Analysis of 3D cardiac deformations with 3D SinMod

Author

Hui Wang ; Stoeck, Christian T. ; Kozerke, Sebastian ; Amini, Arash Ali

Author_Institution

MR Clinical Sci., Philips Healthcare, Cleveland, OH, USA

fYear

2013

fDate

3-7 July 2013

Firstpage

4386

Lastpage

4389

Abstract

In this paper, we propose a novel 3D sine wave modeling (3D SinMod) approach to automatic analysis of 3D cardiac deformations. An accelerated 3D complementary spatial modulation of magnetization (CSPAMM) tagging technique was used to modulate the myocardial tissue and to acquire 3D MR data sets of the whole-heart including three orthog- onal tags within three breath-holds. Each tag set is able to assess the motion along a direction perpendicular to the tag lines. With the application of CSPAMM, the effect of tag fading encountered in SPAMM tagging due to T₁ relaxation is mitigated and tag deformations can be visualized for the entire cardiac cycle, including diastolic phases. In the proposed approach, the environment around each voxel in the 3D volume is modeled as a moving sine wavefront with local frequency and amplitude. The biggest advantage of the proposed technique is that the entire framework, from data acquisition to data analysis is in the 3D domain, which permits quantification of both the in-plane and through-plane motion components. The accuracy and the effectiveness of the proposed method has been validated using both simulated and in vivo tag data.

Keywords

biological tissues; biomechanics; biomedical MRI; cardiology; data acquisition; data analysis; deformation; image motion analysis; magnetisation; medical image processing; physiological models; pneumodynamics; spin-lattice relaxation; 3D SinMod; 3D domain; 3D sine wave modeling approach; 3D volume; CSPAMM application; CSPAMM tagging technique; T₁ relaxation; accelerated 3D complementary spatial modulation of magnetization; accuracy validation; automatic 3D cardiac deformation analysis; breathhold orthogonal tag; cardiac cycle; data acquisition; data analysis; diastolic phase; effectiveness validation; in vivo tag data; in-plane motion component quantification; local amplitude; local frequency; motion assessment; moving sine wavefront; myocardial tissue modulation; simulated tag data; tag deformation visualization; tag fading effect; through-plane motion component quantification; voxel environment modeling; whole-heart 3D MR data set acquisition; Biomedical imaging; Heart; Magnetic resonance imaging; Myocardium; Tagging; Three-dimensional displays; Tracking; 3D CSPAMM; 3D SinMod; Cardiac Deformations; MRI Tagging;

fLanguage

English

Publisher

ieee

Conference_Titel

Engineering in Medicine and Biology Society (EMBC), 2013 35th Annual International Conference of the IEEE

Conference_Location

Osaka

ISSN

1557-170X

Type

conf

DOI

10.1109/EMBC.2013.6610518

Filename

6610518