No abstract available.
Echocardiography, Stress*

No abstract available.
Echocardiography, Stress*

No abstract available.
Dobutamine* ; Echocardiography, Stress* ; Myocardium*

No abstract available.
Echocardiography, Stress ; Relaxation

Echocardiography is one of the most frequently used techniques for diagnosing cardiovascular diseases. Over the last twenty years, technological advances have enabled the application of high-quality imaging. Important recent developments have occurred in echocardiography that are already being used clinically. Equipment and hardware is now available to produce real time three-dimensional and contrast enhanced imaging.. Tissue Doppler and stress echocardiography have provided potential benefit to analyze hemodynamic information of heart. This review discusses each of these new developments and their potential impact on the practice of echocardiography and cardiology in general.
Cardiology ; Cardiovascular Diseases ; Echocardiography* ; Echocardiography, Stress ; Heart ; Hemodynamics ; Nuclear Medicine*

OBJECTIVETo evaluate the value of adenosine tissue Doppler stress echocardiography on ischemic myocardium.

METHODSRoutine dosage (140 microgxkg(-1)xmin(-1) IV for 6 min) adenosine stress echocardiography was performed on 40 patients with chest pain for diagnosis of coronary artery disease (CAD). The images of left ventricular myocardial motion were acquired by tissue Doppler imaging (TDI) based on traditional 2D stress echocardiography before and 3 min, 6 min after adenosine stress (GE Vivid 7, USA). The myocardial velocity, strain and strain rate in 16 segments were offline measured and analyzed on ECHOPAC software. The results were compared with that of coronary angiography (CAG).

RESULTSCAG identified 18 CAD and 22 non-CAD patients with 159 ischemic segments and 465 non-ischemic segments. Adenosine significantly increased the systolic velocity (Sm), early diastolic velocity (Em), late diastolic velocity (Am), peak systolic strain (Smax), systolic strain rate (SRs), early diastolic strain rate (SRe) and late diastolic strain rate (SRa) both ischemic and non-ischemic segments (all P < 0.05). The baseline Sm and Em in ischemic segments were significant lower than non-ischemic segments [(3.16 +/- 1.20) cm/s vs (4.03 +/- 1.27) cm/s, P < 0.01; (3.75 +/- 1.67) cm/s vs (4.66 +/- 1.70) cm/s, P < 0.05]. At peak stress the differences in Sm and Em were more significant [(3.98 +/- 1.63) cm/s vs (5.07 +/- 1.52) cm/s; (4.51 +/- 2.32) cm/s vs (6.52 +/- 2.56) cm/s; P < 0.01]. The reductions on Smax and Se were more significant in ischemic segments compared those in non-ischemic segments (16.91% +/- 3.35% vs 19.56% +/- 5.47%, P < 0.01 and 9.53% +/- 2.89% vs 13.06% +/- 4.63%, P < 0.001). The biggest area under curve (AUC) in peak stress was seen in Se by ROC curve analysis (AUC = 0.740, with sensitivity 67% and specificity 83%).

CONCLUSIONParameters derived from TDI offer reliable and accurate information on ischemic myocardium during adenosine stress echocardiography.

BACKGROUND: Long term athletic training is associated with an increase in left ventricular diastolic cavity dimension, wall thickness, and mass. These changes in left ventricular morphology represent an adaptation to increased ventricular load and are generally described as the “athlete's heart”. In the present study, we used echocardiography to evaluate the left ventricular structure and function in track athletes. METHODS: We studies 48 males(average age 22 years)by Doppler and echocardiography, which consisted of 12 normal controls, 36 track athletes(12 long distance track, 12 sprint, 12 jump). These athletes were trained regularly for 3-19 years(average 9±4 years). RESULTS: 1) At rest, left ventricular diastolic and systolic diameter, systolic interventricular septal wall thickness, diastolic and systolic posterior wall thickness, and left ventricular end diastolic and systolic dimension were larger in long distance track athletes than in the controls. 2) Left ventricular mass was larger in long distance track athltes and sprinter than controls. 3) After maximum exercise, left ventricular diastolic and systolic diameter, systolic interventricular septal wall thickness, diastolic and systolic posterior wall thickness, and left ventricular end diastolic and systolic dimension increased more significantly in long distance track athletes than in the controls. But, in sprinters, the left end systolic diameter, diastolic and systolic interventricular septal thickness, and left end diastolic and systolic dimensions were increased. 4) At rest, the E/A and Ei/Ai of the mitral flow in long distance track athletes increased more than in the controls. But there were no differences of parameters of mitral and aortic flow between long distance track athletes and controls after maximum exercise. CONCLUSIONS: The left ventricular mass of long distance and sprint track athletes were lager Than controls. In the long distance track athletes, the left ventricular structural and functional changes before and after maximum exercise were prominent. In the sprinters, after maximum exercise, the left ventricular structural and functional changes were prominent.
Athletes ; Echocardiography ; Echocardiography, Stress ; Heart Ventricles ; Humans ; Sports

No abstract available.
Dobutamine ; Echocardiography, Stress ; Liver Transplantation ; Liver

No abstract available.
Coronary Artery Disease* ; Coronary Vessels* ; Diagnosis* ; Echocardiography, Stress*

No abstract available.
Coronary Artery Disease* ; Coronary Vessels* ; Diagnosis* ; Dobutamine* ; Echocardiography, Stress*