Asthma exacerbation, colds?
React wisely.

Detect the sounds your child makes in the course of pneumonia or bronchitis

Auscultate your child at home when you are concerned.
You will know the result right away.

Did StethoMe® detect abnormal sounds? Speak to your child’s doctor immediately. You can send the doctor a recording and auscultation results.

Act faster.

Detect the sounds your child makes in the course of pneumonia or bronchitis

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Auscultate your child at home when you are concerned.
You will know the result right away.

Did StethoMe® detect abnormal sounds? Speak to your child’s doctor immediately. You can send the doctor a recording and auscultation results.

Act faster.

Are you sure you are administering relievers at the right time?

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Are you sure you are administering relievers at the right time?

Parents often have doubts about whether to administer a reliever, when to do so and whether it worked.

Administer relievers when there are medical indications for their use.

StethoMe® detects the wheezes and rhonchi that are characteristic of obstruction.

Don’t just guess – be in control.

Parents often have doubts about whether to administer a reliever, when to do so and whether it worked.

Administer relievers when there are medical indications for their use.

StethoMe® detects the wheezes and rhonchi that are characteristic of obstruction.

Don’t just guess – be in control.

Prevent exacerbations more effectively

Regular anti-inflammatory drugs should reduce the chance of exacerbations.

The exacerbation of a child's condition is similar to a volcanic eruption. The gentle tremors that announce an explosion can be detected by sophisticated seismographs.

StethoMe® is extremely sensitive and detects wheezes previously only perceptible to a doctor equipped with a stethoscope. If wheezing occurs during the administration of anti-inflammatory drugs, it may be a signal for the doctor to change their dosage.

Auscultate your child every few days for 30 seconds. Detect silent wheezes at home and follow up with your doctor to respond appropriately.

Don't wait for coughing, shortness of breath, or respiratory wheezes audible to the ‘naked ear’. Advanced exacerbation is more difficult to manage and may require bronchodilators.

Act sooner.

Prevent exacerbations more effectively

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Regular anti-inflammatory drugs should reduce the chance of exacerbations.

The exacerbation of a child's condition is similar to a volcanic eruption. The gentle tremors that announce an explosion can be detected by sophisticated seismographs.

StethoMe® is extremely sensitive and detects wheezes previously only perceptible to a doctor equipped with a stethoscope. If wheezing occurs during the administration of anti-inflammatory drugs, it may be a signal for the doctor to change their dosage.

Auscultate your child every few days for 30 seconds. Detect silent wheezes at home and follow up with your doctor to respond appropriately.

Don't wait for coughing, shortness of breath, or respiratory wheezes audible to the ‘naked ear’. Advanced exacerbation is more difficult to manage and may require bronchodilators.

Act sooner.

Always keep a complete medical history on hand

Medical history

Medical history

The app will find all studies with drug and symptom details. If necessary, show them to your doctor. The more your doctor knows, the more effectively your child can be treated.

Sending the results

Sending the results

Wherever you are, you can send any doctor a link to the website with the examination result by a text message or an email. To read it, your doctor does not need to be familiar with StethoMe® or be registered on our platform.

Auscultate your child at home and know the result right away

The system detects abnormal auscultation sounds and measures respiratory parameters, which are key in controlling asthma, but may also signal other diseases. For example, pneumonia, bronchitis and infections of the airways.

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1

Turn on the stethoscope and the StethoMe® application on your phone. The devices connect automatically.

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2

Place the stethoscope on your child's chest. The system will guide you throughout the process, and will inform you if the measurement is wrong or the surroundings are too noisy. Read the instructions.

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You can see if the examination shows the sounds characteristic of pneumonia and bronchitis or asthma exacerbations.

StethoMe® will inform you immediately if any of the parameters analysed are abnormal.

Join other satisfied parents

Rest assured that we are trusted and reliable

Imagine a physician who has gathered the expertise from performing and interpreting more than 42,000 respiratory auscultations in children. Someone who is never tired, is in an excellent mood and is always available to you.

Introducing StethoMe®. Home medical stethoscope, which is the result of over 5 years of work by 60 experts and scientists.

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Scientific papers / Clinical Trials

At StethoMe®, we place tremendous value on the science behind our solutions. We share our knowledge by publishing our study results in the best scientific journals and by working closely with the scientific community.

Frontiers in Physiology

Artificial Intelligence Approach to the Monitoring of Respiratory Sounds in Asthmatic Patients

Background

Effective and reliable monitoring of asthma at home is a relevant factor that may reduce the need to consult a doctor in person.

Aim

We analyzed the possibility to determine intensities of pathological breath phenomena based on artificial intelligence (AI) analysis of sounds recorded during standard stethoscope auscultation.

Methods

The evaluation set comprising 1,043 auscultation examinations (9,319 recordings) was collected from 899 patients. Examinations were assigned to one of four groups: asthma with and without abnormal sounds (AA and AN, respectively), no-asthma with and without abnormal sounds (NA and NN, respectively). Presence of abnormal sounds was evaluated by a panel of 3 physicians that were blinded to the AI predictions. AI was trained on an independent set of 9,847 recordings to determine intensity scores (indexes) of wheezes, rhonchi, fine and coarse crackles and their combinations: continuous phenomena (wheezes + rhonchi) and all phenomena. The pair-comparison of groups of examinations based on Area Under ROC-Curve (AUC) was used to evaluate the performance of each index in discrimination between groups.

Results

Best performance in separation between AA and AN was observed with Continuous Phenomena Index (AUC 0.94) while for NN and NA. All Phenomena Index (AUC 0.91) showed the best performance. AA showed slightly higher prevalence of wheezes compared to NA.

Conclusions

The results showed a high efficiency of the AI to discriminate between the asthma patients with normal and abnormal sounds, thus this approach has a great potential and can be used to monitor asthma symptoms at home.

Hafke-Dys H, Kuźnar-Kamińska B, Grzywalski T, Maciaszek A, Szarzyński K, Kociński J.
PLoS ONE

The accuracy of lung auscultation in the practice of physicians and medical students

Background

Auscultation is one of the first examinations that a patient is subjected to in a GP’s office, especially in relation to diseases of the respiratory system. However it is a highly subjective process and depends on the physician’s ability to interpret the sounds as determined by his/ her psychoacoustical characteristics.
Here, we present a cross-sectional assessment of the skills of physicians of different specializations and medical students in the classification of respiratory sounds in children.

Methods and findings

185 participants representing different medical specializations took part in the experiment. The experiment comprised 24 respiratory system auscultation sounds. The participants were tasked with listening to, and matching the sounds with provided descriptions of specific sound classes. The results revealed difficulties in both the recognition and description of respiratory sounds. The pulmonologist group was found to perform significantly better than other groups in terms of number of correct answers. We also found that performance significantly improved when similar sound classes were grouped together into wider, more general classes.

Conclusions

These results confirm that ambiguous identification and interpretation of sounds in auscultation is a generic issue which should not be neglected as it can potentially lead to inaccurate diagnosis and mistreatment. Our results lend further support to the already widespread acknowledgment of the need to standardize the nomenclature of auscultation sounds (according to European Respiratory Society, International Lung Sounds Association and American Thoracic Society). In particular, our findings point towards important educational challenges in both theory (nomenclature) and practice (training).

Honorata Hafke-Dys, Anna Bręborowicz, Paweł Kleka, Jędrzej Kociński, Adam Biniakowski
European Journal of Pediatrics

Practical implementation of artificial intelligence algorithms in pulmonary auscultation examination

Lung auscultation is an important part of a physical examination. However, its biggest drawback is its subjectivity. The results depend on the experience and ability of the doctor to perceive and distinguish pathologies in sounds heard via a stethoscope. This paper investigates a new method of automatic sound analysis based on neural networks (NNs), which has been implemented in a system that uses an electronic stethoscope for capturing respiratory sounds. It allows the detection of auscultatory sounds in four classes: wheezes, rhonchi, and fine and coarse crackles. In the blind test, a group of 522 auscultatory sounds from 50 pediatric patients were presented, and the results provided by a group of doctors and an artificial intelligence (AI) algorithm developed by the authors were compared. The gathered data show that machine learning (ML)–based analysis is more efficient in detecting all four types of phenomena, which is reflected in high values of recall (also called as sensitivity) and F1-score.

Conclusions: The obtained results suggest that the implementation of automatic sound analysis based on NNs can significantly improve the efficiency of this form of examination, leading to a minimization of the number of errors made in the interpretation of auscultation sounds.

Tomasz Grzywalski, Mateusz Piecuch, Marcin Szajek, Anna Bręborowicz, Honorata Hafke-Dys, Jędrzej Kociński, Anna Pastusiak, Riccardo Belluzzo
ERS International Congress

Respiratory system auscultation using machine learning - a big step towards objectivisation?

A stethoscope, introduced more than two centuries ago, is still a tool providing potentially valuable information gained during one of the most common examinations. However, the biggest drawback of auscultation is its subjectivity. It depends mainly on the experience and ability of the doctor to perceive and distinguish pathological signals. Many research has shown very low efficiency of doctors in this area.

Moreover, most of physicians are aware of this problem and needs supporting device. Therefore we have developed the Artificial Intelligence (AI) algorithms which recognise pathological sounds (wheezes, rhonchi, fine and coarse crackles). Here we present the comparison of the performance of physicians and AI in detection of those sounds.

A database of more than 10 000 recordings described by a consilium of specialists (pulmonologists and acousticians) was used for AI learning. Then another set of more than 500 real auscultatory sounds were used to investigate the efficiency of AI in comparison to a group of doctors. The standard F1-score was used for evaluation, because it considers both the precision and the recall. For each phenomena, the results for the AI is higher than for doctors with an average advantage of 8.4 percentage points, reaching even 13,5 p.p. for fine crackles.

The results suggest that the implementation of AI can significantly improve the efficiency of auscultation in everyday practice making it more objective, leading to a minimization of errors. The solution is now being tested with a group of hospitals and medical providers and proves its efficiency and usability in everyday practice making this examination faster and more reliable.

Tomasz Grzywalski, Marcin Szajek, Honorata Hafke-Dys, Anna Bręborowicz, Jędrzej Kociński, Anna Pastusiak, Riccardo Belluzzo
Artificial Intelligence in Medicine

Fully Interactive Lungs Auscultation with AI Enabled Digital Stethoscope

Performing an auscultation of respiratory system normally requires the presence of an experienced doctor, but the most recent advances in artificial intelligence (AI) open up a possibility for the laymen to perform this procedure by himself in home environment. However, to make it feasible, the system needs to include two main components: an algorithm for fast and accurate detection of breath phenomena in stethoscope recordings and an AI agent that interactively guides the end user through the auscultation process. In this work we present a system that solves both of these problems using state-of-the-art machine learning al gorithms. Our breath phenomena detection model was trained on 5000 stethoscope recordings of both sick (hospitalized) and healthy children. All recordings were labeled by a pulmonologist and acousticians. Trained model shows nearly optimal performance in terms of both sensitivity and specificity when tested on unseen recordings. The agent is able to accurately assess patient’s lung health status by auscultating only 3 out of 12 locations on average. The decision about each next auscultation location or end of examination is made dynamically, after each recording, based on breath phenomena detected so far. This allows the agent to make best prediction even if the auscultation is time-constrained.

Tomasz Grzywalski, Riccardo Belluzzo, Mateusz Piecuch, Marcin Szajek, Anna Bręborowicz, Anna Pastusiak, Honorata Hafke-Dys, Jędrzej Kociński
Conference on Agents and Artificial Intelligence - ICAART

Interactive Lungs Auscultation with Reinforcement Learning Agent

To perform a precise auscultation for the purposes of examination of respiratory system normally requires the presence of an experienced doctor. With most recent advances in machine learning and artificial intelligence, automatic detection of pathological breath phenomena in sounds recorded with stethoscope becomes a reality. But to perform a full auscultation in home environment by layman is another matter, especially if the patient is a child. In this paper we propose a unique application of Reinforcement Learning for training an agent that interactively guides the end user throughout the auscultation procedure. We show that intelligent selection of auscultation points by the agent reduces time of the examination fourfold without significant decrease in diagnosis accuracy compared to exhaustive auscultation.

Tomasz Grzywalski, Riccardo Belluzzo, Szymon Drgas, Agnieszka Cwalińska, Honorata Hafke-Dys
IEEE International Conference on Big Data

Parameterization of Sequence of MFCCs for DNN-based voice disorder detection

In this article a DNN-based system for detection of three common voice disorders (vocal nodules, polyps and cysts; laryngeal neoplasm; unilateral vocal paralysis) is presented. The input to the algorithm is (at least 3-second long) audio recording of sustained vowel sound /a:/. The algorithm was developed as part of the ”2018 FEMH Voice Data Challenge” organized by Far Eastern Memorial Hospital and obtained score value (defined in the challenge specification) of 77.44. This was the second best result before final submission. Final challenge results are not yet known during writing of this document. The document also reports changes that were made for the final submission which improved the score value in cross-validation by 0.6% points.

Tomasz Grzywalski., Adam Maciaszek, Adam Biniakowski, JanOrwat, Szymon Drgas, Mateusz Piecuch, Riccardo Belluzzo, Krzysztof Joachimiak, Dawid Niemiec, Jakub Ptaszyński, Krzysztof Szarzyński
Biochemistry, Molecular Biology & Allergy

Opportunities for domestic monitoring of children with an electronic stethoscope with automatic auscultation sound analysis system

In case of children suffering from chronic diseases of respiratory system, including asthma, it is very important to track any changes in the respiratory system condition. Domestic patient monitoring is becoming more and more popular. It is much more comfortable for patients who are less stressed, being relieved from any necessity to attend doctor’s offices, and are not exposed to pathogens present in medical facilities. Furthermore, it is also important for the attending physician who is provided with documented data. Until now, any aggravation of a past disease has been reported by children’s parents during medical appointments. Such method for providing information entails potential miscommunication, misjudgement and highly biased evaluation. a solution might be an electronic stethoscope, providing easy way to examine children in domestic conditions and to record auscultation results. Currently, it is possible to record auscultation sounds, provide a doctor with remote access to such records, and also to report any appearance of specific sounds and their intensity. Based on collaboration with scientific centres, there is a solution being developed: StethoMe®, a smart stethoscope, designed to provide a patient with a method for domestic auscultation. This system enables recording of auscultation sounds, submitting them to a physician and automatic classification of recorded sounds in four lasses: wheezes, fine crackles, coarse crackles and rhonchi, according to [1]. a physician may see a panel with provided access to sounds, their spectrograms, being visualisations of sounds facilitating their interpretation, and also an algorithm report, related to potential appearance of specific pathologies. This solutions is currently under development and in a testing phase in Europe.

Honorata Hafke-Dys, Anna Zelent

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