PurposeRespiratory motion causes mismatches between PET images of the myocardium and the corresponding cardiac MR images in cardiac integrated PET/MR. The mismatch may affect the attenuation correction and the diagnosis of non-ischemic cardiomyopathies. In this study, we present a two-stage cardiac PET and MR Late Gadolinium Enhancement (LGE) co-registration method, which seeks to improve diagnostic accuracy of non-ischemic cardiomyopathies via better image co-registration using an integrated wholebody PET/MR system. MethodsThe proposed PET and LGE two-stage co-registration method was evaluated through comparison with one-stage direct co-registration and no-registration. One hundred and ninety-one slices of LGE and forty lesions were studied. Two trained nuclear medicine physicians independently assessed the displacement between LGE and PET to qualitatively evaluate the co-registration quality. The changes of the mean SUV in the normal myocardium and the LGE-enhanced lesions before and after image co-registration were measured to quantitatively evaluate the accuracy and value of image co-registration. ResultsThe two-stage method had an improved image registration score (4.93±0.89) compared with the noregistration method (3.49±0.84, p value <0.001) and the single-stage method (4.23±0.81, p value <0.001).Furthermore, the two-stage method led to increased SUV value in the myocardium (3.87±2.56) compared with the no-registration method (3.14±1.92, p value <0.001) and the single-stage method (3.32±2.16, p value <0.001). The mean SUV in the LGE lesion signi cantly increased from 2.51±2.09 to 2.85±2.35 (p value<0.001) after the two-stage co-registration. ConclusionThe proposed two-stage registration method signi cantly improved the co-registration between PET andLGE in integrated PET/MR imaging. The technique may improve diagnostic accuracy of non-ischemic cardiomyopathies via better image co-registration.Registered No.
Background: Aortic valve disease is a common complication of left ventricular assist device (LVAD) support. Optimizing the outflow graft anastomotic type of LVADs might be an alternative that can reduce this complication. However, the effect of this type of LVAD on the biomechanical states of the aortic valve remains unclear.Methods: In this study, a finite element-smoothed particle hydrodynamics-coupled model was established. Two kinds of anastomotic types (concentric and eccentric graft cases) were designed.Results: The anastomotic type could significantly affect the biomechanical states of the aortic valve. During the opening phase, the motion, deformation, and biomechanical states of the leaflet in both cases were similar to each other. The axial hemodynamic force (AHF) imposed on the leaflet in the eccentric graft case (0.9 N) was slightly larger than that in the concentric graft case (0.3 N). During the closing phase, the rapid closing time of the leaflet in the eccentric graft case (40 ms) was longer than that in the concentric graft case (15 ms). In addition, the peak value of the AHF in the concentric graft case was much larger (13 N) than that in the eccentric graft case (4.5 N). The oscillation of the AHF was observed only in the concentric graft case.Conclusions: The eccentric graft could lead to better biomechanical and hemodynamic states of the aortic valve than the concentric graft.
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