The recently introduced real-time three-dimensional color Doppler flow imaging (RT-3D CDFI) technique provides a quick and accurate calculation of regurgitant jet volume (RJV) and fraction. In order to evaluate RT-3D CDFI in the noninvasive assessment of aortic RJV and regurgitant jet fraction (RJF) in patients with isolated aortic regurgitation, real-time three-dimensional echocardiographic studies were performed on 23 patients with isolated aortic regurgitation to obtain LV end-diastolic volumes (LVEDV), end-systolic volumes (LVESV) and RJV, and then RJF could be calculated. The regurgitant volume (RV) and regurgitant fraction (RF) calculated by two-dimensional pulsed Doppler (2D-PD) method served as reference values. The results showed that aortic RJV measured by the RT-3D CDFI method showed a good correlation with the 2D-PD measurements (r = 0.93, Y = 0.89X + 3.9, SEE = 8.6 mL, P < 0.001); the mean (SD) difference between the two methods was--1.5 (9.8) mL. % RJF estimated by the RT-3D CDFI method was also correlated well with the values obtained by the 2D-PD method (r = 0.88, Y = 0.71X + 14.8, SEE = 6.4%, P < 0.001); the mean (SD) difference between the two methods was--1.2 (7.9) %. It was suggested that the newly developed RT-3D CDFI technique was feasible in the majority of patients. In patients with eccentric aortic regurgitation, this new modality provides additional information to that obtained from the two-dimensional examination, which overcomes the inherent limitations of two-dimensional echocardiography by depicting the full extent of the jet trajectory. In addition, the RT-3D CDFI method is quick and accurate in calculating RJV and RJF.
Aortic Valve Insufficiency/*ultrasonography ; Echocardiography, Doppler, Color ; Echocardiography, Three-Dimensional

No abstract available.
Echocardiography, Doppler, Pulsed* ; Humans

Three-dimensional (3D) echocardiography has been conceived as one of the most promising methods for the diagnosis of valvular heart disease, and recently has become an integral clinical tool thanks to the development of high quality real-time transesophageal echocardiography (TEE). In particular, for mitral valve diseases, this new approach has proven to be the most unique, powerful, and convincing method for understanding the complicated anatomy of the mitral valve and its dynamism. The method has been useful for surgical management, including robotic mitral valve repair. Moreover, this method has become indispensable for nonsurgical mitral procedures such as edge to edge mitral repair and transcatheter closure of paravaluvular leaks. In addition, color Doppler 3D echo has been valuable to identify the location of the regurgitant orifice and the severity of the mitral regurgitation. For aortic and tricuspid valve diseases, this method may not be quite as valuable as for the mitral valve. However, the necessity of 3D echo is recognized for certain situations even for these valves, such as for evaluating the aortic annulus for transcatheter aortic valve implantation. It is now clear that this method, especially with the continued development of real-time 3D TEE technology, will enhance the diagnosis and management of patients with these valvular heart diseases.
*Echocardiography, Doppler, Color ; *Echocardiography, Three-Dimensional ; *Echocardiography, Transesophageal ; Heart Valve Diseases/physiopathology/therapy/*ultrasonography ; Heart Valves/physiopathology/*ultrasonography ; Humans ; Predictive Value of Tests ; Prognosis ; Severity of Illness Index

Mitral regurgitation is one of the most serious heart diseases. With the development of up-to-date medical techniques, the ratio of successful operations in valvular repair and valvular replacement has been largely improved. Examinations before operation become extremely crucial. Accurate method is required in assessing the degree of mitral regurgitation to set down the corresponding treatment method. This paper reviews the evaluation methods of mitral valvular regurgitation provided in these years and presents comments on the application areas as well as the merits and disadvantages of those methods. Finally, the prospect of the method based on three-dimensional Doppler ultrasonographic imaging on mitral regurgitation is discussed.
Echocardiography, Doppler, Color ; Echocardiography, Three-Dimensional ; Humans ; Image Processing, Computer-Assisted ; Mitral Valve Insufficiency ; diagnostic imaging

The visualization of coronary arteries by transthoracic two-dimensional echocardiography has been used for over 10 years. In many cases, the imaging quality is too poor to allow an anatomic evaluation. During the last few years, transesophageal echocardiography has been shown to provide optimal imaging quality in virtually all patients and of all cardiac structures including the coronary arteries. The purpose of this study was to test the ability of transesophageal echocardiography in the visualiation of the coronary arteries and assessment of coronary blood flow by transesophageal two-dimensional pulsed Doppler echocardiography. We Studied 285 patients, 91 men and 194 women, aged 16 to 81 year(mean 50.6 year men, mean 54.2 year women). We have been used a 5-MHz phased array transducer with incorporated color-coded Doppler. The left main coronary artery was visualized 95.1%, left circumflex artery 27.4, left anterior descending artery 21.4% and the main stem of the proximal right coronary artery 45.1%. The time-sequential left anterior descending artery flow pattern generally consisted of a small late systolic component and a large diastolic component. The peak flow velocity in the proximal left anterior descending artery during diastole was 40.8+/-8.0cm/sec(integrity 7.6+/-0.9) and during late systole was 18.5+/-5.5cm/sec(integrity 2.9+/-0.9). There were no complications during and after examination. This study suggests that transesophageal color-coded Doppler two-dimensional echocardiography appers to be a feasible noninvasive technique for imaging the proximal left coronary artery and the left anterior descending artery flow is detectable from the transesophageal approach.
Arteries ; Coronary Vessels* ; Diastole ; Echocardiography ; Echocardiography, Doppler* ; Echocardiography, Doppler, Pulsed ; Echocardiography, Transesophageal ; Female ; Humans ; Male ; Systole ; Transducers

BACKGROUND: In vitro study, normal cardiac prosthetic valve has functional regurgitation due to structural characteristics of prosthetic valve. To evaluate functional regurgitant characteristics of prosthetic valves, we examined patients who had clinically normal mitral prosthesis. METHODS: Transesophageal two-dimensional and color doppler echocardiography were performed to 25 patients who had the clinically normal mitral prosthesis. RESULTS: Seven patients had the mitral bioprosthesis and 18 patients had the mitral mechanical prosthesis. Regurgitation was found in 4 patients(57%) with bioprosthetic valve, and the pattern of regurgitation was central in three patients and unilateral in one patient. But regurgitation was detected in 17 patients(94%) with mechanical prosthesis, and the pattern of regurgitation was bilateral in twelve patients, unilateral in four patients and central in one patient(p=0.0035). The length of regurgitant jets were 22.00+/-6.73(mm) in bioprosthetic valve and 28.65+/-7.33(mm) in mechanical valve. The regurgitant jets were detected in systolic period in most of patients. But in 4 patients who had tachycardia during TEE, regurgitation was detected in systolic and early diastolic period. CONCLUSION: Regurgitation was found in clinically normal cardiac prosthetic valves by TEE. These findings may be useful to differentiate between normal and abnormal cardiac prosthesis.
Bioprosthesis ; Echocardiography, Doppler, Color ; Echocardiography, Transesophageal* ; Humans ; Prostheses and Implants* ; Tachycardia

No abstract available.
Echocardiography* ; Echocardiography, Doppler, Color ; Ligation*

To validate ventricular diastolic phase parameters of reconstructed transmitral flow rate curve by M-mode, 2-dimensional and pulsed Doppler Echocardiography, these parameters were compared with same parameters by left ventriculography. The study population was 22 patients who received both coronary arteriography and echocardiographic examination. Transmitral flow rate curve and left ventricular filling volume curve were reconstructed from transmitral flow velocity curve by pulsed Doppler, mitral annulus diameter by two diameter by two dimensional and diastolic motion of both mitral leafltes by M-mode echocardiography. From left ventriculography, left ventricular filling volume curve and transmitral flow rate curve were made using area-length method by Sandler and Dodge. From trasmitral flow fraction, 1/2 diastolic time filling fraction, normalized peak filling volume, 1/3 diastolic time filling fraction, 1/2 diastolic time fraction, normalized peak early filling rate and ratio of early to late peak filling rate were measured. Correlation between same parameters derived from echocardiography and left ventriculography were observed. 1) Total diastolic filling volume:correlation coefficient r=0.47, P<0.05. 2) 1/3 diastolic time filling fraction:correlation coefficient r=0.90, P<0.001. 3) 1/2 diastolic time filling fraction:correlation coefficient r=0.80, P<0.001. 4) Normalized peak early filling rate:correlation coefficient r=0.57, P<0.01. 5) Ratio of early to late peak filling rate:correlation coefficient r=0.85, P<0.001. Therefore, left ventricular diastolic phase parameters of reconstructed transmitral flow rate curve using, M-mode, 2-dimensional and pulsed Doppler echocardiography seems to be useful for the noninvasive evaluation of the left ventricular diastolic function.
Angiography ; Echocardiography ; Echocardiography, Doppler* ; Echocardiography, Doppler, Pulsed ; Humans

No abstract available.
Echocardiography* ; Echocardiography, Doppler, Pulsed ; Heart Diseases* ; Heart*

BACKGROUND: Although a number of indices of diastolic function based on transmitral flow have been proposed, no single factor seems to be adequate for seperating patients with normal from with abnormal diastolic functions. Pulsed Doppler echocardiography of pulmonary venous flow(PVF) is another non-invasive method to evaluate left ventricular diastolic performance. The purpose of this study is to evaluate the normal PVF pattern by TEE. METHOD: We performed pulsed-wave Doppler studies of the PVF and of the mitral flow by transesophageal-(TEE) and transthoracic echocardiography(TTE) in a healthy young adults. RESULTS: In TEE, all sublects showed four phases of the PVE pattern ; two antewgrade systolic phase(early and late : SE and SL), one antewgrade diastolic phase(D) and one retrograde diastolic phase(A). In TTE, there were three phases of the PVF pattern ; two antewgrade phase(systolic, diastolic) and one retrograde diastolic phase but we couldn't find out early systolic phase flow. Peak velocity of each phase of PVF was as follows:SE was 48.9+/-14.1cm/sec, SL was 56.3+/-16.1cm/sec, D was 52.6+/-14.9cm/sec. The timing of SL flow was correlated significantly with that of peak aortic flow(r=0.42, p=<0.01), while the timing of D flow and that of A flow were correlated significntly with timing of mitral E peak and A peak, respectively(r=0.84, p<0.01 ; r=0.80, p<0.01). CONCLUSIONS: In the young normal subject, PVF showed four phase of flow pattern and could be easily obtained by TEE. Furthermore it may be used for evaluation of left ventricular function.
Echocardiography, Doppler, Pulsed ; Echocardiography, Transesophageal* ; Humans ; Ventricular Function, Left ; Young Adult*