View clinical trials related to Respiratory Sounds.
Filter by:This observational study evaluates whether lung sound analysis with LungPass device can be used to differentiate exacerbation and stable state asthma and COPD.
In this study the investigators record sounds of voice, breaths and cough of subjects who tested positive for COVID19. The investigators then feed these sounds into an artificial intelligence and see if it can learn to recognise features to make COVID19 diagnosis from these sounds in order to avoid to use swabs to test the general population.
Bronchiolitis is a common viral infection of the small airways of infants and some affected infants will require hospital admission. Severe bronchiolitis is a marker for greatly increased risk of developing both preschool wheeze and subsequent school age asthma. Since epidemiological studies suggest that exposure to microbial products protects against preschool wheeze, lysates of bacteria may prevent the development of wheeze after bronchiolitis, with long-term beneficial consequences. BLIPA is a phase 2b, randomised, double blind, placebo-controlled study, investigating the efficacy superiority of bacterial lysate (Broncho Vaxom) capsules over placebo, in reducing wheeze in infants after severe bronchiolitis. The primary end point of the study is parent-reported, healthcare-professional confirmed wheeze at 19-24 months. The study aims to test bacterial lysate capsules (3.5mg over 24 months) for safety, efficacy, and to advance mechanistic understanding of its action.
The primary objective of this study is to reduce respiratory tract infections and wheezing in moderate-late preterms in the first year of life by bacterial lysate administration. Next to determine the correlation of biological markers with respiratory symptoms, immune protection and treatment effect.
Technological developments in the recent decades has enabled the integration of electronic and digital components in the stethoscope design, in an attempt to improve auditory performance and, moreover, to assist in improving user's diagnostic accuracy by incorporating computerized, digital technologies, artificial intelligence capabilities and deep-learning-based algorithms enhancing these devices. We believe that these technologies can be used to significantly improve the diagnostic performance in the primary care phase, by means of a sophisticated stethoscope that enables auscultation to sounds and signals typically found in the sub-sound frequency level. Their transformation into the sound range, and the use of artificial intelligence and machine learning techniques to characterize sound patterns that correspond to specific problems or diseases can substantially enhance the physician's or other care giver's performance to the benefit of the patients. At this stage, the software in development does not purport to make diagnostic decisions, but only to provide information that will enhance decision and diagnosis making process, therefore enable a more accurate and definitive diagnostic decision and perhaps decrease the number of additional diagnostic tests requested.
With the aid of computerized sound analysis, digital acoustic monitoring could provide a more sensitive, specific, and quantifiable indicator for perioperative respiratory abnormalities including wheezing. It is probable that the digital stethoscope has utility in the detection, monitoring, and resolution following treatment of acoustic changes characteristic of turbulent respiratory gas flow due to wheezing and/or the incomplete resolution of atelectasis following the re-initiation of ventilation in a collapsed lung.
Hospital admission for infant bronchiolitis is associated with an increased risk of recurrent wheezing and subsequent asthma in childhood. In the literature, 17 to 60% of children will develop repeated wheezing (infant asthma in France). This highly variable incidence could be linked in part to the fact that the definition of bronchiolitis varies between continents. In Europe the usual definition is an acute and contagious viral infection which affects the bronchioles (small bronchi) of infants accompanied by coughing, rapid breathing and wheezing. In research studies, bronchiolitis must be associated with wheezing and / or crackles on auscultation in Europe, and wheezing imperatively in the USA. The diagnosis of wheezing is difficult, and medical agreement on auscultatory respiratory abnormalities is poor. We thus have developed a wheezing diagnostic tool using artificial intelligence processing of respiratory sound recordings by smartphone (Bokov P, Comput Biol Med 2016, DOI: 10.1016/j.compbiomed.2016.01.002). In a second larger bicentric study that included only infants suspected of bronchiolitis, our approach has consisted in obtaining a recording by smartphone but also by electronic stethoscope in order to allow deferred listening of the sounds (WheezSmart study). The objective of these studies was to obtain a formal diagnosis of wheezing, the current project aims to assess the benefit of this diagnosis. The main objective of this cross-sectional study is to determine whether the formal presence (diagnosis of wheezing from a recording of pulmonary auscultation) is associated with the risk of childhood asthma (diagnosis of asthma at 6 years) regardless of the usual risk factors (atopic / allergic terrain, exposure to smoking, recurrence of symptoms). The secondary objectives are to determine whether the formal presence of wheezing on auscultation is a risk factor for subsequent repeated wheezing (diagnosis of infant asthma) and for initial disease severity (bronchiolitis) compared to SpO2 and admission of the child to hospital. The interest in differentiating between high and low frequency sibilants will be evaluated also.
Wheezing in infants and children less than 3 years of age children is a frequent feature that might be difficult to diagnose when only the caregivers reporting is available. Indeed, in this age group the usual reversible flow limitation measure during pulmonary function testing (PFT) is missing because PFT techniques require the full patient cooperation to perform respiratory tests. Infants PFTs have been developed to measure the same indexes than those measured in adults, but they are difficult to set-up and require medication- induced sleep during day time. However, when flow limitation is sufficient it can be detected during tidal breathing as measured during spirometry using pneumotachograph (PNT). In this test, the tidal breathing flow-volume (TBFV) loop is recorded and studied using different indices to assess the airflow limitation. But, there again, when addressing infants or very young children quiet breathing can only be achieved during sleep and medication- induced sleep necessary. Impedance pneumography (IP) is a method for measuring changes in the thoracic electrical impedance through skin electrodes, which varies as a function of lung aeration i.e. breathing. This technique has mainly been applied to monitor respiratory rate in intensive care settings, but recent technical advancements in IP signal processing and electrode placement strategy have enabled IP to be used for accurate non-invasive tidal flow signal measurement. Compared to direct PNT, high agreement in flow signal and TBFV indices has been demonstrated in young children as well as in infants, even during induced bronchoconstriction. Moreover, in overnight recordings at home, IP was found feasible for quantifying nocturnal TBFV variability in young children with lower respiratory symptoms. In this study, it was shown that preschool children with high risk of asthma present with increased variation of tidal flow profile shape, and momentarily lowered chaoticity, compared to children with lower risk of asthma. Recently a study in Tampere University Hospital (TAUH) Allergy centre (Tampere, Finland, PSHP ethical committee code R14027, ClinicalTrials.gov code NCT02164968) finished collecting overnight TBFV using impedance pneumography on 70 young children with suspected asthma. The preliminary analysis of this data shows that the effect of asthma treatment can be seen in TBFV variability, but to assess the diagnostic capacity of this new method, healthy control sample should be collected. The technology developed by the Finnish medical device company Revenio Research Oy enables to evaluate the variability of the expiratory flow-volume curve. It is calculate as the expiration variability index (EVI) which is decreased in case of bronchoconstriction. In order to explore very young children (less than 3 years of age) unable to participate to any awake lung function test, we set-up a study aiming to: 1) establish reference value for EVI in healthy children 2 months to 3 years old 2) test the variation of EVI in case of acute disease with or without wheezing in this age group children. In this observational prospective multicenter study, we will include 110 asymptomatic healthy subjects to compute reference values of EVI. We will also include 35 previously healthy subjects who have developed an acute non wheezing disease such as fever, rhinitis, otitis or bronchitis to compare their EVI to the reference values. And finally, we will recruit 35 young subjects with an acute wheezing episode. All measurements will be performed at home by the parents, except for some wheezy children who could be hospitalized. It will be proposed to record 2 consecutive nights in healthy asymptomatic children in order to evaluate the night-to-night variability which has already shown to be small in older children. In this multicentre study 120 children will be recruited by the present study in France and the remaining 60 children in another English centre using the same design and technology. It is expected that only children with acute wheezing episode will have a significantly low EVI compare to the reference values established by this study.
AZ-SWED is a parallel group, double blind, placebo control efficacy clinical trial with two separate hypotheses. The trial will compare the 5-day outcome of preschool children presenting to an Emergency Department (ED) with an acute, severe wheezing episode and treated with either once daily oral Azithromycin (12 mg/kg/day for 5 days) or placebo. The AZ-SWED researchers will make separate comparisons in children in whom specific pathogenic bacteria are isolated from nasopharyngeal swabs, and in those in whom they are not isolated. The primary outcome will be the Asthma Flare-up Diary for Young Children (ADYC), a validated instrument that caregivers will transmit electronically daily after discharge from the ED. Families will be contacted daily during the five-day treatment to collect the ADYC, and to assess compliance and complications. A randomly chosen subset of enrolled children will participate in two follow-up visits 5-8 days and 14-21 days after visit 1 to assess development of resistance to study drug and treatment response related changes in the airway microbiome.
Bronchiolitis (BQ) is an acute viral infection of the lower respiratory tract that affects the bronchioles of babies younger than 24 months of age. Respiratory physiotherapy (FTR) appears as a complementary treatment measure in clinical guidelines and consensus on the management of BQ. Nebulization with 3% hypertonic serum before the FTR session induces an osmotic flow of water in the mucus, which facilitates drainage and reduces edema in the submucosal tissue.