The investigators postulated that the use of hyperventilation after induction of anesthesia before CO2 insufflation for laparoscopic surgery in Trendelenburg position would maintain normocapnia and reduce the hemodynamic percussion response of CO2 insufflation.
The use of laparoscopic techniques has become common in clinical practice. Absorption of carbon dioxide (CO2) from the peritoneal cavity is the potential mechanism for hypercapnia and a rise in the end-tidal carbon dioxide (EtCO2). Mild hypercarbia causes sympathetic stimulation which results in a fivefold increase in arginine vasopressin (AVP), tachycardia, increased systemic vascular resistance, systemic arterial pressure, central venous pressure and cardiac output.1 Severe hypercarbia exerts a negative inotropic effect on the heart and reduces left ventricular function.2 Hemodynamic alterations occur only when the PaCO2 is increased by 30 per cent above the normal levels. Clearance of CO2 is a function of the adequacy of alveolar ventilation with respect to pulmonary perfusion. Controlled hyperventilation has proved to be superior over spontaneous respiration or controlled normo-ventilation for maintaining normal PCO2 during laparoscopy. During pelvic laparoscopy there was a rapid rise of about 30% in the CO2 load eliminated by the lungs. This quickly reached a plateau and could be compensated by hyperventilation of the lungs with a 30% increase in minute ventilation. Papadimitriou and co' workers concluded that under sevoflurane anesthesia MAC, prophylactic hyperventilation to ensure mild hypocapnia, (around 33 mmHg) limits the cerebral blood flow velocities enhancing effect of CO2 insufflation, compared with permissive hypercapnia (up to 45 mmHg), during gynecological laparoscopies. However, others advocated that hyperventilation and the head-up position before CO2 insufflation are not sufficient to prevent the CO2-mediated cerebral hemodynamic effects of low-pressure pneumoperitoneum (5-8 mmHg) in children, underwent laparoscopic fundoplication.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
PREVENTION
Masking
TRIPLE
Enrollment
100
Mechanical ventilation was conducted in all the patients with a Datex-Ohmeda Aestiva/5 Smart Ventilator (Madison, WI) through a rebreathing circuit incorporating a CO2 absorber, a heat and moisture exchanger using volume-controlled mode with an inspiratory to expiratory ratio of 1:2.5, and positive end-expiratory pressure (PEEP) of 5 cm H2O. Plateau pressure was kept as low as possible with an upper limit of 30 cm H2O, and the absence of auto-PEEP was ensured by a drop of the expiratory flow to zero on the flow-time curve.
King Faisal University
Khobar, Eastern Province, Saudi Arabia
haemodynamic percussion response
changes in mean arterial blood pressure \[MAP\] and heart rate \[H.R\].
Time frame: at 5 and 10 minutes, in supine and Trendelenburg (30° head-down) positions, respectively, before CO2 insufflation and at 15, 30, 45, and 60 min after CO2 insufflation, and at 5 min after desufflation of pneumoperitoneum
other hemodynamic and respiratory parameters
systemic vascular resistance index (SVRI), cardiac index (CI), stroke volume index (SVI), PaCO2, EtCO2, arterial to end-tidal CO2 gradient (Pa-EtCO2), respiratory rate and airway pressures were recorded.
Time frame: at 5 and 10 minutes, in supine and Trendelenburg (30° head-down) positions, respectively, before CO2 insufflation and at 15, 30, 45, and 60 min after CO2 insufflation, and at 5 min after desufflation of pneumoperitoneum,
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