Your search keyword '"Aditya V. S. Ponnaluri"' showing total 6 results

1. Model of Left Ventricular Contraction: Validation Criteria and Boundary Conditions.

Author

Aditya V. S. Ponnaluri, Ilya A. Verzhbinsky, Jeff D. Eldredge, Alan Garfinkel, Daniel B. Ennis, and Luigi E. Perotti

Published

2019

2. Electrophysiology of Heart Failure Using a Rabbit Model: From the Failing Myocyte to Ventricular Fibrillation.

Author

Aditya V S Ponnaluri, Luigi E Perotti, Michael Liu, Zhilin Qu, James N Weiss, Daniel B Ennis, William S Klug, and Alan Garfinkel

Subjects

Biology (General), QH301-705.5

Abstract

Heart failure is a leading cause of death, yet its underlying electrophysiological (EP) mechanisms are not well understood. In this study, we use a multiscale approach to analyze a model of heart failure and connect its results to features of the electrocardiogram (ECG). The heart failure model is derived by modifying a previously validated electrophysiology model for a healthy rabbit heart. Specifically, in accordance with the heart failure literature, we modified the cell EP by changing both membrane currents and calcium handling. At the tissue level, we modeled the increased gap junction lateralization and lower conduction velocity due to downregulation of Connexin 43. At the biventricular level, we reduced the apex-to-base and transmural gradients of action potential duration (APD). The failing cell model was first validated by reproducing the longer action potential, slower and lower calcium transient, and earlier alternans characteristic of heart failure EP. Subsequently, we compared the electrical wave propagation in one dimensional cables of healthy and failing cells. The validated cell model was then used to simulate the EP of heart failure in an anatomically accurate biventricular rabbit model. As pacing cycle length decreases, both the normal and failing heart develop T-wave alternans, but only the failing heart shows QRS alternans (although moderate) at rapid pacing. Moreover, T-wave alternans is significantly more pronounced in the failing heart. At rapid pacing, APD maps show areas of conduction block in the failing heart. Finally, accelerated pacing initiated wave reentry and breakup in the failing heart. Further, the onset of VF was not observed with an upregulation of SERCA, a potential drug therapy, using the same protocol. The changes introduced at the cell and tissue level have increased the failing heart's susceptibility to dynamic instabilities and arrhythmias under rapid pacing. However, the observed increase in arrhythmogenic potential is not due to a steepening of the restitution curve (not present in our model), but rather to a novel blocking mechanism.

Published

2016

3. Electrophysiology of Heart Failure Using a Rabbit Model: From the Failing Myocyte to Ventricular Fibrillation

Author

James N. Weiss, Aditya V. S. Ponnaluri, Zhilin Qu, Alan Garfinkel, Daniel B. Ennis, Michael Liu, Luigi E. Perotti, William S. Klug, and McCulloch, Andrew D

Subjects

0301 basic medicine, Physiology, Action Potentials, 030204 cardiovascular system & hematology, Cardiovascular, Mathematical Sciences, Electrocardiography, 0302 clinical medicine, Models, Animal Cells, Medicine and Health Sciences, Myocytes, Cardiac, Biology (General), Ecology, medicine.diagnostic_test, Physics, Simulation and Modeling, Models, Cardiovascular, Heart, Reentry, Biological Sciences, 3. Good health, Cardiovascular physiology, Electrophysiology, Heart Disease, Bioassays and Physiological Analysis, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, Ventricular Fibrillation, Cardiology, Rabbits, Electrical conduction system of the heart, Anatomy, Cellular Types, Cardiac, Research Article, medicine.medical_specialty, QH301-705.5, Bioinformatics, Muscle Tissue, Neurophysiology, Research and Analysis Methods, Membrane Potential, 03 medical and health sciences, Cellular and Molecular Neuroscience, QRS complex, Heart Conduction System, Information and Computing Sciences, Internal medicine, Genetics, medicine, Animals, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Heart Failure, Myocytes, Muscle Cells, business.industry, Electrophysiological Techniques, Biology and Life Sciences, Cell Biology, medicine.disease, Electrophysiological Phenomena, 030104 developmental biology, Biological Tissue, Heart failure, Ventricular fibrillation, Cardiovascular Anatomy, Waves, Cardiac Electrophysiology, Wave Propagation, business, Neuroscience

Abstract

Heart failure is a leading cause of death, yet its underlying electrophysiological (EP) mechanisms are not well understood. In this study, we use a multiscale approach to analyze a model of heart failure and connect its results to features of the electrocardiogram (ECG). The heart failure model is derived by modifying a previously validated electrophysiology model for a healthy rabbit heart. Specifically, in accordance with the heart failure literature, we modified the cell EP by changing both membrane currents and calcium handling. At the tissue level, we modeled the increased gap junction lateralization and lower conduction velocity due to downregulation of Connexin 43. At the biventricular level, we reduced the apex-to-base and transmural gradients of action potential duration (APD). The failing cell model was first validated by reproducing the longer action potential, slower and lower calcium transient, and earlier alternans characteristic of heart failure EP. Subsequently, we compared the electrical wave propagation in one dimensional cables of healthy and failing cells. The validated cell model was then used to simulate the EP of heart failure in an anatomically accurate biventricular rabbit model. As pacing cycle length decreases, both the normal and failing heart develop T-wave alternans, but only the failing heart shows QRS alternans (although moderate) at rapid pacing. Moreover, T-wave alternans is significantly more pronounced in the failing heart. At rapid pacing, APD maps show areas of conduction block in the failing heart. Finally, accelerated pacing initiated wave reentry and breakup in the failing heart. Further, the onset of VF was not observed with an upregulation of SERCA, a potential drug therapy, using the same protocol. The changes introduced at the cell and tissue level have increased the failing heart’s susceptibility to dynamic instabilities and arrhythmias under rapid pacing. However, the observed increase in arrhythmogenic potential is not due to a steepening of the restitution curve (not present in our model), but rather to a novel blocking mechanism., Author Summary Ventricular fibrillation (VF) is one of the leading causes of sudden death. During VF, the electrical wave of activation in the heart breaks up chaotically. Consequently, the heart is unable to contract synchronously and pump blood to the rest of the body. In our work we formulate and validate a model of heart failure (HF) that allows us to evaluate the arrhythmogenic potential of individual and combined electrophysiological changes. In diagnostic cardiology, the electrocardiogram (ECG) is one of the most commonly used tools for detecting abnormalities in the heart electrophysiology. One of our goals is to use our numerical model to link changes at the cellular and tissue level in a failing heart to a numerically computed ECG. This allows us to characterize the precursor to and the risk of VF. In order to understand the mechanisms underlying VF in HF, we design a test that simulates a HF patient performing physical exercise. We show that under fast heart rates with changes in pacing, HF patients are more prone to VF due to a new conduction blocking mechanism. In the long term, our mathematical model is suitable for investigating the effect of drug therapies in HF.

Published

2016

4. Method for the unique identification of hyperelastic material properties using full-field measures. Application to the passive myocardium material response

Author

Luigi E, Perotti, Aditya V S, Ponnaluri, Shankarjee, Krishnamoorthi, Daniel, Balzani, Daniel B, Ennis, and William S, Klug

Subjects

Heart, Models, Biological, Biophysical Phenomena, Elasticity, Article

Abstract

Quantitative measurement of the material properties (e.g., stiffness) of biological tissues is poised to become a powerful diagnostic tool. There are currently several methods in the literature to estimating material stiffness and we extend this work by formulating a framework that leads to uniquely identified material properties. We design an approach to work with full field displacement data — i.e., we assume the displacement field due to the applied forces is known both on the boundaries and also within the interior of the body of interest — and seek stiffness parameters that lead to balanced internal and external forces in a model. For in vivo applications, the displacement data can be acquired clinically using magnetic resonance imaging while the forces may be computed from pressure measurements, e.g., through catheterization. We outline a set of conditions under which the least-square force error objective function is convex, yielding uniquely identified material properties. An important component of our framework is a new numerical strategy to formulate polyconvex material energy laws that are linear in the material properties and provide one optimal description of the available experimental data. An outcome of our approach is the analysis of the reliability of the identified material properties, even for material laws that do not admit unique property identification. Lastly, we evaluate our approach using passive myocardium experimental data at the material point and show its application to identifying myocardial stiffness with an in silico experiment modeling the passive filling of the left ventricle.

Published

2016

5. Method for the unique identification of hyperelastic material properties using full-field measures. Application to the passive myocardium material response

Author

Daniel Balzani, William S. Klug, Luigi E. Perotti, Aditya V. S. Ponnaluri, Daniel B. Ennis, and Shankarjee Krishnamoorthi

Subjects

Computer science, 0206 medical engineering, Biomedical Engineering, 02 engineering and technology, Displacement (vector), 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, medicine, Point (geometry), Molecular Biology, business.industry, Applied Mathematics, Work (physics), Stiffness, Structural engineering, Inverse problem, 020601 biomedical engineering, Computational Theory and Mathematics, Modeling and Simulation, Hyperelastic material, Displacement field, medicine.symptom, business, Material properties, Software

Abstract

Quantitative measurement of the material properties (eg, stiffness) of biological tissues is poised to become a powerful diagnostic tool. There are currently several methods in the literature to estimating material stiffness, and we extend this work by formulating a framework that leads to uniquely identified material properties. We design an approach to work with full-field displacement data-ie, we assume the displacement field due to the applied forces is known both on the boundaries and also within the interior of the body of interest-and seek stiffness parameters that lead to balanced internal and external forces in a model. For in vivo applications, the displacement data can be acquired clinically using magnetic resonance imaging while the forces may be computed from pressure measurements, eg, through catheterization. We outline a set of conditions under which the least-square force error objective function is convex, yielding uniquely identified material properties. An important component of our framework is a new numerical strategy to formulate polyconvex material energy laws that are linear in the material properties and provide one optimal description of the available experimental data. An outcome of our approach is the analysis of the reliability of the identified material properties, even for material laws that do not admit unique property identification. Lastly, we evaluate our approach using passive myocardium experimental data at the material point and show its application to identifying myocardial stiffness with an in silico experiment modeling the passive filling of the left ventricle.

Published

2017

6. Simulation methods and validation criteria for modeling cardiac ventricular electrophysiology

Author

Daniel B. Ennis, N.P. Borgstrom, Zhilin Qu, Aditya V. S. Ponnaluri, James N. Weiss, Alan Garfinkel, Luigi E. Perotti, Anna Frid, Olujimi A. Ajijola, Shankarjee Krishnamoorthi, William S. Klug, and Panfilov, Alexander V

Subjects

Physiology, lcsh:Medicine, Action Potentials, Heart electrophysiology, 030204 cardiovascular system & hematology, Arrhythmias, Cardiovascular, Electrocardiography, 0302 clinical medicine, Models, Medicine and Health Sciences, Ventricular Function, Myocytes, Cardiac, Cardiovascular Imaging, lcsh:Science, 0303 health sciences, Multidisciplinary, medicine.diagnostic_test, Cardiac electrophysiology, Applied Mathematics, Models, Cardiovascular, Animal Models, Magnetic Resonance Imaging, Finite element method, Electrophysiology, medicine.anatomical_structure, Diffusion Tensor Imaging, Heart Disease, Cardiovascular Diseases, Physical Sciences, Cardiology, cardiovascular system, Engineering and Technology, Rabbits, Cardiac, Arrhythmia, Research Article, Biotechnology, Computer Modeling, Biophysical Simulations, Cell Physiology, Computer and Information Sciences, medicine.medical_specialty, Purkinje fibers, General Science & Technology, Heart Ventricles, Finite Element Analysis, Biophysics, Bioengineering, Research and Analysis Methods, Purkinje Fibers, 03 medical and health sciences, Model Organisms, Internal medicine, medicine, Animals, Computer Simulation, 030304 developmental biology, Myocytes, business.industry, lcsh:R, Biology and Life Sciences, Computational Biology, Arrhythmias, Cardiac, Magnetic resonance imaging, Cell Biology, Purkinje fiber, medicine.disease, Heart stimulation, Ventricular fibrillation, lcsh:Q, Cardiac Electrophysiology, business, Mathematics, Diffusion MRI, Endocardium

Abstract

We describe a sequence of methods to produce a partial differential equation model of the electrical activation of the ventricles. In our framework, we incorporate the anatomy and cardiac microstructure obtained from magnetic resonance imaging and diffusion tensor imaging of a New Zealand White rabbit, the Purkinje structure and the Purkinje-muscle junctions, and an electrophysiologically accurate model of the ventricular myocytes and tissue, which includes transmural and apex-to-base gradients of action potential characteristics. We solve the electrophysiology governing equations using the finite element method and compute both a 6-lead precordial electrocardiogram (ECG) and the activation wavefronts over time. We are particularly concerned with the validation of the various methods used in our model and, in this regard, propose a series of validation criteria that we consider essential. These include producing a physiologically accurate ECG, a correct ventricular activation sequence, and the inducibility of ventricular fibrillation. Among other components, we conclude that a Purkinje geometry with a high density of Purkinje muscle junctions covering the right and left ventricular endocardial surfaces as well as transmural and apex-to-base gradients in action potential characteristics are necessary to produce ECGs and time activation plots that agree with physiological observations., Shankarjee Krishnamoorthi et. al

Published

2014