Functional measurements based on feature tracking of cine magnetic resonance images identify left ventricular segments with myocardial scar

Maret, Eva; Tödt, Tim; Brudin, Lars; Nylander, Eva; Swahn, Eva; Ohlsson, Jan; Engvall, Jan

doi:10.1186/1476-7120-7-53

Cited by 121 publications

(95 citation statements)

References 31 publications

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“…The technique can be applied for the quantification of right and left ventricular (LV) systolic and diastolic function using strain 10,18 and SR 19 imaging as well as myocardial torsion and diastolic recoil quantification. 20,21 The study of atrial physiology using strain and SR imaging has recently been explored.…”

Section: Quantitative Assesment Of Cardiovascular Physiologymentioning

confidence: 99%

“…The majority of CMR-FT studies have used the Diogenes and Cardiac Performance Analysis-MR software provided by TomTec Imaging systems (TomTec, Unterschleissheim, Germany). 10 Other vendors including Toshiba 11 (Tokyo, Japan) and more recently Circle 12 (Calgary, Canada) have released alternative FT software platforms. The purpose of this article is to summarize the basic principles, evolving clinical applications, accuracy and reproducibility data of CMR-FT.…”

mentioning

confidence: 99%

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Cardiovascular Magnetic Resonance Myocardial Feature Tracking

Schuster

Hor

Kowallick

et al. 2016

Circ: Cardiovascular Imaging

313

206

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Abstract-Heart failure-induced cardiovascular morbidity and mortality constitute a major health problem worldwide and result from diverse pathogeneses, including coronary artery disease, nonischemic cardiomyopathies, and arrhythmias. Assessment of cardiovascular performance is important for early diagnosis and accurate management of patients at risk of heart failure. During the past decade, cardiovascular magnetic resonance myocardial feature tracking has emerged as a useful tool for the quantitative evaluation of cardiovascular function. The method allows quantification of biatrial and biventricular mechanics from measures of deformation: strain, torsion, and dyssynchrony. The purpose of this article is to review the basic principles, clinical applications, accuracy, and reproducibility of cardiovascular magnetic resonance myocardial feature tracking, highlighting the prognostic implications. It will also provide an outlook on how this field might evolve in the future. (Circ Cardiovasc Imaging. 2016;9:e004077.

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Section: Quantitative Assesment Of Cardiovascular Physiologymentioning

confidence: 99%

mentioning

confidence: 99%

Cardiovascular Magnetic Resonance Myocardial Feature Tracking

Schuster

Hor

Kowallick

et al. 2016

Circ: Cardiovascular Imaging

313

206

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“…-16 -shown that measurements of velocity, displacement and peak systolic strain in the radial direction by MRI were able to differentiate segments with varying extent of scar (14). The most accurate information was obtained by measurements of radial strain in that study.…”

Section: Discussionmentioning

confidence: 64%

Phase analysis detects heterogeneity of myocardial deformation on cine MRI

Maret

Liehl

Brudin

et al. 2015

Scandinavian Cardiovascular Journal

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This is the pre peer-reviewed version of the following article, "Phase analysis detects heterogeneity of myocardial deformation on cine MRI", which in its final form has been published at Scand Cardiovasc J. This is the pre peer-reviewed version of the following article, "Phase analysis detects heterogeneity of myocardial deformation on cine MRI", which in its final form has been published at Scand Cardiovasc J. This is the pre peer-reviewed version of the following article, "Phase analysis detects heterogeneity of myocardial deformation on cine MRI", which in its final form has been published at Scand Cardiovasc J. 2015 Mar 10:1-24. [Epub ahead of print] PMID: 25752486.-3 - Abstract ObjectivesMyocardial scar will lead to heterogeneous left ventricular deformation. We hypothesized that a myocardial scar will display an elevated standard deviation of phase and that this effect could be compared with mechanical dispersion. DesignThirty patients (3 women and 27 men) were investigated 4-8 weeks after STelevation myocardial infarction treated with percutaneous coronary intervention.Seventeen had a scar area >75% in at least one antero-or inferoseptal segment (scar) and 13 had scar <1% (non-scar). The phase delays of velocity, displacement and strain were measured in the longitudinal direction, tangential to the endocardial outline, and in the radial direction, perpendicular to the tangent. ResultsThe standard deviation of phase in radial measurements differentiated scar patients from those without scar (p<0.01), while longitudinal measurements did so only for longitudinal strain. Likewise, the standard deviation for radial measurements of time to peak for segmental velocity, displacement and strain performed better than longitudinal measurements and equal to the results of phase. ConclusionPhase dispersion in deformation imaging may be used for detecting heterogeneous left ventricular contraction.This is the pre peer-reviewed version of the following article, "Phase analysis detects heterogeneity of myocardial deformation on cine MRI", which in its final form has been published at Scand Cardiovasc J.

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“…Most of these methods depend on texture features to track predefined points on the inner and outer LV wall. For example, Maret et al [94] used a feature tracking method to estimate the strain and other indexes from cine CMRI and showed that it can be used for the detection of the transmural scar. Hor et al [95] correlated between the estimated strains from tagged MRI (using HARP method) and from cine CMRI (using tracking) in a population with a wide range of cardiac dysfunction.…”

Section: Functional Strainmentioning

confidence: 99%

“…To avoid the inter-slice variability, recent trends estimate the strain from cine CMRI (e.g., [94][95][96][97]). Most of these methods depend on texture features to track predefined points on the inner and outer LV wall.…”

Section: Functional Strainmentioning

confidence: 99%

Developing advanced mathematical models for detecting abnormalities in 2D/3D medical structures.

Elnakib¹

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DEDICATIONThis dissertation is dedicated to my mother, my father, and my wife for their love, patience, and support during the completion of this endeavor.iii ACKNOWLEDGMENTSIn the Name of Allah, the most beneficent, the most merciful. All deepest thanks are due to Allah, the compassionate for the uncountable gifts given to me.I would like to express my sincere gratitude to Professor El-Baz, my dissertation advisor, for the immeasurable amount of support and guidance he has provided throughout this study. He gave me the opportunity to work in his distinguished research group and provided me with an exciting working environment that facilitate many opportunities to develop new ideas and working on promising applications. Dr. El-Baz is always willing to give, share, and appreciate. I knew that I could always expect full credit for my accomplishments. He always supported me with novel ideas that helped me to publish my works in the top international conference and journal papers. It is worthy to mention that Professor El-Baz is a great advisor as well as a good friend who helps any Ph.D. student who works with him in high energy level. I cannot thank him enough, and shall remain grateful for all he has done. Detecting abnormalities in two-dimensional (2D) and three-dimensional (3D) medical structures is among the most interesting and challenging research areas in the medical imaging field. Obtaining the desired accurate automated quantification of abnormalities in medical structures is still very challenging. This is due to a large and constantly growing number of different objects of interest and associated abnormalities, large variations of their appearances and shapes in images, different medical imaging modalities, and associated changes of signal homogeneity and noise for each object. The main objective of this dissertation is to address these problems and to provide proper mathematical models and techniques that are capable of analyzing low and high resolution medical data and providing an accurate, automated analysis of the abnormalities in medical structures in terms of their area/volume, shape, and associated abnormal functionality.This dissertation presents different preliminary mathematical models and techniques that are applied in three case studies: (i) detecting abnormal tissue in vi the left ventricle (LV) wall of the heart from delayed contrast-enhanced cardiac magnetic resonance images (MRI), (ii) detecting local cardiac diseases based on estimating the functional strain metric from cardiac cine MRI, and (iii) identifying the abnormalities in the corpus callosum (CC) brain structure-the largest fiber bundle that connects the two hemispheres in the brain-for subjects that suffer from developmental brain disorders. For detecting the abnormal tissue in the heart, a graph-cut mathematical optimization model with a cost function that accounts for the object's visual appearance and shape is used to segment the the inner cavity. The model is further integrated with a geometric model (i.e., a fast marching...

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Functional measurements based on feature tracking of cine magnetic resonance images identify left ventricular segments with myocardial scar

Cited by 121 publications

References 31 publications

Cardiovascular Magnetic Resonance Myocardial Feature Tracking

Cardiovascular Magnetic Resonance Myocardial Feature Tracking

Phase analysis detects heterogeneity of myocardial deformation on cine MRI

Developing advanced mathematical models for detecting abnormalities in 2D/3D medical structures.

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