All Roads Lead to Rome: Diverse Etiologies of Tricuspid Regurgitation Create a Predictable Constellation of Right Ventricular Shape Changes

Introduction: Myriad disorders cause right ventricular (RV) dilation and lead to tricuspid regurgitation (TR). Because the thin-walled, flexible RV is mechanically coupled to the pulmonary circulation and the left ventricular septum, it distorts with any disturbance in the cardiopulmonary system. TR...

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Published in	Frontiers in physiology Vol. 13; p. 908552
Main Authors	Orkild, Benjamin A., Zenger, Brian, Iyer, Krithika, Rupp, Lindsay C., Ibrahim, Majd M, Khashani, Atefeh G., Perez, Maura D., Foote, Markus D., Bergquist, Jake A., Morris, Alan K., Kim, Jiwon J., Steinberg, Benjamin A., Selzman, Craig, Ratcliffe, Mark B., MacLeod, Rob S., Elhabian, Shireen, Morgan, Ashley E.
Format	Journal Article
Language	English
Published	Switzerland Frontiers Media S.A 02.06.2022
Subjects	cardiac MRI particle-based shape modeling Physiology principal component analysis pulmonary hypertension statistical shape modeling tricuspid regurgitation tricuspid regurgitation cardiac MRI pulmonary hypertension particle-based shape modeling statistical shape modeling congestive heart failure valvular heart disease principal component analysis
Online Access	Get full text
ISSN	1664-042X 1664-042X
DOI	10.3389/fphys.2022.908552

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Abstract	Introduction: Myriad disorders cause right ventricular (RV) dilation and lead to tricuspid regurgitation (TR). Because the thin-walled, flexible RV is mechanically coupled to the pulmonary circulation and the left ventricular septum, it distorts with any disturbance in the cardiopulmonary system. TR, therefore, can result from pulmonary hypertension, left heart failure, or intrinsic RV dysfunction; but once it occurs, TR initiates a cycle of worsening RV volume overload, potentially progressing to right heart failure. Characteristic three-dimensional RV shape-changes from this process, and changes particular to individual TR causes, have not been defined in detail. Methods: Cardiac MRI was obtained in 6 healthy volunteers, 41 patients with ≥ moderate TR, and 31 control patients with cardiac disease without TR. The mean shape of each group was constructed using a three-dimensional statistical shape model via the particle-based shape modeling approach. Changes in shape were examined across pulmonary hypertension and congestive heart failure subgroups using principal component analysis (PCA). A logistic regression approach based on these PCA modes identified patients with TR using RV shape alone. Results: Mean RV shape in patients with TR exhibited free wall bulging, narrowing of the base, and blunting of the RV apex compared to controls ( p < 0.05). Using four primary PCA modes, a logistic regression algorithm identified patients with TR correctly with 82% recall and 87% precision. In patients with pulmonary hypertension without TR, RV shape was narrower and more streamlined than in healthy volunteers. However, in RVs with TR and pulmonary hypertension, overall RV shape continued to demonstrate the free wall bulging characteristic of TR. In the subgroup of patients with congestive heart failure without TR, this intermediate state of RV muscular hypertrophy was not present. Conclusion: The multiple causes of TR examined in this study changed RV shape in similar ways. Logistic regression classification based on these shape changes reliably identified patients with TR regardless of etiology. Furthermore, pulmonary hypertension without TR had unique shape features, described here as the “well compensated” RV. These results suggest shape modeling as a promising tool for defining severity of RV disease and risk of decompensation, particularly in patients with pulmonary hypertension.
AbstractList	Introduction: Myriad disorders cause right ventricular (RV) dilation and lead to tricuspid regurgitation (TR). Because the thin-walled, flexible RV is mechanically coupled to the pulmonary circulation and the left ventricular septum, it distorts with any disturbance in the cardiopulmonary system. TR, therefore, can result from pulmonary hypertension, left heart failure, or intrinsic RV dysfunction; but once it occurs, TR initiates a cycle of worsening RV volume overload, potentially progressing to right heart failure. Characteristic three-dimensional RV shape-changes from this process, and changes particular to individual TR causes, have not been defined in detail. Methods: Cardiac MRI was obtained in 6 healthy volunteers, 41 patients with ≥ moderate TR, and 31 control patients with cardiac disease without TR. The mean shape of each group was constructed using a three-dimensional statistical shape model via the particle-based shape modeling approach. Changes in shape were examined across pulmonary hypertension and congestive heart failure subgroups using principal component analysis (PCA). A logistic regression approach based on these PCA modes identified patients with TR using RV shape alone. Results: Mean RV shape in patients with TR exhibited free wall bulging, narrowing of the base, and blunting of the RV apex compared to controls ( p < 0.05). Using four primary PCA modes, a logistic regression algorithm identified patients with TR correctly with 82% recall and 87% precision. In patients with pulmonary hypertension without TR, RV shape was narrower and more streamlined than in healthy volunteers. However, in RVs with TR and pulmonary hypertension, overall RV shape continued to demonstrate the free wall bulging characteristic of TR. In the subgroup of patients with congestive heart failure without TR, this intermediate state of RV muscular hypertrophy was not present. Conclusion: The multiple causes of TR examined in this study changed RV shape in similar ways. Logistic regression classification based on these shape changes reliably identified patients with TR regardless of etiology. Furthermore, pulmonary hypertension without TR had unique shape features, described here as the “well compensated” RV. These results suggest shape modeling as a promising tool for defining severity of RV disease and risk of decompensation, particularly in patients with pulmonary hypertension. Introduction: Myriad disorders cause right ventricular (RV) dilation and lead to tricuspid regurgitation (TR). Because the thin-walled, flexible RV is mechanically coupled to the pulmonary circulation and the left ventricular septum, it distorts with any disturbance in the cardiopulmonary system. TR, therefore, can result from pulmonary hypertension, left heart failure, or intrinsic RV dysfunction; but once it occurs, TR initiates a cycle of worsening RV volume overload, potentially progressing to right heart failure. Characteristic three-dimensional RV shape-changes from this process, and changes particular to individual TR causes, have not been defined in detail.Methods: Cardiac MRI was obtained in 6 healthy volunteers, 41 patients with ≥ moderate TR, and 31 control patients with cardiac disease without TR. The mean shape of each group was constructed using a three-dimensional statistical shape model via the particle-based shape modeling approach. Changes in shape were examined across pulmonary hypertension and congestive heart failure subgroups using principal component analysis (PCA). A logistic regression approach based on these PCA modes identified patients with TR using RV shape alone.Results: Mean RV shape in patients with TR exhibited free wall bulging, narrowing of the base, and blunting of the RV apex compared to controls (p<0.05). Using four primary PCA modes, a logistic regression algorithm identified patients with TR correctly with 82% recall and 87% precision. In patients with pulmonary hypertension without TR, RV shape was narrower and more streamlined than in healthy volunteers. However, in RVs with TR and pulmonary hypertension, overall RV shape continued to demonstrate the free wall bulging characteristic of TR. In the subgroup of patients with congestive heart failure without TR, this intermediate state of RV muscular hypertrophy was not present.Conclusion: The multiple causes of TR examined in this study changed RV shape in similar ways. Logistic regression classification based on these shape changes reliably identified patients with TR regardless of etiology. Furthermore, pulmonary hypertension without TR had unique shape features, described here as the “well compensated” RV. These results suggest shape modeling as a promising tool for defining severity of RV disease and risk of decompensation, particularly in patients with pulmonary hypertension. Introduction: Myriad disorders cause right ventricular (RV) dilation and lead to tricuspid regurgitation (TR). Because the thin-walled, flexible RV is mechanically coupled to the pulmonary circulation and the left ventricular septum, it distorts with any disturbance in the cardiopulmonary system. TR, therefore, can result from pulmonary hypertension, left heart failure, or intrinsic RV dysfunction; but once it occurs, TR initiates a cycle of worsening RV volume overload, potentially progressing to right heart failure. Characteristic three-dimensional RV shape-changes from this process, and changes particular to individual TR causes, have not been defined in detail. Methods: Cardiac MRI was obtained in 6 healthy volunteers, 41 patients with ≥ moderate TR, and 31 control patients with cardiac disease without TR. The mean shape of each group was constructed using a three-dimensional statistical shape model via the particle-based shape modeling approach. Changes in shape were examined across pulmonary hypertension and congestive heart failure subgroups using principal component analysis (PCA). A logistic regression approach based on these PCA modes identified patients with TR using RV shape alone. Results: Mean RV shape in patients with TR exhibited free wall bulging, narrowing of the base, and blunting of the RV apex compared to controls (p < 0.05). Using four primary PCA modes, a logistic regression algorithm identified patients with TR correctly with 82% recall and 87% precision. In patients with pulmonary hypertension without TR, RV shape was narrower and more streamlined than in healthy volunteers. However, in RVs with TR and pulmonary hypertension, overall RV shape continued to demonstrate the free wall bulging characteristic of TR. In the subgroup of patients with congestive heart failure without TR, this intermediate state of RV muscular hypertrophy was not present. Conclusion: The multiple causes of TR examined in this study changed RV shape in similar ways. Logistic regression classification based on these shape changes reliably identified patients with TR regardless of etiology. Furthermore, pulmonary hypertension without TR had unique shape features, described here as the "well compensated" RV. These results suggest shape modeling as a promising tool for defining severity of RV disease and risk of decompensation, particularly in patients with pulmonary hypertension.Introduction: Myriad disorders cause right ventricular (RV) dilation and lead to tricuspid regurgitation (TR). Because the thin-walled, flexible RV is mechanically coupled to the pulmonary circulation and the left ventricular septum, it distorts with any disturbance in the cardiopulmonary system. TR, therefore, can result from pulmonary hypertension, left heart failure, or intrinsic RV dysfunction; but once it occurs, TR initiates a cycle of worsening RV volume overload, potentially progressing to right heart failure. Characteristic three-dimensional RV shape-changes from this process, and changes particular to individual TR causes, have not been defined in detail. Methods: Cardiac MRI was obtained in 6 healthy volunteers, 41 patients with ≥ moderate TR, and 31 control patients with cardiac disease without TR. The mean shape of each group was constructed using a three-dimensional statistical shape model via the particle-based shape modeling approach. Changes in shape were examined across pulmonary hypertension and congestive heart failure subgroups using principal component analysis (PCA). A logistic regression approach based on these PCA modes identified patients with TR using RV shape alone. Results: Mean RV shape in patients with TR exhibited free wall bulging, narrowing of the base, and blunting of the RV apex compared to controls (p < 0.05). Using four primary PCA modes, a logistic regression algorithm identified patients with TR correctly with 82% recall and 87% precision. In patients with pulmonary hypertension without TR, RV shape was narrower and more streamlined than in healthy volunteers. However, in RVs with TR and pulmonary hypertension, overall RV shape continued to demonstrate the free wall bulging characteristic of TR. In the subgroup of patients with congestive heart failure without TR, this intermediate state of RV muscular hypertrophy was not present. Conclusion: The multiple causes of TR examined in this study changed RV shape in similar ways. Logistic regression classification based on these shape changes reliably identified patients with TR regardless of etiology. Furthermore, pulmonary hypertension without TR had unique shape features, described here as the "well compensated" RV. These results suggest shape modeling as a promising tool for defining severity of RV disease and risk of decompensation, particularly in patients with pulmonary hypertension. Myriad disorders cause right ventricular (RV) dilation and lead to tricuspid regurgitation (TR). Because the thin-walled, flexible RV is mechanically coupled to the pulmonary circulation and the left ventricular septum, it distorts with any disturbance in the cardiopulmonary system. TR, therefore, can result from pulmonary hypertension, left heart failure, or intrinsic RV dysfunction; but once it occurs, TR initiates a cycle of worsening RV volume overload, potentially progressing to right heart failure. Characteristic three-dimensional RV shape-changes from this process, and changes particular to individual TR causes, have not been defined in detail. Cardiac MRI was obtained in 6 healthy volunteers, 41 patients with ≥ moderate TR, and 31 control patients with cardiac disease without TR. The mean shape of each group was constructed using a three-dimensional statistical shape model via the particle-based shape modeling approach. Changes in shape were examined across pulmonary hypertension and congestive heart failure subgroups using principal component analysis (PCA). A logistic regression approach based on these PCA modes identified patients with TR using RV shape alone. Mean RV shape in patients with TR exhibited free wall bulging, narrowing of the base, and blunting of the RV apex compared to controls ( 0.05). Using four primary PCA modes, a logistic regression algorithm identified patients with TR correctly with 82% recall and 87% precision. In patients with pulmonary hypertension without TR, RV shape was narrower and more streamlined than in healthy volunteers. However, in RVs with TR and pulmonary hypertension, overall RV shape continued to demonstrate the free wall bulging characteristic of TR. In the subgroup of patients with congestive heart failure without TR, this intermediate state of RV muscular hypertrophy was not present. The multiple causes of TR examined in this study changed RV shape in similar ways. Logistic regression classification based on these shape changes reliably identified patients with TR regardless of etiology. Furthermore, pulmonary hypertension without TR had unique shape features, described here as the "well compensated" RV. These results suggest shape modeling as a promising tool for defining severity of RV disease and risk of decompensation, particularly in patients with pulmonary hypertension.
Author	Kim, Jiwon J. Zenger, Brian Orkild, Benjamin A. Ibrahim, Majd M Morgan, Ashley E. Khashani, Atefeh G. Bergquist, Jake A. Morris, Alan K. Selzman, Craig Elhabian, Shireen Steinberg, Benjamin A. MacLeod, Rob S. Foote, Markus D. Iyer, Krithika Perez, Maura D. Ratcliffe, Mark B. Rupp, Lindsay C.
AuthorAffiliation	3 School of Computing , University of Utah , Salt Lake City , UT , United States 8 St. Luke’s Medical Center Cardiothoracic and Vascular Surgery , Boise , ID , United States 6 Division of Cardiothoracic Surgery , University of Utah , Salt Lake City , UT , United States 5 Division of Cardiovascular Medicine , University of Utah , Salt Lake City , UT , United States 1 Scientific Computing and Imaging Institute , University of Utah , Salt Lake City , UT , United States 2 Department of Biomedical Engineering , University of Utah , Salt Lake City , UT , United States 7 Department of Surgery , The San Francisco VA Medical Center , University of California, San Francisco , San Francisco , CA , United States 4 Weill-Cornell Medical College , Division of Cardiology , New York , NY , United States
AuthorAffiliation_xml	– name: 2 Department of Biomedical Engineering , University of Utah , Salt Lake City , UT , United States – name: 7 Department of Surgery , The San Francisco VA Medical Center , University of California, San Francisco , San Francisco , CA , United States – name: 6 Division of Cardiothoracic Surgery , University of Utah , Salt Lake City , UT , United States – name: 1 Scientific Computing and Imaging Institute , University of Utah , Salt Lake City , UT , United States – name: 4 Weill-Cornell Medical College , Division of Cardiology , New York , NY , United States – name: 8 St. Luke’s Medical Center Cardiothoracic and Vascular Surgery , Boise , ID , United States – name: 3 School of Computing , University of Utah , Salt Lake City , UT , United States – name: 5 Division of Cardiovascular Medicine , University of Utah , Salt Lake City , UT , United States
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Cites_doi	10.4103/2045-8932.94828 10.20517/2574-1209.2019.32 10.1016/b978-0-12-810493-4.00012-2 10.22489/cinc.2020.346 10.1016/s0002-9149(98)01064-9 10.1016/j.jcmg.2018.07.033 10.22489/cinc.2019.200 10.1111/echo.12212 10.1016/j.jacc.2012.04.032 10.1016/j.ppedcard.2016.07.010 10.1086/676020 10.1161/JAHA.118.011464 10.1016/j.jcmg.2018.06.014 10.1055/s-0037-1604450 10.1111/crj.12713 10.1164/rccm.201412-2271OC 10.1016/j.echo.2017.12.009 10.1016/j.athoracsur.2017.11.077 10.1148/radiol.2016161315 10.1016/j.amjcard.2013.07.046 10.1016/j.athoracsur.2018.01.005 10.1513/AnnalsATS.201509-599FR 10.1186/s12968-019-0551-6 10.1016/j.jtcvs.2006.08.049 10.1161/circulationaha.106.632208 10.1016/j.jtcvs.2012.01.088 10.1016/j.hlc.2006.08.003 10.1016/j.jcmg.2020.01.008
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Copyright	Copyright © 2022 Orkild, Zenger, Iyer, Rupp, Ibrahim, Khashani, Perez, Foote, Bergquist, Morris, Kim, Steinberg, Selzman, Ratcliffe, MacLeod, Elhabian and Morgan. Copyright © 2022 Orkild, Zenger, Iyer, Rupp, Ibrahim, Khashani, Perez, Foote, Bergquist, Morris, Kim, Steinberg, Selzman, Ratcliffe, MacLeod, Elhabian and Morgan. 2022 Orkild, Zenger, Iyer, Rupp, Ibrahim, Khashani, Perez, Foote, Bergquist, Morris, Kim, Steinberg, Selzman, Ratcliffe, MacLeod, Elhabian and Morgan
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Keywords	tricuspid regurgitation cardiac MRI pulmonary hypertension particle-based shape modeling statistical shape modeling congestive heart failure valvular heart disease principal component analysis
Language	English
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Notes	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23 Edited by: Yunlong Huo, Shanghai Jiao Tong University, China These authors share senior authorship These authors have contributed equally to this work Shengzhang Wang, Fudan University, China Reviewed by: Bao Li, Beijing University of Technology, China This article was submitted to Computational Physiology and Medicine, a section of the journal Frontiers in Physiology
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Snippet	Introduction: Myriad disorders cause right ventricular (RV) dilation and lead to tricuspid regurgitation (TR). Because the thin-walled, flexible RV is... Myriad disorders cause right ventricular (RV) dilation and lead to tricuspid regurgitation (TR). Because the thin-walled, flexible RV is mechanically coupled... Introduction: Myriad disorders cause right ventricular (RV) dilation and lead to tricuspid regurgitation (TR). Because the thin-walled, flexible RV is...
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SubjectTerms	cardiac MRI particle-based shape modeling Physiology principal component analysis pulmonary hypertension statistical shape modeling tricuspid regurgitation
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Title	All Roads Lead to Rome: Diverse Etiologies of Tricuspid Regurgitation Create a Predictable Constellation of Right Ventricular Shape Changes
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