A prospective multicentre study testing the diagnostic accuracy of an automated cough sound centred analytic system for the identification of common respiratory disorders in children

The differential diagnosis of paediatric respiratory conditions is difficult and suboptimal. Existing diagnostic algorithms are associated with significant error rates, resulting in misdiagnoses, inappropriate use of antibiotics and unacceptable morbidity and mortality. Recent advances in acoustic e...

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Bibliographic Details
Published in:Respiratory research 2019-06, Vol.20 (1), p.81-10, Article 81
Main Authors: Porter, Paul, Abeyratne, Udantha, Swarnkar, Vinayak, Tan, Jamie, Ng, Ti-Wan, Brisbane, Joanna M, Speldewinde, Deirdre, Choveaux, Jennifer, Sharan, Roneel, Kosasih, Keegan, Della, Phillip
Format: Article
Language:English
Subjects:
Acoustics
Airway management
Algorithm
Algorithms
Ambulatory care
Antibiotics
Artificial intelligence
Asthma
Automation
Bronchopneumonia
Child
Child, Preschool
Childhood
Children
Clinical medicine
Cohort Studies
Cough
Cough - diagnosis
Cough - epidemiology
Croup
Dependence
Diagnosis
Diagnostic systems
Differential diagnosis
Disorders
Female
Hospitals
Humans
Infant
Infant, Newborn
Lungs
Male
Morbidity
Mortality
Pediatric respiratory diseases
Pediatrics
Pneumonia
Prospective Studies
Respiration Disorders - diagnosis
Respiration Disorders - epidemiology
Respiratory
Respiratory diseases
Respiratory tract
Respiratory tract diseases
Smartphone
Sound
Studies
Support services
Systematic review
Teams
Western Australia - epidemiology
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Description
Summary:The differential diagnosis of paediatric respiratory conditions is difficult and suboptimal. Existing diagnostic algorithms are associated with significant error rates, resulting in misdiagnoses, inappropriate use of antibiotics and unacceptable morbidity and mortality. Recent advances in acoustic engineering and artificial intelligence have shown promise in the identification of respiratory conditions based on sound analysis, reducing dependence on diagnostic support services and clinical expertise. We present the results of a diagnostic accuracy study for paediatric respiratory disease using an automated cough-sound analyser. We recorded cough sounds in typical clinical environments and the first five coughs were used in analyses. Analyses were performed using cough data and up to five-symptom input derived from patient/parent-reported history. Comparison was made between the automated cough analyser diagnoses and consensus clinical diagnoses reached by a panel of paediatricians after review of hospital charts and all available investigations. A total of 585 subjects aged 29 days to 12 years were included for analysis. The Positive Percent and Negative Percent Agreement values between the automated analyser and the clinical reference were as follows: asthma (97, 91%); pneumonia (87, 85%); lower respiratory tract disease (83, 82%); croup (85, 82%); bronchiolitis (84, 81%). The results indicate that this technology has a role as a high-level diagnostic aid in the assessment of common childhood respiratory disorders. Australian and New Zealand Clinical Trial Registry (retrospective) - ACTRN12618001521213 : 11.09.2018.
ISSN:1465-993X
1465-9921
1465-993X
1465-9921
DOI:10.1186/s12931-019-1046-6