Endotracheal temperature and humidity measurements in laryngectomized patients: intra- and inter-patient variability.

UNLABELLED: This study assesses intra- and inter-patient variability in endotracheal climate (temperature and humidity) and effects of heat and moister exchangers (HME) in 16 laryngectomized individuals, measured repeatedly (N = 47). Inhalation Breath Length (IBL) was 1.35 s without HME and 1.05 s with HME (P < 0.0001). With HME, end-inspiratory (minimum) humidity values increased 5.8 mg H(2)O/L (P < 0.0001) and minimum temperature values decreased 1.6 degrees C (P < 0.0001). For the temperature and humidity minimums, the inter-patient variability was much smaller than the short- and long-term intra-patient variability. For exhalation breath length and full breath length, the opposite was the case. CONCLUSIONS: (1) Because inter-patient variability is smaller than intra-patient variability, investigating endotracheal climate in a limited number of laryngectomized subjects is justified, provided repeated measurements per patient are accomplished; (2) main contributor to intra-patient variability is the positioning of the catheter tip in the trachea; (3) an HME leads to a shortened IBL which enhances the HME effect.

A newly developed tool for intra-tracheal temperature and humidity assessment in laryngectomized individuals: the Airway Climate Explorer (ACE).

The aim of this study is to develop a postlaryngectomy airway climate explorer (ACE) for assessment of intratracheal temperature and humidity and of influence of heat and moisture exchangers (HMEs). Engineering goals were within-device condensation prevention and fast response time characteristics. The ACE consists of a small diameter, heated air-sampling catheter connected to a heated sensor house, containing a humidity sensor. Air is sucked through the catheter by a controlled-flow pump. Validation was performed in a climate chamber using a calibrated reference sensor and in a two-flow system. Additionally, the analyser was tested in vivo. Over the clinically relevant range of humidity values (5-42 mg H2O/l air) the sensor output highly correlates with the reference sensor readings (R2 > 0.99). The 1-1/e response times are all <0.5 s. A first in vivo pilot measurement was successful. The newly developed, verified, fast-responding ACE is suitable for postlaryngectomy airway climate assessment.

The physiological rationale of heat and moisture exchangers in post-laryngectomy pulmonary rehabilitation: a review.

Total laryngectomy results in a permanent disconnection of the upper and lower airways and inevitably leads to chronic pulmonary complaints like frequent involuntary coughing, increased sputum production and repeated daily forced expectoration to clean the airway. Heat and moisture exchangers (HMEs), applied in an attempt to compensate for the lost functions of the upper respiratory tract, have been found to diminish these symptoms and improve the quality of life significantly. An HME has three physical properties that might be responsible for these improvements. First, its heat and moisture exchanging capacity improves intra-airway preservation of heat and water. Since the condensation and evaporation of moisture are accompanied by the release and uptake of thermal energy, these parameters are inseparable. Secondly, the HME's resistance may reduce dynamic airway compression, thereby improving ventilation. Thirdly, to some extent, an HME might filter out particles, thereby cleaning inspiratory breathing air. This article summarizes our present knowledge of changes in respiratory physiology after total laryngectomy and the influence of the HME by reviewing the physiological impact of these three physical properties separately for in vitro and in vivo data.