Elective Video-assisted Thoracoscopic Surgery Clinical Trial
Official title:
Comparative Study of the Non-dependent Continuous Positive Pressure Ventilation and High Frequency Positive Pressure Ventilation During One-lung Ventilation for Thoracoscopy
Video-assisted thoracoscopic surgery (VATS) is usually performed using well-collapsed lung
is essential for optimum surgical visualization and resection. However, one lung ventilation
(OLV) is associated with deleterious impaired oxygenation secondary to the increases in
shunt fraction.1 There are different approaches for the recruitment of the non-dependent
lung (NL) during OLV such as the selective application of continuous positive pressure
ventilation (CPAP) or high frequency positive pressure ventilation (HFPPV) to the
non-dependent lung.2-4 These strategies may improve arterial oxygenation and reduce shunt
fraction,2-4 However, the use of high CPAP levels impaired the surgical conditions during
thoracotomy.2-3 On contrary, the application of HFPPV either to both lungs5or to the
non-dependent lung permits adequate surgical conditions during thoracotomy.4 The
investigators hypothesize that the application of volume-controlled HFPPV to the
non-dependent lung during OLV for video-assisted thoracoscopic surgery may provide better
surgical field and adequate oxygenation than the use of CPAP 2 cm H2O.
The investigators will evaluate the effects of the selective application of conventional one
lung ventilation, HFPPV, or CPAP 2 cm H2O to the non-dependent lung on surgical field
conditions, and arterial oxygen and carbon dioxide tensions (PaO2 and PaCO2, respectively)
during OLV in the patients scheduled for video-assisted thoracoscopic surgery.
Thirty patients aged 18-60 years (ASA physical status II-III) scheduled for elective
video-assisted thoracoscopic surgery with at least one hour of one-lung ventilation (OLV)
will be included in this randomized prospective placebo-controlled crossover study at the
authors' center after obtaining approval of the institutional ethical committee and informed
written consent. The patients will be randomized to a CPCP2-HFPPV group(n = 15)or a
HFPPV-CPAP2 group(n = 15).
A power analysis of the data obtained from our preliminary pilot study indicated that 26
patients will be sufficient to detect a one SD changes in the visual analog scale assessment
of the surgical field, with a type-I error of 0.05 and a power of 85%, with added 10% more
patients, for a final sample size of 30 patients to account for patients dropping out during
the study. All operations will be performed by the same surgeons.
The patients will be premedicated with fentanyl (1.0 μg/Kg) and i.v. midazolam (0.03 mg/Kg).
All patients will be monitored with five leads electrocardiography, pulse oximetry, and
non-invasive blood pressure and 7mL/Kg of 6% Hydroxyethyl Starch 130/0.4 (Voluven, Fresenius
Kabi, Bad Homburg, Germany) will be given intravenously before induction of general
anesthesia. An arterial line (20 G) will be inserted under local anesthesia. A thoracic
epidural catheter (T4-T7) will be inserted with the patient in sitting position, and a test
dose (1.5% lidocaine 3 mL plus epinephrine 1:200.000) will be administered in order to
exclude an intravascular or intrathecal position of the catheter. No more epidural local
anesthetics will be used during the study in order to avoid effects on hypoxic pulmonary
vasoconstriction.
Anesthesiologists who gave the anesthetic will not be involved in the collection of the
patient's data. General anesthesia will be induced with propofol (2-3 mg/kg), fentanyl (2-3
µg/kg), and cisatracurium (0.2 mg/kg) was given for muscle relaxation.
The trachea will be intubated with a left-sided double-lumen tube (DLT) [Broncho-Cath®;
Mallinckrodt Medical Ltd., Dublin, Ireland]. The correct position of the tube will be
confirmed with a fiberoptic bronchoscope after intubation and after positioning the patient
in the lateral decubitus position. Other patient monitoring included end-tidal CO2,
neuromuscular blockade, and nasopharyngeal temperature will be used. Anesthesia will be
maintained with continuous infusions of propofol (6-8 mg/kg/h) and fentanyl (1 µg/kg/h).
Increments of cisatracurium (0.03 mg/kg) will be given to maintain suppression of the second
twitch using a train-of-four stimulation.
In all patients,the patients' two lungs will be mechanically ventilated with intermittent
positive pressure ventilation using fraction of inspired oxygen (FiO2) of 0.5 in air, tidal
volume (VT) of 8 mL/kg (predicted body weight), inspiratory to expiratory [I: E] ratio of
1:2.5, a positive end-expiratory pressure (PEEP) of 5 cm H2O, respiratory rate (R.R) will be
adjusted to achieve an arterial carbon dioxide tension (PaCO2) 35-45 mm Hg, peak inspiratory
pressures will be limited to 35 cm H2O and a low flow of fresh gas (<2 L/min) in a semi
closed circuit system.
After positioning of the patient in the lateral decubitus position,the dependent
non-operative lung will be ventilated conventionally(OLV)with a tidal volume of 6 mL/kg
(predicted body weight), whereas FiO2, I: E ratio, PEEP, frequency, peak inspiratory
pressures, and a flow of fresh gas will be maintained as during two-lung ventilation and the
lumen of the non-dependent operative lung will be left open to air.
The subjects will be allocated randomly to two groups (n=15 each) by drawing sequentially
numbered sealed opaque envelopes containing a computer-generated randomization code.
In CPAP2-HFPPV group, the non-dependent lung will be allowed to deflate to a CPAP of 2 cm
H2O for 30 min, using a CPAP circuit (Bronchocath® CPAP system; Mallinckrodt Medical, Inc.,
St. Louis, MO) which will be connected to the flowmeter of an oxygen cylinder with a flow
rate of 5 L/min and FiO2 of 1.0.7 Then, the lumen of non-dependent lung will be connected to
a second identical ventilator with low compliant internal circuit. HFPPV will be initiated
for 30 min using a FiO2 of 1.0, VT 3 mL/kg (predicted body weight), I: E ratio <0.3 and R.R
60 breaths/min.
In HFPPV-CPAP2 group, the non-dependent lung will be ventilated using HFPPV of the
non-dependent lung for 30 min followed with non-dependent lung CPAP of 2 cm H2O for 30 min,
At the end of surgery, the nondependent lung will be re-expanded and two-lung ventilation
will be resumed with a tidal volume of 8 mL/kg (predicted body weight). Twenty minutes
before the skin closure, the infusions of propofol and fentanyl will be gradually decreased
by 20% in every 5 minutes. At the end of surgery, the infusions will be discontinued, the
residual neuromuscular block will be antagonized with neostigmine 50 μg/kg and atropine 20
μg/kg, and the patient will be extubated by the same anesthesiologists.
The surgical field conditions, oxygenation and hemodynamic data will be recorded after
induction of general anesthesia (baseline), 15 (NL-15), 30 (NL-30) and 60 minutes (NL-60)
after the selective application of CPAP or HFPV to the nondependent lung, and 15 min after
returning of two-lung ventilation (TLV).
The surgeons will be asked to rate their satisfaction with the surgical field using a 10-cm
VAS (0: worse; 10: excellent field). The ICU and hospital lengths-of-stay will be recorded.
Perioperative hypoxemia (SaO2<90%), respiratory and cardiovascular events, and mortality
will be recorded within 30 days of surgery because a shorter period may have missed
complications and deaths directly related to events that occurred after thoracic surgery.
Statistical analysis will be performed using the Statistical Package for the Social Sciences
(Release 16, SPSS Inc., Chicago, IL, 2007). Data will be tested for normality using the
Kolmogorov-Smirnov test. Repeated-measures analysis of variance will be used for analysis of
serial changes in the patients' data at different times after the start of study
intervention. Chi-square test will be used for categorical data. Dependent t-test and ANOVA
will be used for continuous parametric variables. The Mann-Whitney U test will be performed
for intergroup comparisons for the non-parametric values. Data will be expressed as mean
(SD), number (%), or median [range]. A value of P<0.05 will be considered to be
statistically significant.
;
Allocation: Randomized, Endpoint Classification: Safety/Efficacy Study, Intervention Model: Crossover Assignment, Masking: Double Blind (Subject, Caregiver, Investigator, Outcomes Assessor), Primary Purpose: Treatment