Characterization of the normal cardiac myofiber field  in goat measured with MR-diffusion tensor imaging

Geerts, Liesbeth; Bovendeerd, P.H.M.; Nicolay, Klaas; Arts, Theo

doi:10.1152/ajpheart.00968.2001

Cited by 177 publications

(197 citation statements)

References 26 publications

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“…Our mean value for the three combined hearts of FA = 0.25 ± 0.09 is similar to measurements from other studies, with values of 0.36 in canine [29], 0.35 in goat [23], 0.27 in mouse [41], and 0.36, 0.32 and 0.3 in diastolic, early and late systolic rat respectively [11] having been reported. Thus, fibre direction in the three hearts was well determined.…”

Section: Ventricular Geometrysupporting

confidence: 91%

“…Thus, data from different hearts were aligned at the midwall where h = 0, and the centroid for each slice is at h = −1. This normalisation method removes errors associated with identifying the locations of the endocardial and epicardial surfaces and has been validated by Geerts et al [23], who showed that the standard deviation of the inclination angle data was much reduced when compared to the usual endocardial-to-epicardial normalisation method.…”

Section: Normalised Transmural Positionmentioning

confidence: 99%

“…A normalised transmural position was assigned to each voxel in each sector using the method described by Geerts et al [23]. The location of the midwall was first defined as the position where a fit to the transmural course of the inclination angles (see definition below) changed sign.…”

Section: Normalised Transmural Positionmentioning

confidence: 99%

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Reconstruction and Quantification of Diffusion Tensor Imaging-Derived Cardiac Fibre and Sheet Structure in Ventricular Regions used in Studies of Excitation Propagation

Benson

Gilbert

et al. 2008

Math. Model. Nat. Phenom.

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Abstract. Detailed descriptions of cardiac geometry and architecture are necessary for examining and understanding structural changes to the myocardium that are the result of pathologies, for interpreting the results of experimental studies of propagation, and for use as a three-dimensional orthotropically anisotropic model for the computational reconstruction of propagation during arrhythmias. Diffusion tensor imaging (DTI) provides a means to reconstruct fibre and sheet orientation throughout the ventricles. We reconstruct and quantify canine cardiac architecture in selected regions of the left and right ventricular free walls and the inter-ventricular septum. Fibre inclination angle rotates smoothly through the wall in all regions, from positive in the endocardium to negative in the epicardium. However, fibre transverse and sheet angles show large variability in basal regions. Additionally, regions where two populations (positive and negative) of sheet structure merge are identified. From these data, we conclude that a single DTI-derived atlas model of ventricular architecture should be applicable to modelling propagation in wedges from the equatorial and apical left ventricle, and allow comparisons to experimental studies carried out in wedge preparations. However, due to inter-individual variability in basal regions, a library of individual DTI models of basal wedges or of the whole ventricles will be required.

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Section: Ventricular Geometrysupporting

confidence: 91%

Section: Normalised Transmural Positionmentioning

confidence: 99%

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Reconstruction and Quantification of Diffusion Tensor Imaging-Derived Cardiac Fibre and Sheet Structure in Ventricular Regions used in Studies of Excitation Propagation

Benson

Gilbert

et al. 2008

Math. Model. Nat. Phenom.

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“…The fibrous nature of the heart has been known for centuries, tracing back to as early as 1694 [28], but has been limited to tedious histological studies [20]. The cardiac fiber structure can now be imaged with diffusion tensor magnetic resonance imaging (DT-MRI) [2,15], however the variability of the fiber structure in humans is still not well known (due to the very limited number and the value of post-mortem healthy human hearts) and is largely speculated from studies on other species (dogs [12,13,11,26,22,21,9], goats [8], and rats [3]). Recently, Lombaert et al [17,18] constructed a statistical atlas of the human cardiac fiber architecture and assessed its variability.…”

Section: Introductionmentioning

confidence: 99%

Variability of the Human Cardiac Laminar Structure

Lombaert

Peyrat

Fanton

et al. 2012

Statistical Atlases and Computational Models of the Heart. Imaging and Modelling Challenges

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Abstract. The cardiac fiber architecture has an important role in electrophysiology, in mechanical functions of the heart, and in remodeling processes. The variability of the fibers is the focus of various studies in different species. However, the variability of the laminar sheets is still not well known especially in humans. In this paper, we present preliminary results on a quantitative study on the variability of the human cardiac laminar structure. We show that the laminar structure has a complex variability and we show the possible presence of two populations of laminar sheets. Bimodal distributions of the intersection angle of the third eigenvector of the diffusion tensor have been observed in 10 ex vivo healthy human hearts. Additional hearts will complete the study and further characterize the different populations of cardiac laminar sheets.

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“…The primary eigenvector, therefore can be used for mapping the 3D orientation of the myocardial fibres throughout the heart muscle [4]. Myocardial fibre orientation is an important determinant of myocardial wall stress [5] and exhibits a large regional and transmural variation.…”

Section: Introductionmentioning

confidence: 99%

Passive Ventricular Mechanics Modelling Using MRI of Structure and Function

Wang

Lam

Ennis

et al. 2008

Medical Image Computing and Computer-Assisted Intervention – MICCAI 2008

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Patients suffering from dilated cardiomyopathy or myocardial infarction can develop left ventricular (LV) diastolic impairment. The LV remodels its structure and function to adapt to pathophysiological changes in geometry and loading conditions and this remodeling process can alter the passive ventricular mechanics. In order to better understand passive ventricular mechanics, a LV finite element model was developed to incorporate physiological and mechanical information derived from in vivo magnetic resonance imaging (MRI) tissue tagging, in vivo LV cavity pressure recording and ex vivo diffusion tensor MRI (DTMRI) of a canine heart. MRI tissue tagging enables quantitative evaluation of cardiac mechanical function with high spatial and temporal resolution, whilst the direction of maximum water diffusion (the primary eigenvector) in each voxel of a DTMRI directly correlates with the myocardial fibre orientation. This model was customized to the geometry of the canine LV during diastasis by fitting the segmented epicardial and endocardial surface data from tagged MRI using nonlinear finite element fitting techniques. Myofibre orientations, extracted from DTMRI of the same heart, were incorporated into this geometric model using a free form deformation methodology. Pressure recordings, temporally synchronized to the tissue tagging MRI data, were used to simulate the LV deformation during diastole. Simulation of the diastolic LV mechanics allowed us to estimate the stiffness of the passive LV myocardium based on kinematic data obtained from tagged MRI. This integrated physiological model will allow more insight into the regional passive diastolic mechanics of the LV on an individualized basis, thereby improving our understanding of the underlying structural basis of mechanical dysfunction in pathological conditions.

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Characterization of the normal cardiac myofiber field in goat measured with MR-diffusion tensor imaging

Cited by 177 publications

References 26 publications

Reconstruction and Quantification of Diffusion Tensor Imaging-Derived Cardiac Fibre and Sheet Structure in Ventricular Regions used in Studies of Excitation Propagation

Reconstruction and Quantification of Diffusion Tensor Imaging-Derived Cardiac Fibre and Sheet Structure in Ventricular Regions used in Studies of Excitation Propagation

Variability of the Human Cardiac Laminar Structure

Passive Ventricular Mechanics Modelling Using MRI of Structure and Function

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