STUDY OBJECTIVES: To define the relation between systolic arterial pressure (SAP) changes during ventilation and left ventricular (LV) performance in humans. DESIGN: Prospective repeat-measures series. SETTING: University of Pittsburgh Medical Center Operating Room. PATIENTS: Fifteen anesthetized cardiac surgery patients before and after cardiopulmonary bypass when the mediastinum was either closed or open. INTERVENTIONS: Positive-pressure ventilation. MEASUREMENTS AND RESULTS: SAP and LV midaxis cross-sectional areas were measured during apnea and then were measured for three consecutive breaths. SAP increased during inspiration, this being the greatest during closed chest conditions (p < 0.05). Changes in SAP could not be correlated with changes in either LV end-diastolic areas (EDAs), end-systolic areas, or stroke areas (SAs). If SAP decreased relative to apnea, the decrease occurred during expiration and was often associated with increasing LV EDAs and SAs. SAP often decreased after a positive-pressure breath, but the decrease was unrelated to SA deficits during the breath. Increases in SAP were in phase with increases in airway pressure, whereas decreases in SAP, if present, followed inspiration. No consistent relation between SAP variation and LV area could be identified. CONCLUSIONS: In this patient group, changes in SAP reflect changes in airway pressure and (by inference) intrathoracic pressure (as in a Valsalva maneuver) better than they reflect concomitant changes in LV hemodynamics.
STUDY OBJECTIVES: To define the relation between systolic arterial pressure (SAP) changes during ventilation and left ventricular (LV) performance in humans. DESIGN: Prospective repeat-measures series. SETTING: University of Pittsburgh Medical Center Operating Room. PATIENTS: Fifteen anesthetized cardiac surgery patients before and after cardiopulmonary bypass when the mediastinum was either closed or open. INTERVENTIONS: Positive-pressure ventilation. MEASUREMENTS AND RESULTS: SAP and LV midaxis cross-sectional areas were measured during apnea and then were measured for three consecutive breaths. SAP increased during inspiration, this being the greatest during closed chest conditions (p < 0.05). Changes in SAP could not be correlated with changes in either LV end-diastolic areas (EDAs), end-systolic areas, or stroke areas (SAs). If SAP decreased relative to apnea, the decrease occurred during expiration and was often associated with increasing LV EDAs and SAs. SAP often decreased after a positive-pressure breath, but the decrease was unrelated to SA deficits during the breath. Increases in SAP were in phase with increases in airway pressure, whereas decreases in SAP, if present, followed inspiration. No consistent relation between SAP variation and LV area could be identified. CONCLUSIONS: In this patient group, changes in SAP reflect changes in airway pressure and (by inference) intrathoracic pressure (as in a Valsalva maneuver) better than they reflect concomitant changes in LV hemodynamics.
Authors: Serge Duperret; Franck Lhuillier; Vincent Piriou; Emmanuel Vivier; Olivier Metton; Patricia Branche; Guy Annat; Karim Bendjelid; Jean Paul Viale Journal: Intensive Care Med Date: 2006-11-11 Impact factor: 17.440
Authors: Daniel De Backer; Sarah Heenen; Michael Piagnerelli; Marc Koch; Jean-Louis Vincent Journal: Intensive Care Med Date: 2005-03-08 Impact factor: 17.440
Authors: Fabrice Vallée; Jean Christophe M Richard; Arnaud Mari; Thomas Gallas; Eric Arsac; Pascale Sanchez Verlaan; Benjamin Chousterman; Kamran Samii; Michèle Genestal; Olivier Fourcade Journal: Intensive Care Med Date: 2009-04-04 Impact factor: 17.440