Violin plot of the dependency of time required for rotor anchoring or termination on the initial distance between the rotor tip and the border of the fibrotic region in the 2D model.

Change of the number of filaments in course of time under different ischemia factors obtained from numerical simulations.

Ivan V. Kazbanov (486024)
Richard H. Clayton (655829)
Martyn P. Nash (348320)
Chris P. Bradley (655830)
David J. Paterson (655831)
Martin P. Hayward (655832)
Peter Taggart (108650)
Alexander V. Panfilov (196505)

November 2014

A: normal conditions, B: hyperkalemia, C: hypoxia, D: example of spontaneous fibrillation stop.</...

Effects of refractory gradients and ablation on fibrillatory activity

Ciaccio, EJ
Peters, NS
Garan, H

February 2018

Background The mechanisms involved in onset, maintenance, and termination of atrial fibrillation are...

Analytical Model for Predicting Mechanotransduction Effects in Engineered Cardiac Tissue

Latimer, David C.
Roth, Bradley J.
Parker, Kevin Kit

January 2003

Mechanochemical and mechanoelectrical signaling is imperative for cardiac organogenesis and underlie...

Dynamical anchoring of a distant rotor to a fibrotic region in the 2D model.

Nele Vandersickel (508237)
Masaya Watanabe (738998)
Qian Tao (52731)
Jan Fostier (404603)
Katja Zeppenfeld (6107954)
Alexander V. Panfilov (196505)

January 2019

Unexcitable fibrotic tissue is shown in orange and the transmembrane voltage is shown in shades of g...

Dynamical anchoring of distant arrhythmia sources by fibrotic regions via restructuring of the activation pattern

Nele Vandersickel (508237)
Masaya Watanabe (738998)
Qian Tao (52731)
Jan Fostier (404603)
Katja Zeppenfeld (6107954)
Alexander V. Panfilov (196505)

January 2019

Rotors are functional reentry sources identified in clinically relevant cardiac arrhythmias, such as...

Effect of the dynamical anchoring of a rotor for a patient-specific model of the left ventricle after infero-lateral MI.

Nele Vandersickel (508237)
Masaya Watanabe (738998)
Qian Tao (52731)
Jan Fostier (404603)
Katja Zeppenfeld (6107954)
Alexander V. Panfilov (196505)

January 2019

Red color corresponds to high transmembrane voltage, pink color shows the scar. The top row shows th...

Phase diagram showing the region where the anchoring effect is present in two-parametric space: The size of the scar and the fibrosis level.

Nele Vandersickel (508237)
Masaya Watanabe (738998)
Qian Tao (52731)
Jan Fostier (404603)
Katja Zeppenfeld (6107954)
Alexander V. Panfilov (196505)

January 2019

The scar had a uniform fibrosis distribution. The mark “Attraction” corresponds to the region where ...

Simulation of rotor breakup and fibrillatory activity.

Wei Wang (17594)
Lifan Xu (517246)
John Cavazos (517247)
Howie H. Huang (517248)
Matthew Kay (517249)

January 2014

Top: an image of transmembrane potential showing complex wave activity. Bottom: action potentials...

Myocardial fibrosis in a 3D model: Effect of texture on wave propagation

Dokuchaev, A.
Panfilov, A. V.
Solovyova, O.

January 2020

Non-linear electrical waves propagate through the heart and control cardiac contraction. Abnormal wa...

Video_2_Dispersion of Recovery and Vulnerability to Re-entry in a Model of Human Atrial Tissue With Simulated Diffuse and Focal Patterns of Fibrosis.MPG

Richard H. Clayton (655829)

August 2018

Fibrosis in atrial tissue can act as a substrate for persistent atrial fibrillation, and can be f...

Video_3_Dispersion of Recovery and Vulnerability to Re-entry in a Model of Human Atrial Tissue With Simulated Diffuse and Focal Patterns of Fibrosis.MPG

Richard H. Clayton (655829)

August 2018

Fibrosis in atrial tissue can act as a substrate for persistent atrial fibrillation, and can be f...

Video_4_Dispersion of Recovery and Vulnerability to Re-entry in a Model of Human Atrial Tissue With Simulated Diffuse and Focal Patterns of Fibrosis.MPG

Richard H. Clayton (655829)

August 2018

Fibrosis in atrial tissue can act as a substrate for persistent atrial fibrillation, and can be f...

Video_6_Dispersion of Recovery and Vulnerability to Re-entry in a Model of Human Atrial Tissue With Simulated Diffuse and Focal Patterns of Fibrosis.MPG

Richard H. Clayton (655829)

August 2018

Fibrosis in atrial tissue can act as a substrate for persistent atrial fibrillation, and can be f...

Video_5_Dispersion of Recovery and Vulnerability to Re-entry in a Model of Human Atrial Tissue With Simulated Diffuse and Focal Patterns of Fibrosis.MPG

Richard H. Clayton (655829)

August 2018

Fibrosis in atrial tissue can act as a substrate for persistent atrial fibrillation, and can be f...

Image_1_Dispersion of Recovery and Vulnerability to Re-entry in a Model of Human Atrial Tissue With Simulated Diffuse and Focal Patterns of Fibrosis.TIFF

Richard H. Clayton (655829)

August 2018

Fibrosis in atrial tissue can act as a substrate for persistent atrial fibrillation, and can be f...

Change of the number of filaments in course of time under different ischemia factors obtained from numerical simulations.

Ivan V. Kazbanov (486024)
Richard H. Clayton (655829)
Martyn P. Nash (348320)
Chris P. Bradley (655830)
David J. Paterson (655831)
Martin P. Hayward (655832)
Peter Taggart (108650)
Alexander V. Panfilov (196505)

November 2014

A: normal conditions, B: hyperkalemia, C: hypoxia, D: example of spontaneous fibrillation stop.</...

Effects of refractory gradients and ablation on fibrillatory activity

Ciaccio, EJ
Peters, NS
Garan, H

February 2018

Background The mechanisms involved in onset, maintenance, and termination of atrial fibrillation are...

Analytical Model for Predicting Mechanotransduction Effects in Engineered Cardiac Tissue

Latimer, David C.
Roth, Bradley J.
Parker, Kevin Kit

January 2003

Mechanochemical and mechanoelectrical signaling is imperative for cardiac organogenesis and underlie...

Dynamical anchoring of a distant rotor to a fibrotic region in the 2D model.

Nele Vandersickel (508237)
Masaya Watanabe (738998)
Qian Tao (52731)
Jan Fostier (404603)
Katja Zeppenfeld (6107954)
Alexander V. Panfilov (196505)

January 2019

Unexcitable fibrotic tissue is shown in orange and the transmembrane voltage is shown in shades of g...

Dynamical anchoring of distant arrhythmia sources by fibrotic regions via restructuring of the activation pattern

Nele Vandersickel (508237)
Masaya Watanabe (738998)
Qian Tao (52731)
Jan Fostier (404603)
Katja Zeppenfeld (6107954)
Alexander V. Panfilov (196505)

January 2019

Rotors are functional reentry sources identified in clinically relevant cardiac arrhythmias, such as...

Effect of the dynamical anchoring of a rotor for a patient-specific model of the left ventricle after infero-lateral MI.

Nele Vandersickel (508237)
Masaya Watanabe (738998)
Qian Tao (52731)
Jan Fostier (404603)
Katja Zeppenfeld (6107954)
Alexander V. Panfilov (196505)

January 2019

Red color corresponds to high transmembrane voltage, pink color shows the scar. The top row shows th...

Phase diagram showing the region where the anchoring effect is present in two-parametric space: The size of the scar and the fibrosis level.

Nele Vandersickel (508237)
Masaya Watanabe (738998)
Qian Tao (52731)
Jan Fostier (404603)
Katja Zeppenfeld (6107954)
Alexander V. Panfilov (196505)

January 2019

The scar had a uniform fibrosis distribution. The mark “Attraction” corresponds to the region where ...

Simulation of rotor breakup and fibrillatory activity.

Wei Wang (17594)
Lifan Xu (517246)
John Cavazos (517247)
Howie H. Huang (517248)
Matthew Kay (517249)

January 2014

Top: an image of transmembrane potential showing complex wave activity. Bottom: action potentials...

Myocardial fibrosis in a 3D model: Effect of texture on wave propagation

Dokuchaev, A.
Panfilov, A. V.
Solovyova, O.

January 2020

Non-linear electrical waves propagate through the heart and control cardiac contraction. Abnormal wa...

Video_2_Dispersion of Recovery and Vulnerability to Re-entry in a Model of Human Atrial Tissue With Simulated Diffuse and Focal Patterns of Fibrosis.MPG

Richard H. Clayton (655829)

August 2018

Fibrosis in atrial tissue can act as a substrate for persistent atrial fibrillation, and can be f...

Video_3_Dispersion of Recovery and Vulnerability to Re-entry in a Model of Human Atrial Tissue With Simulated Diffuse and Focal Patterns of Fibrosis.MPG

Richard H. Clayton (655829)

August 2018

Fibrosis in atrial tissue can act as a substrate for persistent atrial fibrillation, and can be f...

Video_4_Dispersion of Recovery and Vulnerability to Re-entry in a Model of Human Atrial Tissue With Simulated Diffuse and Focal Patterns of Fibrosis.MPG

Richard H. Clayton (655829)

August 2018

Fibrosis in atrial tissue can act as a substrate for persistent atrial fibrillation, and can be f...

Video_6_Dispersion of Recovery and Vulnerability to Re-entry in a Model of Human Atrial Tissue With Simulated Diffuse and Focal Patterns of Fibrosis.MPG

Richard H. Clayton (655829)

August 2018

Fibrosis in atrial tissue can act as a substrate for persistent atrial fibrillation, and can be f...

Video_5_Dispersion of Recovery and Vulnerability to Re-entry in a Model of Human Atrial Tissue With Simulated Diffuse and Focal Patterns of Fibrosis.MPG

Richard H. Clayton (655829)

August 2018

Fibrosis in atrial tissue can act as a substrate for persistent atrial fibrillation, and can be f...

Image_1_Dispersion of Recovery and Vulnerability to Re-entry in a Model of Human Atrial Tissue With Simulated Diffuse and Focal Patterns of Fibrosis.TIFF

Richard H. Clayton (655829)

August 2018

Fibrosis in atrial tissue can act as a substrate for persistent atrial fibrillation, and can be f...

Change of the number of filaments in course of time under different ischemia factors obtained from numerical simulations.

Ivan V. Kazbanov (486024)
Richard H. Clayton (655829)
Martyn P. Nash (348320)
Chris P. Bradley (655830)
David J. Paterson (655831)
Martin P. Hayward (655832)
Peter Taggart (108650)
Alexander V. Panfilov (196505)

November 2014

A: normal conditions, B: hyperkalemia, C: hypoxia, D: example of spontaneous fibrillation stop.</...

Effects of refractory gradients and ablation on fibrillatory activity

Ciaccio, EJ
Peters, NS
Garan, H

February 2018

Background The mechanisms involved in onset, maintenance, and termination of atrial fibrillation are...

Analytical Model for Predicting Mechanotransduction Effects in Engineered Cardiac Tissue

Latimer, David C.
Roth, Bradley J.
Parker, Kevin Kit

January 2003

Mechanochemical and mechanoelectrical signaling is imperative for cardiac organogenesis and underlie...

Violin plot of the dependency of time required for rotor anchoring or termination on the initial distance between the rotor tip and the border of the fibrotic region in the 2D model.

Abstract

Extracted data

Violin plot of the dependency of time required for rotor anchoring or termination on the initial distance between the rotor tip and the border of the fibrotic region in the 2D model.

Abstract

Extracted data

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