Airway closure during mixed apneas in preterm infants: is respiratory effort necessary?

Airway closure during mixed apneas in preterm infants may be due to lack of tone in the upper airway followed by collapse and obstruction or diaphragmatic action inducing obstruction. We examine whether respiratory efforts are necessary for airway closure using a new method of detecting airway obstruction, based on the disappearance of an amplified cardiac pulse observed on the respiratory flow tracing. We analyzed 198 episodes of mixed apnea of various lengths (> or = 3 seconds) observed in 33 preterm infants (birth weight, 1.4 +/- 0.1 kg [mean +/- SEM]; study weight, 1.7 +/- 0.1 kg; gestational age, 29 +/- 1 weeks; post-natal age, 33 +/- 4 days). The great majority of these episodes (88%) had a central, followed by an obstructive, component. Infants were studied by using a nosepiece and a flow-through system. Respiratory efforts (abdominal and chest movements) were recorded. Of the apneas, 20 were < 5 seconds; 78, 5 to < 10 seconds; 45, 10 to < 15 seconds; 27, 15 to < 20 seconds; and 28, > or = 20 seconds. Of the 198 mixed apneas, 151 (76%) occurred in the absence of any respiratory effort; 43 (22%) showed a simultaneous cessation of the cardiac oscillation and respiratory effort; and 4 (2%) showed diaphragmatic activity appearing after cessation of the cardiac oscillation (airway occlusion). Respiratory efforts never preceded the cessation of the cardiac oscillation. The findings suggest that diaphragmatic action is not needed to occlude the airway in mixed apneas. The simultaneous cessation of cardiac oscillations (airway occlusion) and onset of respiratory efforts may indicate that such effort contributes to closure or is induced by the same stimulus that closes the airway. We speculate that the mechanism for airway closure in mixed apneas is most likely a lack of upper airway tone, which normally occurs with the cessation of a central drive to breathe.

Effects of central apnea on cerebral blood flow velocity in healthy term infants.

We evaluated a new method of monitoring cerebral blood flow velocity (CBFV) and described changes in CBFV in relation to central apnea in 17 healthy term infants. The area under the velocity curve during apnea did not change, whereas area under the velocity curve per the waveform showed a significant difference, suggesting that stability is maintained through an increase in CBFV with each heartbeat. The maintenance of cerebral hemodynamics during isolated central apnea supports the assumption that these episodes are benign.

Hypoxic airway constriction in infants of very low birth weight recovering from moderate to severe bronchopulmonary dysplasia.

We hypothesized that infants recovering from severe bronchopulmonary dysplasia have airway constriction that is, at least in part, related to borderline hypoxia. If this hypothesis were correct, pulmonary resistance should decrease with the administration of oxygen. To test this hypothesis, we studied 10 infants recovering from severe bronchopulmonary dysplasia (study weight 2490 +/- 275 gm; birth weight 1010 +/- 89 gm; postnatal age 73 +/- 7 days; postconceptional age 38.5 +/- 1.6 weeks) and 10 matched control infants (study weight 2430 +/- 179 gm; birth weight 2320 +/- 195 gm; postnatal age 25 +/- 4 days; postconceptional age 37.5 +/- 0.8 weeks). Resistance and compliance were measured by means of a mask with a flowmeter and an esophageal balloon (with the PEDS computer program). Measurements in both groups were made in quiet sleep, without sedation, during the inhalation of room air and during the fifth minute of oxygen inhalation. We found that (1) total pulmonary resistance, significantly higher in infants with bronchopulmonary dysplasia than in control infants, decreased from 206.1 +/- 47 cm H2O.L-1.sec-1 during inhalation of room air to 106.5 +/- 20.9 during inhalation of 100% oxygen (p less than 0.05) and (2) pulmonary dynamic compliance, lower in infants with bronchopulmonary dysplasia than in control infants, increased significantly with the administration of 100% oxygen. The results suggest that infants with bronchopulmonary dysplasia have airway constriction and that this is alleviated by inhalation of oxygen.