Lung mechanical properties distinguish children with asthma with normal and diminished lung function.

BACKGROUND: Children with asthma, even those with severe persistent disease, can have forced expiratory volume in 1 second (FEV1 ) values ≥100% of predicted, while others have diminished FEV1 . OBJECTIVE: We sought to characterize the lung mechanical properties underlying these two asthma phenotypes and the mechanisms explaining the paradox of severe asthmatic children, whom when clinically stable can have an FEV1 >100% of predicted, but during an acute bronchospastic episode can experience a life-threatening asthma event. METHODS: Lung mechanics were evaluated in three groups of children: asthmatics with FEV1 ≥100% (HFEV1 ; n = 13), asthmatics with FEV1 ≤80% (LFEV1 ; n = 14) and non-asthmatic controls (n = 10). A linear mixed model was used to examine the relationship between volume and static transpulmonary pressures obtained at total lung capacity (TLC); actual TLC %of predicted and flow; and static transpulmonary pressure and flow. RESULTS: HFEV1 asthmatics had larger airways (FEV1 z-scores 1.12 vs -2.37; P < .05), greater lung volumes (mean % of predicted TLC 134.8% vs 109.6%; P < .05) and lower airway resistance (mean %of predicted Raw 101.9% vs 199.9%; P < .05) compared to the LFEV1 group. Moreover, HFEV1 asthmatics had significantly reduced elastic recoil pressure (pressure-volume curve shifted upward and to the left) and higher lung compliance (0.21 vs 00.9 L/cm H2 O; P < .05) compared to the LFEV1 group. The pressure-flow curves revealed the LFEV1 group to have significantly increased resistance to flow in the upstream segment of the airways at all lung volumes studied compared to HFEV1 . CONCLUSION AND CLINICAL RELEVANCE: HFEV1 asthmatic children display distinct lung mechanical proprieties compared to their LFEV1 asthmatic peers. With loss of elastic recoil pressure, the HFEV1 group could generate normal FEV1 due to proportionally enlarged airways and reduced airway resistance, while airflow limitation in the LFEV1 is due to increased airway resistance. Loss of elastic recoil and interdependence during acute bronchoconstriction episodes may predispose the HFEV1 group to catastrophic reductions in airflow.

Do NHLBI lung function criteria apply to children? A cross-sectional evaluation of childhood asthma at National Jewish Medical and Research Center, 1999-2002.

Although National Heart Lung Institute (NHLBI) guidelines categorize asthma severity based on spirometry, few studies have evaluated the utility of these spirometric values in grading asthma severity in children. Asthma is thought to be progressive, but little is known about the loss of lung function in childhood. This study sought to determine the spirometric indices in children from 4-18 years of age. Retrospective cross-sectional analysis was performed on all spirometries done in children at the National Jewish Medical and Research Center from 1999-2002. In total, 2,728 children performed 24,388 measures. The mean +/- SD values for forced vital capacity (FVC), forced expired volume in 1 sec (FEV(1)), FEV(1)/FVC ratio, and forced expiratory flow (FEF)(25-75) were 92.7 +/- 16.2, 92.2 +/- 18.0, 85.3 +/- 9.3, and 78.0 +/- 36.5 percent predicted, respectively. Seventy-seven percent of FEV(1) values were >/= 80%, 18.6% were between 60-80%, and 3.1% were <60% of predicted. FEV(1) was highest in 5-year-old children; it declined thereafter, reaching a nadir at 11 years, followed by a partial recovery from 12-18 years. Expressed in liters, FEV(1) values were lower than expected at every age, with the greatest difference at 18 years. FEV(1)/FVC ratios declined through childhood, suggesting impaired airway but not lung growth in children with asthma. In conclusion, the majority of asthmatic children attending a tertiary care facility had FEV(1) values within normal range. With increasing age, the increase in FEV(1) lags behind that of nonasthmatics, so that by 18 years, maximum FEV(1) is impaired. The NHLBI FEV(1) cutoff values do not appear to accurately stratify pediatric asthma, and no useful FEV(1) cutoff could be generated.