Chest pain

Man With Chest Pain and Dyspnea

 

  • Answer: E, inferior MI with the culprit artery being the right coronary artery distal to the right ventricular branch

    DISCUSSION

    Acute MI of the inferior wall results from occlusion of the right coronary artery in 80% of cases or the left circumflex coronary artery in 20%. Patient outcome depends largely on which artery is affected; thus, the presumptive identification of the culprit artery on the basis of the ECG recorded at admission is of clinical importance.1
    ST-segment elevation greater in lead III than in lead II and ST-segment depression of more than 0.5 to 1 mm in leads I and aVL suggest involvement of the right coronary artery rather than the left circumflex artery with a sensitivity of 79%, specificity of 100%, negative predictive value of 88%, and positive predictive value of 100%. The association with ST-segment elevation in lead V1 suggests proximal occlusion (before the right ventricular branch) of the right coronary artery with associated right ventricular infarction.1-6

    If the ST segment is more elevated in lead III than in lead II and a 0.5 mm ST segment elevation is noted in lead I, this will favor the left circumflex artery as the culprit vessel. If the ST segment is isoelectric in lead I, the (∑ ↓ST in leads V1 to V3)/ (∑ ↑ST in leads II, III, and aVF) should be done. A ratio greater than 1 implies that the left circumflex is the culprit vessel. Conversely, a ratio less than 1 indicates that the culprit vessel is likely to be the right coronary artery.1-6

    On the other hand, if the ST-segment elevation in lead II is greater than that in lead III, with an isoelectric or elevated ST segment in lead aVL, the left circumflex artery is likely to be the culprit vessel with a sensitivity of 83%, a specificity of 96%, a negative predictive value of 93%, and a positive predictive value of 91%.1-6

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    HOSPITAL COURSE

    The patient was treated with 50 mg of tenecteplase and started on heparin, intravenous metoprolol, nitroglycerin infusion, and aspirin. After 1 hour, the following ECG shown in Figure 1 was recorded.

    What is the diagnosis?

    A. Ventricular tachycardia with atrioventricular (AV) dissociation
    B. Junctional escape rhythm with complete heart block
    C. Normal sinus rhythm with premature ventricular complexes
    D. Accelerated idioventricular rhythm, with fusion beats and normal sinus rhythm


    Answer: D

    What would be the best therapy for the patient at this time?

    A. Amiodarone, 300 mg IV by rapid infusion, then 0.5 mg/min IV for the next 24 hours
    B. Amiodarone, 15 mg/min IV for 10 minutes (150 mg), then 1 mg/min IV for 6 hours (360 mg),
    then 0.5 mg/min IV for 18 hours (540 mg)
    C. Lidocaine, 50 to 100 mg IV over 2 to 3 minutes (loading dose), 0.02 to 0.05 mg/kg at a rate of 1 to 4 mg/min IV (maintenance)
    D. Continue with the current medical management with the addition of a glycoprotein IIb/IIIa inhibitor and take the patient emergently for a percutaneous coronary intervention
    E. Continue with the current medical management because the thrombolytic therapy was effective


    Answer: E

    The patient’s repeated ECG a few hours later is shown in Figure 2.

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    DISCUSSION

    Accelerated idioventricular rhythm. An accelerated idioventricular rhythm (AIVR), also called “slow VT,” arises below the atrioventricular (AV) node and has a rate between 50 and 100 or 120 beats per minute. It may be the result of sinus pacemaker failure, and therefore be an escape rhythm, or it may represent an abnormal ectopic focus in the ventricle that is accelerated by sympathetic stimulation and circulating catecholamines. The arrhythmia usually begins with a fusion beat. The onset is gradual (nonparoxysmal). It can be regular or irregular and occasionally can show sudden coupling, suggesting the presence of exit block. Additional characteristics of AIVR are listed in the Table.

    idioventricular rhythm

    Several conditions, including myocardial ischemia (especially inferior wall ischemia or infarction), digoxin toxicity, electrolyte imbalance (eg, hypokalemia), and hypoxemia may accentuate the phase-4 depolarization in the subordinate pacemaker tissues of the AV junction or His-Purkinje system, thus increasing the rate of impulse generation. Frequently, when inferior wall ischemia is present, the subordinate pacemaker acceleration coexists with sinus node depression. The latter permits escape and domination of the non-sinus pacemaker function. AIVR occurs in up to 50% of patients with acute MI. Some studies have suggested an association with reperfusion following thrombolytic therapy. However, AIVR is neither a sensitive nor very specific marker for successful reperfusion.7-9

    Fusion beats often develop at the onset and termination of arrhythmia, which occurs when the cardiac pacemaker foci are competing for control of ventricular depolarization. Because of the slow rate, capture beats also are common. As a result of the slow rate and nonparoxysmal onset, precipitation of more rapid ventricular arrhythmias rarely is observed.

    Most episodes are transient and require no treatment. Furthermore, treatment is contraindicated if AIVR is an escape rhythm, since suppression of the pacemaker focus will result in asystole. Rhythm termination generally occurs gradually, while the underlying sinus rhythm accelerates or the AIVR slows down.9

    Capture beats versus fusion beats. If the AV node and the His-Purkinje system are not refractory to atrial impulses, AV conduction can occur. This results in a capture beat whereby ventricular conduction occurs over the normal conduction system, resulting in a normal-appearing (narrow) QRS complex. A capture beat occurs at a shorter RR interval than the RR interval of the AIVR. AV conduction also may occur simultaneously with depolarization of the ventricular focus. In this instance, the ventricle will be depolarized in part over the normal pathway and in part from the ventricular focus. The resulting QRS complex will be intermediate in morphology between a normal QRS and a QRS of ventricular origin. In this instance, the RR interval will not change. This is called a fusion beat (Figure 3).

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    HOSPITAL COURSE

    The patient underwent a left heart catheterization that showed normal left anterior descending and left circumflex vessels, with a long eccentric area of 80% to 90% narrowing in the right coronary artery. This was treated by angioplasty with a drug-eluting stent. His left ventriculogram showed an ejection fraction of 30% to 35% with akinesis of the apex and severe hypokinesis of the basal and inferior walls. The patient tolerated the procedure well and was discharged home in stable condition.

References

1. Fiol M, Cygankiewicz I, Carrillo A, et al. Value of electrocardiographic algorithm based on “ups and downs” of ST in assessment of a culprit artery in evolving inferior wall acute myocardial infarction. Am J Cardiol. 2004;94(6):709-714.
2. Hasdai D, Birnbaum Y, Herz I, et al. ST segment depression in lateral limb leads in inferior wall acute myocardial infarction: implications regarding the
culprit artery and the site of obstruction. Eur Heart J. 1995;16:1549-1553.
3. Herz I, Assali AR, Adler Y, Solodky A, Sclarovsky S. New electrocardiographic criteria for predicting either the right or left circumflex artery as the culprit
coronary artery in inferior wall acute myocardial infarction. Am J Cardiol. 1997;80:1343-1345.
4. Zimetbaum P, Krishnan S, Gold A, Carrozza JP II, Josephson M. Usefulness of ST segment elevation in lead III exceeding that of lead II for identifying
the location of the totally occluded coronary artery in inferior wall myocardial infarction. Am J Cardiol. 1998;81:918-919.
5. Lopez-Sendon J, Coma-Canella I, Alcasena S, Seoane J, Gamallo C. Electrocardiographic findings in acute right ventricular infarction: sensitivity and specificity of electrocardiographic alterations in right precordial leads V4R, V3R, V1, V2, and V3. J Am Coll Cardiol. 1985;6:1273-1279.
6. Bairey CN, Shah K, Lew AS, Hulse S. Electrocardiographic differentiation of occlusion of the left circumflex versus the right coronary artery as a cause of inferior acute myocardial infarction. Am J Cardiol. 1987;60:456-459.
7. Gorgels APM, Vos MA, Letsch IS, et al. Usefulness of the accelerated idioventricular rhythm as a marker for myocardial necrosis and reperfusion during thrombolytic therapy in acute myocardial infarction. Am J Cardiol. 1988;61:231-235.
8. Vaturi M, Birnbaum Y. The use of the electrocardiogram to identify epicardial coronary and tissue reperfusion in acute myocardial infarction.
J Thromb Thrombolysis. 2000;10(2):137-147.
9. Antman EM, Anbe DT, Armstrong PW, et al. ACC/AHA guidelines for the management of patients with ST-elevation myocardial infarction—executive summary: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (Writing Committee to Revise the 1999 Guidelines for the Management of Patients With Acute Myocardial Infarction). Circulation. 2004;110:588-636.