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Echocardiographic Images (echocardiographic + image)

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Medical Sciences100%

Selected Abstracts

Active Vegetations Can Be Differentiated from Chronic Vegetations by Visual Inspection of Standardized Two-Dimensional Echocardiograms

ECHOCARDIOGRAPHY, Issue 2 2000
PH.D., TAHIR TAK M.D.
The ability to differentiate active from chronic valvular vegetations (VEGs) by digital image processing and by visual observation was evaluated in 18 patients with a clinical diagnosis of infective endocarditis (IE). Two-dimensional echocardiographic (2-DE) examinations were performed on all patients at diagnosis and after a mean period of 52 days. Two comparable images (active and chronic) from the same patient and in the same phase of the cardiac cycle were digitized, magnified, and displayed on a high resolution monitor. The mean pixel intensity (MPI) was 72 ± 14 in the active stage and 143 ± 23 in the chronic stage (P < 0.0001). The VEG size was 0.64 ± 0.15 cm2 in the active stage and decreased to 0.46 ± 0.17 cm2 in the chronic stage (P < 0.001). Two experienced echocar-diographers, who were blinded to the age of the VEGs, identified each echocardiographic image as active or chronic based on visual observation of density of the VEGs. The VEGs were correctly identified as active or chronic in 17 out of the 18 patients. In summary, although digital image processing of 2-DE may be useful, the density of VEGs assessed by visual inspection will help differentiate between active and chronic VEGs of IE. The standardization procedure at the time of the initial study and use of identical gain settings in subsequent studies are key factors in making this distinction. [source]

Enhanced Left Ventricular Endocardial Border Delineation with an Intravenous Injection of SonoVue, a New Echocardiography Contrast Agent:

ECHOCARDIOGRAPHY, Issue 8 2000
A European Multicenter Study
The safety and efficacy of SonoVue (also referred to as BR1), a new contrast agent for delineating endocardial border of the left ventricle after intravenous administration, was assessed. Two hundred and eighteen patients with suspected coronary artery disease undergoing fundamental echocardiography for the assessment of left ventricle were enrolled in a prospective multicenter, single blind, cross-over study with random sequence allocation of four different doses of SonoVue. Endocardial border definition in the apical and parasternal views was scored as O = not visible, 1 = barely visible, and 2 = well visualized before and after contrast enhancement. Analysis was performed by two pairs of off-site observers. Safety of SonoVue was also assessed. Results of our study indicated that the mean improvements in the endocardial border visualization score were as follows: 3.1 ± 7.8 (95% CI, 2.5 and 3.7) for 0.5 ml, 3.4 ± 8.0 (95% CI, 2.8 and 4.0) for 1 ml, 3.4 ± 7.9 (95% CI, 2.8 and 4.0) for 2 ml, and 3.7 ± 8.0 (95% CI, 3.1 and 4.3) for 4 ml (P < 0.05 for all doses from baseline). Changes from baseline in endocardial visualization scores were also seen in the apical views (P < 0.05) and they were dose-dependent (P < 0.001). Similar enhancements of endocardial visualization scores were observed in the apical views in patients with suboptimal baseline echocardiographic images. Diagnostic confidence for assigning a score and image quality also were significantly better following contrast enhancement. No significant changes in the laboratory parameters and vital signs were noted following contrast enhancement, and the side effects were minimal. It was concluded that SonoVue is safe and effective in delineating endocardial border, including in patients with suboptimal baseline images. [source]

Age Dependency of Myocardial Structure: A Quantitative Two-Dimensional Echocardiography Study in a Normal Population

ECHOCARDIOGRAPHY, Issue 3 2000
MARIA-AURORA MORALES M.D.
Histological changes of the myocardium occur with aging due to an increase in collagen content, hypertrophy of fibers, and patchy fibrosis. Quantitative analysis of conventional echocardiographic images provides an in vivo assessment of myocardial structure by the evaluation of the gray level distribution; with this technique, a relation between myocardial fibrosis and pathological ultrasonic response has been documented. The aim of this study was to evaluate the relation between ultrason-ically assessed myocardial structure and age in a normal population. Seventy-eight subjects (47 men; mean age, 51 years; age range, 23,87 years) without apparent cardiovascular and systemic disease underwent conventional two-dimensional echocardiographic examinations. Still frames at end-diastole from apical four-chamber view were digitized and converted in matrices of 256 × 256 pixels. First-order statistical analysis was performed to describe a region of interest in the interventricular septum. The following parameters were studied: mean (gray level amplitude), standard deviation (overall contrast), uniformity (tonal organization), and entropy (tendency of gray levels to be spread). Myocardial structure was assessed in 75 of 78 subjects, divided into three groups: I, age 23,40 years; II, age 41,65 years; and III, > 65 years. Significant differences for all the parameters were found between the age groups. Age correlated directly with mean and entropy (r = 0.77 and 0.69, respectively) and inversely with uniformity (r = 0.70). Our results suggest that quantitative echocardiography can reveal age-related changes in myocardial structure that are characterized by a greater echogenicity and loss in tonal organization, possibly due to increased collagen content within the fibers. [source]

Palpable Cardiac Impulse Predicts Adequate Acoustic Windows

ECHOCARDIOGRAPHY, Issue 1 2000
F.A.C.C., JAMES P. EICHELBERGER M.D.
In this study, we sought to determine the usefulness of palpating an apical cardiac impulse on physical examination in predicting adequate echocardiographic images for stress echocardiography. A variety of stress tests using either echocardiographic imaging or nuclear imaging are available to referring physicians. Deciding which test is best for a given patient is often dificult. In the case of stress echocardiography, the most significant limitation is poor image quality i n a small portion of patients. We enrolled 136 consecutive outpatients referred for echocardiography. The presence or absence of a palpable cardiac apex on physical examination was recorded by two independent and blinded examiners. Data, including age, sex, weight, prior chest surgery, and smoking, were also collected. Echocardiographic imaging of the left ventricle was scored according to the number of adequately visualized wall segments in a standard 16-segment model. One hundred eleven patients (82%) had adequate visualization of at least 14 of 16 wall segments. Ninety-eight patients (72%) had a palpable cardiac impulse, of whom 90 (92%) also had adequate acoustic image quality versus only 21 (55%) of the 38patients in whom an apex was not palpable (P < 0.0001). Other variables that were measured were not significantly related to image quality, with the exception of weight; patients with adequate images weighed a mean of 75 kg versus 91 kg i n those with inadequate images (P < 0.0006). However, multivariate analysis showed a palpable apex to be the only independent predictor after controlling for other variables. A physical examination assessment for a palpable apical impulse is useful to predict adequate echocardiographic image quality for stress echocardiography. When used in conjunction with other parameters, this may lead to more appropriate referral to augmented stress testing. (ECHOCARDIOGRAPm, Volume 17, January 2000) [source]

Defibrillation Causes Immediate Cardiac Dilation in Humans

JOURNAL OF CARDIOVASCULAR ELECTROPHYSIOLOGY, Issue 8 2003
Erin Sylvester B.S.
Introduction: Prior studies in isolated heart tissue have shown both excitation and deexcitation to be the primary mechanism of defibrillation. This article presents the first evidence in man of deexcitation immediately following defibrillation by tracking the heart's mechanical response. Methods and Results: The geometric changes of the ventricular chambers were measured before and after defibrillation in seven human subjects receiving an implantable cardioverter defibrillator (ICD). The ICD was used to produce approximately three episodes of ventricular fibrillation and defibrillation in each subject. Twenty-two two-dimensional echocardiographic images of the right ventricle (RV) and 11 images of the left ventricle (LV) were recorded and analyzed at 30 frames per second. Just over 2 seconds of each episode were digitized, beginning half a second before the defibrillation shock. Individual frames were analyzed to yield cross-sectional, ventricular chamber area as a function of time. Immediately following defibrillation, ventricular chambers dilated with significant fractional area increase (RV: 1.58 ± 0.25, LV: 1.10 ± 0.06), with peak dilation at 194 ± 114 msec. Conclusion: Defibrillation causes a rapid increase in ventricular chamber area due to relaxation of the myocardium, suggesting that defibrillation synchronizes the cardiac cells to the deexcited state in man. (J Cardiovasc Electrophysiol, Vol. 14, pp. 832-836, August 2003) [source]