Your search keyword '"Raju R. Viswanathan"' showing total 18 results

1. Improved interstitial and intravascular MR imaging coils.

Author

Norman B. Konyer, Raju R. Viswanathan, Raghu Raghavan, G. Mills, Martin L. Brady, and Michael J. Bronskill

Published

2002

2. Intraparenchymal drug delivery via positive-pressure infusion: experimental and modeling studies of poroelasticity in brain phantom gels.

Author

Zhi-Jian Chen, William C. Broaddus, Raju R. Viswanathan, Raghu Raghavan, and George T. Gillies

Published

2002

3. Accurate and Reproducible Target Navigation with the Stereotaxis Niobe® Magnetic Navigation System

Author

P B A Michelle Armacost, David T. Curd, Ruchir Sehra, Raju R. Viswanathan, Torrey Munger, Janet Adair, and Francis M. Creighton

Subjects

medicine.medical_specialty, Reproducibility, business.industry, Device placement, Navigation system, Stereotaxis, equipment and supplies, Imaging phantom, Surgery, Catheter, Physiology (medical), medicine, Cardiology and Cardiovascular Medicine, business, human activities, Biomedical engineering

Abstract

Introduction: The Stereotaxis Niobe® Magnetic Navigation System (MNS, Stereotaxis, Inc., St. Louis, MO, USA) allows for remote-control navigation of magnetically enabled catheters and guidewires for clinical ablation and electrophysiology (EP) device placement using two permanent magnets located on opposite sides of the patient table. Our objective was to provide a clinical framework for expected navigational accuracy during a case by calibrating the system's reproducibility using a realistic heart phantom under various conditions. Methods and Results: We performed two sets of experiments to demonstrate the accuracy of magnetic catheters using the MNS. The first experiment calibrated deviations in the deflection of an EP catheter by the magnetic system from the expected angles using proprietary algorithms based on predicted geometry. We found that the magnetic fields produced catheter angulation movements within a mean of 4° of biophysical predictions. The second experiment used the MNS to navigate these catheters to previously labeled target positions within a phantom heart model and estimated the actual displacement from desired target positions. We found that the accuracy for reaching the desired targets was 100%. Conclusions: Remote navigation of magnetically enabled EP catheters using the MNS accurately and reproducibly navigates to target sites in a heart phantom. This may enable more complex, successful, and time-efficient procedures in the cardiac catheterization laboratory.

Published

2006

4. Tubes in tubes: catheter navigation in blood vessels and its applications

Author

Wayne Lawton, Sohan Ranjan, Raju R. Viswanathan, and Raghu Raghavan

Subjects

Engineering, Catheter insertion, business.industry, Applied Mathematics, Mechanical Engineering, Acoustics, Artery walls, Condensed Matter Physics, Visual navigation, Visualization, Catheter, Mechanics of Materials, Modeling and Simulation, General Materials Science, business, Biomedical engineering

Abstract

The construction of realistic simulators for medical procedures is increasingly important. We describe here a physical model and a numerical algorithm to simulate the insertion and navigation of a catheter into an arterial system. A novel formulation of the elasticity of thin rods was developed for modeling the catheter. The catheter bends and twists within the blood vessels, not simply tracking a central curve. The inner artery walls are modeled as rigid surfaces; this constraint of catheter containment within rigid walls is implemented through the use of a wall potential. The model has been integrated into an interactive system, with visualization and a direct catheter input interface (previously described), called da Vinci (Visual navigation of catheter insertion).

Published

2000

5. Electrophysiology catheter and system for gentle and firm wall contact

Author

Raju R Viswanathan, Pappone C, Raju, R Viswanathan, and Pappone, C

Published

2007

6. A Civil Engineering Model of Protein Conformational Change

Author

Solaiyappan Meiyappan, Raghu Raghavan, Yi Yu, Wayne Lawton, and Raju R. Viswanathan

Subjects

Conformational change, Chemistry, Organic Chemistry, Peptide binding, Civil engineering, Catalysis, Finite element method, Computer Science Applications, Inorganic Chemistry, symbols.namesake, Protein structure, Computational Theory and Mathematics, Structural biology, symbols, Molecule, Physical and Theoretical Chemistry, van der Waals force, Oxygen binding

Abstract

We present a variational approach for the simulation of large conformational changes of proteins (including multiple protein chains/ligands) which takes advantage of their cross-linked one-dimensional nature, a structure which often occurs in civil engineering. Conformational changes are computed by incremental energy minimisation. We use an efficient finite element method for finding equilibria of complexes composed of inter-linked chains; this method is based on recent advances in the description of one-dimensional elasticity. Protein backbone elasticity, van der Waals repulsions, hydrogen bonds and salt bridges are taken into account, together with user-defined geometric distance constraints that may be imposed for purposes of simulating various binding processes based on chemical knowledge. These computational methods have been integrated into a system, Proteinmorphosis, which includes interactive visualisation. The conformational change of calmodulin upon peptide binding is examined as a first experiment. Allostery in hemoglobin, which consists of a cooperative oxygen binding mechanism, is a second, more sophisticated, numerical experiment. Different modelling strategies are designed to understand the allostery. The results for both molecules are consistent with existing hypotheses, and reproduce the known atomic positions after binding to within the experimental error. The modelling system is part of an on-going program to model structural biology, from protein structure to cell and tissue properties.

Published

1999

7. Ribbons and groups: a thin rod theory for catheters and filaments

Author

Sohan Ranjan, Raghu Raghavan, Wayne Lawton, and Raju R. Viswanathan

Subjects

genetic structures, Differential equation, Quantitative Biology::Tissues and Organs, General Physics and Astronomy, Perturbation (astronomy), Statistical and Nonlinear Physics, Rod, Finite element method, Condensed Matter::Soft Condensed Matter, symbols.namesake, Formalism (philosophy of mathematics), Classical mechanics, Euler's formula, symbols, sense organs, Mathematical Physics, Rotation group SO, Mathematics

Abstract

We use the rotation group and its algebra to provide a novel description of deformations of special Cosserat rods or thin rods that have negligible shear. Our treatment was motivated by the problem of the simulation of catheter navigation in a network of blood vessels, where this description is directly useful. In this context, we derive the Euler differential equations that characterize equilibrium configurations of stretch-free thin rods. We apply perturbation methods, used in time-dependent quantum theory, to the thin rod equations to describe incremental deformations of partially constrained rods. Further, our formalism leads naturally to a new and efficient finite element method valid for arbitrary deformations of thin rods with negligible stretch. Associated computational algorithms are developed and applied to the simulation of catheter motion inside an artery network.

Published

1999

8. A Continuum Mechanics-based Model for Cortical Growth

Author

Wayne Lawton, Sohan Ranjan, Raju R. Viswanathan, and Raghu Raghavan

Subjects

Statistics and Probability, General Immunology and Microbiology, Continuum mechanics, Applied Mathematics, Object (grammar), General Medicine, General Biochemistry, Genetics and Molecular Biology, Constraint (information theory), Shear (sheet metal), Classical mechanics, Modeling and Simulation, General Agricultural and Biological Sciences, Process (anatomy), Quasistatic process, Energy functional, Mathematics, Physical law

Abstract

One method for the synthesis of object shapes is by using physical laws. A continuum mechanics-based model of growth is proposed here. An energy functional of the shape of an elastic object, is defined. At every instant of the growth process, the shape of the object corresponds to a minimum of this energy functional; growth is taken to be a quasistatic process. The model is used to simulate the growth of a one-dimensional “brain cortex”. Starting from almost smooth initial configurations, growth leads to the formation of complex folds or convolutions. It is demonstrated that apart from the constraint of fitting in the skull, two other constraints are both necessary and sufficient to robustly generate patterns actually seen in cortical contours. These are: a minimum thickness for cortical folds due to white matter, and a shear constraint on the white matter tracts. Finally, an interesting difference between periodic and non-periodic initial conditions is pointed out.

Published

1997

9. Sign-constrained synapses and biased patterns in neural networks

Author

Raju R. Viswanathan

Subjects

Quantitative Biology::Neurons and Cognition, Artificial neural network, General Physics and Astronomy, Statistical and Nonlinear Physics, Context (language use), Neurophysiology, Inhibitory postsynaptic potential, medicine.anatomical_structure, medicine, Excitatory postsynaptic potential, Neuron, Algorithm, Neuroscience, Mathematical Physics, Sign (mathematics), Gauge symmetry, Mathematics

Abstract

The storage of biased patterns is examined in neural networks with sign-constrained synapses. Every neuron has outgoing synapses which are either all inhibitory or all excitatory. For random patterns stored in such networks, it is known that the presence of a discrete gauge symmetry makes the maximal storage capacity independent of the proportion of excitatory neurons to inhibitory neurons. When the stored patterns are biased, however, this discrete gauge symmetry is broken, with the result that the maximal capacity depends on the proportion of excitatory neurons to inhibitory ones. The dependence of the capacity on the fraction of excitatory neurons in the network, f, is calculated using the space of interactions approach. It is found that the storage capacity is maximal at f=0.5; this result is true regardless of the particular value of the bias in the stored patterns. The significance of this result in the neurophysiological context is discussed.

Published

1993

10. Neural networks with biased bipolar synapses and biased patterns

Author

Raju R. Viswanathan

Subjects

Coupling, Quantitative Biology::Neurons and Cognition, Artificial neural network, Computer science, General Physics and Astronomy, Statistical and Nonlinear Physics, Partition function (mathematics), Type (model theory), Topology, Space (mathematics), Constraint (information theory), Synapse, Distribution (mathematics), Mathematical Physics

Abstract

A neural network model with bipolar synaptic couplings is studied with a global constraint on the synapses which earn neuron receives, corresponding to a bias of the couplings. When the network is used to store biased patterns, it is shown that the maximal storage capacity for any non-zero bias of the stored patterns corresponds to a particular type of the connectivity pattern of the network as encoded in the constraint. The 'space of interactions' approach yields the dependence of the storage capacity on the distribution of the couplings for every pattern bias. It turns out that the optimal coupling bias is non-zero and independent of the bias in the patterns.

Published

1993

11. Proteinmorphosis: a mechanical model for protein conformational changes

Author

Yi Yu, Raghu Raghavan, S. Meiyappan, Raju R. Viswanathan, and Wayne Lawton

Subjects

Models, Molecular, Conformational change, Calmodulin, Databases, Factual, Protein Conformation, Allosteric regulation, Peptide binding, Protein Structure, Secondary, symbols.namesake, Hemoglobins, User-Computer Interface, Molecule, Computer Simulation, Physics, biology, Hydrogen bond, Computational Biology, Proteins, Hydrogen Bonding, Oxyhemoglobins, biology.protein, symbols, Thermodynamics, Calmodulin-Binding Proteins, van der Waals force, Biological system, Oxygen binding

Abstract

Proteinmorphosis is a physically-based interactive modeling system for simulating large or small conformational changes of proteins and protein complexes. It takes advantage of the cross-linked one-dimensional nature of protein chains. The user can, based on her chemical knowledge, pull pairs of points (lying either on a single protein or on different molecules) together by specifying geometric distance constraints. The resulting conformation(s) of the molecule(s) of interest is computed by an efficient finite element formalism taking into account elasticity of the protein backbone, van der Waals repulsions, hydrogen bonds, salt bridges and the imposed distance constraints. The conformational change is computed incrementally and the result can be visualized as an animation; complete interactivity is provided to position and view the proteins as desired by the user. Physical properties of regions on the protein can also be chosen interactively. The conformational change of calmodulin upon peptide binding is examined as a first experiment. It is found that the result is satisfactory in reproducing the conformational change that follows on peptide binding. We use Proteinmorphosis to study the cooperative hemoglobin oxygen binding mechanism in a second, more sophisticated, experiment. Different modeling strategies are designed to understand the allosteric (cooperative) binding process in this system and the results are found to be consistent with existing hypotheses.

Published

1999

12. Pulsed field ablation prevents chronic atrial fibrotic changes and restrictive mechanics after catheter ablation for atrial fibrillation.

Author

Nakatani Y, Sridi-Cheniti S, Cheniti G, Ramirez FD, Goujeau C, André C, Nakashima T, Eggert C, Schneider C, Viswanathan R, Krisai P, Takagi T, Kamakura T, Vlachos K, Derval N, Duchateau J, Pambrun T, Chauvel R, Reddy VY, Montaudon M, Laurent F, Sacher F, Hocini M, Haïssaguerre M, Jaïs P, and Cochet H

Subjects

Contrast Media, Fibrosis, Gadolinium, Heart Atria diagnostic imaging, Heart Atria pathology, Heart Atria surgery, Humans, Magnetic Resonance Imaging, Atrial Fibrillation diagnosis, Catheter Ablation adverse effects, Catheter Ablation methods

Abstract

Aims: Pulsed field ablation (PFA), a non-thermal ablative modality, may show different effects on the myocardial tissue compared to thermal ablation. Thus, this study aimed to compare the left atrial (LA) structural and mechanical characteristics after PFA vs. thermal ablation., Methods and Results: Cardiac magnetic resonance was performed pre-ablation, acutely (<3 h), and 3 months post-ablation in 41 patients with paroxysmal atrial fibrillation (AF) undergoing pulmonary vein (PV) isolation with PFA (n = 18) or thermal ablation (n = 23, 16 radiofrequency ablations, 7 cryoablations). Late gadolinium enhancement (LGE), T2-weighted, and cine images were analysed. In the acute stage, LGE volume was 60% larger after PFA vs. thermal ablation (P < 0.001), and oedema on T2 imaging was 20% smaller (P = 0.002). Tissue changes were more homogeneous after PFA than after thermal ablation, with no sign of microvascular damage or intramural haemorrhage. In the chronic stage, the majority of acute LGE had disappeared after PFA, whereas most LGE persisted after thermal ablation. The maximum strain on PV antra, the LA expansion index, and LA active emptying fraction declined acutely after both PFA and thermal ablation but recovered at the chronic stage only with PFA., Conclusion: Pulsed field ablation induces large acute LGE without microvascular damage or intramural haemorrhage. Most LGE lesions disappear in the chronic stage, suggesting a specific reparative process involving less chronic fibrosis. This process may contribute to a preserved tissue compliance and LA reservoir and booster pump functions., (© The Author(s) 2021. Published by Oxford University Press on behalf of the European Society of Cardiology.)

Published

2021

13. Pulsed field ablation selectively spares the oesophagus during pulmonary vein isolation for atrial fibrillation.

Author

Cochet H, Nakatani Y, Sridi-Cheniti S, Cheniti G, Ramirez FD, Nakashima T, Eggert C, Schneider C, Viswanathan R, Derval N, Duchateau J, Pambrun T, Chauvel R, Reddy VY, Montaudon M, Laurent F, Sacher F, Hocini M, Haïssaguerre M, and Jais P

Subjects

Esophagus diagnostic imaging, Esophagus surgery, Heart Atria surgery, Humans, Treatment Outcome, Atrial Fibrillation diagnostic imaging, Atrial Fibrillation surgery, Catheter Ablation adverse effects, Pulmonary Veins diagnostic imaging, Pulmonary Veins surgery

Abstract

Aims: Extra-atrial injury can cause complications after catheter ablation for atrial fibrillation (AF). Pulsed field ablation (PFA) has generated preclinical data suggesting that it selectively targets the myocardium. We sought to characterize extra-atrial injuries after pulmonary vein isolation (PVI) between PFA and thermal ablation methods., Methods and Results: Cardiac magnetic resonance (CMR) imaging was performed before, acutely (<3 h) and 3 months post-ablation in 41 paroxysmal AF patients undergoing PVI with PFA (N = 18, Farapulse) or thermal methods (N = 23, 16 radiofrequency, 7 cryoballoon). Oesophageal and aortic injuries were assessed by using late gadolinium-enhanced (LGE) imaging. Phrenic nerve injuries were assessed from diaphragmatic motion on intra-procedural fluoroscopy. Baseline CMR showed no abnormality on the oesophagus or aorta. During ablation procedures, no patient showed phrenic palsy. Acutely, thermal methods induced high rates of oesophageal lesions (43%), all observed in patients showing direct contact between the oesophagus and the ablation sites. In contrast, oesophageal lesions were observed in no patient ablated with PFA (0%, P < 0.001 vs. thermal methods), despite similar rates of direct contact between the oesophagus and the ablation sites (P = 0.41). Acute lesions were detected on CMR on the descending aorta in 10/23 (43%) after thermal ablation, and in 6/18 (33%) after PFA (P = 0.52). CMR at 3 months showed a complete resolution of oesophageal and aortic LGE in all patients. No patient showed clinical complications., Conclusion: PFA does not induce any signs of oesophageal injury on CMR after PVI. Due to its tissue selectivity, PFA may improve safety for catheter ablation of AF., (© The Author(s) 2021. Published by Oxford University Press on behalf of the European Society of Cardiology.)

Published

2021

14. Emerging Technologies for Pulmonary Vein Isolation.

Author

Ramirez FD, Reddy VY, Viswanathan R, Hocini M, and Jaïs P

Subjects

Animals, Humans, Atrial Fibrillation surgery, Catheter Ablation methods, Pulmonary Veins surgery

Abstract

Atrial fibrillation is the most common sustained cardiac arrhythmia and is associated with considerable morbidity and mortality. Electrically isolating the pulmonary veins from the left atrium by catheter ablation is superior to antiarrhythmic drug therapy for maintaining sinus rhythm, but its success varies depending on multiple factors, including arrhythmic burden. Although procedural outcomes have improved over the years, further gains are limited by a seemingly zero-sum relationship between effectiveness and safety, which is largely a product of the available technologies. Current energies used to create contiguous, transmural, and durable atrial lesions can result in serious complications if they reach the esophagus or phrenic nerve, for instance-structures that can be adjacent to the atrial myocardium, often within millimeters of the energy source. Consequently, high rates of pulmonary vein-left atrium reconnections are consistently seen in clinical studies and in clinical practice as operators appropriately forgo ablation effectiveness to protect patients from harm. However, as ablative technologies evolve to circumvent this stalemate, safer, and more effective pulmonary vein isolation seems increasingly realistic. Furthermore, the innovative nature of these technologies raises the prospect of markedly improved procedural efficiency, which could increase patient comfort, reduce operator occupational injuries, and enhance the use of health resources-all of which are increasingly important considerations particularly as the demand for catheter ablation for atrial fibrillation continues to rise. We herein review 3 promising candidate ablation technologies with the potential to revolutionize the management of patients with atrial fibrillation: electroporation (pulsed-field ablation), expandable lattice-tip radiofrequency ablation/electroporation, and ultra-low temperature cryoablation.

Published

2020

15. Pulsed Field Ablation Versus Radiofrequency Ablation: Esophageal Injury in a Novel Porcine Model.

Author

Koruth JS, Kuroki K, Kawamura I, Brose R, Viswanathan R, Buck ED, Donskoy E, Neuzil P, Dukkipati SR, and Reddy VY

Subjects

Animals, Catheter Ablation adverse effects, Disease Models, Animal, Postoperative Complications etiology, Swine, Atrial Fibrillation surgery, Catheter Ablation methods, Esophagus injuries, Heart Atria surgery, Postoperative Complications prevention & control

Abstract

Background: Pulsed field ablation (PFA) can be myocardium selective, potentially sparing the esophagus during left atrial ablation. In an in vivo porcine esophageal injury model, we compared the effects of newer biphasic PFA with radiofrequency ablation (RFA)., Methods: In 10 animals, under general anesthesia, the lower esophagus was deflected toward the inferior vena cava using an esophageal deviation balloon, and ablation was performed from within the inferior vena cava at areas of esophageal contact. Four discrete esophageal sites were targeted in each animal: 6 animals received 8 PFA applications/site (2 kV, multispline catheter), and 4 animals received 6 clusters of irrigated RFA applications (30 W×30 seconds, 3.5 mm catheter). All animals were survived to 25 days, sacrificed, and the esophagus submitted for pathological examination, including 10 discrete histological sections/esophagus., Results: The animals weight increased by 13.7±6.2% and 6.8±6.3% ( P =0.343) in the PFA and RFA cohorts, respectively. No PFA animals (0 of 6, 0%) developed abnormal in-life observations, but 1 of 4 RFA animals (25%) developed fever and dyspnea. On necropsy, no PFA animals (0 of 6, 0%) demonstrated esophageal lesions. In contrast, esophageal injury occurred in all RFA animals (4 of 4, 100%; P =0.005): a mean of 1.5 mucosal lesions/animal (length, -21.8±8.9 mm; width, -4.9±1.4 mm) were observed, including one esophago-pulmonary fistula and deep esophageal ulcers in the other animals. Histological examination demonstrated tissue necrosis surrounded by acute and chronic inflammation and fibrosis. The necrotic RFA lesions involved multiple esophageal tissue layers with evidence of arteriolar medial thickening and fibrosis of periesophageal nerves. Abscess formation and full-thickness esophageal wall disruptions were seen in areas of perforation/fistula., Conclusions: In this novel porcine model of esophageal injury, biphasic PFA induced no chronic histopathologic esophageal changes, while RFA demonstrated a spectrum of esophageal lesions including fistula and deep esophageal ulcers and abscesses.

Published

2020

16. Endocardial ventricular pulsed field ablation: a proof-of-concept preclinical evaluation.

Author

Koruth JS, Kuroki K, Iwasawa J, Viswanathan R, Brose R, Buck ED, Donskoy E, Dukkipati SR, and Reddy VY

Subjects

Animals, Arrhythmias, Cardiac, Endocardium, Heart Ventricles surgery, Myocardium, Swine, Catheter Ablation, Tachycardia, Ventricular surgery

Abstract

Aims: Pulsed field ablation (PFA) is a novel, non-thermal modality that selectively ablates myocardium with ultra-short electrical impulses while sparing collateral tissues. In a proof-of-concept study, the safety and feasibility of ventricular PFA were assessed using a prototype steerable, endocardial catheter., Methods and Results: Under general anaesthesia, the left and right ventricles of four healthy swine were ablated using the 12-Fr deflectable PFA catheter and a deflectable sheath guided by electroanatomic mapping. Using the study catheter, electrograms were recorded for each site and pre-ablation and post-ablation pacing thresholds (at 2.0 ms pulse width) were recorded in two of four animals. After euthanasia at 35.5 days, the hearts were submitted for histology. The PFA applications (n = 39) resulted in significant electrogram reduction without ventricular arrhythmias. In ablation sites where it was measured, the pacing thresholds increased by >16.8 mA in the right ventricle (3 sites) and >16.1 mA in the left ventricle (7 sites), with non-capture at maximum amplitude (20 mA) observable in 8 of 10 sites. Gross measurements, available for 28 of 30 ablation sites, revealed average lesion dimensions to be 6.5 ± 1.7 mm deep by 22.6 ± 4.1 mm wide, with a maximum depth and width of 9.4 mm and 28.6 mm, respectively. In the PFA lesions, fibrous tissue homogeneously replaced myocytes with a narrow zone of surrounding myocytolysis and no overlying thrombus. When present, nerve fascicles and vasculature were preserved within surrounding fibrosis., Conclusion: We demonstrate that endocardial PFA can be focally delivered using this prototype catheter to create homogeneous, myocardium-specific lesions., (© The Author(s) 2019. Published by Oxford University Press on behalf of the European Society of Cardiology.)

Published

2020

17. Preclinical Evaluation of Pulsed Field Ablation: Electrophysiological and Histological Assessment of Thoracic Vein Isolation.

Author

Koruth J, Kuroki K, Iwasawa J, Enomoto Y, Viswanathan R, Brose R, Buck ED, Speltz M, Dukkipati SR, and Reddy VY

Subjects

Action Potentials, Animals, Catheter Ablation adverse effects, Female, Pulmonary Veins pathology, Pulmonary Veins physiopathology, Sus scrofa, Vena Cava, Superior pathology, Vena Cava, Superior physiopathology, Catheter Ablation methods, Pulmonary Veins surgery, Thorax blood supply, Vena Cava, Superior surgery

Abstract

Background: Pulsed field ablation (PFA) is a uniquely tissue-selective, nonthermal cardiac ablation modality. Delivery parameters such as the electrical waveform composition and device design are critical to PFA's efficacy and safety, particularly tissue specificity. In a series of preclinical studies, we sought to examine the electrophysiological and histological effects of PFA and compare the safety and feasibility of durable pulmonary vein and superior vena cava (SVC) isolation between radiofrequency ablation and PFA waveforms., Methods: A femoral venous approach was used to gain right and left atrial access under general anesthesia in healthy swine. Baseline potentials in right superior pulmonary and inferior common vein and in SVC were assessed. Bipolar PFA was performed with monophasic (PFA Mono ) and biphasic (PFA Bi ) waveforms in 7 and 7 swine sequentially and irrigated radiofrequency ablation in 3 swine. Vein potentials were then assessed acutely, and at ≈10 weeks; histology was obtained., Results: All targeted veins (n=46) were successfully isolated on the first attempt in all cohorts. The PFA Bi waveform induced significantly less skeletal muscle engagement. Pulmonary vein isolation durability was assessed in 28 veins: including the SVC, durability was significantly higher in the PFA Bi group (18/18 PFA Bi , 10/18 PFA Mono , 3/6 radiofrequency, P =0.002). Transmurality rates were similar across groups with evidence of nerve damage only with radiofrequency. Pulmonary vein narrowing was noted only in the radiofrequency cohort. The phrenic nerve was spared in all cohorts but at the expense of incomplete SVC encirclement with radiofrequency., Conclusions: In this chronic porcine study, PFA-based pulmonary vein and SVC isolation were safe and efficacious with demonstrable sparing of nerves and venous tissue. This preclinical study provided the scientific basis for the first-in-human endocardial PFA studies.

Published

2019

18. Earth before life.

Author

Marzban C, Viswanathan R, and Yurtsever U

Subjects

Evolution, Molecular, Regression Analysis, Earth, Planet, Genome, Models, Genetic

Abstract

Background: A recent study argued, based on data on functional genome size of major phyla, that there is evidence life may have originated significantly prior to the formation of the Earth., Results: Here a more refined regression analysis is performed in which 1) measurement error is systematically taken into account, and 2) interval estimates (e.g., confidence or prediction intervals) are produced. It is shown that such models for which the interval estimate for the time origin of the genome includes the age of the Earth are consistent with observed data., Conclusions: The appearance of life after the formation of the Earth is consistent with the data set under examination.

Published

2014