Mechanical Ventilation Complication Clinical Trial
Official title:
A Pilot Study of a New Ultrasonographic Tool to Assess Regional Pulmonary Strain in Patients Under General Anesthesia Using One-lung Ventilation.
Mechanical ventilation is frequently used in the operating room and the intensive care
settings. Although essential in many cases, mechanical ventilation can be responsible for
ventilator-induced lung injury (VILI). The relationship between mechanical ventilation and
VILI has been clearly demonstrated in animals and is highly suspected in humans. The putative
mechanism responsible for VILI is excessive pulmonary strain or overdistension. Frequently
observed in mechanically ventilated patients, the presence of a severe pre-existing pulmonary
disease can increase the risk of overdistension. The development of a tool allowing early
detection of pulmonary overdistension would represent a great asset in the prevention of VILI
by allowing safer adjustments of mechanical ventilation parameters. Ultrasonographic imaging
is a non-radiant, non-invasive technique already available in the intensive care setting.
Already used for cardiac strain measurements, ultrasonography is a promising avenue to assess
pulmonary strain.
This pilot study will aim to create a small dataset of local pleural strain values assessed
at predetermined pulmonary areas using ultrasound imaging in patients undergoing thoracic
surgery requiring one-lung ventilation. This dataset will be used to help plan larger scale
studies.
At four different time points during thoracic surgery, images of the pleura of the dependent
lung will be made at 2 predetermined areas. The images will be made: after induction (tidal
volume of 10 mL/kg), during two-lung ventilation (tidal volume of 10 mL/kg) and during
one-lung ventilation (tidal volume of 10 mL/kg and 5 mL/kg). The sites to be studied will be:
the 3rd intercostal space at the mid-clavicular line (dependent lung), the 8th intercostal
space at the posterior axillary line (dependent lung). Three consecutive respiratory cycles
at each site will be recorded for subsequent analysis.
Lung ultrasonography will be performed by the principal investigator and a co-investigator
using a Terason (Teratech Corporation, Burlington, MA) device and a 12L5 linear ultrasound
probe. For each image, the probe will be oriented perpendicularly to the pleura with the
pointer towards the participant's head. A depth of 4 cm will be used and adjusted in order to
have the pleural line located between the center and the three-quarts of the screen. The
beam's focal zone will be positioned at the level of the pleural line. A 12 MHz frequency
will be used.
Using a reference ultrasonographic image, an experienced lung ultrasonographer will segment
the pleura. From this image, an algorithm will define a region of interest which will be
followed throughout the rest of the images of the video sequence. Thereafter, the algorithm
will calculate the various components of pulmonary strain in relation to tidal volume. The
principal investigator or a co-investigator will visually validate the speckle-tracking.
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