Multichannel lung sound analysis to detect severity of lung disease in cystic fibrosis

Abstract Objective Respiratory disease in Cystic fibrosis (CF) patients is one of the main causes of the reduction in pulmonary function and death. The primary goals of CF treatment include maintaining or improving pulmonary function and reducing the rate of pulmonary function decline. Therefore, the severity of lung disease should be monitored in CF patients. The objective of this study is to examine multichannel lung sound analysis in detecting the severity of lung disease in CF patients. Methods 209 multichannel lung sound samples were recorded from thirty seven CF patients using a thirty channel acquisition system. Then, expiration to inspiration lung sound power ratio features in different frequency bands (E/I F) were extracted from large airway, upper airway and peripheral airway channels. These features were compared between the groups with different severity levels of the lung disease using Support Vector Machine, Artificial Neural Network, Decision tree and Naive Baysian classifiers by ‘leave-one-sample-out’ method. Results It was shown that features of upper airways and peripheral airways were more effective in discriminating normal from mild (91.1%) and moderate from severe (92.8%) respiratory sound samples, respectively. The best result for discriminating between all groups of severity was related to neural network classifier which performs 89.05% average accuracy. Also, ‘leave-one-subject-out’ method confirmed the results. Conclusion The proposed multichannel lung sound analysis method was successful in discriminating different severity levels of CF lung disease. Moreover, analysis of different lung region signals in consecutive levels of lung disease was consistent with regional damage of lung in CF.

[1]  D. Saha,et al.  Novel algorithm to identify and differentiate specific digital signature of breath sound in patients with diffuse parenchymal lung disease , 2015, Respirology.

[2]  Anna Barney,et al.  The reliability of lung crackle characteristics in cystic fibrosis and bronchiectasis patients in a clinical setting , 2009, Physiological measurement.

[3]  Stuart A. Bowyer,et al.  Automatic adventitious respiratory sound analysis: A systematic review , 2017, PloS one.

[4]  Rashid Ansari,et al.  Automated respiratory phase and onset detection using only chest sound signal , 2008, 2008 30th Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[5]  João Dinis,et al.  Validation of a time-frequency wheeze detector in cystic fibrosis: A pilot study , 2011 .

[6]  J. Seyyedi,et al.  Cystic fibrosis prevalence among a group of high-risk children in the main referral children hospital in Iran , 2017, Journal of education and health promotion.

[7]  January Gnitecki,et al.  Separating heart sounds from lung sounds. Accurate diagnosis of respiratory disease depends on understanding noises. , 2007, IEEE engineering in medicine and biology magazine : the quarterly magazine of the Engineering in Medicine & Biology Society.

[8]  G R Wodicka,et al.  Measurement of respiratory acoustic signals. Effect of microphone air cavity width, shape, and venting. , 1995, Chest.

[9]  T. Shimoda,et al.  Peripheral bronchial obstruction evaluation in patients with asthma by lung sound analysis and impulse oscillometry. , 2017, Allergology international : official journal of the Japanese Society of Allergology.

[10]  Philip S. Yu,et al.  Top 10 algorithms in data mining , 2007, Knowledge and Information Systems.

[11]  T. Shimoda,et al.  Prediction of airway inflammation in patients with asymptomatic asthma by using lung sound analysis. , 2014, The journal of allergy and clinical immunology. In practice.

[12]  E. Elkin,et al.  Pulmonary exacerbations in cystic fibrosis: Young children with characteristic signs and symptoms , 2013, Pediatric pulmonology.

[13]  Mounya Elhilali,et al.  Computerized Lung Sound Screening for Pediatric Auscultation in Noisy Field Environments , 2018, IEEE Transactions on Biomedical Engineering.

[14]  Fabrizio Pancaldi,et al.  Analysis of pulmonary sounds for the diagnosis of interstitial lung diseases secondary to rheumatoid arthritis , 2018, Comput. Biol. Medicine.

[15]  M. Rosenfeld,et al.  Antibiotic treatment of signs and symptoms of pulmonary exacerbations: A comparison by care site , 2015, Pediatric pulmonology.

[16]  Y. Nagasaka,et al.  Treatment evaluation using lung sound analysis in asthmatic children , 2017, Respirology.

[17]  R. Ruseckaite,et al.  The Australian Cystic Fibrosis Data Registry Annual Report, 2017 , 2018 .

[18]  Shigeyoshi Nakajima,et al.  Detection of Airway Obstruction from Frequency Distribution Feature of Lung Sounds with Small Power of Abnormal Sounds , 2015, ICGEC.

[19]  Marc Decramer,et al.  Morphometric Analysis of Explant Lungs in Cystic Fibrosis. , 2016, American journal of respiratory and critical care medicine.

[20]  S. Stanojevic,et al.  Effect of pulmonary exacerbations on long-term lung function decline in cystic fibrosis , 2011, European Respiratory Journal.

[21]  Kenneth Sundaraj,et al.  Characterization and classification of asthmatic wheeze sounds according to severity level using spectral integrated features , 2019, Comput. Biol. Medicine.

[22]  Goutam Saha,et al.  Multichannel lung sound analysis for asthma detection , 2018, Comput. Methods Programs Biomed..

[23]  Hiroyuki Mochizuki,et al.  Changes in the breath sound spectrum during methacholine inhalation in children with asthma , 2018, Respirology.

[24]  D. Sanders,et al.  Regional differences in the evolution of lung disease in children with cystic fibrosis , 2012, Pediatric pulmonology.

[25]  Kenneth Sundaraj,et al.  Identification of asthma severity levels through wheeze sound characterization and classification using integrated power features , 2019, Biomed. Signal Process. Control..

[26]  Mary Anne Koda-Kimble,et al.  Applied Therapeutics: The Clinical Use of Drugs , 1992 .

[27]  Nitesh V. Chawla,et al.  SMOTE: Synthetic Minority Over-sampling Technique , 2002, J. Artif. Intell. Res..

[28]  S. Himanen,et al.  High frequency components of tracheal sound are emphasized during prolonged flow limitation , 2009, Physiological measurement.

[29]  J. Hewett,et al.  Is an FEV1 of 80% predicted a normal spirometry in cystic fibrosis children and adults? , 2018, The clinical respiratory journal.