Stroke volume calculated from the mitral valve echogram in patients with and without ventricular dyssynergy

Functional mitral stenosis after surgical annuloplasty for ischemic mitral regurgitation: importance of subvalvular tethering in the mechanism and dynamic deterioration during exertion

OBJECTIVE

Diastolic subvalvular mitral leaflet tethering by left ventricular remodeling that restricts leaflet opening in the presence of annular size reduction by surgery for ischemic mitral regurgitation potentially causes functional mitral stenosis in the absence of organic leaflet lesions. Exercise, known to worsen systolic tethering and ischemic mitral regurgitation, might also dynamically exacerbate such mitral stenosis by increasing tethering. This study evaluates the mechanism and response of such mitral stenosis to exercise.

METHODS

We measured the diastolic mitral valve area, annular area, and peak and mean transmitral pressure gradient by echocardiography in 20 healthy individuals and 31 patients who underwent surgical annuloplasty for ischemic mitral regurgitation.

RESULTS

Although the mitral valve area and annular area did not significantly differ in healthy individuals (4.7 +/- 0.6 cm(2) vs 5.2 +/- 0.6 cm(2), not significant), mitral valve area was significantly smaller than the annular area in patients after annuloplasty (1.6 +/- 0.2 cm(2) vs 3.3 +/- 0.5 cm(2), P < .01). The mitral valve area was less than 1.5 cm(2) only after the surgery (P < .01) and was significantly correlated with restricted leaflet opening (r(2) = 0.74, P < .001), left ventricular dilatation (r(2) = 0.17, P < .05), and New York Heart Association functional class (P < .05). Exercise stress echocardiography of 12 patients demonstrated dynamic worsening in functional mitral stenosis (mitral valve area: 2.0 +/- 0.5 cm(2) to 1.4 +/- 0.2 cm(2), P < .01; mean pressure gradient: 1.5 +/- 0.9 mm Hg to 6.0 +/- 2.2 mm Hg, P < .01).

CONCLUSIONS

Persistent subvalvular leaflet tethering in the presence of annular size reduction by surgery in ischemic mitral regurgitation frequently causes functional mitral stenosis at the leaflet tip level, which is related to heart failure symptoms and can be dynamic with significant exercise-induced worsening.

Evaluation of effects of nitroglycerin therapy by echocardiography

Echocardiography (Echo) is a convenient method in diagnosing and in quantification of cardiac abnormalities, although dependent on registration quality. M-mode and two-dimensional Echo give adequate information regarding heart dimensions and cavity volume but only indirect information of pressures. M-mode Echo gives an ideal opportunity to study left ventricular wall motion as an expression of systolic and diastolic function. Both inter and intra patient comparisons will be possible to perform. Improved wall function after intake of nitroglycerin and other nitrate preparations, has been reported in Echo studies both in resting state and in induced acute myocardial ischemia during exercise in man or in acute coronary occlusion in dogs.

Restricted diastolic opening of the mitral leaflets in patients with left ventricular dysfunction: evidence for increased valve tethering

OBJECTIVES

We tested the hypothesis that patients with incomplete systolic mitral leaflet closure (IMLC: apically displaced coaptation) also have restricted diastolic leaflet opening that is independent of mitral inflow volume and provides evidence supporting increased leaflet tethering.

BACKGROUND

Competing hypotheses for functional mitral regurgitation (MR) with IMLC include global left ventricular (LV) dysfunction per se (reduced leaflet closing force) versus geometric distortion of the mitral apparatus by LV dilation (augmented leaflet tethering). These are inseparable in systole, but restricted leaflet motion has also been observed in diastole, and attributed to reduced mitral inflow.

METHODS

Diastolic mitral leaflet excursion and orifice area were measured by two-dimensional echocardiography in 58 patients with global LV dysfunction, 36 with and 22 without IMLC, compared with 21 normal subjects. The biplane Simpson's method was used to calculate LV ejection volume, which equals mitral inflow volume in the absence of aortic regurgitation.

RESULTS

The diastolic mitral leaflet excursion angle was markedly reduced in patients with IMLC compared with those without IMLC, whose ventricles were smaller, and normal subjects (17 +/- 10 degrees vs. 58 +/- 13 degrees vs. 67 +/- 8 degrees, p < 0.0001). Excursion angle was dissociated from mitral inflow volume (r2 = 0.04); excursion was reduced in patients with IMLC despite a normal inflow volume in the larger ventricles with MR (60 +/- 25 vs. 61 +/- 12 ml in normal subjects, p = NS), and excursion was nearly normal in patients without IMLC despite reduced inflow volume (40 +/- 10 ml, p < 0.001 vs. normal subjects). The anterior leaflet when maximally open coincided well with the line connecting its attachments to the anterior annulus and papillary muscle tip (angular difference = 3 +/- 7 degrees vs. 25 +/- 9 degrees vs. 32 +/- 10 degrees in patients with and without IMLC vs. normal subjects, p < 0.0001). In patients with IMLC, the leaflet tip orifice was smaller in an anteroposterior direction but wider than in the other groups, giving a normal total area (6.8 +/- 1.8 vs. 7.1 +/- 1.2 vs. 6.9 +/- 0.8 cm2, p = NS).

CONCLUSIONS

Patients with LV dysfunction and systolic IMLC also have restricted diastolic leaflet excursion that is independent of inflow volume, coincides with the tethering line connecting the annulus and papillary muscle and reflects limitation of anterior motion relative to the posteriorly placed papillary muscles without a decrease in total orifice area. These observations are consistent with increased tethering by displaced mitral leaflet attachments in the dilated ventricles of patients with IMLC that can restrict both diastolic opening and systolic closure.

Instantaneous transmitral flow using Doppler and M-mode echocardiography: comparison with radionuclide ventriculography

To improve the accuracy of Doppler echocardiographic indices of left ventricular filling, we derived two indices of instantaneous transmitral flow with the use of Doppler velocities and M-mode echocardiography. These indices were calculated from the product of pulsed Doppler mitral velocities and either the excursion of the anterior mitral leaflet or the separation of both mitral leaflets as measures of the changing mitral orifice area. The derived flow indices and the mitral velocities alone were compared to left ventricular filling as determined by radionuclide ventriculography in 24 patients. When compared as areas under the matched decile divisions of the derived filling sequences by linear regression analysis, the relationship for combined Doppler and M-mode versus radionuclide left ventricular filling was closer to the line of identity (slope = 0.98 and 0.94 using the anterior mitral leaflet and both mitral leaflets, respectively, both p = NS versus the line of identity) than was the relationship for mitral velocities alone versus radionuclide left ventricular filling (slope = 0.74, p less than 0.05 versus the line of identity). The instantaneous mitral volume flow indices more closely resemble the time course and shape of radionuclide left ventricular filling curves than do mitral velocities alone, and the application of these indices should assist the quantitative description by Doppler echocardiography of left ventricular filling.

Calculating cardiac output from transmitral volume flow using Doppler and M-mode echocardiography

To simplify transmitral volume flow determination by Doppler echocardiography, a formula for calculating mean mitral valve orifice area using M-mode echocardiography without any 2-dimensional measurements was developed and evaluated in this study. The maximal mitral orifice area was assumed to be circular and its diameter was calculated from the maximal M-mode mitral leaflet separation. The maximal area was multiplied by the mean to maximal anterior mitral leaflet excursion ratio to correct for phasic changes in flow orifice area during ventricular filling. This measurement had a high correlation (r = 0.97, standard error of the estimate + 0.26 cm2) with mean mitral valve orifice area calculated from frame-by-frame analysis of short-axis 2-dimensional echoes in a select group of 10 normal volunteers and 10 patients with cardiomyopathy who had very high quality images of the mitral valve leaflet tips. Cardiac output calculated using the new method for orifice area estimation combined with apex view mitral valve Doppler velocities was then validated in 48 consecutive patients undergoing thermodilution cardiac output determinations with a close correlation between Doppler and thermodilution cardiac output (2.3 to 6.1 liter/min, r = 0.93, standard error of the estimate = 362 ml). The correlation improved when 12 patients with mild mitral insufficiency were excluded (r = 0.95). The M-mode echocardiogram-derived mitral valve orifice method combined with Doppler mitral valve velocities is accurate, easy to perform, has a high success rate and should increase the applicability of Doppler echocardiography for estimation of cardiac output.

Pressure-flow relations across the normal mitral valve

The stenotic mitral valve area is a major determinant of the atrioventricular pressure-flow relation, and mean atrioventricular pressure gradient is proportionate to the square of mean flow rate. In the absence of obstruction, this relation is linear. The effect of the normal mitral valve area on this pressure-flow relation has not been previously examined. Pulsed Doppler studies of transmitral flow were performed simultaneously with thermodilution cardiac outputs in 25 patients in sinus rhythm and with no valvular disease. Mean flow rate was determined as thermodilution stroke volume/diastolic filling period measured by Doppler. Several instantaneous pressure gradients were estimated from multiple velocity measurements using the modified Bernoulli equation and were plotted against time. Mean pressure gradient was estimated by dividing the area under the pressure-time curve by the diastolic filling period. Average and standard deviation of mean flow rate and pressure gradient was 223 +/- 70 ml/s and 1.4 +/- 0.8 mm Hg, respectively. There was an excellent linear correlation between these 2 parameters (r = 0.91, SEE = 30 ml/s). This confirms the linear relation of mean pressure gradient to mean flow rate in the absence of obstruction. The excellent correlation, obtained without considerations of individual variations of valve area, suggests that this relation is independent of valve area, under normal physiologic conditions.

Echographic application of the Gorlin formula for assessment of aortic stenosis: correlation with cardiac catheterization in pediatric patients

We have investigated the use of M-mode echocardiography for the diagnosis of aortic valve stenosis by application of the Gorlin formula. The hemodynamic parameters which enter this formula are shown to derive wholly from noninvasive measurements. The predicted valve areas correspond with those derived by classical catheterization studies at a level of r = 0.89, SE = 0.11 cm2, n = 10. These results suggest that the Gorlin formula for aortic stenosis may have application in a noninvasive context.

Echocardiographic aortic to mitral valve opening area ratio for determining the presence and severity of mitral regurgitation

A simple and accurate noninvasive method to quantify the degree of mitral regurgitation (MR) is lacking. Therefore, the ratio of the aortic (AVO) to mitral valve opening area (MVO) from 2-dimensionally guided M-mode echocardiographic tracings was examined as an estimate for the presence and severity of MR. Seventy-two patients who had undergone catheterization were studied: 49 with idiopathic dilated cardiomyopathy, 7 with coronary artery disease and 16 with organic MR. Twenty-eight patients had no MR (group I), 23 had mild/moderate MR (group II) and 21 had severe MR (group III). The AVO/MVO ratio was 0.86 +/- 0.2 in group I, 0.53 +/- 0.1 in group II and 0.31 +/- 0.1 in group III (p less than 0.001). An AVO/MVO ratio of 0.65 or less predicted MR with a sensitivity of 98% and a specificity of 86%. Furthermore, a strong relation was found between the ratio and the angiographic severity of MR. Thus, the AVO/MVO ratio is a simple echocardiographic parameter for detecting the presence and severity of MR.

Doppler echocardiographic measurement of cardiac output using the mitral orifice method

Cardiac output was determined in 20 patients with various cardiac conditions by measuring the cross sectional area of the mitral orifice by echocardiography and the transmitral flow by the Doppler technique. Cardiac output was calculated by multiplying the corrected mitral orifice area by the maximum diastolic velocity integral recorded by the pulsed mode. The results were compared with that obtained by the Fick method. The correlation for cardiac output by the two techniques was high in the whole group, particularly in patients without mitral regurgitation. There was also a good correlation for stroke volume determined by the two methods. Cardiac output was significantly overestimated by the continuous mode and in patients with mitral regurgitation. These results show that the mitral orifice method provides a new and reliable approach to the non-invasive measurement of cardiac output.

Hemodynamic evaluation by M-mode echocardiography in acute myocardial infarction

We assessed the relationship between echocardiographic and hemodynamic parameters in 28 patients with documented acute myocardial infarction (AMI), who underwent M-mode echocardiography and Swan-Ganz catheterization during the same hospitalization. Patients with valvular heart disease were excluded from the study. On mitral valve echogram, DE interval was measured and the area enclosed by mitral valve echogram during DE interval (DE subarea ) was calculated in each echocardiogram. DE subarea /DE interval ratio was computed for each measurement set. Hemodynamic parameters were obtained in the usual fashion. Patients with pulmonary artery wedge pressure (PWP) less than 18 mm Hg showed a DE interval markedly longer than patients with PWP greater than 18 mm Hg: 81.72 +/- 15.23 vs 55.12 +/- 9.85 msec (p less than 0.001). Patients with cardiac index greater than 2.2 L min-1 m-2 had a DE subarea /DE interval ratio greater than patients with cardiac index less than 2.2 L min-1 m-2: 0.169 +/- 0.035 vs 0.094 +/- 0.017 dm2 sec-1 (p less than 0.001). Echocardiographic and hemodynamic data were then correlated in the whole study group, and it was found that DE interval was significantly (p less than 0.001) and inversely correlated to PWP; stroke index more than cardiac index was correlated (p less than 0.005) both to DE subarea /DE interval ratio and to DE interval itself; DE interval was not affected by heart rate. We were able to categorize the patients into four subsets on the basis of echocardiographic measurements. Our findings suggest the possibility of providing, through M-mode echocardiography, a noninvasive and accurate evaluation of PWP and stroke index.

Role of chordae tendineae in mitral valve opening: two-dimensional echocardiographic evidence

Study of 16 normal and 33 flail mitral valves provides evidence of the active participation of chordae tendineae in mitral valve opening. The normal valves have straight chordae at all phases of opening. During isovolumic relaxation and progressive opening phases, the smooth configuration of the mid-anterior mitral leaflet is broken by a sharp outward "tenting." This tenting is localized at chordal insertions, reflecting significant tension at these points. Flail mitral valves allow comparison of opening motion between mitral segments with normal chordal attachment and flail segments without chordal support. Posterior flail leaflets demonstrate delay in initiation of opening motion relative to the normal anterior leaflet. The most dramatic examples of this delay reveal a maximal opening excursion of the anterior leaflet before the flail posterior leaflet initiates opening motion. The untethered free margins of opening flail anterior leaflets produce the appearance of the flail segment trailing the body of the anterior leaflet with a sharp break in leaflet contour between the supported and unsupported segments. These configurational expressions of mitral valve opening are inconsistent with a passive hemogenic mechanism. They support an active myogenic process mediated through direct traction on the valve by the chordae tendineae.

Method for computation of cardiac output in mitral stenosis independent of left ventricular dimensions and kinetic state: correlation with cardiac catheterization via the Fick method

An hydraulic orifice formula offering the possibility of quantifying cardiac output in conditions of mitral stenosis is tested using potentially noninvasive portions of catheterization data from patients evaluated for obstructive mitral valve disease. The equation studied is V = (1/21) R A T2, where V is the cardiac output (ml/min), R is the heart frequency, A is the mitral valve area (cm2), and T is the diastolic filling interval (sec/min). The mitral valve area was determined by the Gorlin formula, and R and T were measured from the pressure tracings recorded at cardiac catheterization. The degree of correspondence between the equation tested and the measured cardiac output as determined by the Fick principle technique is characterized by r = 0.87, SE = 450 ml/min, N = 10. The results suggest that the new formulation may offer a noninvasive method for estimating the cardiac output status of patients with mitral valve disease once mitral valve area is measured either at catheterization or by two-dimensional echocardiography.

Mitral and aortic valve orifice area in normal subjects and in patients with congestive cardiomyopathy: determination by two dimensional echocardiography

Previous determinations of normal valve orifice areas have been mainly from postmortem studies. In this study mitral and aortic valve orifice area were determined from two dimensional echocardiograms in 20 normal subjects and 20 patients with congestive cardiomyopathy. Mitral valve orifice area was larger than quoted in standard textbooks. Both mitral and aortic valve orifice area were reduced in patients with cardiomyopathy. Valve opening was assessed relative to left ventricular and aortic root size. The ratio of mitral valve orifice area to left ventricular cross-sectional area was markedly reduced in patients with cardiomyopathy compared with normal subjects. The ratio of aortic valve orifice area to aortic root size also was reduced in patients with cardiomyopathy. Anterior mitral leaflet E point-septal separation was similar to that in previous reports contrasting normal subjects with patients with myopathy. Among patients with cardiomyopathy, mitral E point-septal separation was primarily a function of left ventricular size and was not significantly correlated with fractional shortening or ejection fraction within this group having uniformly poor systolic function.

Evaluation of M-mode echographic estimates of left ventricle function: relationship of selected ultrasonic and hemodynamic parameters

We examined the relationship between echocardiographic and hemodynamic parameters in 48 patients with left ventricular ejection fractions less than 50% without primary valvular disease. Pulmonary wedge pressure (PWP) correlated with the PR-AC interval (r = -0.62) and with left atrial dimension (r = 0.64) but not with left ventricular diastolic dimension. A PR-AC interval less than or equal to 60 msec was observed in 26 of 29 (90%) patients with a PWP greater than or equal to 14 mm Hg versus 1 of 10 (10%) patients with a PWP less than 14 mm Hg. The correlation between PWP and the PR-AC interval was substantially better in patients with a PR interval less than or equal to 200 msec (r = -0.79) than in patients with a PR interval greater than 200 msec (r = -0.55). The PR-AC interval also correlated with the ejection fraction (r = 0.47). A left atrial dimension greater than or equal to 4.0 cm was observed in 29 of 35 (83%) patients with a PWP greater than or equal to 14 mm Hg versus 0 of 9 (0%) patients with a PWP less than 14 mm Hg. Stroke volume (SV) correlated with aortic root excursion (r = 0.71) and with SV calculated from formulas based on mitral valve motion (r = 0.76) or aortic valve motion (r = 0.62). However, no echo formula provided valid estimates of cardiac output. We conclude that M-mode echocardiography provides a relatively useful noninvasive method of assessing left ventricular filling pressure in patients with reduced ejection fraction and no valvular disease.

Two-dimensional echocardiographic assessment of left ventricular stroke volume: experimental correlation with thermodilution and cineangiography in normal and ischemic states

Left ventricular stroke volumes derived by two-dimensional echocardiography (2D echo) were compared with thermodilution and cineangiography measurements in closed-chest dogs before andone hour after proximal LAD occlusion. Stroke volume was calculated from end-diastolic and end-systolic volumes reconstructed by two models: 1) Simpson's rule employing left ventricular length and five short-axis cross-sectional areas; 2) a simplified volume formula (V = 5/6 area . length), utilizing a single short-axis area at either the mitral valve or midpapillary muscle level. The comprehensive Simpson reconstruction yielded a good correlation of 2D echo stroke volume against thermodilution (r = 0.89) over a range of normal (N = 14) and ischemic (N = 8) states. The simplified formula provided a satisfactory correlation (r = .90, N = 22) when using the midpapillary cross-section, which encompassed the induced ischemic dys-synergy. In contrast, when using the mitral valve level cross-section above the site of ventricular asymmetry, there was no significant statistical correlation. Comparison of cineangiography with 2D echo volume reconstruction based on the simplified formula with the midpapillary muscle level section yielded good correlations for stroke volume (r = 0.87) and ejection fraction (r = 0.97). Intraobserver and interobserver variability of duplicate echo stroke volume measurements was 8% and 10%, respectively. We conclude that 2D echocardiography in dogs permits quantitation of left ventricular stroke volume in normal and ischemic states.