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.
When large volumes of air are inhaled at rapid rates of ventilation, substantial segments of the tracheobronchial tree become involved in the conditioning process and the inspirate does not reach body conditions of temperature and humidity until it passes well into the peripheral bronchi. To determine if the manner in which ventilation is elevated is an important factor in producing this response, we measured the temperature of the airstream at six points in the tracheobronchial tree from the pharynx to the subsegmental bronchi during 5 min of exercise and voluntary hyperventilation in seven normal subjects while they inhaled frigid air. Minute ventilation and respiratory frequency were recorded at minute intervals and intrathoracic temperatures were measured continuously. With both forms of hyperpnea, airway temperature fell dramatically, and there were no significant differences between exercise and hyperventilation. These results demonstrate that the thermal events that occur within the lung during short, moderately intense degrees of exercise can be readily simulated by voluntary hyperventilation when ventilation and inspired air conditions are matched. Our data also indicate that this form of exercise does not result in an increase in airstream temperature and raise the possibility that the bronchial blood supply may be determined by the local thermal needs of the airways to recover heat and water independent of, at least moderate, increases in cardiac output.
The purpose of this study was to test the hypothesis that mediators and cells associated with bronchoconstriction or inflammation are locally synthesized and/or released in the airways of asthmatic subjects in response to isocapnic hyperpnea (ISH). Seven atopic, mildly asthmatic subjects were studied. Baseline measurements were reported previously and included forced expiratory volumes, flow rates, bronchoalveolar lavage (BAL), and methacholine reactivity. Approximately 1 yr later, spirometry and BAL were repeated, but BAL was performed immediately after ISH challenge. As indices of inflammation, BAL measurements were made of eosinophils, neutrophils, epithelial cells, leukotrienes B4, C4, D4, and E4, prostaglandins D2, E2, and F2 alpha, thromboxane B2, histamine, and total protein. Compared with baseline, ISH was associated with higher BAL concentrations of the following: leukotriene B4 (10 versus 121 pg/ml, p = 0.02), leukotrienes C4/D4/E4 (46 versus 251 pg/ml, p = 0.02), eosinophils (0.8 versus 2.2%, p = 0.04), and epithelial cells (2.1 versus 6.1%, p = 0.05). Trends toward significant increases were seen in BAL concentrations of neutrophils and prostaglandin D2. No statistically significant increases were found in BAL measurements of total protein, histamine, prostaglandins E2 or F2 alpha, thromboxane B2, lymphocytes, or macrophages. The magnitude of the response to ISH, as measured by change in FEV1, did not correlate with BAL levels of cells or mediators. This study indicates that ISH, even in mildly asthmatic subjects, is associated with airway increases in a spectrum of bronchoactive mediators and inflammatory cells, supporting the observations of others that antagonists of a single mediator are unlikely to have major clinical effectiveness in ISH or exercise-induced asthma.
We developed and tested a method, based on conduction heat transfer analysis, to infer airway mucosal temperatures from airstream temperature-time profiles during breath-hold maneuvers. The method assumes that radial conduction of heat from the mucosal wall to inspired air dominates heat exchange during a breath-hold maneuver and uses a simplified conservation of energy analysis to extrapolate wall temperatures from air temperature vs. time profiles. Validation studies were performed by simultaneously measuring air and wall temperatures by use of a retractable basket probe in the upper airways of human volunteers and intrathoracic airways of paralyzed intubated dogs during breath holding. In both protocols, a good correlation was demonstrated between directly measured wall temperatures and those calculated from adjacent airstream temperature vs. time profiles during a breath hold. We then calculated intrathoracic bronchial wall temperatures from breath-hold airstream temperature-time profiles recorded in normal human subjects after cold air hyperpnea at 30 and 80 l/min. The calculations show airway wall temperatures in the upper intrathoracic airways that are below core body temperature during hyperpnea of frigid air and upper thoracic airways that are cooler than more peripheral airways. The data suggest that the magnitude of local intrathoracic heat/water flux is not represented by heat/water loss measurements at the airway opening. Both the magnitude and locus of heat transport during cold gas hyperventilation vary with changes in inspired gas temperature and minute ventilation; both may be important determinants of airway responses.
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