Measurement of tracheal temperature is not a reliable index of total respiratory heat loss in mechanically ventilated patients

To characterize the intrathoracic thermal events that occur during breathing in humans, we developed a flexible probe (OD 1.4 mm) containing multiple thermistors evenly spaced over 30.2 cm, that could be inserted into the tracheobronchial tree with a fiberoptic bronchoscope. With this device we simultaneously recorded the airstream temperature at six points from the trachea to beyond the subsegmental bronchi in six normal subjects while they breathed ambient and frigid air at multiple levels of ventilation (VE). During quiet breathing of room air the average temperature ranged from 32.0 +/- 0.05 degrees C in the upper trachea to 35.5 +/- 0.3 degrees C in the subsegmental bronchi. As ventilation was increased, the temperature along the airways progressively decreased, and at a VE of 100+ 1/min the temperature at the above two sites fell to 29.2 +/- 0.5 and 33.9 +/- 0.8 degrees C, respectively. Interval points were intermediate between these extremes. With cold air, the changes were considerably more profound. During quiet breathing, local temperatures approximated those recorded in the maximum VE room-air trial, and at maximum VE, the temperatures in the proximal and distal airways were 20.5 +/- 0.6 and 31.6 +/- 1.2 degrees C, respectively. During expiration, the temperature along the airways progressively decreased as the air flowed from the periphery of the lung to the mouth: the more the cooling during inspiration, the lower the temperature during expiration. These data demonstrate that in the course of conditioning inspired air the intrathoracic and intrapulmonic airways undergo profound thermal changes that extend well into the periphery of the lung.

We studied ventilator circuit colonization and condensate formation in 30 mechanical ventilators during the first 24 h after a circuit change. Parts of the circuit nearest the patient were more frequently contaminated and had the highest levels of colonization. There was rapid colonization of tubing after a circuit change; 33% of the ventilators were colonized at 2 h, 64% at 12 h, and 80% at 24 h. The median level of colonization at 24 h was 7 X 10(4) organisms/ml. Water condensate collected in the ventilator circuits at a mean rate of 30 ml/h (range, 10 to 60 ml/h). At 24 h, 80% of the condensate samples were contaminated at a median level of 2 X 10(5) organisms/ml. The bacteria isolated from the condensate usually correlated with organisms previously isolated from the patient's sputum, suggesting that the patient's oropharyngeal flora is the primary source of circuit colonization. Highly contaminated condensate in the ventilator circuit may be a significant risk factor for nosocomial pneumonia. We suggest that circuit condensate be emptied regularly, handled as infectious waste, and that special efforts be taken to prevent contaminated condensate from inadvertently washing into the patient's tracheobronchial tree.