Pitfalls and limitations of M-mode echocardiography

Pitfalls in the echo-Doppler diagnosis of hypertrophic cardiomyopathy

While Doppler echocardiography has become the gold standard for the diagnosis of hypertrophic cardiomyopathy, there are many pitfalls in its use. Some of these pitfalls are technical in nature resulting from inadequate image quality, incorrect transducer angulation, and improper equipment settings. Other pitfalls relate to the diversity and heterogeneity in defining hypertrophic cardiomyopathy and to the host of disorders that may mimic it by echocardiography. The pattern and extent of ventricular hypertrophy, systolic anterior motion of the mitral valve, and Doppler determination of left ventricular outflow tract obstruction, diastolic dysfunction, and mitral regurgitation are discussed, as are wall-motion abnormalities and myocardial echo reflectivity. While these echocardiographic features of hypertrophic cardiomyopathy are nonspecific when seen in isolation, their combined presence in the appropriate clinical setting makes the diagnosis likely.

Echocardiographic recognition of paraseptal structures

Improved echocardiographic equipment provides detailed images of the heart and shows anatomic paraseptal structures previously not well defined. Echocardiograms were analyzed from 33 patients who later underwent cardiac transplantation, and the paraseptal structures noted were correlated with the pathologic specimens. Patterns associated with right ventricular chordae tendineae, the moderator band and the posterior papillary muscle are illustrated. Hypertrophic and fibrotic right ventricular trabeculae and left ventricular paraseptal bands are noted. These structures can be specifically sought and identified using the current generation of echocardiographs, thereby avoiding potential problems of septal definition and measurement.

Echocardiographic recognition and implications of ventricular hypertrophic trabeculations and aberrant bands

The accuracy of two-dimensional echocardiography in the recognition of aberrant ventricular bands and pathologic trabeculations (hypertrophic, fibrotic, or both) was assessed in 35 patients who underwent cardiac transplantation and pathologic examination. At pathologic study the prevalence of specific intracavitary structures ranged from 28% to 43%. Left ventricular thrombi were found in 12 patients (34%) and right ventricular thrombi in three (9%). Echocardiography accurately defined left ventricular aberrant bands and left ventricular thickened or fibrotic trabeculations. Bands, trabeculations, and thrombi each showed characteristic echocardiographic patterns. In the right ventricle, these structures were recognized, but accurate discrimination among them was not possible by echocardiography. Aberrant bands and pathologic trabeculations mimicked or obscured fresh or organized thrombi in three patients on two-dimensional echocardiography. Left ventricular longitudinal bands and pathologic right ventricular trabeculations obscured the interventricular septal border in four patients; the presence of these abnormalities could lead to the erroneous diagnosis of asymmetric septal hypertrophy on M mode echocardiography. By expressing the accuracy of two-dimensional echocardiography in the recognition of left ventricular anomalous bands, our results support the feasibility of prospective studies to clarify their clinical significance.

The relation of age to the thickness of the interventricular septum, the posterior left ventricular wall and their ratio

We obtained echocardiographic measurements of interventricular septal and posterior left ventricular wall thickness in 100 apparently normal subjects in whom there was no evidence or history of coronary artery disease, hypertension or prolapsing mitral valve. Subjects were divided into five age groups of 20-29, 30-39, 40-49, 50-59 and 60-70 years and there were 20 subjects in each group. Measurements of interventricular septum and posterior left ventricular wall thickness were made in each subject at both mitral and sub-mitral levels at the time of Q wave inscription, and the measurements were related to body surface area. The interventricular septum increased from a median of 8.3 mm in the age group 20-29 to 11.2 mm in the group 60-70, whereas the posterior left ventricular wall increased from 7.5 mm to 9.8 mm. The difference in the medians between the groups 20-29 and 60-70 was statistically significant for both interventricular septum and posterior left ventricular wall (P less than 0.02). Our data showed that interventricular septal, posterior left ventricular wall thickness measurements and their ratio should be related to age in order to assess their significance.

Aortic valve systolic flutter as a screening test for severe aortic stenosis

Previous efforts using M-mode echocardiography or 2-dimensional (2-D) echocardiography have not consistently separated patients with and without significant aortic stenosis (AS). We postulated that an aortic valve sufficiently pliant to produce systolic flutter on M-mode echocardiography could exclude significant AS and reviewed the M-mode echocardiograms of 50 consecutive patients (mean age 59 years) catheterized for presumed AS; 2-D echocardiography was also performed in 18 of 50 patients (36%). In 40 of 50 patients (80%) the aortic valve cusps were easily identified on M-mode echocardiography: 19 of 40 (48%) had systolic flutter with a mean aortic valve gradient of 4 +/- 8 mm Hg (mean +/- standard deviation [SD]) and an aortic valve area of 2.8 +/- 0.4 cm2; 21 of 40 (52%) had no systolic flutter with a mean aortic valve gradient of 55 +/- 19 mm Hg and an aortic valve area of 0.7 +/- 0.3 cm2. In the 10 of 50 patients (20%) in whom aortic valve cusps were not clearly identified, the mean aortic valve gradient was 50 +/- 24 mm Hg and the aortic valve area 0.8 +/- 0.4 cm2. Systolic flutter was not seen with an aortic valve gradient greater than 30 mm Hg or an aortic valve area less than 1 cm2. Aortic valve systolic opening by M-mode echocardiography or 2-D echocardiography did not accurately predict the severity of AS. Thus, aortic valve systolic flutter seen on M-mode echocardiography is strong evidence against significant AS, but the absence of systolic flutter does not allow reliable prediction of the severity of AS. The finding of systolic flutter by M-mode echocardiography may be a useful screening test in patients presumed to have AS.

Contrast echocardiography: the descending thoracic aorta and the left atrial posterior wall in neonates

Contrast echocardiographic studies were performed in two neonates. Glucose injections through umbilical arterial catheters demonstrate that the descending thoracic aorta is in close contact with the left atrial posterior wall (LAPW) and with the atrioventricular junction. The recognition of this particular part of LAPW is extremely important since it shows that the ultrasound beam is not in the standard direction. Probably the left atrium cannot so easily expand in that direction. Consequently, the left atrial dimension should not be measured here for the purpose of controlling variations in left atrium dilatation.

Separation of left atrium from right pulmonary artery: a new echocardiographic sign of pericardial effusion

We report a new echocardiographic sign of pericardial effusion in patients with pericardial effusion examined by the suprasternal approach. In normal individuals the right pulmonary artery is closely connected with the superior wall of the left atrium. A separation of these structures is only to be noticed during atrial contraction. In 12 of 17 patients with a pericardial effusion observed a separation of the left atrium from the right pulmonary artery ranging from 3 to 20 mm throughout the cardial cycle. We suggest that this echo-free zone represents fluid in the transverse pericardial sinus which is located between the two structures. In five patients with a small pericardial effusion (less than 400 ml) this observation could not be made.

Two dimensional echocardiographic recognition of the descending thoracic aorta: value in differentiating pericardial from pleural effusions

The course of the descending thoracic aorta has recently been visualized with two dimensional echocardiography and its presence confirmed with contrast studies. In the parasternal short axis view, we used the location of the descending thoracic aorta to differentiate pericardial from pleural effusions in 40 patients. Sixteen patients, each with an isolated pericardial effusion, had an echo-free space between the descending thoracic aorta and left ventricular posterior wall. Nine patients, each with an isolated pleural effusion, had an echo-free space posterior to the descending aorta. Fifteen patients, each with both a pericardial and pleural effusion, had echo-free spaces both between the descending thoracic aorta and left ventricular posterior wall and also posterior to the descending thoracic aorta. With one exception, all patients had anatomic confirmation of these findings. Forty-one patients undergoing cardiac surgery served as controls and none had a posterior echo-free space in relation to the descending thoracic aorta. At operation, no pericardial or pleural effusion was evident. The location of the descending thoracic aorta on two dimensional echocardiography serves as a valuable landmark in localizing the pericardial-pleural interface, thereby differentiating pericardial from pleural effusions.

Left ventricular responses to a program of lower-limb strength training

Nine healthy male subjects ages 18-27 exercised five days per week. Three days per week they performed five repetitions of squats, leg extensions and leg flexions with maximal resistance for a total of 11 sets. On the other two days each week subjects performed five leg presses and 20 calf raises with maximal resistance. Resting echocardiograms and physiologic evaluations were made prior to starting the strength training and again after ten weeks of training. Resting heart rate +/- SEM before and after training was 65 +/- 2 and 58 +/- 1.7 beats/min (P < .001). Maximal O2 uptake did not change significantly. Left ventricular wall thickness +/- SEM before and after training increased from 0.76 +/- .02 to 0.85 +/- 0.04 cm (P < .05). Left ventricular mass +/- SEM increased from 81.9 +/- 5 to 92.3 +/- 3.7 g (P < .05). The percentage of left ventricular fractional shortening +/- SEM increased from 32 percent +/- 1.2 to 36 percent +/- .9 (P < .001). Lower limb strength training in normal subjects did not increase maximal O2 uptake, but did induce increases in left ventricular wall thickness similar to that seen in champion strength-trained athletes. In addition, improvement in left ventricular performance without significant changes in left ventricular volumes was also observed.

Two dimensional echocardiographic recognition of the descending thoracic aorta

Two dimensional echocardiography was used to identify the descending thoracic aorta in 106 subjects. In 12 of these subjects, contrast injection techniques were used to identify this structure as it descended posteriorly adjacent to the atrioventricular groove. The course of the descending thoracic aorta was mapped using both the long axis and transverse axis views. The normal descending thoracic aorta (26 subjects) measured 10 +/- 1.4 mm/m2 during diastole. Unusual M mode echocardiographic patterns of the descending aorta may be confused with other disease states; they are clarified with the two dimensional study. The size and appearance of the descending aorta in different types of cardiovascular disease, including aortic aneurysm, in 80 patients are described. It is anticipated that two dimensional echocardiography will prove to be a useful method of studying patients with aortic disease.

Postpartum cardiac failure--heart failure due to volume overload?

Ventricular function has been studied in 43 patients with the peripartum cardiac failure (PPCF) syndrome which occurs around Zaria. All patients had an echocardiogram on admission and 10 patients had right heart catheterization. Despite the gross edema, left ventricular function assessed by echocardiography and systolic time intervals was relatively good and the estimated cardiac output were high. At catheterization, although the pressures were high, the cardiac outputs were greater than normal in four out of six patients. No patient had a low cardiac output. These findings are not compatible with a severe heart muscle disorder, or cardiomyopathy. We suggest that the primary event in PPCF of Zaria is fluid retention which leads to a form of high output cardiac failure. The postpartum practices in this area (taking high sodium diets and lying on heated beds) almost certainly cause the fluid to accumulate initially, but the heart may be unable to meet the demands either because of preexisting heart muscle disease or, more likely, because of a rise of the peripheral resistance due to the volume expansion, overburdens such dilated hearts and leads to myocardial damage. Since there are similarities between this condition and PPCF in temperate climates, it is possible that there is a common mechanism which the traditional practices of this area have unveiled.

The superiority of mitral E point-ventricular septum separation to other echocardiographic indicators of left ventricular performance

M-mode echocardiography, angiocardiography, and coronary arteriography were done in 40 patients with coronary heart disease, 12 with congestive cardiomyopathy, and 14 with no detectable cardiac or coronary abnormality. We measured mitral E point-ventricular septum separation (EPSS) at the moment of the E peak; the previously described method measures EPSS as the vertical distance between the nadir of systolic septal motion and the subsequent mitral E peak. Angiocardiographic ejection fractions correlated better with EPSS (r = 0.83) than with left ventricular (LV) end-diastolic internal diameter (r = 0.62), LV internal diameter systolic shortening fraction (r = 0.64), LV echocardiographic ejection fraction (r = 0.70), and LV posterior wall systolic thickening (r = 0.58). Patients with angiocardiographic ejection fractions below 55% usually had EPSS values over 10 mm by our method. Six false negatives and one false positive occurred. Our observations in patients with impaired LV performance suggest that LV dilatation, and especially dilatation of the LV outflow tract, is relatively more important than reduction in the amplitude of diastolic anterior mitral excursion in the production of high EPSS values. Although the usual method for measuring EPSS and ours are equally satisfactory, ours has certain theoretical advantages.

Problems in ultrasonic estimates of septal thickness

Problems related to cardiac anatomy and ultrasonic instrumentation affect the accuracy of echographic identification of endocardial echoes. A cadaver model and 13 patients were studied, with direct identification or with the aid of echographic contrast techniques, to identify accurately the endocardial echo. The study showed that (1) echographic contrast agents delineate an endocardial echo in the central portion of the ultransonic beam; (2) a specular reflector exists within the right ventricular cavity; (3) specular reflectors within the septum may give the false appearance of border-forming echoes; (4) septal thickness varies by 1 to 5 mm after the endocardial echo has been identified by the contrast agent; and (5) spurious echoes, related to a wide beam angle, can be confused with the endocardial echo. In light of these problems, three criteria were utilized for endocardial echo identification: the prominent notch in the left septal echo, the specular quality of the right septal echo, and the association of multiple myocardial echoes moving in parallel. With these criteria, the endocardial echoes in 11 of the 13 patients could be accurately identified without the use of a contrast agent. The identification of these problems should provide helpful guidelines in developing more accurate and reproducible criteria for septal thickness measurements.

Cardiovascular nuclear medicine and intensive care

The clinical application of cardiovascular nuclear imaging techniques to intensive care medicine holds great promise for improved non-invasive assessment of the patient. With the development of new radiopharmaceutical agents and better instrument resolution, it is now possible to provide quantitative information concerning myocardial perfusion, acute myocardial ischaemia, left ventricular function, thromboembolic pulmonary disease and analysis of the patient's respiratory function. The patient can be studied during various phases of his disease, with these techniques furnishing objective guidelines of the therapy and prognosis.

Two-dimensional echocardiographic recognition of ruptured chordae tendineae

Real-time, phased-array, two-dimensional echocardiographic studies identified ruptured chordae tendineae in five patients: four patients had a flail mitral valve and one had flail mitral and tricuspid valves. The characteristic abnormality was a rapid systolic motion of the involved leaflet beyond the line of valve closure into the atrium. The maximal abnormal systolic motion was greatest at the tip of the leaflet with a loss of the normal coaptation point. By contrast, the two-dimensional echocardiographic feature of mitral valve prolapse is an abnormal systolic motion that is maximal in the body of the leaflet with intact leaflet coaptation. Thus, two-dimensional echocardiography can identify flail mitral and tricuspid valves and is useful in distinguishing ruptured chorade from valvular prolapse.

Eelectrocardiographic correlates of ultrasonically increased septal, left ventricular posterior wall and left ventricular internal dimensions

The electrocardiograms (ECG) of 64 subjects who exhibited an echocardiographically demonstrable increase in thickness of the interventricular septum and left ventricular posterior wall (Group 1, 22 patients), isolated left ventricular internal dimension (Group 2,26 patients), combined wall thickness and chamber diameter (Group 3, 2 patients), and septal thickness, (Group 4, asymmetric septal hypertrophy, 14 patients) were reviewed in order to determine sensitivity of ECG criteria for the diagnosis of left ventricular hypertrophy (LVH) proposed in 1949 by Sokolow and Lyon (13), in 1968 by Romhilt and Estes (14), and in 1973 the New York Heart Association (15). Relative sensitivity of the three methods was as follows: Total group, NYHA (77%) greater than Sokolow and Lyon (67%) greater than Romhilt and Estes (58%); Group 1, NYHA (91%) greater than Sokolow and Lyon (73%) greater than Romhilt and Estes (54%); Group 2, NYHA and Sokolow and Lyon (65%) greater than Romhilt and Estes (61%); Group 4, NYHA (79%) greater than Sokolow and Lyon (64%) greater than Romhilt and Estes (57%). We conclude that 1)ECG criteria of the NYHA for the diagnosis of LVH correlate best with an increase of ultrasonically determined septal, left ventricular posterior wall or left ventricular internal dimensions when compared with voltage criteria of Sokolow and Lyon and the point score system of Romhilt and Estes; and 2) isolated increase of left ventricular internal dimension, in the absence of thickened septum or posterior left ventricular wall, frequently results in ECG criteria compatible with the diagnosis of LVH.