This study delves into the life and significant contributions of René Théophile Hyacinthe Laennec,a prominent French physician of the 19^(th) century,and thoroughly examines his revolutionary creation,the st...This study delves into the life and significant contributions of René Théophile Hyacinthe Laennec,a prominent French physician of the 19^(th) century,and thoroughly examines his revolutionary creation,the stethoscope.Laennec’s innovative spirit not only revolutionized medical diagnosis during his time but also left a lasting imprint on the broader field of medicine,influencing healthcare for generations.This extensive inquiry covers various aspects,including his historical context,the development of the stethoscope,its profound implications for medical diagnosis,and its enduring impact on the history of medicine.展开更多
The practice of cardiac auscultation is a critical tool used by physicians to detect alterations in the cardiovascular system. A case of both left and right sided endocarditis initially detected by electronic ausculta...The practice of cardiac auscultation is a critical tool used by physicians to detect alterations in the cardiovascular system. A case of both left and right sided endocarditis initially detected by electronic auscultation in a woman with a history of injection drug use is described. The electronic stethoscope, with the ability to amplify heart sounds, established the presence of both a systolic and diastolic murmur when standard auscultation failed to detect the diastolic component. Urgent standard echocardiography confirmed concurrent tricuspid and aortic valves endocarditis, and the patient was referred for surgical evaluation urgently. The present case demonstrates the value of the electronic stethoscope to amplify murmurs in the early detection of endocarditis. The case presented also serves as a useful reminder that right-sided endocarditis can have important leftsided complications.展开更多
Diseases of the cardiovascular system are one of the major causes of death worldwide.These diseases could be quickly detected by changes in the sound created by the action of the heart.This dynamic auscultations need ...Diseases of the cardiovascular system are one of the major causes of death worldwide.These diseases could be quickly detected by changes in the sound created by the action of the heart.This dynamic auscultations need extensive professional knowledge and emphasis on listening skills.There is also an unmet requirement for a compact cardiac condition early warning device.In this paper,we propose a prototype of a digital stethoscopic system for the diagnosis of cardiac abnormalities in real time using machine learning methods.This system consists of three subsystems that interact with each other(1)a portable digital subsystem of an electronic stethoscope,(2)a decision-making subsystem,and(3)a subsystemfor displaying and visualizing the results in an understandable form.The electronic stethoscope captures the patient’s phonocardiographic sounds,filters and digitizes them,and then sends the resulting phonocardiographic sounds to the decision-making system.The decision-making systemclassifies sounds into normal and abnormal using machine learning techniques,and as a result identifies abnormal heart sounds.The display and visualization subsystem demonstrates the results obtained in an understandable way not only for medical staff,but also for patients and recommends further actions to patients.As a result of the study,we obtained an electronic stethoscope that can diagnose cardiac abnormalities with an accuracy of more than 90%.More accurately,the proposed stethoscope can identify normal heart sounds with 93.5%accuracy,abnormal heart sounds with 93.25%accuracy.Moreover,speed is the key benefit of the proposed stethoscope as 15 s is adequate for examination.展开更多
Stethoscopes are commonly used to diagnose cardiac and respiratory diseases.The advent of digital stethoscopes added the capability to remotely monitor the cardiorespiratory well-being of patients and facilitate digit...Stethoscopes are commonly used to diagnose cardiac and respiratory diseases.The advent of digital stethoscopes added the capability to remotely monitor the cardiorespiratory well-being of patients and facilitate digital remote auscultations for physicians to examine their patients outside of the clinic.To increase the adoption of a hybrid diagnosis between in-person and remote auscultations,it is important to characterize the frequency response of different configurations of digital stethoscopes.A standard testing platform was adopted from the literature and re-validated by seven physicians.Two wearable and two non-wearable digital stethoscopes were investigated.A similarity factor score was used to analyze select time-synchronized acoustic events that achieved high fidelity between stethoscopes.The frequency responses between devices were compared using the correlation coefficient.Two devices reported the highest correlation coefficient of 0.72 and 0.75 in the wearable and non-wearable categories,respectively.The correlation coefficient of the frequency responses between the same pair of devices on the human chest was 0.91.With such a high agreement in the frequency response between the wearable and non-wearable digital stethoscope,it can be concluded that the configuration of digital stethoscope is not a limiting factor of performance,and both are acceptable and desirable for physicians to adopt either configuration in remote delivery of healthcare.展开更多
The outbreak and spread of coronavirus disease 2019(COVID-19)are not only a disaster of people’s life and health over the world,[1–3]but also the challenge for medical practitioner in clinical management.Owing to ma...The outbreak and spread of coronavirus disease 2019(COVID-19)are not only a disaster of people’s life and health over the world,[1–3]but also the challenge for medical practitioner in clinical management.Owing to many diagnostic instruments are not suitable or convenient to use any more in contagious ward considering the risk of cross infections,such as traditional stethoscope or electrocardiogram(ECG).In this scenarios,wireless and digital equipment are optimal choices for epidemic management in order to exert rapid diagnosis and disease evaluation.Herein,we reported a case of the patient suffering both COVID-19 and myocardial infarction,for which the tele-ECG and wireless stethoscope facilitated the accurate diagnosis and instant management.展开更多
In this paper, we demonstrate the prototype of a new stethoscope using laser technology to make the heart-beat signal “visible”. This heartbeat detection technique could overcome the limitation of the acoustic steth...In this paper, we demonstrate the prototype of a new stethoscope using laser technology to make the heart-beat signal “visible”. This heartbeat detection technique could overcome the limitation of the acoustic stethoscope brought by the poor ability of human ear to hear low frequency heart sounds. This is important, as valuable information from sub-audio sounds is present at frequencies below the range of human hearing. Moreover, the diagnostic accuracy of the acoustic stethoscope is also very sensitive to noise from immediate environment. In the prototype of laser-based stethoscope, the heartbeat signal is correlated to the optical spot of a laser beam reflected from a thin mirror attached to the patient’s chest skin. The motion of the mirror with the chest skin is generated by the heart sounds. A linear optical sensor is applied to detect and record the motion of the optical spot, from which the heartbeat signal in time-domain is extracted. The heartbeat signal is then transformed to frequency domain through digital signal processing. Both time-domain and frequency-domain signals are analyzed in order to classify different type of heart murmurs. In the prototype of the laser-based stethoscope, we use a heart-sound box to simulate the chest of a human being. The heart-sounds collected from real patients are applied to activate the vibration of the heart-sound box. We also analyze different heart murmur patterns based on the time-domain and frequency-domain heartbeat signals acquired from the optical system.展开更多
文摘This study delves into the life and significant contributions of René Théophile Hyacinthe Laennec,a prominent French physician of the 19^(th) century,and thoroughly examines his revolutionary creation,the stethoscope.Laennec’s innovative spirit not only revolutionized medical diagnosis during his time but also left a lasting imprint on the broader field of medicine,influencing healthcare for generations.This extensive inquiry covers various aspects,including his historical context,the development of the stethoscope,its profound implications for medical diagnosis,and its enduring impact on the history of medicine.
文摘The practice of cardiac auscultation is a critical tool used by physicians to detect alterations in the cardiovascular system. A case of both left and right sided endocarditis initially detected by electronic auscultation in a woman with a history of injection drug use is described. The electronic stethoscope, with the ability to amplify heart sounds, established the presence of both a systolic and diastolic murmur when standard auscultation failed to detect the diastolic component. Urgent standard echocardiography confirmed concurrent tricuspid and aortic valves endocarditis, and the patient was referred for surgical evaluation urgently. The present case demonstrates the value of the electronic stethoscope to amplify murmurs in the early detection of endocarditis. The case presented also serves as a useful reminder that right-sided endocarditis can have important leftsided complications.
文摘Diseases of the cardiovascular system are one of the major causes of death worldwide.These diseases could be quickly detected by changes in the sound created by the action of the heart.This dynamic auscultations need extensive professional knowledge and emphasis on listening skills.There is also an unmet requirement for a compact cardiac condition early warning device.In this paper,we propose a prototype of a digital stethoscopic system for the diagnosis of cardiac abnormalities in real time using machine learning methods.This system consists of three subsystems that interact with each other(1)a portable digital subsystem of an electronic stethoscope,(2)a decision-making subsystem,and(3)a subsystemfor displaying and visualizing the results in an understandable form.The electronic stethoscope captures the patient’s phonocardiographic sounds,filters and digitizes them,and then sends the resulting phonocardiographic sounds to the decision-making system.The decision-making systemclassifies sounds into normal and abnormal using machine learning techniques,and as a result identifies abnormal heart sounds.The display and visualization subsystem demonstrates the results obtained in an understandable way not only for medical staff,but also for patients and recommends further actions to patients.As a result of the study,we obtained an electronic stethoscope that can diagnose cardiac abnormalities with an accuracy of more than 90%.More accurately,the proposed stethoscope can identify normal heart sounds with 93.5%accuracy,abnormal heart sounds with 93.25%accuracy.Moreover,speed is the key benefit of the proposed stethoscope as 15 s is adequate for examination.
文摘Stethoscopes are commonly used to diagnose cardiac and respiratory diseases.The advent of digital stethoscopes added the capability to remotely monitor the cardiorespiratory well-being of patients and facilitate digital remote auscultations for physicians to examine their patients outside of the clinic.To increase the adoption of a hybrid diagnosis between in-person and remote auscultations,it is important to characterize the frequency response of different configurations of digital stethoscopes.A standard testing platform was adopted from the literature and re-validated by seven physicians.Two wearable and two non-wearable digital stethoscopes were investigated.A similarity factor score was used to analyze select time-synchronized acoustic events that achieved high fidelity between stethoscopes.The frequency responses between devices were compared using the correlation coefficient.Two devices reported the highest correlation coefficient of 0.72 and 0.75 in the wearable and non-wearable categories,respectively.The correlation coefficient of the frequency responses between the same pair of devices on the human chest was 0.91.With such a high agreement in the frequency response between the wearable and non-wearable digital stethoscope,it can be concluded that the configuration of digital stethoscope is not a limiting factor of performance,and both are acceptable and desirable for physicians to adopt either configuration in remote delivery of healthcare.
文摘The outbreak and spread of coronavirus disease 2019(COVID-19)are not only a disaster of people’s life and health over the world,[1–3]but also the challenge for medical practitioner in clinical management.Owing to many diagnostic instruments are not suitable or convenient to use any more in contagious ward considering the risk of cross infections,such as traditional stethoscope or electrocardiogram(ECG).In this scenarios,wireless and digital equipment are optimal choices for epidemic management in order to exert rapid diagnosis and disease evaluation.Herein,we reported a case of the patient suffering both COVID-19 and myocardial infarction,for which the tele-ECG and wireless stethoscope facilitated the accurate diagnosis and instant management.
文摘In this paper, we demonstrate the prototype of a new stethoscope using laser technology to make the heart-beat signal “visible”. This heartbeat detection technique could overcome the limitation of the acoustic stethoscope brought by the poor ability of human ear to hear low frequency heart sounds. This is important, as valuable information from sub-audio sounds is present at frequencies below the range of human hearing. Moreover, the diagnostic accuracy of the acoustic stethoscope is also very sensitive to noise from immediate environment. In the prototype of laser-based stethoscope, the heartbeat signal is correlated to the optical spot of a laser beam reflected from a thin mirror attached to the patient’s chest skin. The motion of the mirror with the chest skin is generated by the heart sounds. A linear optical sensor is applied to detect and record the motion of the optical spot, from which the heartbeat signal in time-domain is extracted. The heartbeat signal is then transformed to frequency domain through digital signal processing. Both time-domain and frequency-domain signals are analyzed in order to classify different type of heart murmurs. In the prototype of the laser-based stethoscope, we use a heart-sound box to simulate the chest of a human being. The heart-sounds collected from real patients are applied to activate the vibration of the heart-sound box. We also analyze different heart murmur patterns based on the time-domain and frequency-domain heartbeat signals acquired from the optical system.