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CFPD Modelling of Airflow and Particle Behaviour in Human Realistic Airways analyses the effects of different breathing conditions on particle deposition fraction and airflow behaviour, allowing readers to gain a deep understanding of air-particle dynamics behaviour in the human respiratory system, which covers the oral cavity, tracheobronchial airway, bronchus, and more. The fundamentals of CFD modelling is also explored, allowing the readers to apply both the fundamental concepts and the data presented in other CFD models as well as in finding the best breathing/particle deposition modes for maximum drug transport to the desired respiratory system regions. Readers can gain a deeper understanding on the inter-related effect of breathing patterns and particles transport and deposition within the human respiratory system Features comprehensive descriptions on fundamental CFD methods which is widely applicable for other CFD problems An essential resource for practicing clinicians in enhancing the effectiveness for drug delivery, engineers in optimising their designs for spray devices and nebulizers; as well as for mechanical and biomedical Engineering students in learning how CFD could be applied in various situations
Traditional research methodologies in the human respiratory system have always been challenging due to their invasive nature. Recent advances in medical imaging and computational fluid dynamics (CFD) have accelerated this research. This book compiles and details recent advances in the modelling of the respiratory system for researchers, engineers, scientists, and health practitioners. It breaks down the complexities of this field and provides both students and scientists with an introduction and starting point to the physiology of the respiratory system, fluid dynamics and advanced CFD modeling tools. In addition to a brief introduction to the physics of the respiratory system and an overview of computational methods, the book contains best-practice guidelines for establishing high-quality computational models and simulations. Inspiration for new simulations can be gained through innovative case studies as well as hands-on practice using pre-made computational code. Last but not least, students and researchers are presented the latest biomedical research activities, and the computational visualizations will enhance their understanding of physiological functions of the respiratory system.
People may inhale 100 millions of particles each day, including toxic particulate matter as well as drug aerosols. Some of those deposited in the respiratory system can be either harmful or therapeutic to humans depending upon the particle material, deposition site, and local concentration. These transport and deposition phenomena as well as the resulting biomedical processes are greatly determined by the airflow field, particle properties, breathing pattern, and geometric airway characteristics. Realistic models of tracheobronchial and nasal⁄oral- tracheobronchial airways were built. Airflow and particle transport and deposition in these airway models were investigated in detail by mainly using the validated, in-house FORTRAN code CFPD (computational fluid-particle dynamics), which is a cell-centered, finite volume multi-block code. Both laminar and transitional-turbulent-laminar flows were considered for different transient and steady inhalation flow rates and inlet velocity profiles. The resulting effects of transients, upstream conditions and geometric characteristics, i.e., spatial angle and/or cartilaginous rings, are fully discussed. A new code based on the lattice-Boltzmann method (LBM) has been developed and validated to investigate airflow patterns and pressure changes in representative alveolar structures of the human respiratory zone. The new idea of targeted drug aerosol delivery technology was numerically tested for a more realistic human airway configuration and thereby addressing the problem of inter-subject variability. Specifically, controlled air-particle streams were studied using the oral and asymmetric tracheobronchial airway models. The results were compared with data obtained for a symmetric Weibel Type A tracheobronchial airway model.
Prolonged exposure to inhaled micron-sized airborne particles is a known public health concern. These particles impact the health of staggering numbers of residents of polluted urban areas, as well as significant portions of the third world where it is still common to burn wood or charcoal indoors for cooking or heating. An understanding of the fate of inhaled particles in the lungs is useful for assessing their associated health risks, as well as improving the effectiveness of respiratory drug delivery techniques. The transport of microparticles is inseparable from behavior of the suspending airflow and this is studied using computational fluid dynamics techniques. The anatomy of the airways seems to have evolved to encourage turbulent airflow for functions such as mixing of flow to promote the warming and humidification of inhaled air, as well as for filtration. Large eddy simulation models are employed to capture turbulent flow in extremely complex patient-specific airway geometries. These collectively comprise the oral and nasal cavities, larynx, trachea, and the bronchial tree. The flow in anatomically-accurate rhesus macaque airways is also studied. Simulations are carried out for inspiratory flow rates corresponding to nominal Reynolds numbers in the hundreds to low-thousands yet somewhat surprisingly yield unsteady flows due to local geometric factors. A computed mean flow field is compared extensively with magnetic resonance velocimetry measurements carried out in the same computed-tomography--based lung geometry, showing good agreement. Microparticle deposition predictions are also verified. Focus is placed on the dynamics of the flow in the nasal airway, trachea, and bronchial tree. After becoming unsteady at constrictions in the upper airways, the flow is found to be chaotic, exhibiting fluctuations with broad-band spectra even at the most distal simulated airways in which the Reynolds numbers are as low as 300. The unsteadiness is attributed to the convection of turbulent structures produced in the upper airways as well as to local kinetic energy production throughout the bronchial tree.
"Particle deposition in the respiratory tract is studied in order to better understand the negative health effects due to cigarette smoke inhalation. Until recently, idealized models of the respiratory airways based on the original Weibel model have been used to calculate deposition. These models consist of symmetric bifurcating airways and do not take into account variations of airway diameter, and asymmetry in the human respiratory tract. Until recently, little work has been done to accurately recreate the entire upper respiratory tract including the oral cavity, pharynx, and larynx. Technological improvement has changed the way in which researchers approach this problem. With the advent of high resolution scans of the respiratory tract, accurate replica models can be created to better predict cigarette smoke particle (CSP) deposition. These models recreate actual lung geometries found in patients. For this thesis, two realistic geometric models are created. One is based on an adult male and the other on an adolescent male. CSP deposition is determined for both models in order to compare the difference cased by age in smoking. In addition, an unsteady breathing curve, indicative of realistic smoking behavior is utilized to more accurately represent the breathing conditions. Both models consist of the oral cavity, throat, larynx, trachea, and first five to seven generations of the lungs. The adult model is based on a dental cast of the mouth, a CT scan of the throat and larynx, and images based on the National Institute of Health's Visible Human Project for the tracheobronchial tree. The adolescent model is based upon a scaled oral cavity and CT scans of the rest of the reparatory tract. The program 3D Doctor is used to reconstruct the two dimensional CT scan images into a three dimensional model. VPSculpt and SolidWorks are used to combine the different parts of the models and clean up the geometry. The geometry is meshed in Gambit and exported to the Computational Fluid Dynamics (CFD) software package Fluent to perform the fluid flow and particle deposition analysis. The Fluent Discrete Phase Model (DPM) is used to determine particle trajectories and deposition. It is found that deposition increases with the size of the inhaled particles. Particles tend to deposit towards the back of the throat, the area of the trachea just below the glottis, and at bifurcations in the airways. However, when compared to other studies in literature, deposition tended to be higher with smaller particle sizes, but more comparable with larger particle sizes. Adolescent deposition was found to be lower than adult deposition for all particle sizes."--Abstract.
Keywords: CFD, drug delivery, airflow, particle deposition, nasal airway.
A major challenge in the Computational Fluid Dynamics (CFD) modeling of the human respiratory system is the complex variation of geometric scale from the trachea to the peripheral airways. The current literature on image-based lung flow analysis is limited to a few (typically 5) generations beyond the trachea. Such studies, which are limited largely by computational intensity and computational cost, also have limited accuracy. In this study we propose a hybrid methodology that enables CFD analysis from the middle to the distal airways through to the alveolar level. A hybrid lung model is generated where the middle airways are reconstructed from human CT-scans using open-source image analysis and extended to distal parts utilizing a section of airway branching tree generated based on deterministic algorithm. Such hybrid models allow the application of physiologically relevant boundary conditions instead of the approximation methods often used in previous studies in the region of interest. Two different breathing conditions are investigated, and the results are validated by comparison with previous experimental and numerical data.
Inhaled Particles integrates all that is known about inhaled particles in a unified treatment. It aims to provide a scientific framework essential to a reasonable understanding of inhaled particles. The emphasis is placed on demonstrating the key roles of lung morphology on airflow and particle transport as well as identifying physical and biological factors that influence deposition. Special attention is paid to maintaining consistency of treatment and a balance between theoretical modeling and experimental measurements. The book covers all important aspects of inhaled particles including inhalability, aerosol dispersion, particle deposition, and clearance. It reviews concisely the basic background of lung morphology, respiratory physiology, aerodynamics, and aerosol science pertinent to the subject. Essential aspects of health effects and applications are also included. An easy-to-read, self contained introduction to the field An excellent source of updated research information Useful for students and professionals in aerosol science, environmental health science, occupational hygiene, health physics and biomedical engineering