Evaluation of Fetal Left Ventricular Size and Function Using Speckle‐Tracking and the Simpson Rule (original) (raw)
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Journal of Ultrasound in Medicine, 2018
Introduction-This study was conducted to evaluate the 24-segment transverse widths of the right and left ventricles distributed from the base to the apex of the ventricular chambers and compute the right ventricular (RV)/left ventricular (LV) ratios for each segment. Methods-Two hundred control fetuses were examined between 20 and 40 weeks' gestation. Using offline speckle-tracking software, the 24 end-diastolic transverse widths were computed and the RV/LV ratios were regressed against 7 independent variables related to the size, weight, and age of the fetuses. Five fetuses with coarctation of the aorta and 5 fetuses with pulmonary stenosis were examined to exemplify the utility of these measurements. Findings-The 24-segment transverse widths were associated with changes in fetal size, weight, and age. Regression equations were developed to describe these changes with R 2 values between .5 and .82. The measurements were normally distributed (Shapiro-Wilk > 0.5). The RV/LV ratio for the 24 segments did not strongly correlate (R 2 = .001 to-.2) with fetal size, weight, or gestational age. Fetuses with coarctation of the aorta and pulmonary stenosis demonstrated characteristic changes in the 24-segment transverse widths and the RV/LV ratios in the basal (segments 1-8), mid (segments 9-16) and apical (segments 17-24) sections of the ventricles. Conclusions-The 24-segment transverse widths of the right and left ventricles and the RV/LV ratios provide a comprehensive method to examine the width of the ventricular chambers.
Prenatal Diagnosis, 2017
Introduction: The purpose of this study was to simultaneously measure with speckle tracking software (STS) the end-diastolic ventricular area (A), basal transverse width (BW), mid-chamber transverse width, (MW) and the basal-apical length (BAL) in normal fetuses and those with pathology. Methods: The 4-chamber view of the fetal heart was obtained in 200 control fetuses between 20 and 40 weeks of gestation and in nine 3rd trimester fetuses with heart malformations. The mean and standard deviation for the A, BW, MW, and BAL were computed from the control fetuses and Zscores computed in 9 fetuses with cardiac malformations. Results: The A, BAL, BW, and MW were correlated with 7 somatic and age independent variables (R 2 = 0.63-0.85). The highest R 2 values occurred for the head circumference, estimated fetal weight and ultrasound mean gestational age (0.82-0.85). Z-score values and centiles from the 9 fetuses with cardiac malformations suggested that the A, BW, MW, and BAL were below or above the 5 th and 95 th centiles as expected for the corresponding ventricular pathology. Conclusions: This study reports an integrated approach to evaluate the end-diastolic size of the right and left ventricular chambers and demonstrated clinical utility in fetuses with cardiac malformations.
Ultrasound in Obstetrics & Gynecology, 2019
Objectives To measure, using speckle-tracking technology, the fractional area change (FAC) of the right and left ventricles in normal fetal hearts between 20 and 40 weeks of gestation. Methods The four-chamber view of the fetal heart was obtained in 200 normal fetuses between 20 and 40 weeks of gestation. FAC was computed from the ventricular areas (((end-diastolic area − end-systolic area)/end-diastolic area) × 100) for the right and left ventricles, and regressed against seven independent biometric and age variables. FAC was correlated with longitudinal fractional shortening (LFS) (((end-diastolic longitudinal length − end-systolic longitudinal length)/enddiastolic longitudinal length) × 100) obtained from the mid-ventricular basal-apical lengths of the right and left ventricular chambers and with transverse fractional shortening (TFS) (((end-diastolic transverse length − end-systolic transverse length)/end-diastolic transverse length) × 100) from three transverse positions (base, mid, apical) located within each ventricular chamber. To evaluate potential clinical utility, FAC, LFS and TFS results were examined in nine fetuses with a congenital heart defect (CHD). Results Regression analysis demonstrated significant associations between FAC and the independent biometric and age variables (R 2 = 0.13-0.15). FAC was significantly correlated with LFS (R 2 = 0.18-0.28) and TFS (R 2 = 0.13-0.33). Examination of the fetuses with CHD revealed that six of the nine had abnormal FAC Z-score values for the index pathological ventricle. When abnormal LFS and TFS values were compared to the FAC in these fetuses, the FAC was either abnormally low or normal.
International Heart Journal
In fetal echocardiography, conventional parameters for assessing cardiac function are limited because of limited echocardiographic windows or the fetus' position. We aimed to evaluate the feasibility and reproducibility of fetal left ventricular (LV) twist by two-dimensional, speckle-tracking echocardiography (2DSTE) in a Japanese population. We included 55 normal fetuses at gestational ages between 21 and 36 weeks. Subjects with adverse maternal health issues were excluded. LV twist was calculated as the net difference between LV basal and apical rotation at end-systole estimated with 2DSTE. We were able to analyze the 2DSTE images in 44 cases (80%). The mean (±SE) apical rotation, basal rotation, and LV twist were 7.88 ± 0.77, −3.68 ± 0.50, and 11.1 ± 0.75 degrees, respectively. We could not analyze 11 cases (20%) because of poor image quality due to fetal position in five cases (45.5%), failure to track the endocardium because of blurred images in five cases (45.5%), and failure to obtain images of the heart due to the presence of the placenta in front of the fetus in one case (9.1%). There were no significant differences in the demographic data between pregnant women in whom LV twist analysis was feasible and not feasible. The intra-and interobserver intraclass correlation coefficients were 0.67 and 0.64, respectively. LV twist analysis by 2DSTE in the fetus was feasible in a substantial population and may provide new insight into cardiac function during the prenatal period. On the other hand, its reproducibility was moderate and needs to be improved.
Radiologia Brasileira, 2021
The functional assessment of the fetal heart has been incorporated into cardiac ultrasound screening as a routine procedure, encompassing fetuses with and without structural heart diseases. It has long been known that various cardiac and extracardiac conditions, such as fetal growth restriction, fetal tumors, twin-to-twin transfusion syndrome, fetal anemia, diaphragmatic hernia, arteriovenous fistula with high cardiac output, and congenital heart diseases (valvular regurgitation and primary myocardial disease), can alter hemodynamic status and fetal cardiac function. Several ultrasound and Doppler echocardiographic parameters of fetal cardiovascular disease have been shown to correlate with perinatal mortality. However, it is still difficult to identify the signs of fetal heart failure and to determine their relationship with prognosis. The aim of this study was to review the main two-dimensional Doppler ultrasound parameters that can be used in the evaluation of fetal cardiac funct...
24-SEGMENT Sphericity Index: A New Technique to Evaluate Fetal Cardiac Diastolic Shape
Ultrasound in Obstetrics & Gynecology, 2018
Objective Because of parallel circulation in the fetus and the differential effect that various disease states may have on the shape of the right and left ventricles, this study was conducted to evaluate the sphericity index (SI) of 24 transverse segments distributed from the base to the apex of each of the ventricular chambers. Methods Two hundred control fetuses were examined between 20 and 40 weeks of gestation. The displacement of the ventricular endocardium during the cardiac cycle was computed using offline speckle-tracking software. From the ASCII output of the analysis, we analyzed 24 end-diastolic transverse segments, distributed from the base to the apex of each ventricle, as well as the end-diastolic mid-basal-apical length. The SI was computed for each of the 24 segments by dividing the mid-basal-apical length by the transverse length for each segment. Regression analysis was performed against biometric measurements and gestational age according to last menstrual period and ultrasound. Eight fetuses, in which the four-chamber view appeared subjectively to demonstrate chamber disproportion, were evaluated as examples to demonstrate the utility of this technology. Results The SI for each segment was independent of gestational age and fetal biometric measurements. The SI of the right ventricle was significantly (P < 0.001) lower than that of the left ventricle for segments 1-18, suggesting that the right ventricle was more globular in shape than was the left ventricle at the base, mid and a portion of the apical segments of the chamber. Fetuses with various cardiac structural abnormalities and abnormal fetal growth had abnormal SI values that reflected either a more globular or a more flattened ventricular chamber. Conclusion Determination of SI for each of 24 segments of the fetal right and left ventricles provides a
The International Journal of Cardiovascular Imaging
Speckle tracking echocardiography is a promising method for assessment of myocardial function in fetal and neonatal hearts, but further studies are necessary to validate and optimize the settings for use in fetal cardiology. Previous studies have shown that the definition of the region of interest (ROI) affects strain values in adults. The aim of this study was to investigate how different widths of ROI influences measurements of four-chamber longitudinal systolic strain in fetuses late in pregnancy. Thirty-one singleton, healthy fetuses born to healthy mothers underwent an echocardiographic examination during gestational week 37. Speckle tracking was performed with two different settings for ROI width; the narrowest and second most narrow, provided both widths were assessed as suitable for the myocardial wall thickness of the fetus. We found an inverse correlation between the ROI width and the strain values. Four-chamber longitudinal strain changed from − 20.7 ± 3.6% to − 18.0 ± 4....
Objectives: Echocardiographic assessment of Left ventricular systolic function is traditionally being performed by estimation of fractional shortening (FS) and ejection fraction (EF). Speckle tracking echocardiography (STE) is a promising tool for assessment of myocardial function. The aim of this study is to evaluate the global longitudinal strain (GLS) using 2D-STE in healthy neonates to establish normal reference ranges. Method: It is a retrospective study through an analysis of transthoracic echocardiogram of normal healthy neonates. We enrolled all neonates in our institution from January 1st, 2021 to February 28th, 2021. 2-D STE was used to assess left ventricular GLS from the apical views. Results: 185 neonates were enrolled. Mean value for left ventricle GLS (%) was-19.9 ± 1.2, GLS-derived EF (%) was 60.0 ± 2.7; while the left ventricle EF by biplane Simpson's method (%) was 61.0 ± 3. There is a good positive correlation between the Left Ventricle EF by biplane Simpson's method and EF by 2-D STE, which was statistically significant (r = .294, n = 102, p = .003). Apical 4-chamber longitudinal strain and strain-derived EF is significantly correlated with GLS and bi-plan EF respectively. Conclusion: 2-STE is feasible technique for analyzing newborn myocardial systolic function. The normal range of GLS in neonates is not much different than reported for the pediatric. There is a good positive correlation between the Left Ventricle EF by 2-D STE and EF by biplane method.
Evaluation of fetal heart dimensions from 12 weeks to term
The American Journal of Cardiology, 2001
To evaluate whether fetal cardiac measurements can be made in the second trimester, we examined a cohort of normal pregnancies between 12 and 18 weeks' gestation using state-of-the-art ultrasound equipment. We examined this population longitudinally at intervals of 2 weeks, as well as at 32 weeks' gestation. From the 4-chamber view we measured the ventricular and atrial cavity dimensions, the thickness of the ventricular walls and septum at end-diastole, and the annulus dimensions of the mitral and tricuspid valves. Using a variety of views we also measured the long and cross-sectional diameters of the atria, the aorta, the pulmonary artery and its main left and right branches, the ductus arteriosus, and the superior and inferior vena cavae. To test the frequency with which measurements could be made, we divided them into measurements that were clear and easy to define (statistically good), to those that were unclear (statistically bad), or those that were not measured at all (none). Data were then analyzed by regres-sion analysis, analysis of variance, and covariance. The frequency of reliable measurements varied inversely with gestational age. The inflection point for measurements was approximately at 16 weeks. Data from this longitudinal study were evaluated against those obtained from our previous study. Because no statistical differences were found in measurements between these studies where they overlapped, the data were pooled into 1 large group and the mean and SEEs calculated for all variables. Our study demonstrates that with current transabdominal imaging, fetal cardiac measurements can be made reliably in normal fetuses from 16 weeks' gestation onward. The frequency of obtaining data in younger normal fetuses suggests it is unlikely that reliable observations can be made routinely in abnormal fetuses <16 weeks old, although this might be possible in individual fetuses. ᮊ2001 by Excerpta Medica, Inc.