Your search keyword '"Breath sound"' showing total 171 results

1. A framework of heart sound noise reduction using multi-channel structure.

Author

Guo, BinBin and Tang, Hong

Subjects

HEART sounds, CONVOLUTIONAL neural networks, INDEPENDENT component analysis, NOISE control, SPECTRUM analysis, SIGNAL-to-noise ratio

Abstract

• We proposed a novel method for noise reduction of multichannel heart sound signals, which was based on FastICA algorithm and CNN model. • The method performs classification and consistency analysis of the independent components to extract reliable independent components of heart sounds. • The method improves the SNRs of each channel signal up to 20 dB, which is superior to the Wiener filtering and singular spectrum analysis (SSA). Various noises could contaminate heart sounds and yield inaccurate diagnosis. This paper proposed a framework of heart sound noise reduction using multi-channel structure. Multi-channel heart sound (MCHS) signals were preprocessed, and then decomposed into independent components (ICs) using FastICA algorithm. The ICs were evaluated for consistency using correlation analysis, and reliable ICs were identified. The reliable ICs were classified based on a convolutional neural network (CNN) into two groups: one is of ICs for heart sounds and the other is of ICs for noise, respectively. Consequently, the MCHS signals were reconstructed from the ICs group of heart sounds. To validate the proposed framework, the MCHS signals of 15 subjects were acquired and mixed with breath sounds under different signal-to-noise ratios (SNRs). the simulation results showed that the framework had effective noise reduction performances in suppressing the breath sounds. The SNR of the denoised MCHS could be improved to 20 dB. the proposed framework was better than traditional methods, such as Wiener filter and singular spectrum analysis (SSA). The practical applications proved that the framework is possible to reconstruct the heart sound signals in low signal quality situation. [ABSTRACT FROM AUTHOR]

Published

2024

2. Real-Time Multi-Level Neonatal Heart and Lung Sound Quality Assessment for Telehealth Applications

Author

E. Grooby, C. Sitaula, D. Fattahi, R. Sameni, K. Tan, L. Zhou, A. King, A. Ramanathan, A. Malhotra, G. A. Dumont, and F. Marzbanrad

Subjects

Breath sound, deep learning, heart rate, heart sound, neonatal monitoring, ordinal regression, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

In this study, a new method is proposed to assess heart and lung signal quality objectively and automatically on a 5-level scale in real-time, and to assess the effect of signal quality on vital sign estimation. A total of 207 10 s long chest sounds were taken from 119 preterm and full-term babies. Thirty of the recordings from ten subjects were obtained with synchronous vital signs from the Neonatal Intensive Care Unit (NICU). As a reference, seven annotators independently assessed the signal quality. For automatic quality classification, 400 features were extracted from the chest sounds. After feature ranking and selection, class balancing, and hyperparameter optimization, a variety of multi-class and ordinal classification and regression algorithms were trained. Then, heart rate and breathing rate were automatically estimated from the chest sounds. For the deep learning model, YAMNet, a deep convolutional neural network pre-trained on the AudioSet-Youtube corpus for sound classification was used. After modification of the final output layers of the neural network and class balancing, transfer learning was applied to YAMNet for heart and lung signal quality classification. The results of subject-wise leave-one-out cross-validation show that the best-performing models had a balanced accuracy of 56.8% and 51.2% for heart and lung qualities, respectively. The best-performing models for real-time analysis (< 200 ms) had a balanced accuracy of 56.7% and 46.3%, respectively. Our experimental results underscore that increasing the signal quality leads to a reduction in vital sign error.

Published

2022

3. Nonlinear signal processing, spectral, and fractal-based stridor auscultation: A machine learning approach.

Author

Raj, Vimal, Renjini, A., Swapna, M. S., Sreejyothi, S., and Sankararaman, S.

Subjects

*SIGNAL processing, *MACHINE learning, *TIME series analysis, *FRACTAL analysis, *AUSCULTATION, *FISHER discriminant analysis

Abstract

The work reported in the paper analyses the adventitious stridor breath sound (ST) and the normal bronchial breath sound (BR) using spectral, fractal, and nonlinear signal processing methods. The sixty breath sound signals are subjected to power spectral density (PSD) and wavelet analyses to understand the temporal evolution of the frequency components. The energy envelope of the PSD plot of ST shows three peaks labeled as A (256 Hz), B (369 Hz), and C (540 Hz), of which A alone is present in BR at 265 Hz. The appearance of B and C in the PSD plot of ST is due to the obstructions in the trachea and upper airways caused by lesions. The phase portrait analysis of the time series data of ST and BR gives information about the dynamical system's randomness and sample entropy. The study reveals that the fractal dimension and sample entropy values are higher for BR, which may be due to the musical ordered behavior of ST. The machine learning techniques based on the features extracted from the PSD data and phase portrait parameters offer good predictability, besides the classification of BR and ST, thereby revealing its potential in pulmonary auscultation. [ABSTRACT FROM AUTHOR]

Published

2022

4. Acoustic Wave Technology

Author

Dey, Nilanjan, Ashour, Amira S., Mohamed, Waleed S., Nguyen, Nhu Gia, Neustein, Amy, Series Editor, Dey, Nilanjan, Ashour, Amira S., Mohamed, Waleed S., and Nguyen, Nhu Gia

Published

2019

5. Neonatal Heart and Lung Sound Quality Assessment for Robust Heart and Breathing Rate Estimation for Telehealth Applications.

Author

Grooby, Ethan, He, Jinyuan, Kiewsky, Julie, Fattahi, Davood, Zhou, Lindsay, King, Arrabella, Ramanathan, Ashwin, Malhotra, Atul, Dumont, Guy A., and Marzbanrad, Faezeh

Subjects

HEART sounds, FEATURE extraction, HEART beat, RESPIRATORY organ sounds, TELEMEDICINE, PREMATURE infants, FEATURE selection, NEONATOLOGY

Abstract

With advances in digital stethoscopes, internet of things, signal processing and machine learning, chest sounds can be easily collected and transmitted to the cloud for remote monitoring and diagnosis. However, low quality of recordings complicates remote monitoring and diagnosis, particularly for neonatal care. This paper proposes a new method to objectively and automatically assess the signal quality to improve the accuracy and reliability of heart rate (HR) and breathing rate (BR) estimation from noisy neonatal chest sounds. A total of 88 10-second long chest sounds were taken from 76 preterm and full-term babies. Six annotators independently assessed the signal quality, number of detectable beats, and breathing periods from these recordings. For quality classification, 187 and 182 features were extracted from heart and lung sounds, respectively. After feature selection, class balancing, and hyperparameter optimization, a dynamic binary classification model was trained. Then HR and BR were automatically estimated from the chest sound and several approaches were compared.The results of subject-wise leave-one-out cross-validation, showed that the model distinguished high and low quality recordings in the test set with 96% specificity, 81% sensitivity and 93% accuracy for heart sounds, and 86% specificity, 69% sensitivity and 82% accuracy for lung sounds. The HR and BR estimated from high quality sounds resulted in significantly less median absolute error (4 bpm and 12 bpm difference, respectively) compared to those from low quality sounds. The methods presented in this work, facilitates automated neonatal chest sound auscultation for future telehealth applications. [ABSTRACT FROM AUTHOR]

Published

2021

6. Using Sleep Monitoring System for Estimating and Analysing the Sleep Stages.

Author

Yuzhou Luo, Ping Wang, Kaijun Yu, Song Luo, and Longjie Sun

Abstract

In this work, the sleep stages discrimination by breath sounds have been used as characteristic parameters for monitoring sleeping condition. Our objective was to determine and verify a high performance algorithm to correlate the sleep stages with respective stages of breath sound signals. The algorithm was designed for breath sound signals and was tested with several all-night days data acquired with our laboratory-made sleep monitoring system. Furthermore, a commercial system was compared for validating the efficiency of our proposed algorithm. This work is the first study that successfully used breath sounds to classify sleeping conditions. The experiment validates the effectiveness of the proposed algorithm. [ABSTRACT FROM AUTHOR]

Published

2021

7. Real-World Verification of Artificial Intelligence Algorithm-Assisted Auscultation of Breath Sounds in Children

Author

Jing Zhang, Han-Song Wang, Hong-Yuan Zhou, Bin Dong, Lei Zhang, Fen Zhang, Shi-Jian Liu, Yu-Fen Wu, Shu-Hua Yuan, Ming-Yu Tang, Wen-Fang Dong, Jie Lin, Ming Chen, Xing Tong, Lie-Bin Zhao, and Yong Yin

Subjects

auscultation, breath sound, electronic stethoscope, artificial intelligence, children, Pediatrics, RJ1-570

Abstract

Objective: Lung auscultation plays an important role in the diagnosis of pulmonary diseases in children. The objective of this study was to evaluate the use of an artificial intelligence (AI) algorithm for the detection of breath sounds in a real clinical environment among children with pulmonary diseases.Method: The auscultations of breath sounds were collected in the respiratory department of Shanghai Children's Medical Center (SCMC) by using an electronic stethoscope. The discrimination results for all chest locations with respect to a gold standard (GS) established by 2 experienced pediatric pulmonologists from SCMC and 6 general pediatricians were recorded. The accuracy, sensitivity, specificity, precision, and F1-score of the AI algorithm and general pediatricians with respect to the GS were evaluated. Meanwhile, the performance of the AI algorithm for different patient ages and recording locations was evaluated.Result: A total of 112 hospitalized children with pulmonary diseases were recruited for the study from May to December 2019. A total of 672 breath sounds were collected, and 627 (93.3%) breath sounds, including 159 crackles (23.1%), 264 wheeze (38.4%), and 264 normal breath sounds (38.4%), were fully analyzed by the AI algorithm. The accuracy of the detection of adventitious breath sounds by the AI algorithm and general pediatricians with respect to the GS were 77.7% and 59.9% (p < 0.001), respectively. The sensitivity, specificity, and F1-score in the detection of crackles and wheeze from the AI algorithm were higher than those from the general pediatricians (crackles 81.1 vs. 47.8%, 94.1 vs. 77.1%, and 80.9 vs. 42.74%, respectively; wheeze 86.4 vs. 82.2%, 83.0 vs. 72.1%, and 80.9 vs. 72.5%, respectively; p < 0.001). Performance varied according to the age of the patient, with patients younger than 12 months yielding the highest accuracy (81.3%, p < 0.001) among the age groups.Conclusion: In a real clinical environment, children's breath sounds were collected and transmitted remotely by an electronic stethoscope; these breath sounds could be recognized by both pediatricians and an AI algorithm. The ability of the AI algorithm to analyze adventitious breath sounds was better than that of the general pediatricians.

Published

2021

8. Respiratory Monitoring

Author

Marr, Stacey, Dabbagh, Ali, editor, Conte, Antonio Hernandez, editor, and Lubin, Lorraine, editor

Published

2017

9. Hybrid method for noise rejection from breath sound using transient artifact reduction algorithm and spectral subtraction.

Author

Haider NS and Behera AK

Subjects

Humans, Pulmonary Disease, Chronic Obstructive physiopathology, Signal Processing, Computer-Assisted, Asthma physiopathology, Algorithms, Respiratory Sounds, Artifacts, Signal-To-Noise Ratio

Abstract

Objectives: Computerized breath sound based diagnostic methods are one of the emerging technologies gaining popularity in terms of detecting respiratory disorders. However, the breath sound signal used in such automated systems used to be too noisy, which affects the quality of the diagnostic interpretations. To address this problem, the proposed work presents the new hybrid approach to reject the noises from breath sound., Methods: In this method, 80 chronic obstructive pulmonary disease (COPD), 75 asthmatics and 80 normal breath sounds were recorded from the participants of a hospital. Each of these breath sound data were decontaminated using hybrid method of Butterworth band-pass filter, transient artifact reduction algorithm and spectral subtraction algorithm. The study examined the algorithms noise rejection potential over each category of breath sound by estimating the noise rejection performance metrics, i.e., mean absolute error (MAE), mean square error (MSE), peak signal to noise ratio (PSNR), and signal to noise ratio (SNR)., Results: Using this algorithm, the study obtained a high value of SNR of 70 dB and that of PSNR of 72 dB., Conclusions: The study could definitely a suitable one to suppress noises and to produce noise free breath sound signal., (© 2024 Walter de Gruyter GmbH, Berlin/Boston.)

Published

2024

10. Ingestión de cuerpo extraño (batería de botón) con presentación atípica en el lactante. Reporte de caso y revisión de la bibliografía.

Author

Banos-Rocha, Lina Margarita, Ignorosa-Arellano, Karen Rubi, Quesada-Tortoriello, Ana Isabel, Cadena-Leon, Jose Francisco, Toro-Monjaraz, Erick Manuel, Zarate-Mondragon, Flora E., Loredo-Mayer, Alejandro, Cervantes-Bustamante, Roberto, and Ramirez-Mayans, Jaime Alfonso

Abstract

BACKGROUND: Stridor is a high-pitched breath sound resulting from turbulent air flow in the narrowing areas of the large airways. A wide variety of differential diagnoses must be considered in the pediatric patient with stridor, including infectious and noninfectious causes, being foreign body aspiration as one of the etiologies to consider. CLINICAL CASE: Previously healthy 11-month-old infant with sudden stridor and 5-dayold refusal of food. He received 2 antimicrobial schemes without improvement, in a fortuitous way it was detected, in the thorax radiography, a rounded object, opaque radio, located in the superior third of the esophagus. A foreign body, similar to a button battery, was removed endoscopically, leaving an ulcerated lesion with areas of necrosis (Zargar IIB). It was treated with broad-spectrum antibiotics, steroids and parenteral nutrition. His progress was satisfactory, without complications. In the control endoscopy at 6 weeks a scar was noticed in the affected area. CONCLUSIONS: Cough and acute-onset stridor, followed by gastrointestinal manifestations such as vomiting and feeding refusal in infants and toddlers without a history of infectious disease, forced to rule out the presence of a foreign body, additional evaluation and endoscopic removal in an appropriate time. [ABSTRACT FROM AUTHOR]

Published

2020

11. Blow the balloon for the ease -- A cross-sectional study on wheezing patients.

Author

Lakshmi, Sree, Rani, S. Leslie, and Brundha, M. P.

Subjects

*EXPIRATORY flow, *LUNG volume, *PULMONARY function tests, *CROSS-sectional method, *STRENGTH training, *RESPIRATORY muscles

Abstract

Aim and Objective: The aim of the study was to evaluate the effect of balloon blowing exercise on wheezing patients. Introduction: Wheezing is a dynamic sign, occurs when airflow through narrowed airways, by creating vibrations in the audible frequency. In this highly polluted society, all age groups are affected invariably with respiratory diseases, in which wheezing is the most common condition. To control the severity of wheezing, Balloon blowing exercise has been introduced. It is cheap and can be followed by all age groups. The principle followed in blowing the balloon exercise is to increase the maximum expiratory volume of lungs. Materials and Methods: The sample size of 15 students of the age group 18-20 years was selected. They were given the balloon and asked to blow the balloon for the consecutive 30 days, both in the morning and evening for 15 min. The lung functions such as FVC, FEV1, and PEF were measured using spirometer before and after the exercise. Results and Discussion: There is a significant increase in the forced vital capacity (FVC) of wheezing patient after balloon blowing exercise. Among the respiratory function test parameters, only FVC showed a significant increase of P = 0.056. Since it is a pilot study, it had many limitations. Therefore, future studies need to be conducted with more subjects, measuring the balloon resistance accurately. Conclusions: Blowing the balloon strengthens the respiratory muscles and results in increased of forced vital capacity (FVC), forced expiratory volume in one sec (FEV1), and peak expiratory flow (PEF). This exercise improves pulmonary function and reduces the risk of lung disorder from wheezing. [ABSTRACT FROM AUTHOR]

Published

2020

12. Automated Diagnoses of Respiratory Health Problems Using Breathing Sounds

Author

Vong, John, Song, Insu, Fodor, János, Series editor, Rudas, Imre J., Series editor, Vong, John, and Song, Insu

Published

2015

13. Securing Online Medical Data

Author

Vong, John, Song, Insu, Fodor, János, Series editor, Rudas, Imre J., Series editor, Vong, John, and Song, Insu

Published

2015

14. Separation and Classification of Crackles and Bronchial Breath Sounds from Normal Breath Sounds Using Gaussian Mixture Model

Author

Haider, Ali, Ashraf, M. Daniyal, Azhar, M. Usama, Maruf, Syed Osama, Naqvi, Mehdi, Khawaja, Sajid Gul, Akram, M. Usman, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Kobsa, Alfred, Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Nierstrasz, Oscar, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Loo, Chu Kiong, editor, Yap, Keem Siah, editor, Wong, Kok Wai, editor, Teoh, Andrew, editor, and Huang, Kaizhu, editor

Published

2014

15. Is the Baby Normal?

Author

Hutson, John M., Beasley, Spencer W., Hutson, John M., and Beasley, Spencer W.

Published

2013

16. Auscultation of the respiratory system

Author

Malay Sarkar, Irappa Madabhavi, Narasimhalu Niranjan, and Megha Dogra

Subjects

Breath sound, bronchial breathing, crackles, rubs, wheeze, Diseases of the circulatory (Cardiovascular) system, RC666-701, Diseases of the respiratory system, RC705-779

Abstract

Auscultation of the lung is an important part of the respiratory examination and is helpful in diagnosing various respiratory disorders. Auscultation assesses airflow through the trachea-bronchial tree. It is important to distinguish normal respiratory sounds from abnormal ones for example crackles, wheezes, and pleural rub in order to make correct diagnosis. It is necessary to understand the underlying pathophysiology of various lung sounds generation for better understanding of disease processes. Bedside teaching should be strengthened in order to avoid erosion in this age old procedure in the era of technological explosion.

Published

2015

17. Neonatal Resuscitation

Author

Datta, Sanjay, Kodali, Bhavani Shankar, Segal, Scott, Datta, Sanjay, Kodali, Bhavani Shankar, and Segal, Scott

Published

2010

18. Common causes of congenital stridor in infants.

Author

Clark, Christine M., Kugler, Kathryn, and Carr, Michele M.

Subjects

PARALYSIS, CARTILAGE diseases, LARYNGEAL diseases, VOCAL cord diseases, FLUOROSCOPY, MEDICAL history taking, PHYSICAL diagnosis, RESPIRATORY obstructions, RESPIRATORY organ sounds, RESPIRATORY organ abnormalities, DISEASE complications, CHILDREN, DISEASE risk factors, PREVENTION

Abstract

Stridor is a high-pitched respiratory sound that signals upper airway obstruction. It can be encountered by clinicians in a variety of clinical settings and requires a team-based, interdisciplinary approach. Early recognition is crucial, as the differential diagnosis can be broad, and causes range from benign to life-threatening. This article reviews the most commonly encountered causes of chronic congenital stridor in infants, focusing on the diagnostic approach, pathophysiology, clinical presentation, and management strategies. [ABSTRACT FROM AUTHOR]

Published

2018

19. Approach to the Patient With a Respiratory Disorder

Author

Patel, Nirav, L., Matthew, Skolnik, Neil S., editor, and Mintz, Matthew L., editor

Published

2006

20. Case 64: An Anterior Mediastinal Mass. What Will You Do?

Author

Brock-Utne, John G. and Brock-Utne, John G.

Published

2013

21. Case 39: Rising End-Tidal Carbon Dioxide

Author

Brock-Utne, John G. and Brock-Utne, John G.

Published

2013

22. Case 24: Difficulty in Extubation

Author

Brock-Utne, John G. and Brock-Utne, John G.

Published

2013

23. ATLS Update: Case Studies in Trauma

Author

Girard, Daren and Cahill, John D., editor

Published

2003

24. A simple method for monitoring sleeping conditions by all-night breath sound measurement.

Author

Luo, Yuzhou and Jiang, Zhongwei

Subjects

*SLEEP, *RESPIRATORY measurements, *RESPIRATION, *SPECTRUM analysis, *TIME-domain analysis

Abstract

In this work, a simple method for monitoring sleeping conditions by all-night breath sound measurement is proposed. Our research target is to develop and validate a high performance method to classify sleeping conditions into several stages based on breath sound. Subjects were recorded in home/group house using bluetooth breath sound sensor. Breath sound-based features extracted from time and spectral domains can accurately discriminate between snore or non-snore and respiratory variance of breath sound, and so on. This breath sound signal analysis method enables detection and analysis of apnea/hypopnea. This work is the first study that successfully used simple method to monitor sleeping conditions. The experiment validate the effectiveness of the proposed method. [ABSTRACT FROM PUBLISHER]

Published

2017

25. Assessment of the Child with Respiratory Disease

Author

Hussey, Juliette, Prasad, S. Ammani, Prasad, S. Ammani, editor, Hussey, Juliette, editor, and Campling, Jo, editor

Published

1995

26. Die nächtliche Atemfrequenz bei COPD-Patienten unterschiedlicher GOLD-Schweregrade mit/ohne Nikotinkonsum: Berechnet mittels Atemgeräuschanalyse

Author

Simon Hofmann, Florian Schudt, Ulrich Koehler, C. Noeh, P. Fischer, Olaf Hildebrandt, Keywan Sohrabi, and Volker Gross

Subjects

Pulmonary and Respiratory Medicine, Gynecology, medicine.medical_specialty, Respiratory rate, business.industry, Copd patients, Breath sound, Pulmonary disease, Nicotine, 03 medical and health sciences, 0302 clinical medicine, 030228 respiratory system, Severity of illness, Medicine, 030212 general & internal medicine, business, medicine.drug

Abstract

ZusammenfassungDie Atemfrequenz ist ein wichtiger Risikomarker, mit dessen Hilfe kritisch kranke und gefährdete Patienten im klinischen Alltag frühzeitig erkannt werden können. Ziel dieser Pilotstudie an 31 Patienten der COPD-Schweregrade II – IV war es, die mittlere nächtliche Atemfrequenz anhand von Atemgeräuschaufnahmen zu bestimmen und die Abhängigkeit der Atemfrequenz von COPD-Schweregrad und Raucherstatus zu untersuchen. Die mittlere Atemfrequenz (AF) des Gesamtkollektivs betrug 19/min. Bei den COPD-GOLD-Schweregraden konnten keine signifikanten Unterschiede hinsichtlich der mittleren Atemfrequenz ermittelt werden. Unter Berücksichtigung des Nikotinkonsums zeigte sich bei den aktiven Rauchern eine signifikant höhere mittlere AF von 20,84 ± 4,45/min im Vergleich zu den Nichtrauchern mit 17,41 ± 3,14/min (p

Published

2019

27. Characteristics of breath sound in infants with risk factors for asthma development

Author

Shigemi Yoshihara, Shuichi Ito, Hiroyuki Mochizuki, Hideyuki Tabata, Mayumi Enseki, Kota Hirai, Hiroyuki Furuya, Masahiko Kato, Hiromi Shioya, Hiromi Tadaki, Fusae Yamazaki, and Manabu Miyamoto

Subjects

Male, 0301 basic medicine, lcsh:Immunologic diseases. Allergy, Pediatrics, medicine.medical_specialty, Allergy, Breath sound, Respiratory Syncytial Virus Infections, 03 medical and health sciences, 0302 clinical medicine, Risk Factors, Surveys and Questionnaires, Animals, Humans, Immunology and Allergy, Medicine, Medical History Taking, Respiratory Sounds, Asthma, business.industry, Area under the curve, Infant, Mean age, Pets, General Medicine, Atopic dermatitis, Limiting, medicine.disease, Hospitalization, 030104 developmental biology, 030228 respiratory system, Child, Preschool, Female, Tobacco Smoke Pollution, Airway, business, lcsh:RC581-607

Abstract

Background: Breath sound parameters have been suggested as biomarkers of the airway narrowing in children. Using a commercially available breath sound analyzer, the characteristics of the airway condition were investigated in infants with the risk factors for asthma development. Methods: A total of 443 infants (mean age, 9.9 months; range, 3–24 months) were included in the present study. The breath sound parameters of the frequency limiting 99% of the power spectrum (F99), the roll-off from 600 to 1200 Hz (Slope) and spectrum curve indices, the total area under the curve of the dBm data (A3/AT) and the ratio of power and frequency at 50% and 75% of the highest frequency of the power spectrum (RPF75 and RPF50), were evaluated. Using an ATS-DLD based original Japanese questionnaire, we examined the characteristics of airway condition of infants. Results: Finally, 283 infants in good health were included in the present study. The RPF75, RPF50, Slope and F99 in infants with positive results of allergy and atopic dermatitis were significantly increased more than those in the infants with negative result. Conclusions: Our data highlight the characteristics of breath sounds in infants with risk factors for asthma. The breath sound analysis may be useful for assessing the airways of infants for asthma development. Keywords: Asthma, Breath sound analysis, Infant, Risk factors, Sound spectrum

Published

2019

28. A breath sound analysis in children with cough variant asthma

Author

Kota Hirai, Hiroyuki Mochizuki, Hiromi Tadaki, Mariko Nukaga, Hideyuki Tabata, Masahiko Kato, and Mayumi Enseki

Subjects

lcsh:Immunologic diseases. Allergy, Male, Agonist, medicine.medical_specialty, Adolescent, medicine.drug_class, Breath sound, Internal medicine, medicine, Humans, Immunology and Allergy, Child, Adrenergic beta-2 Receptor Agonists, Cough variant asthma, Respiratory Sounds, Inhalation, business.industry, General Medicine, Limiting, medicine.disease, Asthma, Respiratory Function Tests, Chronic cough, Cough, Bronchial hyperresponsiveness, Child, Preschool, Cardiology, Female, medicine.symptom, lcsh:RC581-607, business

Abstract

Background: Cough variant asthma (CVA) is characterized by a chronic cough and bronchial hyperresponsiveness without confirmation of wheezing. Using a breath sound analyzer, we evaluate the characteristics of breath sound in children with CVA. Methods: Nine children with CVA (median age, 7.0 years) participated. The existence of breath sounds was confirmed by sound spectrogram. Breath sound parameters, the frequency limiting 50% and 99% of the power spectrum (F50 and F99), the roll-off from 600 to 1200 Hz (Slope) and spectrum curve indices, the ratio of the third and fourth area to the total area of the power spectrum (P3/PT and P4/PT) and the ratio of power and frequency at 50% and 75% of the highest frequency of the power spectrum (RPF75 and RPF50) were calculated before and after β2 agonist inhalation. A spirogram and/or forced oscillation technique were performed in all subjects. Results: On a sound spectrogram, wheezing was confirmed in seven of nine patients. All wheezing on the image was polyphonic, and they almost disappeared after β2 agonist inhalation. An analysis of the breath sound spectrum showed that PT, P3/PT, P4/PT, RPF50 and RPF75 were significantly increased after β2 agonist inhalation. Conclusions: Children with CVA showed a high rate of inaudible wheezing that disappeared after β2 agonist inhalation. Changes in the spectrum curve indices also indicated the bronchial reversibility. These results may suggest the characteristics of CVA in children. Keywords: Children, Chronic cough, Cough valiant asthma, Lung sound analysis, Wheezing

Published

2019

29. Case 45: Postoperative Respiratory Arrest

Author

Brock-Utne, John G. and Brock-Utne, John G.

Published

2013

30. Case 28: Pressurized Intravenous Hetastarch

Author

Brock-Utne, John G. and Brock-Utne, John G.

Published

2013

31. Case 12: Postinduction Difficult Intubation

Author

Brock-Utne, John G. and Brock-Utne, John G.

Published

2013

32. Auscultation of the respiratory system.

Author

Sarkar, Malay, Madabhavi, Irappa, Niranjan, Narasimhalu, and Dogra, Megha

Subjects

*AUSCULTATION, *RESPIRATORY organs, *RESPIRATORY organ sounds

Abstract

Auscultation of the lung is an important part of the respiratory examination and is helpful in diagnosing various respiratory disorders. Auscultation assesses airflow through the trachea-bronchial tree. It is important to distinguish normal respiratory sounds from abnormal ones for example crackles, wheezes, and pleural rub in order to make correct diagnosis. It is necessary to understand the underlying pathophysiology of various lung sounds generation for better understanding of disease processes. Bedside teaching should be strengthened in order to avoid erosion in this age old procedure in the era of technological explosion. [ABSTRACT FROM AUTHOR]

Published

2015

33. Using breath sound data to detect intraoperative respiratory depression in non-intubated anesthesia

Author

Hanjun Jiang, Huili Kan, Zhihua Wang, Ping Chen, Sikai Wang, Kang Zhao, Zongwang Zhang, Binjie Zhu, and Ming Liu

Subjects

General Computer Science, business.industry, Breath sound, Anesthesia, Medicine, Respiratory system, business, Depression (differential diagnoses)

Published

2021

34. The breath sound analysis for diseases diagnosis and stress measurement.

Author

Moedomo, Ria Lestari, Mardiyanto, M. Sukrisno, Ahmad, Munawar, Alisjahbana, Bachti, and Djatmiko, Tjahjono

Abstract

This research paper describes the study of the breath sound analysis and application development for two fold purposes: (1) for diseases diagnosis tool, specifically the lung and respiratory diseases; and (2) for stress measurement. The Lung Diseases Diagnosis Application consists of software and hardware components which formed a first-hand diagnosis tool of the lung diseases, to support the paramedics/doctors in lung diseases diagnosis. One of the most common and proven technique for lung disease diagnosis is the Auscultation, the term refers to listening to the internal sounds of the respiratory system (breath sounds), usually by using a stethoscope. However, this diagnosis way depends heavily on the listening skills and judgment of the paramedics/doctors only. In this research, we develop a new diagnosis tool with a new front-end equipment for the lung diseases diagnosis application: hand-phone equipped with a highly sensitive microphone, to record the breath-sound. This recorded breath-sound is then processed to generate the lung sound, which is approximately similar with the lung-sound heard and recorded by a stethoscope and the lung-sound is analysed to diagnose whether the patient's lung is healthy or not. This application would hopefully support the paramedics/doctors mobility to rural areas as well as remote diagnosis. The requirement is to create a first-hand diagnostic tool which allows paramedic mobility to rural areas for lung diseases diagnostic purposes. The study first describes about the existing lung diseases diagnostic tools and researches, stress measurement, then analysis and preliminary design of lung diseases diagnosis application. To enable each Lung Health Public Council (Balai Besar Kesehatan Paru Masyarakat) and Hospitals as data owner to maintain its own data, and to provide the data confidentiality as well, the cloud computing environment is then applied. Hopefully this research could serve both purposes: the lung diseases diagnosis and stress measurement. [ABSTRACT FROM PUBLISHER]

Published

2012

35. The lung diseases diagnosis software: Influenza and Tuberculosis case studies in the cloud computing environment.

Author

Lestari, Ria, Ahmad, Munawar, Alisjahbana, Bachti, and Djatmiko, Tjahjono

Abstract

This research paper describes study of the lung diseases diagnosis software with Influenza and Tuberculosis as the cases study. Influenza is a highly contagious infection of the respiratory tract. In Indonesia, numerous number of Avian-Influenza (H5N1) cases occurred in rural area, such as cases in Garut, Jawa Barat in 2006 which started in Cikelet district causing 14 infected-cases and 5 death-cases and has put Garut in an emergency situation until 2010. The H5N1 detection in rural area requires fast yet accurate diagnosis result to enable immediate curative actions. The most accurate result is provided by RT-PCR (Reverse-Transcription Polymerase-Chain-Reaction), which is high investment, and usually locates in urban area. Another diagnostic tool, rapid diagnostic test, is most common tool but gives inaccurate result because of its low sensitivity and specificity. In case of Tuberculosis, Indonesia ranks number 3, after India and China, as a country with most number of infected-people. Symptoms are chronic-cough with blood-tinged-sputum, fever, night-sweats and weight-loss. Tuberculosis is diagnosed by identifying Mycobacterium-tuberculosis organism in clinical sample. When this is not possible, probable diagnosis may be made using imaging X-rays or scans, tuberculin skin test and/or Interferon-Gamma-Release-Assay (IGRA). The main problem with tuberculosis diagnosis is difficulty in culturing this slow-growing organism in laboratory, which may take 4 to 12 weeks for blood or sputum-culture. The requirement is to create a first-hand diagnostic tool which allows paramedic mobility to rural areas for Influenza/Tuberculosis diagnostic purposes. The study first introduces lung auscultation method, then analysis and preliminary design of lung diseases diagnosis software. To enable each Lung Health for Public Council (Balai Besar Kesehatan Paru Masyarakat) and Health Service Office (Dinas Kesehatan) within province/region/country as data owner to maintain its own data, and to provide the data confidentiality as well, the cloud computing environment is then applied. [ABSTRACT FROM PUBLISHER]

Published

2012

36. Optimal watermarking scheme for breath sound.

Author

Lei, Baiying, Insu Song, and Rahman, Shah Atiqur

Abstract

In this paper, a new watermarking scheme for breath sound based on lifting wavelet transform (LWT), discrete cosine transform (DCT), singular value decomposition (SVD) and dither modulation (DM) quantization is proposed to embed encrypted source and identity information, and medical conditions, such as cold and flu symptoms in breath sound while preserving important biological signals for detecting breathing patterns and breathing rates. In the proposed scheme, LWT is first carried out to decompose the signal followed by applying DCT on the approximate coefficients. SVD is then performed on the LWT-DCT coefficients to get the singular values. The novelty of our proposed method includes the introduction of the particle swarm optimization (PSO) technique to optimization the quantization steps of the DM approach too. Simulation results show that our watermarking scheme achieves good robustness against common signal processing attacks and maintains the imperceptivity. The comparison results also show good performance of our scheme. [ABSTRACT FROM PUBLISHER]

Published

2012

37. Diagnosis of COVID-19 via acoustic analysis and artificial intelligence by monitoring breath sounds on smartphones.

Author

Chen, Zhiang, Li, Muyun, Wang, Ruoyu, Sun, Wenzhuo, Liu, Jiayi, Li, Haiyang, Wang, Tianxin, Lian, Yuan, Zhang, Jiaqian, and Wang, Xinheng

Abstract

Scientific evidence shows that acoustic analysis could be an indicator for diagnosing COVID-19. From analyzing recorded breath sounds on smartphones, it is discovered that patients with COVID-19 have different patterns in both the time domain and frequency domain. These patterns are used in this paper to diagnose the infection of COVID-19. Statistics of the sound signals, analysis in the frequency domain, and Mel-Frequency Cepstral Coefficients (MFCCs) are then calculated and applied in two classifiers, k-Nearest Neighbors (kNN) and Convolutional Neural Network (CNN), to diagnose whether a user is contracted with COVID-19 or not. Test results show that, amazingly, an accuracy of over 97% could be achieved with a CNN classifier and more than 85% on kNN with optimized features. Optimization methods for selecting the best features and using various metrics to evaluate the performance are also demonstrated in this paper. Owing to the high accuracy of the CNN model, the CNN model was implemented in an Android app to diagnose COVID-19 with a probability to indicate the confidence level. The initial medical test shows a similar test result between the method proposed in this paper and the lateral flow method, which indicates that the proposed method is feasible and effective. Because of the use of breath sound and tested on the smartphone, this method could be used by everybody regardless of the availability of other medical resources, which could be a powerful tool for society to diagnose COVID-19. [ABSTRACT FROM AUTHOR]

Published

2022

38. Content-based classification of breath sound with enhanced features.

Author

Lei, Baiying, Rahman, Shah Atiqur, and Song, Insu

Subjects

*RESPIRATORY disease diagnosis, *SOUNDS, *RESPIRATION, *MEDICAL needs assessment, *TIME-frequency analysis, TREATMENT of respiratory diseases

Abstract

Abstract: Since breath sound (BS) contains important indicators of respiratory health and disease, analysis and detection of BS has become an important topic, with diagnostic and assessment of treatment capabilities. In this paper, the identification and classification of respiratory disorders based on the enhanced perceptual and cepstral feature set (PerCepD) is proposed. The hybrid PerCepD feature can capture the time-frequency characteristics of BS very well. Thus, it is very effective for the exploration and classification of normal and pathological BS related data. The classification models based on support vector machine (SVM) and artificial neural network (ANN) have been adopted to achieve automatic detection from BS data. The high detection accuracy results validate the performance of the proposed feature sets and classification model. The experimental results also demonstrate that the high accuracy of the pathological BS data can provide reliable diagnostic suggestions for breath disorders, such as flu, pneumonia and bronchitis. [Copyright &y& Elsevier]

Published

2014

39. THE REMOTE ANALYSIS OF BREATH SOUND IN COVID-19 PATIENTS: A SERIES OF CLINICAL CASES

Author

Evgenii Furman, Sheludko, Charushin A, Sokolovsky, Eirikh E, Gregory B. Furman, and Sergey Malinin

Subjects

Sound (medical instrument), medicine.medical_specialty, medicine.diagnostic_test, Coronavirus disease 2019 (COVID-19), business.industry, Breath sound, Fast Fourier transform, Audiology, Remote analysis, Programming method, Computer analysis, medicine, Respiratory sounds, business

Abstract

BackgroundRespiratory sounds have been recognized as a possible indicator of behavior and health. Computer analysis of these sounds can indicate of characteristic sound changes caused by COVID-19 and can be used for diagnosis of this illness.PurposeThe communication aim is development of fast remote computer-assistance diagnosis of COVID-19, based on analysis of respiratory sounds.Materials and MethodsFast Fourier transform (FFT) was applied for analyses of respiratory sounds recorded near the mouth of 9 COVID-19 patients and 4 healthy volunteers. Sampling rate was 48 kHz.ResultsComparing of FFT spectrums of the respiratory sounds of the patients and volunteers we proposed numerical healthy-ill criterions.ConclusionsThe proposed computer method, based on analysis of the FFT spectrums of respiratory sounds of the patients and volunteers, allows one to automatically diagnose COVID-19 with sufficiently high diagnostic values. This method can be applied at development of noninvasive self-testing kits for COVID-19.

Published

2020

40. An alternative approach for continuous monitoring of heart and breath sounds in pediatric patients

Author

Muhammad Suleman, Dileep Kumar, Fauzia Anis Khan, and Summaiya Ali

Subjects

medicine.medical_specialty, Stethoscope, business.industry, Breath sound, Continuous monitoring, Anesthetic management, Precordial examination, Critical Care and Intensive Care Medicine, World health, law.invention, Esophageal stethoscope, Anesthesiology and Pain Medicine, law, Intensive care, Emergency medicine, Medicine, business

Abstract

Anesthetic management in neonates, infants and young children is always a challenge. Both esophageal and precordial stethoscopes are used for continuous monitoring of heart and breath sounds in this age group. Recent (2018) publication of Standards for Safe Practice of Anesthesia by World Health Organization-World Federation of Societies of Anesthesiologists (WHO-WFSA) have also recommended monitoring with a precordial or esophageal stethoscope. Citation: Kumar D, Ali S, Khan FA, Suleman M. An alternative approach for continuous monitoring of heart and breath sounds in pediatric patients. Anaesth pain & intensive care 2019;23(4):__ Received: 30 December 2019; Reviewed & Accepted: 31 December 2019

Published

2020

41. Study of Lung and Heart Diagnosis Application based on Frequency Separation of Breath Sound.

Author

Mardiyanto, Muhammad Sukrisno, Moedomo, Ria Lestari, and Munir, Achmad

Abstract

Abstract: In this paper, the study of lung and heart diagnosis application is investigated based on frequency separation of breath sound frequency. The aim of study is to investigate how to separate and process the breath sound frequency into lung sound frequency and heart sound frequency. Since the lung and the heart are the vital organ of human, therefore the needs of immediate preventive and curative actions are primarily important. Here, the frequency separation of breath sound is carried out by using the modulation filtering method. From the investigation, although the results still need some more improvement, however it shows that the method is implementable for the separation of lung sound and heart sound from the breath sounds frequency. It is then useful for the development of application for lung and heart diagnosis diseases. [Copyright &y& Elsevier]

Published

2013

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

Author

HABUKAWA, Chizu, MURAKAMI, Katsumi, MOCHIZUKI, Hiroyuki, TAKAMI, Satoru, MURAMATSU, Reiko, TADAKI, Hiromi, HAGIWARA, Satomi, MIZUNO, Takahisa, ARAKAWA, Hirokazu, and NAGASAKA, Yukio

Subjects

*WHEEZE, *METHACHOLINE compounds, *SPIROMETRY, *BRONCHODILATOR agents, *RESPIRATION

Abstract

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. [ABSTRACT FROM AUTHOR]

Published

2010

43. Changes in the breath sound spectrum during methacholine inhalation in children with asthma

Author

Hiroyuki Mochizuki, Masahiko Kato, Hideyuki Tabata, Hiroyuki Furuya, Mariko Nukaga, Shinichi Matsuda, Kota Hirai, and Mayumi Enseki

Subjects

Pulmonary and Respiratory Medicine, Inhalation, Breath sound, business.industry, Area under the curve, medicine.disease, 03 medical and health sciences, 0302 clinical medicine, 030228 respiratory system, Anesthesia, Bronchodilation, medicine, Methacholine, Bronchoconstriction, 030212 general & internal medicine, medicine.symptom, Airway, business, medicine.drug, Asthma

Abstract

Background and objective An effort-independent breath sound analysis is expected to be a safe and simple method for clinical assessment of changes in airway function. The effects of bronchoconstriction and bronchodilation on novel breath sound parameters in asthmatic children were investigated. Methods The study population included 49 children with atopic asthma (male = 33; mean age: 10.2 years). We evaluated breath sound parameters of the highest frequency of the power spectrum (HFp), frequency limiting 50% and 99% of the power spectrum (F50 and F99) and roll-off from 600 Hz to the HFp (Slope). We also assessed new parameters obtained using the ratios of sound spectrum parameters (spectrum curve indices), such as the ratio of the third and fourth power area to the total power area (P3/PT and P4/PT), the ratio of the third and fourth areas to the total area under the curve (A3/AT and B4/AT) and the ratio of power and frequency at 75% of HFp and 50% of HFp (RPF75 and RPF50). This was measured before and after methacholine inhalation challenge and after β2 agonist inhalation. Results The parameters, F50 and F99, showed no changes after methacholine inhalation. Conversely, the A3/AT (12.5–10.0%, P

Published

2017

44. A clinical method for detecting bronchial reversibility using a breath sound spectrum analysis in infants

Author

Mayumi Enseki, Mariko Nukaga, Kota Hirai, Hideyuki Tabata, Shinichi Matsuda, and Hiroyuki Mochizuki

Subjects

Male, Pulmonary and Respiratory Medicine, medicine.medical_specialty, Breath sound, Speech recognition, 03 medical and health sciences, 0302 clinical medicine, Inspiratory breath, Internal medicine, medicine, Humans, 030212 general & internal medicine, Respiratory Sounds, Asthma, Inhalation, business.industry, Spectrum Analysis, Infant, Bronchial Diseases, Mean age, medicine.disease, Frequency spectrum, Clinical method, Respiratory Function Tests, 030228 respiratory system, Child, Preschool, Cardiology, Female, Spectrum analysis, business

Abstract

Background Using a breath sound analyzer, we investigated clinical parameters for detecting bronchial reversibility in infants. Methods A total of 59 infants (4–39 months, mean age 7.8 months) were included. In Study 1 , the intra- and inter-observer variability was measured in 23 of 59 infants. Breath sound parameters, the frequency at 99% of the maximum frequency ( F 99 ), frequency at 25%, 50%, and 75% of the power spectrum (Q 25 , Q 50 , and Q 75 ), and highest frequency of inspiratory breath sounds (HFI), and parameters obtained using the ratio of parameters, i.e. spectrum curve indices, the ratio of the third and fourth area to total area ( A 3 / A T and B 4 / A T , respectively) and ratio of power and frequency at F 75 and F 50 (RPF 75 and RPF 50 ), were calculated. In Study 2 , the relationship between parameters of breath sounds and age and stature were studied. In Study 3 , breath sounds were studied before and after β 2 agonist inhalation. Results In Study 1 , the data showed statistical intra- and inter-observer reliability in A 3 / A T ( p =0.042 and 0.034, respectively) and RPF 50 ( p =0.001 and 0.001, respectively). In Study 2 , there were no significant relationships between age, height, weight, and BMI. In Study 3 , A 3 / A T and RPF 50 significantly changed after β 2 agonist inhalation ( p =0.001 and p Conclusions Breath sound analysis can be performed in infants, as in older children, and the spectrum curve indices are not significantly affected by age-related factors. These sound parameters may play a role in the assessment of bronchial reversibility in infants.

Published

2017

45. A simple method for monitoring sleeping conditions by all-night breath sound measurement

Author

Yuzhou Luo and Zhongwei Jiang

Subjects

Computer science, Breath sound, business.industry, Applied Mathematics, digestive, oral, and skin physiology, 0206 medical engineering, 02 engineering and technology, medicine.disease, 020601 biomedical engineering, otorhinolaryngologic diseases, 0202 electrical engineering, electronic engineering, information engineering, medicine, 020201 artificial intelligence & image processing, Computer vision, Artificial intelligence, business, Hypopnea, Analysis

Abstract

In this work, a simple method for monitoring sleeping conditions by all-night breath sound measurement is proposed. Our research target is to develop and validate a high performance method to classify sleeping conditions into several stages based on breath sound. Subjects were recorded in home/group house using bluetooth breath sound sensor. Breath sound-based features extracted from time and spectral domains can accurately discriminate between snore or non-snore and respiratory variance of breath sound, and so on. This breath sound signal analysis method enables detection and analysis of apnea/hypopnea. This work is the first study that successfully used simple method to monitor sleeping conditions. The experiment validate the effectiveness of the proposed method.

Published

2017

46. An Overview of Respiratory Airflow Estimation Techniques: Acoustic vs Non-Acoustic

Author

Nurulfajar Abd Manap, Priya Devi Muthusamy, and Kenneth Sundaraj

Subjects

Estimation, Respiratory Airflow, Signal processing, Future studies, Respiratory flow, Breath sound, Computer science, Flow estimation, Airflow, Control engineering

Abstract

The primary objective of this analysis to provide an overview of the respiratory airflow estimation techniques, including both acoustic and non-acoustic approaches. This paper also highlights and addresses the applications where the breathing flow estimation was found to be crucial. The detailed summary of both acoustic and non-acoustic techniques were presented. The non-acoustic methods require airflow measurement devices or sensors whereas the acoustic methods only involve processing of breath sound signals to estimate airflow. A brief discussion of the advantages and disadvantages of the acoustic and non-acoustic approaches of respiratory flow estimation were included in this article. The literature discloses that current advances in computing technology provide a platform to integrate the signal processing methods and machine learning algorithms to estimate airflow non-invasively. The future studies to be extended after estimation the respiratory flow also were addressed in the paper.

Published

2019

47. Assessment of breath sounds at birth using digital stethoscope technology

Author

Faezeh Marzbanrad, Fatema Tuz Zohra, Ajay Kevat, Robert Roseby, Mathieu Acchiardi, Kenneth Tan, Atul Malhotra, and Ashwin Ramanathan

Subjects

Adult, medicine.medical_specialty, Stethoscope, Breath sound, Frequency profile, Audiology, law.invention, law, Pregnancy, medicine, Humans, Prospective Studies, Respiratory Sounds, business.industry, Vaginal delivery, Stethoscopes, Infant, Newborn, Delivery mode, Mode of delivery, Auscultation, Case-Control Studies, Pediatrics, Perinatology and Child Health, Sound analysis, Female, Elective caesarean section, business

Abstract

Newborn transition is a phase of complex change involving lung fluid clearance and lung aeration. We aimed to use a digital stethoscope (DS) to assess the change in breath sound characteristics over the first 2 h of life and its relationship to mode of delivery. A commercially available DS was used to record breath sounds of term newborns at 1-min and 2-h post-delivery via normal vaginal delivery (NVD) or elective caesarean section (CS). Sound analysis was conducted, and two comparisons were carried out: change in frequency profiles over 2 h, and effect of delivery mode. There was a significant drop in the frequency profile of breath sounds from 1 min to 2 h with mean (SD) frequency decreasing from 333.74 (35.42) to 302.71 (47.19) Hz, p 0.001, and proportion of power (SD) in the lowest frequency band increasing from 0.27 (0.11) to 0.37 (0.15), p 0.001. At 1 min, NVD infants had slightly higher frequency than CS but no difference at 2 h.Conclusion: We were able to use DS technology in the transitioning infant to depict significant changes to breath sound characteristics over the first 2 h of life, reflecting the process of lung aeration.What is Known:• Lung fluid clearance and lung aeration are critical processes that facilitate respiration and mode of delivery can impact this• Digital stethoscopes offer enhanced auscultation and have been used in the paediatric population for the assessment of pulmonary and cardiac soundsWhat is New:• This is the first study to use digital stethoscope technology to assess breath sounds at birth• We describe a change in breath sound characteristics over the first 2 h of life and suggest a predictive utility of this analysis to predict the development of respiratory distress in newborns prior to the onset of symptoms.

Published

2019

48. Breath Sounds Recognition and Classification for Respiration System Diseases

Author

Chao Jiang, Lichuan Liu, and Wei Li

Subjects

0508 media and communications, Breath sound, Computer science, Speech recognition, 0502 economics and business, 05 social sciences, Pattern recognition (psychology), Respiratory morbidity, 050801 communication & media studies, 050211 marketing, Active listening

Abstract

One of the most common reasons for children consulting a general practitioner is respiratory morbidity. For healthcare providers, listening to breath sounds is an important diagnose method for respiration system diseases. However, parents and caregivers dont always have the required knowledge and experience to identify children's various breath sounds. Also, it is extremely hard to obtain feedback from young children about their physical conditions. Therefore, it is necessary to provide a tool to monitor young children healthy condition. In this paper, we propose novel approaches to recognize and classify children's breath sounds. We obtain and analyze audio features of young children's breath sound signals in time and frequency domains, based on these features, classify breath signals to specific breath segments. Nearest neighborhood (NN) and artificial neural network (ANN) were used for pattern recognition and classification. Clinical data were used to design and verify the proposed approaches. Experiments show that the proposed approaches offer accurate results.

Published

2019

49. Classification of Snoring Sound-Related Signals Based on MLP

Author

Huancheng Liu, Xiaoyu Shi, Xinpeng Zhang, and Limin Hou

Subjects

Sound (medical instrument), business.industry, Breath sound, Computer science, Process (computing), Breathing sounds, Pattern recognition, 02 engineering and technology, 03 medical and health sciences, Noise, 0302 clinical medicine, Feature (computer vision), Multilayer perceptron, 0202 electrical engineering, electronic engineering, information engineering, 020201 artificial intelligence & image processing, Artificial intelligence, business, 030217 neurology & neurosurgery, Dropout (neural networks)

Abstract

An efficient method to classify snore, breath sound and other noises based on the multilayer perceptron (MLP) was proposed in this paper. The spectral-related feature sets of the sound were extracted and used as the input feature of MLP. The minbatch training was designed to get the effective MLP model in training process. The dropout method was applied to optimize the structure of MLP. The correct rates for distinguishing snoring, breathing sounds, and other noises are 98.88%, 97.36%, and 95.15%, respectively.

Published

2019

50. 'Velcro-type' crackles predict specific radiologic features of fibrotic interstitial lung disease

Author

Sgalla, G, Walsh, S, Sverzellati, N, Fletcher, S, Cerri, S, Dimitrov, B, Nikolic, D, Barney, A, Pancaldi, F, Larcher, L, Luppi, F, Jones, M, Davies, D, Richeldi, L, Walsh, SLF, Jones, MG, Sgalla, G, Walsh, S, Sverzellati, N, Fletcher, S, Cerri, S, Dimitrov, B, Nikolic, D, Barney, A, Pancaldi, F, Larcher, L, Luppi, F, Jones, M, Davies, D, Richeldi, L, Walsh, SLF, and Jones, MG

Abstract

Background: "Velcro-type" crackles on chest auscultation are considered a typical acoustic finding of Fibrotic Interstitial Lung Disease (FILD), however whether they may have a role in the early detection of these disorders has been unknown. This study investigated how "Velcro-type" crackles correlate with the presence of distinct patterns of FILD and individual radiologic features of pulmonary fibrosis on High Resolution Computed Tomography (HRCT). Methods: Lung sounds were digitally recorded from subjects immediately prior to undergoing clinically indicated chest HRCT. Audio files were independently assessed by two chest physicians and both full volume and single HRCT sections corresponding to the recording sites were extracted. The relationships between audible "Velcro-type" crackles and radiologic HRCT patterns and individual features of pulmonary fibrosis were investigated using multivariate regression models. Results: 148 subjects were enrolled: bilateral "Velcro-type" crackles predicted the presence of FILD at HRCT (OR 13.46, 95% CI 5.85-30.96, p < 0.001) and most strongly the Usual Interstitial Pneumonia (UIP) pattern (OR 19.8, 95% CI 5.28-74.25, p < 0.001). Extent of isolated reticulation (OR 2.04, 95% CI 1.62-2.57, p < 0.001), honeycombing (OR 1.88, 95% CI 1.24-2.83, < 0.01), ground glass opacities (OR 1.74, 95% CI 1.29-2.32, p < 0.001) and traction bronchiectasis (OR 1.55, 95% CI 1.03-2.32, p < 0.05) were all independently associated with the presence of "Velcro-type" crackles. Conclusions: "Velcro-type" crackles predict the presence of FILD and directly correlate with the extent of distinct radiologic features of pulmonary fibrosis. Such evidence provides grounds for further investigation of lung sounds as an early identification tool in FILD.

Published

2018