Normal Right Ventricular Three‐Dimensional Architecture, as Assessed with Diffusion Tensor Magnetic Resonance Imaging, is Preserved During Experimentally Induced Right Ventricular Hypertrophy

Nielsen, Eva Amalie; Smerup, Morten; Agger, Peter; Frandsen, Jesper; Ringgard, S.; Pedersen, Michael; Vestergaard, Peter; Nyengaard, Jens Randel; Andersen, Jannike Mørch; Lunkenheimer, P. P.; Anderson, Robert H.; Hjortdal, Vibeke E.

doi:10.1002/ar.20873

Cited by 44 publications

(51 citation statements)

References 27 publications

(42 reference statements)

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“…60,94 As for the LV, the aggregated RV myocytes form helical angles and intrude in the oblique orientation from the epicardial to endocardial layers. 21,60 In response to afterload, the hypertrophied RV maintains this basic structure and does not form an extensive layer of circular myocytes, which may explain the previously discussed shift from a longitudinal to circumferential strain pattern. 21 Although shared myofibers likely play a role in mediating adverse ventricular-ventricular interactions, they may also constitute a target for therapeutic intervention.…”

Section: March 4 2014mentioning

confidence: 94%

“…21,60 In response to afterload, the hypertrophied RV maintains this basic structure and does not form an extensive layer of circular myocytes, which may explain the previously discussed shift from a longitudinal to circumferential strain pattern. 21 Although shared myofibers likely play a role in mediating adverse ventricular-ventricular interactions, they may also constitute a target for therapeutic intervention. We have developed a rabbit model of sustained increased RV afterload using adjustable pulmonary artery banding.…”

Section: March 4 2014mentioning

confidence: 94%

“…20 This observation is somewhat surprising in that diffusion tensor magnetic resonance imaging shows that fiber orientation in RV hypertrophy is not fundamentally different from normal. 21 Likewise, the functionally single systemic RV in hypoplastic left heart syndrome may adapt a more circumferential versus longitudinal contraction pattern after stage 1 of surgical palliation (a particularly vulnerable period for these patients). 22 Yet, the RV in hypoplastic left heart syndrome continuously faces systemic resistance from fetal through postnatal life, and it is difficult to attribute changes in RV contraction patterns to increased afterload alone.…”

Section: Rv Versus LV Failure 1035mentioning

confidence: 99%

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Right Versus Left Ventricular Failure

2014

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1033V entricular failure manifests in many forms, its underlying physiology ranging from overt left ventricular (LV) systolic dysfunction to isolated right ventricular (RV) diastolic dysfunction, and the wide portfolio of resulting symptoms vary from chronic fluid retention to acute multiorgan dysfunction and death. In this review, we discuss the morphological, functional, and molecular similarities and differences in RV and LV responses to adverse loading and failure. We further discuss whether LV and RV function and failure can truly be discussed as separate entities and thereby examine interactions between the ventricles that on one hand contribute to ventricular dysfunction but on the other may be harnessed for therapeutic benefit. Embryological and Physiological Differences Between the RV and LVThe RV and LV have different embryological origins.1 The LV originates from the primary heart field; the RV, from the secondary heart field. Consequently, several genes specifically control RV formation, including, among others, Hand2 and Tbx20.2 During gestation, the RV functions as the systemic ventricle ( Figure 1A). During fetal life, in addition to supplying the modest amount of pulmonary blood flow, the RV pumps blood to the lower body and placenta and contributes more than half of the combined cardiac output.3 With the transition from fetal to postnatal physiology and with the reduction in pulmonary vascular resistance, the subpulmonary RV transforms its morphology and geometry, becoming a thin-walled chamber to adopt its postnatal physiological characteristics. 4 Because it faces a low impedance pulmonary circulation, the normal postnatal RV maintains a cardiac output equal to that of the LV at approximately a fifth of the energy cost. The trapezoidal RV pressure-volume loop reflects this difference, with few if any isovolumic periods. Consequently, RV output starts early during pressure generation and is later maintained by a "hangout period" when antegrade flow continues into the pulmonary artery despite the onset of RV relaxation.5 In contrast, the rectangular LV pressure-volume loops reflect the LV square-wave pump function with distinct and well-developed isovolumic contraction and relaxation periods.6 Likewise, RV myocytes display faster twitch velocities than LV myocytes. 7The physiological differences are reflected in morphological differences between the ventricles (Table 1). The low-pressure RV is triangular in the sagittal plane and crescent-shaped in cross section as a result of the concave RV free wall and convex interventricular septum wrapping around the high-pressured, thick-walled, bullet-shaped LV. Consequently, although the normal RV has a lower ratio of volume to surface area and a thinner wall than the LV, 8 the low cavity pressure determines a lower wall stress and lower oxygen demands.Anatomic differences are also apparent in myocardial architecture. LV subepicardial and subendocardial fibers are oblique and helical with fiber angles ranging from 30° to 80° with a mean of ≈60°, whereas ...

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Section: March 4 2014mentioning

confidence: 94%

Section: March 4 2014mentioning

confidence: 94%

Section: Rv Versus LV Failure 1035mentioning

confidence: 99%

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Right Versus Left Ventricular Failure

2014

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“…25 The mechanisms for systemic RV dysfunction are incompletely understood but may include suboptimal myofiber arrangement, 26 myocardial ischemia from supplydemand mismatch, and a less robust conduction system. CMR can quantify the amount of systemic RV hypertrophy and the systemic ventricular size and function ( Figure 6).…”

Section: B Systemic Right Ventricular Size and Functionmentioning

confidence: 99%

Cardiac Magnetic Resonance in Adults with Congenital Heart Disease

Partington

Valente

2013

Methodist DeBakey Cardiovascular Journal

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Increasing numbers of adults with congenital heart disease are referred for cardiac magnetic resonance imaging. Knowledge of the congenital heart anatomy, prior surgical interventions, and the development of an imaging focus for each individual patient plays a crucial role when performing a successful cardiac magnetic resonance imaging examination. The following manuscript focuses on cardiac magnetic resonance imaging considerations of three specific conotruncal congenital heart lesions: tetralogy of Fallot, transposition of the great arteries (TGA), and physiologically corrected TGA (c-TGA).

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“…The middle layer is the thickest. The myocardial fiber architecture in the RV is comparable to that in the LV except for the middle circumferential layer (12).…”

Section: Myocardial Fiber Orientationmentioning

confidence: 90%

Assessment of Ventricular Function in Normal and Failing Hearts Using 4D Flow CMR

Zajac¹

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Front cover: Multicolor drawing of the heart and the outflow by Dr. Staffan Wirell, handed to me the day I became a PhD student. Permission to print. ABSTRACTHeart failure is a common disorder and a major cause of illness and death in the population, creating an enormous health-care burden. It is a complex condition, representing the end-point of many cardiovascular diseases. In general heart failure progresses slowly over time and once it is diagnosed it has a poor prognosis which is comparable with that of many types of cancer.The heart has an ability to adapt in response to long lasting increases in hemodynamic demand; the heart conforms its shape and size in order to maintain adequate cardiac output. This process is called remodeling and can be triggered by pathologies such as hypertension or valvular disease. When the myocardial remodeling is maintained chronically it becomes maladaptive and is associated with an increased risk of heart failure.In many cases, heart failure is associated with left bundle branch block (LBBB). This electrical disturbance leads to dyssynchronous left ventricular (LV) contraction and relaxation which may contribute to cardiac dysfunction and ultimately heart failure. Mechanical dyssynchrony can be treated with cardiac resynchronization therapy (CRT). However, many heart failure patients do not demonstrate clinical improvement despite CRT.Blood flow plays an important role in the normal development of the fetal heart. However, flow-induced forces may also induce changes in the heart cells that could lead to pathological remodeling in the adult heart. Until recently, measurement tools have been inadequate in describing the complex three-dimensional and time-varying characteristics of blood flow within the beating heart. 4D (3D + time) flow cardiovascular magnetic resonance (CMR) enables acquisition of three-dimensional, three-directional, time-resolved velocity data from which visualization and quantification of the blood flow patterns over a complete cardiac cycle can be performed. In this thesis, novel 4D Flow CMR based methods are used to study the intraventricular blood flow in healthy subjects and heart failure patients with and without ventricular dyssynchrony in order to gain new knowledge of the ventricular function.Different flow components were assessed in normal heart ventricles. It was found that inflowing blood that passes directly to outflow during the same heartbeat (the Direct Flow component) was larger and possessed more kinetic energy (KE) than other flow components. Diastolic flow through the normal heart appears to create favorable conditions for effective systolic ejection. This organized blood flow pattern within the normal LV is altered in heart failure patients and is associated with decreased preservation of KE which might be unfavorable for efficient LV ejection. Inefficient flow of blood through the heart may influence diastolic wall stress, and thus contribute to pathological myocardial remodeling.In dyssynchronous LVs of heart failure patients with LBB...

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Normal Right Ventricular Three‐Dimensional Architecture, as Assessed with Diffusion Tensor Magnetic Resonance Imaging, is Preserved During Experimentally Induced Right Ventricular Hypertrophy

Cited by 44 publications

References 27 publications

Right Versus Left Ventricular Failure

Right Versus Left Ventricular Failure

Cardiac Magnetic Resonance in Adults with Congenital Heart Disease

Assessment of Ventricular Function in Normal and Failing Hearts Using 4D Flow CMR

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