Respiratory Inductance Plethysmography calibration for pediatric upper airway obstruction: an animal model

We describe a single-posture method for deriving the proportionality constant (K) between rib cage (RC) and abdominal (AB) amplifiers of the respiratory inductive plethysmograph (RIP). Qualitative diagnostic calibration (QDC) is based on equations of the isovolume maneuver calibration (ISOCAL) and is carried out during a 5-min period of natural breathing without using mouthpiece or mask. In this situation, K approximates the ratio of standard deviations (SD) of the uncalibrated changes of AB-to-RC volume deflections. Validity of calibration was evaluated by 1) analyzing RIP waveforms during an isovolume maneuver and 2) comparing changes of tidal volume (VT) amplitude and functional residual capacity (FRC) level measured by spirometry (SP) with RIP values. Comparisons of VT(RIP) to VT(SP) were also obtained in a variety of postures during natural (uninstructed) preferential RC and AB breathing and with voluntary changes of VT amplitude and FRC level. VT(RIP)-to-VT(SP) comparisons were equal to or closer than published reports for single posture, ISOCAL, multiple- and linear-regression procedures. QDC of RIP in supine posture with comparisons to SP in that posture and others showed better accuracy in horizontal than upright postures.

Thoracoabdominal asynchrony (TAA) has long been thought clinically useful in the assessment of airflow obstruction (AO) in infants. To test the hypothesis that the measurement of TAA is useful in the assessment of lung mechanics in infants with AO, we have used respiratory inductive plethysmography (RIP) to quantity TAA. We compared changes in TAA to changes in lung mechanics before and after aerosolized bronchodilator (BD) administration in 13 infants. Abdominal wall (AB) and rib cage (RC) motion were displayed on an X-Y recorder in a Lissajous figure. Asynchrony between RC and AB motion was quantified by comparing the width m of the Lissajous figure (difference between AB inspiratory and expiratory positions) at mid-RC excursion with the total AB excursion at its extremes (s). Phase angle phi ws computed as sin phi = m/s (or phi = 180 degrees - mu, where sin mu = m/s for phase angles greater than 90 degrees) and was taken as a measure of TAA. Lung resistance RL and elastance EL were calculated from esophageal pressure (Pes), mouth pressure, tidal volume, and tidal flow. All infants displayed TAA at baseline. After BD administration, TAA decreased in those infants in whom RL decreased. The percentage decrease in the phase angle from baseline after BD administration was significantly correlated with the decrease in peak-to-peak Pes (delta Pes) and the percentage decrease in RL and EL. We conclude that AO in infants leads to TAA through altered pleural pressure swings acting on the compliant chest wall. Changes in lung mechanics induced by bronchodilators are reflected in changes in TAA.(ABSTRACT TRUNCATED AT 250 WORDS)

Because of the challenges of using standard measurements such as spirometry to measure respiratory function in 3- to 5-year-old children, there may be a role for respiratory inductive plethysmography (RIP), which is noninvasive and requires minimal subject cooperation. In this study, we described normative values of thoracoabdominal motion and timing mechanics in 3- to 5-year-old children, and hypothesized positional dependence of these measurements in this age group. We measured relative thoracoabdominal motion during tidal breathing using the phase angle (Phi), the labored breathing index, and the phase relation during the total breath and timing mechanics with the ratio of time to peak tidal expiratory flow to expiratory time (TPTEF/TE). Preschools within the greater Philadelphia area and the Pulmonary Office of The Children's Hospital of Philadelphia. Fifty healthy children between 3 years and 5 years of age. RIP. All measures varied with position. Thoracoabdominal motion was nearly synchronous in the sitting position and most asynchronous in the supine position (Phi, 15.7 +/- 4.0 degrees vs 56.1 +/- 4.3 degrees, respectively; p < 0.001). This also led to an increase in the TPTEF/TE from the sitting to the supine positions (30.3 +/- 1.4% vs 37.0 +/- 1.6%, respectively; p < 0.001). Measurements of thoracoabdominal motion and timing mechanics did not change with age, weight, height, or gender. We conclude that the positional dependence of these measurements is due to the alteration in respiratory mechanics between the sitting, standing, and supine positions. We further conclude that if RIP is to be a useful longitudinal measure of respiratory function in this age range, comparison measurements should be made in the same position.