key: cord-0146012-5e5qzfa2 authors: Jiang, Chuanyang; Zhao, Jiaqi; Yu, Jiao title: The optimal design for cylindrical tubes used as acoustic stethoscopes for auscultation in COVID-19 diagnosis date: 2020-08-23 journal: nan DOI: nan sha: 90b208c79d334487d55296992684fe3206e96f83 doc_id: 146012 cord_uid: 5e5qzfa2 During the COVID-19 outbreak, the auscultation of heart and lung sounds has played an important role in the comprehensive diagnosis and real-time monitoring of confirmed cases. With clinicians wearing protective clothing in isolation wards, a potato chip tube stethoscope, which is a secure and flexible substitute for a conventional stethoscope, has been used in the first-line treatment of COVID-19 by Chinese medical workers. In this study, an optimal design for this simple cylindrical stethoscope is proposed based on the fundamental theory of acoustic waveguides. Analyses of the cut-off frequency, sound power transmission coefficient, and sound wave propagation in the uniform lossless tube provide theoretical guidance for selecting the geometric parameters for this simple cylindrical stethoscope. In addition, relevant suggestions about surface treatments for the inner wall as well as the use of noise-reduction earplugs are also part of this optimal design. The COVID-19 pandemic has become an enormous public health concern, attracting intense attention not only in China but also around the globe. Given the high contagiousness of SARS-Coronavirus-2 (SARS-CoV-2), 1 strict personal protective measures have been implemented by the Chinese medical workers who have worked in infection isolation wards. In addition, the rigorous use of personal protective equipment, especially protective clothing, makes auscultation with conventional acoustic stethoscopes impossible. 2 However, it is essential to use stethoscopes to assess the subtleties of the heart and lung sounds and to monitor the progression of pneumonia with COVID-19 dynamically. Under the circumstances, Gao 2 reported that a simple, disinfected cylindrical stethoscope made from an empty potato chip tube was applied during the first-line treatment of COVID-19. Though economical and safe, it is absolutely essential that this type of stethoscope, which is directly used in auscultation, is subjected to acoustic analysis and designed to obtain a more reliable acoustic performance. Hence, it is the aim of the present investigation to provide a theoretically optimal design for this alternative stethoscope. In this study, a potato chip tube ( Fig. 1 ) is modeled as a cylindrical rigid-walled waveguide with a diameter d = 6.530 cm. According to the basic theory of acoustic waveguides in constant cross section 3 , the cut-off frequency of the plane wave in the hollow cylindrical waveguide is . . where is the radius of the circular cross section and is the speed of sound in air at 20 . Considering that all the physiologically crucial heart and lung sounds range from 20 Hz to 1000 Hz, 4,5 which is evidently less than the in Eq. 1, the sounds used for auscultation will propagate only in plane-wave mode. Therefore, this pure propagation mode can greatly assist physicians and particularly cardiologists in dynamically monitoring as well as making accurate judgments regarding individual cardiopulmonary function. Notably, because the sounds that are valuable in the effective diagnosis of cardiac and pulmonary diseases by thoracic auscultation range from 20 Hz to 1000 Hz, 4,5 we were inspired to design the diameter dimension of the cylindrical stethoscope, and using Eq. 1, we obtain 4 In addition to meeting the cut-off frequency requirements, the sound transmission to the external auditory canal must be considered in the design. To explore the essence of this research, slight differences in external auditory canal shapes and diameters between individuals are ignored. Moreover, because we are discussing the low frequency range below 1000 Hz, standing wave patterns in the human auditory canal do not need to be considered here because they occur at much higher frequencies [6] [7] [8] . Within the scope of the above approximation, the acoustic model that describes a circular waveguide with a sudden change in the cross-section is illustrated in Fig. 2 to analyze the sound transmission during auscultation. It is assumed that the coordinate origin is precisely at the junction between these two waveguides that represent the simple cylindrical stethoscope of cross-sectional area and a physician's external auditory canal of cross-sectional area . It should be noted that the boundary conditions must include continuity in pressure and continuity in volume velocity. As a result, the sound power transmission coefficient in the simplified acoustic duct of the varied cross section 9 is . (3) Using the first-order derivative of with regards to yields . From Eq. 4, the extreme point of function occurs when and the second-order derivative of with regard to is negative, indicating that the sound power transmission coefficient reaches the largest value when equals in this application. In a real clinical situation, the size of the chest piece of the acoustic stethoscope, regardless of the diaphragms or the bells, is not as small as that of the cross-section of the external auditory canal (typically approximately 0.8 cm in diameter 10 ), but it ranges from approximately 3.3 cm -4.4 cm 11 due to a couple of factors that influence the picking up of sounds and vibration, including the effective auscultation area of heart and lung sounds as well as the curvature of the human body surface. For the optimal length of the cylindrical stethoscope, the fundamental equations that describe the sound wave propagation in the uniform, lossless waveguide are as follows 12 • , • , where is the sound pressure, ρ is the density of air in the waveguide, A is the cross-sectional area, is the speed of sound in air, and u is the volume velocity at (x,t). After using the Laplace transform, the transfer function of the cylindrical acoustic waveguide 12 is where Ω Ω is angular frequency . To calculate the formant frequency, when the denominator is zero, we find . (n=0, 1, 2, …) Then rejecting the negative value yields, First, we used 0 to discuss the fundamental frequency of the formant. From Ref. Then, when 1 and 2, the values of the corresponding frequencies are 860 Hz and 1433.3 Hz. According to Eq. 12, to obtain a formant at a lower frequency, such as 100 Hz, a longer tube should be used. Based on the analysis and calculation above, we can summarize the basic results on the optimal design of this simple cylindrical stethoscope. First, a diameter of less than 0.2 m will ensure the sound below 1000 Hz, which is physically important for cardiopulmonary function auscultation, to transmit in plane-wave mode within the cylindrical tube structure. Second, the diameter of this hollow cylindrical stethoscope is from 3.3 cm -4.4 cm, which is believed to have a relative potential advantage over the current diameter of the potato chip tube stethoscope, partly because this size is suitable for picking up heart and lung sounds and partly because this design makes the difference between and smaller, contributing to the sound transmission to the external auditory canal. Third, the use of the current length (30 cm) of the cylindrical stethoscope should cover the medium and high frequency ranges of physically important heart and lung sounds (300 Hz -1000 Hz). In using Eq. 11 at n = 0, we derive that if the length of the cylindrical stethoscope increases to 0.8 m -0.9 m, the low frequency heart sounds of 95.6 Hz -107.5 Hz will be amplified via the formant effect, to reach a level that is easy to hear. However, given the flexibility and convenience of the device operation, lengths longer than 0.9 m are not recommended during real auscultation when using this simple diagnostic tool. Moreover, instead of using the original material from the inner wall of the cylindrical stethoscope, which is to some degree infiltrated by oil, an appropriate substitute, such as a coat of enamel, should be painted smoothly and uniformly on the surface to reduce the frictional loss of sound due to viscosity. In addition, a great deal of attention must be paid to the fact that medical workers who intend to conduct auscultations using this simple device ought to wear a single earplug in the ear that is not being used during auscultation to reduce the impact of ambient noise during diagnosis. Dating back to 1816, the French doctor Laennec, who invented the world's first stethoscope, successfully conducted a cardiac auscultation using a cylindrical paper stethoscope. 13 In conclusion, during the COVID-19 pandemic, simple cylindrical stethoscopes have been applied to cardiac and pulmonary function auscultation in China, and this economical instrument is considered as a suitable diagnostic tool when conventional stethoscopes cannot be used by medical workers in protective clothing, or when medical resources are extremely scarce in poverty-stricken areas of developing countries. The cut-off frequency analysis indicates that a hollow cylindrical tube with a diameter of less than 0.2 m allows the heart and lung sounds within the auscultation frequency range to propagate in plane-wave mode. Compared with the potato chip tube stethoscope, we propose an optimization of this simple stethoscope by reducing the diameter to 3.3 cm -4.4 cm. For a simple cylindrical stethoscope measuring 30 cm in length, the medium and high frequencies of the heart and lung sounds can induce acoustic resonance when transmitted down the tubing of the simple stethoscope which is considered to be beneficial for auscultation. The acoustic performance of the simple stethoscope for low-frequency chest sounds requires further experimental confirmations from clinicians, and it could be improved by increasing its length. 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