Recent breakthroughs in the creation and use of transgenic animals have provided an experimental approach to manipulate processes at the protein level and study the consequence on the organ level. Unfortunately, not all variables of interest can be measured in a single preparation. In sufficiently realistic, computer models of heart electrophysiology can play a major role in relating information that can be measured experimentally to information that cannot and, perhaps more importantly, provide linkages across disparate scales. The objective of the proposed project is to develop software tools to advance computer modeling of the heart such that fine-grain changes in structure and membrane properties at the microscopic level can be incorporated properly into large scale-organ models, helping to unlock the molecular basis of arrhythmia. A unified problem solving environment, CARDIOPSE, will be developed for the rapid construction and manipulation of heart models based on image data and by doing so, enable preparation specific simulation, visualization and analysis of electrophysiology from ion-channel to torso. The proposed work will focus on creating the first microscopic and macroscopic integrative computer models of mouse electrophysiology suitable for exploring molecular level changes on global measurements like the ECG. Unlike other heart modeling tools, the proposed software will be designed for efficient simulation of both microscopic discrete models and macroscopic continuous models in 3D.
The specific aims are to 1) develop tools for directly segmenting MRI diffusion tensor imaging data at sub 100 micron resolution and confocal microscopy data at sub-cellular resolution to form preparation specific computational grids of the mouse heart ultrastructure and macroscopic fiber architecture. A library of models will be developed for normal and hypertrophied hearts; 2) create a novel finite-volume based scheme for representing intracellular and extracellular current flow in three-dimensional cardiac ultrastructure of coupled cells embedded in an extracellular matrix. The models will be used to study discrete impulse conduction and extracellular potentials in three-dimensions and to test assumptions used in macroscopic models for normal and diseased states; 3) develop a unified computational framework and tools-set for creating, simulating, visualizing and analyzing preparation specific cardiac electrophysiology from ion-channel to torso.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL076767-02
Application #
6881114
Study Section
Special Emphasis Panel (ZRG1-SSS-9 (50))
Program Officer
Baldwin, Tim
Project Start
2004-05-01
Project End
2008-02-28
Budget Start
2005-03-01
Budget End
2006-02-28
Support Year
2
Fiscal Year
2005
Total Cost
$432,536
Indirect Cost
Name
Duke University
Department
Biomedical Engineering
Type
Schools of Engineering
DUNS #
044387793
City
Durham
State
NC
Country
United States
Zip Code
27705
Tranquillo, Joseph V; Badie, Nima; Henriquez, Craig S et al. (2010) Collision-based spiral acceleration in cardiac media: roles of wavefront curvature and excitable gap. Biophys J 98:1119-28
Stinstra, Jeroen; MacLeod, Rob; Henriquez, Craig (2010) Incorporating histology into a 3D microscopic computer model of myocardium to study propagation at a cellular level. Ann Biomed Eng 38:1399-414
Jacquemet, Vincent; Henriquez, Craig S (2009) Genesis of complex fractionated atrial electrograms in zones of slow conduction: a computer model of microfibrosis. Heart Rhythm 6:803-10
Jacquemet, Vincent; Henriquez, Craig S (2009) Modulation of conduction velocity by nonmyocytes in the low coupling regime. IEEE Trans Biomed Eng 56:893-6
Pourtaheri, Navid; Ying, Wenjun; Kim, Jong M et al. (2009) Thresholds for transverse stimulation: fiber bundles in a uniform field. IEEE Trans Neural Syst Rehabil Eng 17:478-86
Jacquemet, Vincent; Henriquez, Craig S (2008) Loading effect of fibroblast-myocyte coupling on resting potential, impulse propagation, and repolarization: insights from a microstructure model. Am J Physiol Heart Circ Physiol 294:H2040-52
Ying, Wenjun; Rose, Donald J; Henriquez, Craig S (2008) Efficient fully implicit time integration methods for modeling cardiac dynamics. IEEE Trans Biomed Eng 55:2701-11
Ying, Wenjun; Henriquez, Craig S (2007) Hybrid finite element method for describing the electrical response of biological cells to applied fields. IEEE Trans Biomed Eng 54:611-20
Hubbard, Marjorie Letitia; Ying, Wenjun; Henriquez, Craig S (2007) Effect of gap junction distribution on impulse propagation in a monolayer of myocytes: a model study. Europace 9 Suppl 6:vi20-8
Jacquemet, Vincent; Henriquez, Craig S (2007) Modelling cardiac fibroblasts: interactions with myocytes and their impact on impulse propagation. Europace 9 Suppl 6:vi29-37

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