Karla Logie

Air Trapping on Chest CT Is Associated with Worse Ventilation Distribution in Infants with Cystic Fibrosis Diagnosed following Newborn Screening

Background In school-aged children with cystic fibrosis (CF) structural lung damage assessed using chest CT is associated with abnormal ventilation distribution. The primary objective of this analysis was to determine the relationships between ventilation distribution outcomes and the presence and extent of structural damage as assessed by chest CT in infants and young children with CF. Methods Data of infants and young children with CF diagnosed following newborn screening consecutively reviewed between August 2005 and December 2009 were analysed. Ventilation distribution (lung clearance index and the first and second moment ratios [LCI, M1/M0 and M2/M0, respectively]), chest CT and airway pathology from bronchoalveolar lavage were determined at diagnosis and then annually. The chest CT scans were evaluated for the presence or absence of bronchiectasis and air trapping. Results Matched lung function, chest CT and pathology outcomes were available in 49 infants (31 male) with bronchiectasis and air trapping present in 13 (27%) and 24 (49%) infants, respectively. The presence of bronchiectasis or air trapping was associated with increased M2/M0 but not LCI or M1/M0. There was a weak, but statistically significant association between the extent of air trapping and all ventilation distribution outcomes. Conclusion These findings suggest that in early CF lung disease there are weak associations between ventilation distribution and lung damage from chest CT. These finding are in contrast to those reported in older children. These findings suggest that assessments of LCI could not be used to replace a chest CT scan for the assessment of structural lung disease in the first two years of life. Further research in which both MBW and chest CT outcomes are obtained is required to assess the role of ventilation distribution in tracking the progression of lung damage in infants with CF.

Altered lung structure and function in mid-childhood survivors of very preterm birth

Rationale Survivors of preterm birth are at risk of chronic and lifelong pulmonary disease. Follow-up data describing lung structure and function are scarce in children born preterm during the surfactant era. Objectives To obtain comprehensive data on lung structure and function in mid-childhood from survivors of preterm birth. We aimed to explore relationships between lung structure, lung function and respiratory morbidity as well as early life contributors to poorer childhood respiratory outcomes. Methods Lung function was tested at 9–11 years in children born at term (controls) and at ≤32 weeks gestation. Tests included spirometry, oscillatory mechanics, multiple breath nitrogen washout and diffusing capacity of the lung for carbon monoxide. Preterm children had CT of the chest and completed a respiratory symptoms questionnaire. Main results 58 controls and 163 preterm children (99 with bronchopulmonary dysplasia) participated. Preterm children exhibited pulmonary obstruction and hyperinflation as well as abnormal peripheral lung mechanics compared with term controls. FEV1 was improved by 0.10 z-scores for every additional week of gestation (95% CI 0.028 to 0.182; p=0.008) and by 0.34 z-scores per z-score increase in birth weight (0.124 to 0.548; p=0.002). Structural lung changes were present in 92% of preterm children, with total CT score decreased by 0.64 (−0.99 to −0.29; p<0.001) for each additional week of gestation. Obstruction was associated with increased subpleural opacities, bronchial wall thickening and hypoattenuated lung areas on inspiratory chest CT scans (p<0.05). Conclusions Abnormal lung structure in mid-childhood resulting from preterm birth in the contemporary era has important functional consequences.

Expiratory flow limitation and breathing strategies in overweight adolescents during submaximal exercise

Objective:To investigate whether ventilatory factors limit exercise in overweight and obese children during a 6-min step test and to compare ventilatory responses during this test with those of healthy weight children.Design:Cross-sectional, prospective comparative study.Subjects:Twenty-six overweight/obese subjects and 25 healthy weight subjects with no known respiratory illness.Measurements:Various fatness and fat distribution parameters (using air displacement plethysmography and anthropometry), pulmonary function tests, breath-by-breath gas analysis during exercise, perceived exertion.Results:Young people who are overweight or obese are more likely to experience expiratory flow limitation (expFL) during submaximal exercise compared with their healthy weight peers [OR 7.2 (1.4, 37.3), P=0.019]. Subjects who had lower lung volumes at rest were even more likely to experience exercise-induced expFLs [OR 8.35 (1.4–49.3)]. Both groups displayed similar breathing strategies during submaximal exercise.Conclusion:Young people who are overweight/obese are more likely to display expFL during submaximal exercise compared with children of healthy weight . Use of compensatory breathing strategies appeared to enable overweight children to avoid the experience of breathlessness at this intensity of exercise.

Exhaled breath temperature in healthy children is influenced by room temperature and lung volume

Exhaled breath temperature (EBT) has been proposed for the non‐invasive assessment of airway inflammation. Previous studies have not examined the influence of room temperature or lung size on the EBT.

Increased prevalence of expiratory flow limitation during exercise in children with bronchopulmonary dysplasia

Evidence regarding the prevalence of expiratory flow limitation (EFL) during exercise and the ventilatory response to exercise in children born preterm is limited. This study aimed to determine the prevalence of EFL as well as contributing factors to EFL and the ventilatory response to exercise in preterm children with and without bronchopulmonary dysplasia (BPD). Preterm children (≤32 weeks gestational age) aged 9–12 years with (n=64) and without (n=42) BPD and term controls (n=43), performed an incremental treadmill exercise test with exercise tidal flow–volume loops. More preterm children with BPD (53%) had EFL compared with preterm children without BPD (26%) or term controls (28%) (p<0.05). The presence of EFL was independently associated with decreased forced expiratory volume in 1 s/forced vital capacity z-score and lower gestational age (p<0.05). There was no difference in peak oxygen uptake between preterm children with BPD and term controls (48.0 versus 48.4 mL·kg−1·min−1; p=0.063); however, children with BPD had a lower tidal volume at peak exercise (mean difference −27 mL·kg−1, 95% CI −49– −5; p<0.05). Children born preterm without BPD had ventilatory responses to exercise similar to term controls. Expiratory flow limitation is more prevalent in children born preterm with BPD and is associated with airway obstruction and a lower gestational age. Children born preterm have an increased prevalence of expiratory limitation during exercise associated with reduced lung function and lower gestational age http://ow.ly/jLsk30leOVI

Pulmonary infection in infants with cystic fibrosis (CF) leads to progressive ventilation inhomogenities

Background : The current guidelines for acceptable levels of ambient PM ( Methods : The PM fraction was extracted from surface soil samples from 4 communities across Western Australia. BALB/c 10 mice were intranasally exposed to 100 µg of PM . Control mice received 100 µg of polystyrene beads (2.5 µm) or vehicle 10 alone. Mice were assessed for inflammation (cellular influx, MIP-2, IL-6 and IL-1β), lung volume (plethysmography) and lung mechanics (forced oscillation technique) 6, 24 or 168 hours post-exposure. The physical and chemical characteristics of the particles were assessed by cascade impactor and ICP-MS/OES respectively. Principal component analysis of the outcome measures were used to construct lung impairment scores. Multivariate linear regression models were then used to identify the characteristics of the particles driving the lung responses. Results : Exposure to geogenic particles caused an acute inflammatory response (6 hours post-exposure), an acute impairment in lung mechanics (24 hours post-exposure) and a long term deficit in lung volume (168 hours post-exposure). Both the inflammatory response and long term deficits in lung volume were associated with the concentration of Fe and variability in particle size (GSD) while the impairment in lung mechanics was associated with Fe and particle size (MMAD). Conclusions : Despite the complex physico-chemical characteristics of geogenic dusts we were able to identify the concentration of Fe and physical dimensions of the particles as the key drivers of lung responses. Using these data we may be able to predict which communities are at greatest risk of adverse respiratory health due to high geogenic particle loads.