Mitral valve resistance determines hemodynamic consequences of severe rheumatic mitral stenosis and immediate outcomes of percutaneous valvuloplasty.

INTRODUCTION: The mitral valve area (MVA) poorly reflects the hemodynamic status of (MS). In this study, we compared the MVA with mitral valve resistance (MVR) with regard to the determination of hemodynamic consequences of MS and the immediate outcomes of percutaneous balloon mitral valvuloplasty (PBMV). METHODS: In a prospective study, 36 patients with severe rheumatic MS with left ventricular ejection fraction (LVEF) >50% were evaluated. They underwent transthoracic echocardiography (TTE) and catheterization. The MVA was measured by two-dimensional planimetry and pressure half-time (PHT), and the MVR was calculated using the equation: 1333 × transmitral pressure gradient mean transmitral diastolic flow rate. RESULTS: The patients' mean age was 47.8±10.5 years. MVR ≥140.6 dynes·s/cm5 detected systolic pulmonary arterial pressure (sPAP) >55 mm Hg with a sensitivity of 100% and a specificity of 74%. The sensitivity and specificity of MVA<0.75 cm2 to discriminate elevated sPAP were 81% and 89%, respectively. PHT ≥323.5 mseconds had a sensitivity of 78% and a specificity of 96% to detect an elevated sPAP. To predict a successful PBMV, preprocedural MVR ≥106.1 dynes·s/cm5 had a sensitivity of 100% and a specificity of 67% (area under the curve [AUC]=0.763; 95% confidence interval [CI]=0.520-1.006; P=.034); preprocedural MVA <0.95 cm2 had a sensitivity of 78% and a specificity of 73% (AUC=0.730; 95% CI=0.503-0.956; P=.065); and preprocedural PHT ≥210.5 mseconds had a sensitivity of 73% and a specificity of 78% (AUC=0.707; 95% CI=0.474-0.941; P=.095). CONCLUSIONS: MVR seems to be more accurate than MVA in determining the hemodynamic consequences of severe MS as determined by sPAP. In addition, preprocedural MVR detected successful PBMVs.

Match and mismatch between opening area and resistance in mild and moderate rheumatic mitral stenosis.

BACKGROUND: Mitral valve resistance (MVR) is a hemodynamic consequence of mitral stenosis (MS), but it has no clear threshold with a shortage of data to be reliable. We aimed to investigate match and mismatch between opening area and resistance especially in patients with moderate and mild MS. METHODS: This study comprised 88 patients with moderate and mild rheumatic MS. Transthoracic echocardiographic study estimated the following: mitral valve area (MVA) by both planimetry (2D) and pressure half-time (PHT), mitral valve score (MVS), mean transmitral pressure gradient (MPG), diastolic filling time (DFT), left ventricular out flow tract diameter (LVOTd) and velocity-time integral (LVOTvti), and MVR = MPG/aortic flow ratio [(LVOTd) (LVOTvti)/DFT] in dynes·s/cm5 . Patients were classified into two groups: group 1 (51 patients) with matched MVR and group 2 (37 patients) with mismatched higher MVR. RESULTS: In the matched group, moderate MS showed MVR <105 dynes·s/cm5 and <76dynes·s/cm5 with mild MS. Group 2 compared to group 1 had higher NYHA class (1.4±0.6 vs 1.2±0.4, P<.05) and higher MVS (8.1±1.8 vs 7±0.9, P<.05). MVR showed positive correlation with MVS (r=.5, P<.05), and logistic regression analysis showed that MVS is the only independent predictor of the MVR severity in the mismatched group (i.e., with higher MVR compared to the ROC analysis results) (B±SE=6.997±2.826, t=2.476, 95% CI 1.241±12.752 with an odds ratio=0.412, P<.05). CONCLUSION: On investigating match and mismatch between opening area and resistance, the only independent predictor of mismatch is the mitral valve score.

Value of the mitral valve resistance in evaluation of symptomatic patients with mild and moderate mitral stenosis--a dobutamine stress echocardiographic study.

BACKGROUND: Conventional stenosis indexes poorly reflect the major hemodynamic consequence of mitral stenosis (MS). Valve resistance (VR) is a physiologic expression of stenosis. OBJECTIVES: This study aimed to demonstrate whether the mitral valve resistance (MVR) and its changes, relate to restricted exercise capacity in patients with mild and moderate mitral stenosis. METHODS: Twenty-four patients with rheumatic mild-to-moderate MS underwent transthoracic echocardiographic study (resting and dobutamine stress echocardiography [DSE]), divided into two groups; group I: symptomatic (12 patients) and group II: asymptomatic (12 patients). Mitral valve area (MVA), mean transmitral diastolic pressure gradient (TMPG), cardiac output (CO), and MVR were measured in all patients at rest and at peak DSE. Changes (∆) in MVA, TMPG, CO, and MVR were calculated. Data underwent statistical analysis. RESULTS: From resting to peak dobutamine infusion, the MVR significantly decreased from 111.4 ± 28.2 to 83.6 ± 27.0 dynes sec/cm(5) in group II (P < 0.001). The increase in MVR in group I (13.8 ± 10.3 dynes sec/cm(5)) compared with its reduction (-27.8 ± 15.6 dynes sec/cm(5)) in group II were highly significant different (P < 0.001). A reduction in MVR by less than 21.5 dynes sec/cm(5) at peak dobutamine infusion reflect a cutoff value considered to detect the hemodynamic significance of mild-to-moderate MS with a sensitivity of 92% and a specificity of 73%. CONCLUSION: The changes in the MVR can be used as a DSE parameter for expression of stenosis severity and to describe discrepancy in symptom status in patients with mild-to-moderate mitral stenosis.

A Comparative Study of the echocardiographic Methods Assessing Severity of Stenosis in Pateints with mitral Stenosis

BACKGROUND: Determination of mitral valve area (MVA) in patients with mitral stenosis is very important in clinical practice. Therefore, the ability to assess accurately MVA by noninvasive technique is of great meaning to the management of patients with mitral stenosis. Echo-Doppler(ED) method was derived from the study of fluid dynamics that the flow volume is proportional to orifice area, velocity of flow which shows period requird by the flow. It has been proposed recently that measuring the flow convergence region proximal to an orifice by Doppler flow mapping can be used to derive cardiac output or flow rate proximal to stenotic orifices and therefore to calculate their areas by the continuity equation (area=flow rate/velocity). Applying these methods in mitral stenosis would provide a unique way of validating the underlying concept because the predicted areas could be compared with those measured directly by planimetry and pressure half-time method. Valve resistance has been proposed as an alternative hemodynamic indicator, but initially this index was not used because it was unlikely to remain constant at different flow rates. Recently valve resistance provided a better indices of hemodynamic obstruction than mitral valve area, and these indices usually estimated by invasive method, but it is able to calculate from Doppler echocardiography and compared to the results of invasive method. METHODS: The mitral inflow volume can be obtained by estimating the stroke volume (SV) by Teichholz's method from M-mode echocardiogram of the left ventricle, and the mean diastolic velocity(MDV) and diastolic filling period (DFP) by mitral inflow continuous-wave Dopler echocardiogram. Therefore, Echo-Doppler method is MVA=SV/MDV×DFP. Doppler color flow recordings of mitral inflow were obtained from the apex, and the radius of the proximal flow convergence region was measured at its peak diastolic value from the calculated assuming uniform radial flow convergence toward the orifice, modified by a factor that accounted for the inflow funnel angle formed by the mitral leaflets. Mitral valve area was then calculated as peak flow rate divided by peak velocity by continuous-wave Doppler. To Compare the stenotic indices from noninvasive method and invasive method, cardiac catheterization was performed. RESULTS: 1) ED-MVA of these 28 patients with mitral stenosis correlated well at a coeffitient of 0.867 than PHT-MVA(r=0.513) or 2DE(r=0.513) in comparison with Cath-MVA. 2) Excluding 4 patients with mitral regurgitation, the ED-MVA of 24 patients with isolated mitral stenosis showed a better correlation with r=0.944 than with PHT-MVA(r=0.642) or 2DE-MVA(r=0.647) in comparison with Cath-MVA. 3) MVA determined by PISA method were correlated with planimetry method on 2DE(r=0.51, p < 0.001). 4) MVA determined by PISA method were correlated with PTH method(r=0.44, p=0.002). 5) Agreement with planimetrymethod was similar for 26 patients with mitral regurgitation and 24 without it, as well as for 34 in atrial fibrillation. 6) The correlation coefficient of mitral valve area and mitral valve resistance between echocardiography(r=0.87) and cardiac catheterization(r=0.82) showed positive correlation(p < 0.001). 7) Linear regression analysis showed a negative correlation of mitral valve resistance and Gorlin mitral valve area between echocardiography (r=−0.84) and cardiac catheterization(r=−0.84). CONCLUSION: Echocardiographic evaluation of mitral valve stenosis by planimetry, pressur half-time method, Echo-Doppler method, PISA method, and mitral valve resistance were useful noninvasive methods in assessing the severity of mitral stenosis. In mitral stenosis patients with mitral regurgitation and/or aortic regurgitation, PISA and mitral valve resistance methods were also reliable. In conclusion, these results suggested that the echocardiographic methods could be sufficient for assessing the severity of mitral stenosis without the necessity of invasive technique.

Evaluation of the Mitral Valve Resistance as a Hemodynamic Parameter in Mitral Stenosis

BACKGROUND: Mitral stenosis is charcterized by decrease in mitral valve area anatomically and increase in transmitral pressure gradient hemodynamically. And these changes have been used to quantify the severity of mitral stenosis clinically. To evaluate the clinical usefulness of mitral valve resistance as a hemodynamic parameter in patients with mitral stenosis, we compared the mitral valve resistance to the clinical status of the patient with mitral stenosis, the other hemodynamic parameters and static parameter. METHODS: We analyzed and reviewed the data obtained from the consecutive 27 patients with mitral stenosis(7 male, 20 female : mean age 38+/-9 years) who had been underwent percutaneous mitral valvuloplasty(PMV). RESULTS: Befor PMV, the mitral valve resistance was significantly correlated with exercise capacity on treadmill test(r=-0.37, p<0.05), mitral valve area(r=-0.72, p<0.01), transmitral mean pressure gradient(r=0.83, p<0.01),not with cardiac output, mixed venous oxygen saturation. After PMV, the mitral valve resistance was significantly correlated with mitral valve area (r=-0.72, p<0.01), transmitral mean pressure gradient(r=0.90, p<0.01).According to the results summerizing and comparing the values of before and after percutaneous mitral valvuloplasty, the mitral valve resistance had good relationship with preexisting paramerters of severity such as mitral valve area(r=-0.82, p<0.01), transmitral mean pressure gradient (r=0.92, p<0.01). CONCLUSION: This results indicate that the mitral valve resistance is a useful hemodynamic parameter in patients with mitral valve stenosis and reflects the exercise capacity during the treadmill test which was the objective parameter of practical and clinical status of the patient well than the other hemodynamic parameters in case of remarkably reduced transmitral valve blood flow due to severe mitral valve stenosis, because the degree of change in the mitral valve resistance in relagion to the degree of change in transmitral valve blood flow is relatively more constant than the other hemodynamic parameters.

Mitral Valve Area and Resistance in Mitral Stenosis: Comparison of Cardiac Catheterization and Doppler Echocardiography

BACKGROUND: The valve area derived from the Gorlin formula has been used clinically for decades as an index of severity on the assessiment of valve stenosis, in spite of some limitations on Gorlin formula studied in aortic stenosis and mitral bioprostheses. It had been shown that Gorlin valve area varied if the hemodynamic conditions during measurement are changed. Valve resistance has been proposed as an alternative hemodynamic indicator, but initially this index was not used because it was unlikely to remain constant at different flow rates. Recently valve resistance provided a better indices of hemodynamic obstruction than mitral valve area, and these stenotic indices usually estimated by angiographic method and we studied the valve resistance by Doppler echocardiographic measurement. METHOD AND RESULT: To compare the clinical implication about these stenotic indices measured by echcoardiography and cardiac catheterization, we studied 41 patients of mitral stenosis with normal sinus rhythm. The results were as follows ; 1) In catheterization, increased heart rate, mean pressure gradient and decreased diastolic time was observed, but mitral area, resistance, cardiac output and mitral flow was not different. 2) Linear regression analysis showed negative correlation of mitral valve resistance and Gorlin mitral area(echocardiography r=-0.84, catheterization r=-0.84)(p<0.001). 3) Correlation coefficeint of mitral valve area and mitral valve resistance between echocardiography(r=0.87) and catheterization(r=0.82) showed positive correlation(p<0.001). CONCLUSION: These results suggest that mitral valve resistance by echocardiography is a useful method in the evaluation of the severity of mitral stenosis.