Your search keyword '"E. M’Bakulu"' showing total 3 results

1. Comparison of cardiac output measured by oesophageal Doppler ultrasonography or pulse pressure contour wave analysis

Author

Sébastien Froelich, Anaïs Caillard, C. Madadaki, Fabrice Vallée, G. Dubreuil, A. Tantot, Etienne Gayat, E. M’Bakulu, Damien Bresson, François Bart, and Alexandre Mebazaa

Subjects

Adult, Male, medicine.medical_specialty, Cardiac output, Hemodynamics, Context (language use), Anesthesia, General, Pulse Wave Analysis, symbols.namesake, Esophagus, Internal medicine, medicine, Humans, Vasoconstrictor Agents, Arterial Pressure, Prospective Studies, Cardiac Output, Aged, Monitoring, Physiologic, Models, Statistical, business.industry, Continuous monitoring, Liter, Ultrasonography, Doppler, Middle Aged, Pulse pressure, Anesthesiology and Pain Medicine, Blood pressure, Cardiology, symbols, Fluid Therapy, Female, business, Doppler effect, Algorithms

Abstract

Background Maintaining adequate organ perfusion during high-risk surgery requires continuous monitoring of cardiac output to optimise haemodynamics. Oesophageal Doppler Cardiac Output monitoring (DCO) is commonly used in this context, but has some limitations. Recently, the cardiac output estimated by pulse pressure analysis- (PPCO) was developed. This study evaluated the agreement of cardiac output variations estimated with 9 non-commercial algorithms of PPCO compared with those obtained with DCO. Methods High-risk patients undergoing neurosurgery were monitored with invasive blood pressure and DCO. For each patient, 9 PPCO algorithms and DCO were recorded before and at the peak effect for every haemodynamic challenge. Results Sixty-two subjects were enrolled; 284 events were recorded, including 134 volume expansions and 150 vasopressor boluses. Among the 9 algorithms tested, the Liljestrand-Zander model led to the smallest bias (0.03 litre min−1 [−1.31, +1.38] (0.21 litre min−1 [−1.13; 1.54] after volume expansion and −0.13 litre min−1 [−1.41, 1.15] after vasopressor use). The corresponding percentage of the concordance was 91% (86% after volume expansion and 94% after vasopressor use). The other algorithms, especially those using the Winkessel concept and the area under the pressure wave, were profoundly affected by the vasopressor. Conclusions Among the 9 PPCO algorithms examined, the Liljestrand-Zander model demonstrated the least bias and best limits of agreement, especially after vasopressor use. Using this particular algorithm in association with DCO calibration could represent a valuable option for continuous cardiac output monitoring of high risk patients. Clinical Trial Registration Comite d'ethique de la Societe de Reanimation de Langue Francaise No. 11–356.

Published

2014

2. Comparaison du débit cardiaque mesuré par Doppler œsophagien et par 9 algorithmes d’analyse du contour de l’onde de pouls au cours d’épreuves thérapeutiques

Author

Etienne Gayat, Alexandre Mebazaa, François Bart, A. Tantot, F. Vallée, G. Dubreuil, E. M’Bakulu, A. Caillard, and C. Madadaki

Subjects

Physics, Anesthesiology and Pain Medicine, General Medicine

Published

2013

3. Comparison of cardiac output measured by oesophageal Doppler ultrasonography or pulse pressure contour wave analysis.

Author

Caillard A, Gayat E, Tantot A, Dubreuil G, M'Bakulu E, Madadaki C, Bart F, Bresson D, Froelich S, Mebazaa A, and Vallée F

Subjects

Adult, Aged, Algorithms, Anesthesia, General, Arterial Pressure, Female, Fluid Therapy, Hemodynamics, Humans, Male, Middle Aged, Models, Statistical, Monitoring, Physiologic, Prospective Studies, Pulse Wave Analysis, Vasoconstrictor Agents therapeutic use, Cardiac Output physiology, Esophagus diagnostic imaging, Ultrasonography, Doppler methods

Abstract

Background: Maintaining adequate organ perfusion during high-risk surgery requires continuous monitoring of cardiac output to optimise haemodynamics. Oesophageal Doppler Cardiac Output monitoring (DCO) is commonly used in this context, but has some limitations. Recently, the cardiac output estimated by pulse pressure analysis- (PPCO) was developed. This study evaluated the agreement of cardiac output variations estimated with 9 non-commercial algorithms of PPCO compared with those obtained with DCO., Methods: High-risk patients undergoing neurosurgery were monitored with invasive blood pressure and DCO. For each patient, 9 PPCO algorithms and DCO were recorded before and at the peak effect for every haemodynamic challenge., Results: Sixty-two subjects were enrolled; 284 events were recorded, including 134 volume expansions and 150 vasopressor boluses. Among the 9 algorithms tested, the Liljestrand-Zander model led to the smallest bias (0.03 litre min(-1) [-1.31, +1.38] (0.21 litre min(-1) [-1.13; 1.54] after volume expansion and -0.13 litre min(-1) [-1.41, 1.15] after vasopressor use). The corresponding percentage of the concordance was 91% (86% after volume expansion and 94% after vasopressor use). The other algorithms, especially those using the Winkessel concept and the area under the pressure wave, were profoundly affected by the vasopressor., Conclusions: Among the 9 PPCO algorithms examined, the Liljestrand-Zander model demonstrated the least bias and best limits of agreement, especially after vasopressor use. Using this particular algorithm in association with DCO calibration could represent a valuable option for continuous cardiac output monitoring of high risk patients., Clinical Trial Registration: Comité d'éthique de la Société de Réanimation de Langue Française No. 11-356., (© The Author 2015. Published by Oxford University Press on behalf of the British Journal of Anaesthesia. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published

2015