Lack of specificity of new negative U waves for anterior myocardial ischemia as evidenced by intracoronary electrogram during balloon angioplasty

Early/Subtle Electrocardiography Features of Acute Coronary Syndrome and ST-Segment Elevation Myocardial Infarction

Chest pain is one of the most common presenting complaints in the emergency department. Interpreting a 12-lead electrocardiography (ECG) for evidence of ischemia is always challenging. Frank ECG changes such as ST-segment elevation and ST-segment depression can be easily identified by emergency physicians. However, identifying subtle or early features of ACS in the 12-lead ECG is essential in preventing significant mortality and morbidity from ACS. In the following case series, we describe five of the subtle/early ECG changes of ACS, namely (1) T-wave inversion in lead aVL; (2) terminal QRS distortion; (3) hyperacute T-waves; (4) negative U-waves in precordial leads; and (5) loss of precordial T-wave balance. In all these cases, the initial 12-lead ECG showed only subtle/early ECG changes which were followed up with serial ECGs which progressed to STEMI.

Mechanisms of abnormal Q waves in hypertrophic cardiomyopathy assessed by intracoronary electrocardiography

INTRODUCTION

To clarify the mechanisms of abnormal Q waves in hypertrophic cardiomyopathy (HCM), local epicardial electrical activities were assessed by intracoronary electrocardiography (ECG).

METHODS AND RESULTS

Unipolar intracoronary ECG was recorded by introducing a guide wire for angioplasty into the left anterior descending artery (LAD) in 20 patients with HCM and 10 control subjects. Intracoronary ECG showed no Q waves in any control subjects. Intracoronary ECG showed no Q waves in 8 HCM patients without abnormal Q waves on surface ECG. In 12 HCM patients with abnormal Q waves on surface ECG, 4 showed Q waves on intracoronary ECG associated with regional wall-motion abnormalities, suggesting Q waves are formed by loss of electrical forces due to transmural myocardial fibrosis. The remaining 8 patients, who did not have Q waves on intracoronary ECG, showed greater thickening of the basal free wall than the apical free wall, with no wall-motion abnormalities. Intracoronary ECG was characterized by increased R or R' waves and prolonged R peak times at the proximal LAD, suggesting Q waves are formed by increased electrical forces of hypertrophied basal septal and/or ventricular free wall, unopposed by apical forces.

CONCLUSION

The study findings provide evidence for two mechanisms of abnormal Q waves in HCM: (1) loss of electrical forces due to transmural myocardial fibrosis, and (2) altered direction of resultant initial QRS vector due to increased electrical forces of disproportionate hypertrophy of the basal septal and/or ventricular free wall, unopposed by apical forces.

The negative U wave: a pathogenetic enigma but a useful, often overlooked bedside diagnostic and prognostic clue in ischemic heart disease

The pathogenesis of U-wave inversion and its clinical value are still not clear, although the U wave was described by Einthoven together with the other electrocardiographic (ECG) waves. Not considered a useful diagnostic clue, it is not usually mentioned in ECG reports. In recent years, stimulated by the long QT syndromes and by the discovery of U-wave changes in some pathologic, mostly cardiac states, this neglected wave has attracted new interest. This review focuses on the negativity of the U wave in ischemic heart disease. The discovery of M cells and their electrophysiology has established the cellular basis for repolarization and has contributed to our knowledge of U-wave genesis. Hemodynamic changes during diastole in acute ischemia also furnish interesting elements for the interpretation of U-wave changes, and some experimental and clinical studies, besides designating stretch as a cause of U-wave changes, have also proved their value for more accurate bedside diagnosis and prognosis. They may indicate the extent of myocardial ischemia, the presence of collateral circulation, and the possible territory and vessel involved. When U-wave changes are the first and only sign of ischemia, they may contribute to a decision regarding the hospital admission of a patient without typical ischemic symptoms. Furthermore, U-wave changes during exercise tests increase their sensitivity.

Occurrence of transient U-wave inversion during vasospastic anginal attack is not related to the direction of concurrent ST-segment shift

STUDY OBJECTIVES

We sought to assess the incidence of transient U-wave inversion during vasospasm of the left anterior descending coronary artery (LAD) with ST-segment depression as opposed to that with ST-segment elevation.

DESIGN

Retrospective study.

SETTING

Cardiology division of acute-care hospitals.

PATIENTS

We studied 49 patients with vasospastic angina whose vasospasm was induced in the LAD, not in the left circumflex coronary artery, by intracoronary injection of acetylcholine.

MEASUREMENTS AND RESULTS

The ECG traces obtained during acetylcholine-induced vasospasm of the LAD were examined. Based on the direction of ST-segment shift, the patients were categorized into two groups: the ST-segment elevation group (n = 27) and the depression group (n = 22). There were no differences in age, gender, or cardiovascular risk factors between the two groups. The distribution of the spastic site in the LAD was also similar. A total reduction in luminal diameter during a provoked attack was more often observed in the ST-segment elevation group than in the ST-segment depression group (37% vs 9%, p = 0.02). Collateral circulation to the LAD was found in only one patient in each group. There were no differences between the two groups in heart rate, systolic BP, and double product of heart rate and systolic BP during the attack. The incidence of acetylcholine-induced anginal attack with U-wave inversion in the ST-segment depression group was nearly as high as that in the ST-segment elevation group (77% vs 78%, p > 0.99).

CONCLUSIONS

The development of transient U-wave inversion during vasospasm of the LAD induced by intracoronary injection of acetylcholine does not depend on the magnitude of myocardial ischemia as judged by the direction of ST-segment shift.

Use of intracoronary electrocardiography for detecting ST-T, QTc, and U wave changes during coronary balloon angioplasty

Intracoronary electrocardiography (IC-ECG) is a more sensitive method than surface ECG to detect electrical changes during percutaneous transluminal coronary angioplasty (PTCA). It also provides direct monitoring of ST-T segment, QTc intervals, and U-wave genesis during balloon inflation. These changes are reflective of myocardial ischemia. The authors studied the effect of transient myocardial ischemia on ST-T segment, QTc intervals, and U-wave appearance by comparing standard and perfusion balloon angioplasty. PTCA of left anterior descending artery was performed in 14 patients using the standard balloons and in 11 patients using the perfusion balloons. Patients with perfusion balloon angioplasty had less ST-T elevation (0.15 +/- 0.05 mV versus 1.04 +/- 0.19 mV, P < 0.001), less QTc-shortening intervals (0.01 +/- 0.02 seconds versus -0.05 +/- 0.04 seconds, P < 0.001), and less positive U waves (two versus nine). The authors concluded that balloon angioplasty with perfusion balloons is associated with less ischemia as reflected by ST-T, QTc-shortening intervals, and U-wave changes. There was more positive U-wave appearance with the standard balloon angioplasty, which implies more ischemia. In addition, QTc-shortening intervals are associated with the development of U waves during standard balloon angioplasty. These findings suggest that IC-ECG is a sensitive tool in detecting myocardial ischemia. IC-ECG may also help to clarify the nature of chest pain during PTCA in some patients. Like QT dispersion (QTd), QTc-shortening intervals and new U waves can have prognostic implications and additional studies are needed to define this role.

Transient U wave inversion during treadmill exercise testing in patients with left anterior descending coronary artery disease

The transient U wave inversion during exercise is specific for detecting left anterior descending coronary artery (LAD) disease. In a homogeneous patient group restricted to LAD disease, however, the significance of the electrocardiographic finding has not yet been clarified. Thus, clinical characteristics in patients with angiographically documented one-vessel disease of the LAD and exercise-induced U wave inversion were delineated. Symptom-limited treadmill exercise testing was performed in 60 patients (43 men, 17 women; mean age 64 +/- 8 years) with angina pectoris whose culprit lesion was located only in the LAD. U wave polarity and amplitude were determined before, during, and after exercise with the P-Q segment as the isoelectric line. Exercise-induced transient U wave inversion was defined as positive when there was a discrete negative deflection > or = 0.05 mV within the T-P segment. Of all patients, 16 (27%) had exercise-induced U wave inversion. There were no differences in age, male gender, antianginal medication use, and coronary angiographic data between the two patients groups: patients with and without U wave inversion. Heart rate and double product of heart rate and systemic systolic blood pressure at peak exercise were also similar. Prevalence of abnormal exercise-induced S-T segment shift was 94% (15 of 16 patients) and 61% (27 of 44 patients) of patients with and without U wave inversion, respectively. The difference was statistically significant (p = 0.02). Among patients with exercise-induced S-T segment shift, the proportion of patients with S-T segment elevation to all the patients was larger in patients with U wave inversion than in patients without U wave inversion [3 (20%) of 15 patients vs 0 (0%) of 27 patients, p = 0.03)]. In conclusion, the exercise-induced U wave inversion in patients with one-vessel disease of the LAD indicates the severe degree of myocardial ischemia induced in the territory perfused by the LAD. However, the electrocardiographic finding does not appear to have independent significance since it closely correlates with the presence of S-T segment shift.

Associations between different status of myocardial ischemia and ischemia-related negative or positive epicardial U-waves: observations during coronary angioplasty

This study examined the relationships between the polarity of the U wave on intracoronary electrocardiogram (ECG) and the status of myocardial ischemia during angioplasty. The ECG features of ischemia-related U waves were also evaluated. Among 63 patients with intracoronary ECGs adequate for analysis of U waves, there were 26 patients showing a change of the U wave to a negative direction and 18 patients showing a change to a positive direction from baseline to coronary occlusion. Among these patients, 10 of the former showed a distinct change in polarity of the U wave from positive to negative (group A), and 7 of the latter patients showed the opposite change (group B). Patients in group B had a higher incidence of prior myocardial infarction (86% vs 30%; P < .05), presence of an abnormal Q wave on intracoronary ECG (71% vs 20%; P < .05), poor wall motion in the angioplasty-related area (100% vs 30%; P < .01), and lower left ventricular ejection fraction (55.7% +/-8.1% vs 66.6% +/- 4.5%; P < .01) than patients in group A. The remaining patients (other than groups A and B) showing U wave change in a negative (n = 16) or positive (n = 11) direction presented with similar features to those in groups A or B, respectively. The ECG features of several types of ischemia-related U wave were determined by analysis of intracoronary ECG obtained from the patients in groups A and B. In group A, the Bazett-corrected Q (positive U) interval measured at baseline (myocardial state; near normal) was significantly shorter than the Q-(negative U) interval measured during coronary occlusion (acute ischemia) (0.518 +/- 0.031 s vs 0.579 +/- 0.046 s; P < .01). In group B, the Q-(negative U) interval measured at baseline (chronic ischemia) was longer than the Q-(positive U) interval measured during angioplasty (acute-on-chronic ischemia) (0.582 +/- 0.034 s vs 0.501 +/- 0.027 s; P < .001). Thus, intracoronary ECG recorded during angioplasty in the present study revealed physiologic U wave, two types ("acute" and "chronic") of ischemia-related negative and one type ("pseudonormal") of ischemia-related positive U waves, each of which appeared in a different status of myocardial ischemia and possessed characteristic ECG features in its appearance.

Reflection of epicardial U-wave changes in surface inferior electrocardiograms during inferoposterior or anterior wall myocardial ischemia

The surface inferior electrocardiogram (ECG) has limited value for detecting frequently occurring epicardial U-wave changes over the ischemic inferoposterior wall. Reciprocal U-wave changes could occur in this ECG during anterior wall myocardial ischemia.

How epicardial U-wave changes are reflected in body surface precordial electrocardiograms in anterior or inferoposterior myocardial ischaemia during coronary angioplasty

OBJECTIVES

To examine the epicardial U-wave changes recorded in intracoronary electrocardiograms (ECGs) during anterior or inferoposterior myocardial ischaemia and the corresponding changes in precordial ECGs recorded from the body surface in humans.

METHODS

40 patients undergoing coronary angioplasty of the left anterior descending (LAD) coronary artery (22 patients) or left circumflex (LC) artery (18 patients). Intracoronary and surface precordial ECGs were simultaneously recorded under baseline conditions and during angioplasty.

RESULTS

Four different patterns of U-wave change were identified on the intracoronary ECG: change to positivity, no change, change to negativity, and biphasic change. The incidence of each pattern was similar in the two groups (LAD v LC groups, 23% v 39%; 23% v 17%; 41% v 44%; 13% v 0%, respectively). The intracoronary ECG was more sensitive than the surface ECG for detecting U-wave changes (intracoronary v surface ECG: LAD group, 77% v 55%; LC group, 83% v 28%). A study of the correlation between intracoronary and surface precordial ECGs showed that in patients who had U-wave changes in their intracoronary ECG (17 LAD and 15 LC patients) 65% of the LAD group but only 6% of the LC group had primary U-wave changes in the surface precordial ECG, and that 27% of the LC patients had reciprocal U-wave changes in the right to central precordial ECG.

CONCLUSIONS

These results provide fundamental information for an understanding of the correlation between U-wave changes in the epicardial and surface pre-cordial ECGs during myocardial ischaemia in humans. As well as the primary U-wave changes seen in many of those with anterior myocardial ischaemia, some of those with posterior myocardial ischaemia had reciprocal U-wave changes in their surface precordial ECGs.

QRS alterations in body surface potential distributions during percutaneous transluminal coronary angioplasty in single-vessel disease

Body surface QRS potentials were recorded with 63 chest leads in 20 patients with proximal single-vessel disease located on either the left anterior descending coronary artery (n = 10), the right coronary artery (n = 6), or the left circumflex coronary artery (n = 4) before, during, and after percutaneous transluminal coronary angioplasty. In each case, three consecutive inflations of relatively short duration (37 +/- 14 seconds) were carried out. Electrical activity was displayed as unipolar electrograms and body surface potential maps. The total QRS complex duration decreased in 14 of the 20 patients. Focal conduction disturbances were observed in six cases; all six had left anterior descending coronary artery occlusion and two were also accompanied by a clear shortening of the right epicardial breakthrough time. In these two cases, an initial activation loss seemed to be characteristic, whereas in the other four cases, a rather diffuse slowing of intraventricular conduction, especially during the terminal portion of the QRS, could be observed. Individual and group mean isointegral difference body surface potential maps (during-minus-before dilation) were considered valuable for the interpretation of localized changes in intraventricular conduction during percutaneous transluminal coronary angioplasty, and their individual variations could, at least partly, be explained by the presence or absence of collateral circulation. Two different hypotheses are suggested to account for the QRS complex shortening observed during short-term myocardial ischemic injury: (1) coronary artery occlusion delayed activation of the portion of the septal region that is normally activated early during the QRS, and/or (2) coronary artery occlusion increased the speed of propagation within the ventricles. Both of these hypotheses are discussed in light of earlier clinical and experimental results.