scholarly journals Precise automated determination of the total and segmented right ventricular volumes for functional studies of the right ventricle using CMR

2011 ◽  
Vol 13 (S1) ◽  
Author(s):  
Dominik Gabbert ◽  
Andreas Entenmann ◽  
Michael Jerosch-Herold ◽  
Chris Hart ◽  
Inga Voges ◽  
...  
Keyword(s):  
Right Ventricle ◽  
Right Ventricular ◽  
Ventricular Volumes ◽  
Functional Studies ◽  
The Right ◽  
Automated Determination

Measurement of left and right ventricular volume from implanted radiopaque markers

1981 ◽  
Vol 240 (6) ◽  
pp. H896-H900
Author(s):  
W. P. Santamore ◽  
R. Carey ◽  
D. Goodrich ◽  
A. A. Bove
Keyword(s):  
Standard Deviation ◽  
Left Ventricle ◽  
Right Ventricle ◽  
Right Ventricular ◽  
Ventricular Volume ◽  
Left Ventricular ◽  
Ventricular Volumes ◽  
Radiopaque Markers ◽  
Left And Right ◽  
The Right

To better understand biventricular mechanics, an algorithm was developed to simultaneously calculate right and left ventricular volumes from randomly placed subendocardial radiopaque markers. Mathematically, the ventricle is represented as a stack of circular discs. The radius R of each disc is calculated as the distance from the subendocardial radiopaque marker to a computer generated base-to-apex line, and the height H of each disc is determined by the projected distance between radiopaque markers along the base-to-apex line. Accordingly, the volume (V) is calculated as V = pi . sigma Hi . Ri2. The validity of this algorithm was tested on 10 canine left ventricular casts, on 10 human right ventricular casts, and in five experiments. For the left ventricle, the regression line between the casts (VT) and calculated (VC) volumes was VC = 0.55 VT + 6.6, with r = 0.95, standard error of estimate (Sy) = 1.9 ml, and the standard deviation of percent error = 12.6%. For the right ventricle, VC = 1.75 VT = 42.5, with r = 0.86, Sy = 16.2 ml, and the standard deviation of percent error = 24.8%. In five animal experiments, radiopaque markers were implanted into the endocardium of the left and right ventricles and comparisons were made between angiographic- and marker-determined ventricular volumes. For the five experiments, the mean correlation coefficient, relating the marker volumes to the angiographic volumes, were 0.92 +/- 0.01 for the left ventricle and 0.89 +/- 0.02 for the right ventricle. The results, which are similar to other volume-determination methods, indicate that this method can be applied to determine right and left ventricular volume. Once implanted, fluoroscopy of these markers provides a noninvasive means of calculating ventricular volume.

Pulmonary Vascular Versus Right Ventricular Function Changes During Targeted Therapies of Pulmonary Hypertension – An Argument for Upfront Combination Therapy?

2012 ◽  
Vol 8 (3) ◽  
pp. 209
Author(s):  
Wouter Jacobs ◽  
Anton Vonk-Noordegraaf ◽  
◽  
Keyword(s):  
Combination Therapy ◽  
Right Ventricle ◽  
Right Ventricular ◽  
Pulmonary Vascular Resistance ◽  
Vascular Resistance ◽  
Meta Analysis ◽  
Right Heart Failure ◽  
Functional Class ◽  
Pulmonary Vasculature ◽  
The Right

Pulmonary arterial hypertension is a progressive disease of the pulmonary vasculature, ultimately leading to right heart failure and death. Current treatment is aimed at targeting three different pathways: the prostacyclin, endothelin and nitric oxide pathways. These therapies improve functional class, increase exercise capacity and improve haemodynamics. In addition, data from a meta-analysis provide compelling evidence of improved survival. Despite these treatments, the outcome is still grim and the cause of death is inevitable – right ventricular failure. One explanation for this paradox of haemodynamic benefit and still worse outcome is that the right ventricle does not benefit from a modest reduction in pulmonary vascular resistance. This article describes the physiological concepts that might underlie this paradox. Based on these concepts, we argue that not only a significant reduction in pulmonary vascular resistance, but also a significant reduction in pulmonary artery pressure is required to save the right ventricle. Haemodynamic data from clinical trials hold the promise that these haemodynamic requirements might be met if upfront combination therapy is used.

CMR markers for early right ventricular dysfunction in precapillary pulmonary hypertension

2020 ◽  
Vol 41 (Supplement_2) ◽  
Author(s):  
J Vos ◽  
T Leiner ◽  
A.P.J Van Dijk ◽  
F.J Meijboom ◽  
G.T Sieswerda ◽  
...  
Keyword(s):  
Pulmonary Hypertension ◽  
Right Ventricle ◽  
Right Ventricular ◽  
Circumferential Strain ◽  
Peak Strain ◽  
Healthy Controls ◽  
Free Wall ◽  
Global Circumferential Strain ◽  
The Right ◽  
Rv Function

Abstract Introduction Precapillary pulmonary hypertension (pPH) causes right ventricular (RV) pressure overload inducing RV remodeling, often resulting in dysfunction and dilatation, heart failure, and ultimately death. The ability of the right ventricle to adequately adapt to increased pressure loading is key for patients' prognosis. RV ejection fraction (RVEF) by cardiac magnetic resonance (CMR) is related to outcome in pPH patients, but this global measurement is not ideal for detecting early changes in RV function. Strain analysis on CMR using feature tracking (FT) software provides a more detailed assessment, and might therefore detect early changes in RV function. Aim 1) To compare RV strain parameters in pPH patients and healthy controls, and 2) to compare strain parameters in a subgroup of pPH patients with preserved RVEF (pRVEF) and healthy controls. Methods In this prospective study, a CMR was performed in pPH patients and healthy controls. Using FT-software on standard cine images, the following RV strain parameters were analyzed: global, septal, and free wall longitudinal strain (GLS, sept-LS, free wall-LS), time to peak strain (TTP, as a % of the whole cardiac cycle), the fractional area change (FAC), global circumferential strain (GCS), global longitudinal and global circumferential strain rate (GLSR and GCSR, respectively). A pRVEF is defined as a RVEF >50%. To compare RV strain parameters in pPH patients to healthy controls, the Mann-Whitney U test was used. Results 33 pPH-patients (55 [45–63] yrs; 10 (30%) male) and 22 healthy controls (40 [36–48] yrs; 15 (68%) male) were included. All RV strain parameters were significantly reduced in pPH patients compared to healthy controls (see table), except for GCS and GCSR. Most importantly, in pPH patients with pRVEF (n=8) GLS (−26.6% [−22.6 to −27.3] vs. −28.1% [−26.2 to −30.6], p=0.04), sept-LS (−21.2% [−19.8 to −23.2] vs. −26.0% [−24.0 to −27.9], p=0.005), and FAC (39% [35–44] vs. 44% [42–47], p=0.02) were still significantly impaired compared to healthy controls. The RV TTP was significantly increased in pPH patients compared to healthy controls (47% [44–57] vs. 40% [33–43], p≤0.001). Conclusions Several CMR-FT strain parameters of the right ventricle are impaired in pPH patients when compared to healthy controls. Moreover, even in pPH patients with a preserved RVEF multiple RV strain parameters (GLS, sept-LS, and FAC) remained significantly impaired, and TTP significantly prolonged, in comparison to healthy controls. This suggests that RV strain parameters may be used as an early marker of RV dysfunction in pPH patients. Funding Acknowledgement Type of funding source: None

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