Fluid mechanics and sound generation for lung-clearance therapy: advanced design modality for a biomedical therapeutic device

Purpose The study described here aims to set forth an analysis approach for a specific biomedical therapeutic device principally involving fluid mechanics and resulting sound generation. The function of the therapeutic device is to clear mucus from the airways of the lungs. Clearance of the airways is a primary means of relief for cystic fibrosis and is also effective in less profound dysfunctions such as asthma. The complete system consists of a device to periodically pulse air pressure and a vest that girdles the abdomen of the patient and receives and discharges the pulsating airflow. The source of pulsed air can be tuned both with respect to the amplitude and frequency of the pressure pulsations. Design/methodology/approach The key design tools used here are computational fluid dynamics and the theory of turbulence-based sound generation. The fluid flow inside of the device is multidimensional, unsteady and turbulent. Findings Results provided by the fluid mechanic study include the rates of fluid flow between the device and the inflatable vest, the rates of air supplied to and extracted from the device, the fluid velocity magnitudes and directions that result from the geometry of the device and the magnitude of the turbulence generated by the fluid motion and the rotating component of the device. Both the velocity magnitudes and the strength of the turbulence contribute to the quantitative evaluation of the sound generation. Originality/value A comprehensive literature search on this type of therapeutic device to clear mucus from the airways of the lungs revealed no previous analysis of the fluid flow and sound generation inside of the device producing the pulsed airflow. The results presented in this paper pinpoint the locations and causes of sound generation that can cause audible discomfort for patients.

[1]  E. Sparrow,et al.  Perforated plates for fluid management: Plate geometry effects and flow regimes , 2014 .

[2]  R. Chatburn High-frequency assisted airway clearance. , 2007, Respiratory care.

[3]  A. Bush,et al.  Comparison of active cycle of breathing and high‐frequency oscillation jacket in children with cystic fibrosis , 2004, Pediatric pulmonology.

[4]  Angui Li,et al.  Numerical investigations on effects of seven drag reduction components in elbow and T-junction close-coupled pipes , 2015 .

[5]  B. Mousavi,et al.  Numerical Simulation of Tonal and Broadband Hydrodynamic Noises of Non-Cavitating Underwater Propeller , 2014 .

[6]  B. Button,et al.  Structure and function of the mucus clearance system of the lung. , 2013, Cold Spring Harbor perspectives in medicine.

[7]  I. Proudman,et al.  The generation of noise by isotropic turbulence , 1952, Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences.

[8]  P. Baconnier,et al.  Positive End Expiratory Pressure and Expiratory Flow Limitation: A Model Study , 2001, Acta biotheoretica.

[9]  J. Alison,et al.  Vibration and its effect on the respiratory system. , 2006, The Australian journal of physiotherapy.

[10]  T. Myers Positive expiratory pressure and oscillatory positive expiratory pressure therapies. , 2007, Respiratory care.

[11]  E. Main,et al.  Airway Clearance Strategies in Cystic Fibrosis and Non-Cystic Fibrosis Bronchiectasis , 2015, Seminars in Respiratory and Critical Care Medicine.

[12]  D Elad,et al.  Computational model of oscillatory airflow in a bronchial bifurcation. , 1998, Respiration physiology.

[13]  Sajjad Beigmoradi Aerodynamic Drag and Noise Minimization of Rear End Parameters in a Simplified Car Model Utilizing Robust Parameter Design Method , 2015 .

[14]  T A Wilson,et al.  A computational model for expiratory flow. , 1982, Journal of applied physiology: respiratory, environmental and exercise physiology.

[15]  W. Warwick,et al.  Investigation of non-uniform airflow signal oscillation during high frequency chest compression , 2005, Biomedical engineering online.

[16]  A. Kendrick Airway clearance techniques in cystic fibrosis: physiology, devices and the future. , 2012, Journal of the Royal Society of Medicine.

[17]  F. Menter Two-equation eddy-viscosity turbulence models for engineering applications , 1994 .

[18]  Bill Diong,et al.  Modeling Human Respiratory Impedance , 2007 .

[19]  J. R. Phillips,et al.  Modeled velocity of airflow in the airways during various respiratory patterns , 2004, The 26th Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[20]  J. Fink,et al.  High-frequency oscillation of the airway and chest wall. , 2002, Respiratory care.

[21]  Warren J. Warwick,et al.  A Simulation Tool to Study High-Frequency Chest Compression Energy Transfer Mechanisms and Waveforms for Pulmonary Disease Applications , 2010, IEEE Transactions on Biomedical Engineering.

[22]  L. Morrison,et al.  Oscillating devices for airway clearance in people with cystic fibrosis. , 2017, The Cochrane database of systematic reviews.

[23]  Sandip Pawar,et al.  Evaluation of Cabin Comfort in Air Conditioned Buses Using CFD , 2014 .

[24]  R. Chatburn,et al.  Performance comparison of two oscillating positive expiratory pressure devices: Acapella versus Flutter. , 2003, Respiratory care.

[25]  W. Warwick,et al.  High Frequency Chest Compression Effects Heart Rate Variability , 2007, 2007 29th Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[26]  C. Dosman,et al.  High-frequency chest compression: a summary of the literature. , 2005, Canadian respiratory journal.

[27]  W. Warwick,et al.  High-frequency chest compression system to aid in clearance of mucus from the lung. , 1990, Biomedical instrumentation & technology.

[28]  Ahmed F. El-Sayed,et al.  Unsteady aerodynamics and aeroacoustics of a fan rotor of a high-bypass ratio turbofan engine , 2014 .