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Methacholine Inhalation Challenge (methacholine + inhalation_challenge)

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Medical Sciences100%

Selected Abstracts

Changes in the highest frequency of breath sounds without wheezing during methacholine inhalation challenge in children

RESPIROLOGY, Issue 3 2010
Chizu HABUKAWA
ABSTRACT A breath sound analyser was used to detect bronchoconstriction without wheezing during methacholine inhalation challenge in children. The highest frequency of inspiratory breath sounds increased significantly during bronchoconstriction and decreased after inhalation of a bronchodilator. The highest frequency of inspiratory breaths sounds was correlated with bronchial reactivity. Background and objective: It is difficult for clinicians to identify changes in breath sounds caused by bronchoconstriction when wheezing is not audible. A breath sound analyser can identify changes in the frequency of breath sounds caused by bronchoconstriction. The present study aimed to identify the changes in the frequency of breath sounds during bronchoconstriction and bronchodilatation using a breath sound analyser. Methods: Thirty-six children (8.2 ± 3.7 years; males : females, 22 : 14) underwent spirometry, methacholine inhalation challenge and breath sound analysis. Methacholine inhalation challenge was performed and baseline respiratory resistance, minimum dose of methacholine (bronchial sensitivity) and speed of bronchoconstriction in response to methacholine (Sm: bronchial reactivity) were calculated. The highest frequency of inspiratory breath sounds (HFI), the highest frequency of expiratory breath sounds (HFE) and the percentage change in HFI and HFE were determined. The HFI and HFE were compared before methacholine inhalation (pre-HFI and pre-HFE), when respiratory resistance reached double the baseline value (max HFI and max HFE), and after bronchodilator inhalation (post-HFI and post-HFE). Results: Breath sounds increased during methacholine-induced bronchoconstriction. Max HFI was significantly greater than pre-HFI (P < 0.001), and decreased to the basal level after bronchodilator inhalation. Post-HFI was significantly lower than max HFI (P < 0.001). HFI and HFE were also significantly changed (P < 0.001). The percentage change in HFI showed a significant correlation with the speed of bronchoconstriction in response to methacholine (P = 0.007). Conclusions: Methacholine-induced bronchoconstriction significantly increased HFI, and the increase in HFI was correlated with bronchial reactivity. [source]

Adult asthma after non-respiratory syncytial virus bronchiolitis in infancy: Subgroup analysis of the 20-year prospective follow-up study

PEDIATRICS INTERNATIONAL, Issue 2 2007
EIJA PIIPPO-SAVOLAINEN
Abstract Background: Recent studies have stressed the influence of other viruses than respiratory syncytial virus (RSV) in the development of asthma in later childhood after bronchiolitis in infancy. However, the virus-specific prognosis until adulthood has remained obscure, due to lack of sufficiently long follow-up studies. The aim of the present study was to evaluate adult respiratory morbidity after bronchiolitis in infancy, focused on cases not caused by RSV. Methods: A total of 54 children hospitalized for bronchiolitis at age <2 years were re-studied at median age 19 years; 22 with RSV bronchiolitis and 22 with non-RSV bronchiolitis outside RSV epidemic were included. RSV etiology was studied by antigen and antibody assays on admission. Adult asthma was defined by two ways, based on written questionnaire, clinical examination and home peak expiratory flow monitoring. Lung function was evaluated by flow-volume spirometry (FVS), bronchial reactivity by methacholine inhalation challenge (MIC), and atopy by skin prick tests (SPT). Results: In the non-RSV group, asthma by two definitions was present in 41,50% (vs 18,27% in RSV group). In logistic regression, adjusted for gender, age on admission, current atopy and smoking, non-RSV etiology of bronchiolitis, compared with RSV etiology, increased asthma risk by both strict (odds ratio [OR], 8.34; 95% confidence interval [CI], 1.18,58.69) and less strict (OR, 7.93; 95% CI, 1.14,55.41) criteria. An abnormal result in FVS was present in 32,41% and in MIC in 48,52% of cases in non-RSV and RSV groups, respectively. Conclusions: Infants with non-RSV bronchiolitis requiring treatment in hospital are at an increased risk for subsequent asthma in adulthood. [source]

Changes in the highest frequency of breath sounds without wheezing during methacholine inhalation challenge in children

RESPIROLOGY, Issue 3 2010
Chizu HABUKAWA
ABSTRACT A breath sound analyser was used to detect bronchoconstriction without wheezing during methacholine inhalation challenge in children. The highest frequency of inspiratory breath sounds increased significantly during bronchoconstriction and decreased after inhalation of a bronchodilator. The highest frequency of inspiratory breaths sounds was correlated with bronchial reactivity. Background and objective: It is difficult for clinicians to identify changes in breath sounds caused by bronchoconstriction when wheezing is not audible. A breath sound analyser can identify changes in the frequency of breath sounds caused by bronchoconstriction. The present study aimed to identify the changes in the frequency of breath sounds during bronchoconstriction and bronchodilatation using a breath sound analyser. Methods: Thirty-six children (8.2 ± 3.7 years; males : females, 22 : 14) underwent spirometry, methacholine inhalation challenge and breath sound analysis. Methacholine inhalation challenge was performed and baseline respiratory resistance, minimum dose of methacholine (bronchial sensitivity) and speed of bronchoconstriction in response to methacholine (Sm: bronchial reactivity) were calculated. The highest frequency of inspiratory breath sounds (HFI), the highest frequency of expiratory breath sounds (HFE) and the percentage change in HFI and HFE were determined. The HFI and HFE were compared before methacholine inhalation (pre-HFI and pre-HFE), when respiratory resistance reached double the baseline value (max HFI and max HFE), and after bronchodilator inhalation (post-HFI and post-HFE). Results: Breath sounds increased during methacholine-induced bronchoconstriction. Max HFI was significantly greater than pre-HFI (P < 0.001), and decreased to the basal level after bronchodilator inhalation. Post-HFI was significantly lower than max HFI (P < 0.001). HFI and HFE were also significantly changed (P < 0.001). The percentage change in HFI showed a significant correlation with the speed of bronchoconstriction in response to methacholine (P = 0.007). Conclusions: Methacholine-induced bronchoconstriction significantly increased HFI, and the increase in HFI was correlated with bronchial reactivity. [source]

Relationship between bronchial hyperresponsiveness and development of asthma in children with chronic cough

PEDIATRIC PULMONOLOGY, Issue 6 2001
Hideko Nishimura MD
Abstract To evaluate the relationship between bronchial hyperresponsiveness (BHR) and the development of asthma in children with chronic cough, we performed methacholine inhalation challenges and transcutaneous oxygen pressure (tcPO2) measurements in 92 children with chronic cough aged from 1,13 years (55 boys and 37 girls; mean, 5.3 years) and followed them for ,,,10 years. Forty-four age-matched children with asthma (24 males and 20 females; mean, 6.5 years) and 44 age-matched children without cough or asthma served as controls (18 males and 26 females; mean, 4.6 years). Consecutive doubling doses of methacholine were inhaled until a 10% decrease in tcPO2 from baseline was observed. The cumulative dose of methacholine at the inflection point of the tcPO2 record (Dmin-PO2) was considered to represent hyperresponsiveness to inhaled methacholine. After 10 years or more of follow-up, 60 of the 92 subjects with cough answered our questionnaire, and 27/60 had been diagnosed with asthma. There was a statistical difference in Dmin-PO2 between the children who presented with chronic cough originally and who developed asthma (asthma-developed group) and those who did not develop asthma (asthma-free group). There was no difference in the value of Dmin-PO2 between the asthma-developed group and the asthma group, or between the asthma-free group and the age-matched control group. Among the children with chronic cough, there was no difference in Dmin-PO2 between girls and boys, either in the asthma-developed group or in the asthma-group. We conclude that 45% of the children with a chronic cough in early life developed asthma, and that BHR in children with chronic cough during the childhood period is a strong risk factor for the development of asthma. Pediatr Pulmonol. 2001; 31:412,418. © 2001 Wiley-Liss, Inc. [source]