous reservoirs, cannulae, an arterial filter, and tubing. The extracorporeal technique currently used in infants and neonates is sometimes associated with neurologic damage. We are developing a modified cardiopulmonary bypass system for neonates that has been tested in vitro and in one animal in vivo. Unlike other extracorporeal circuits which use steady flow, this system utilizes pulsatile flow, a low prime volume (500 ml) and a closed circuit. During in vitro experiments, the pseudo patient's mean arterial pressure was kept constant at 40 mmHg and the extracorporeal circuit pressure did not exceed a mean pressure of 200 mmHg. In our single in vivo experiment, the primary objective was to determine whether physiologic pulsatility with a 1OF (3.3 mm) aortic cannula could be achieved. The results suggest that this is possible.

KW - Extracorporeal circulatory support

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KW - Pulsatile flow

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Design of a physiologic pulsatile flow cardiopulmonary bypass system for neonates and infants

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