The broad objective of this research is to apply the image-based fluid-structure interaction (FSI) technique to study the mechanical force resulting from the multiscale interactions between pulmonary gas flow and lung tissue mechanics, and its role in the distribution and progression of lung disease. A biological hypothesis motivating this work is that lung diseases alter mechanical force, which then alters stress-mediated adenosine triphosphate nucleotide release, disturbs periciliary liquid (PCL) water homeostasis, and weakens the integrated airway defense system, forming a vicious cycle of events. In a multidisciplinary effort, this proposal seeks to adopt an innovative systems biology approach that integrates mechanics and cell models to model transmittal of mechanical force from macro to micro scales, and further translation to biochemical responses at cellular level to maintain the PCL volume for mucociliary clearance. To achieve the objective and test the hypothesis, we propose the following specific aims. (1) Study the distributions of airflow-induced shear stress and airway-wall tissue stress in the central 6 generations of airways where the maximum resistance occurs. The emphasis will be placed on alteration of stresses due to airway rigidity, airway narrowing, and tissue stiffness, especially near the bifurcations in both upper and lower lobes as assessed in normal, asthmatic and emphysema subjects. (2) Study the biochemical responses of bronchial epithelial cells to the alteration of stresses in terms of the regional distributions of PCL water level and calcium ion concentration together with thermodynamics for heat and moisture in the human lung. The emphasis will be placed on deviation from PCL water homeostasis due to depletion or over-production of PCL volume near the bifurcations in both upper and lower lobes, and assess its implication on mucociliary transport. (3) Share the databases and models developed for this project with research and clinical communities via our medical image file archive system and model repository. To achieve these aims, we will extend our existing flow model to include lung tissue mechanics via image-registration-assisted FSI to simulate transmittal of mechanical force between airflow and tissue. We will also incorporate a stress-dependent nucleotide model into our existing model for calcium signaling and transmembrane ion and water fluxes in the ciliated epithelial cell. The fluid-structure (organ- tissue) mechanics model and the epithelial cell model will be integrated with regionally distributed airway thermodynamics to predict dynamic changes in the depth of the PCL layer and calcium ion concentration in the healthy and diseased airways. Both multi-detector row computed tomography (MDCT) experiments and cell culture experiments will be performed for model refinement and validation.

Public Health Relevance

This proposal aims to adopt a systems biology approach that integrates mechanics and cell models to understand the interplay between mechanical forces and cellular biochemical responses for airway defense in the healthy and diseased lungs.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
2R01HL094315-04A1
Application #
7758994
Study Section
Special Emphasis Panel (ZRG1-BST-E (50))
Program Officer
Croxton, Thomas
Project Start
2010-04-01
Project End
2014-03-31
Budget Start
2010-04-01
Budget End
2011-03-31
Support Year
4
Fiscal Year
2010
Total Cost
$366,560
Indirect Cost
Name
University of Iowa
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
062761671
City
Iowa City
State
IA
Country
United States
Zip Code
52242
Haghighi, Babak; D Ellingwood, Nathan; Yin, Youbing et al. (2018) A GPU-based symmetric non-rigid image registration method in human lung. Med Biol Eng Comput 56:355-371
Henry, Brian; Royston, Thomas J (2018) Localization of adventitious respiratory sounds. J Acoust Soc Am 143:1297
Wu, Dan; Boucher, Richard C; Button, Brian et al. (2018) An integrated mathematical epithelial cell model for airway surface liquid regulation by mechanical forces. J Theor Biol 438:34-45
Choi, Sanghun; Miyawaki, Shinjiro; Lin, Ching-Long (2018) A Feasible Computational Fluid Dynamics Study for Relationships of Structural and Functional Alterations with Particle Depositions in Severe Asthmatic Lungs. Comput Math Methods Med 2018:6564854
Miyawaki, Shinjiro; Tawhai, Merryn H; Hoffman, Eric A et al. (2017) Automatic construction of subject-specific human airway geometry including trifurcations based on a CT-segmented airway skeleton and surface. Biomech Model Mechanobiol 16:583-596
Henry, Brian; Royston, Thomas J (2017) A multiscale analytical model of bronchial airway acoustics. J Acoust Soc Am 142:1774
Jahani, Nariman; Choi, Sanghun; Choi, Jiwoong et al. (2017) A four-dimensional computed tomography comparison of healthy and asthmatic human lungs. J Biomech 56:102-110
Miyawaki, Shinjiro; Hoffman, Eric A; Wenzel, Sally E et al. (2017) Aerosol deposition predictions in computed tomography-derived skeletons from severe asthmatics: A feasibility study. Clin Biomech (Bristol, Avon) :
Miyawaki, Shinjiro; Hoffman, Eric A; Lin, Ching-Long (2017) Numerical simulations of aerosol delivery to the human lung with an idealized laryngeal model, image-based airway model, and automatic meshing algorithm. Comput Fluids 148:1-9
Choi, Sanghun; Haghighi, Babak; Choi, Jiwoong et al. (2017) Differentiation of quantitative CT imaging phenotypes in asthma versus COPD. BMJ Open Respir Res 4:e000252

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