Monday, July 9, 2012

ECG Interpretation Review #48 (Chest Pain - STEMI - 1st Degree - 2nd Degree AV Block - Infero-lateral - 2-to-1 - Wraparound)

The 12-lead ECG shown in Figure 1 was obtained from 50-year-old woman with “chest tightness”.
  • What two major conclusions should be reached regarding ECG interpretation of this tracing? 
Figure 1 – 12-lead ECG from a 50-year-old woman with chest tightness. (Reproduced from ECG-2014-ePub). – NOTE – Enlarge by clicking on Figures – Right-Click to open in a separate window.
INTERPRETATION: The two conclusions to be reached are: i) that there is a large acute evolving STEMI (ST-Elevation-Myocardial Infarction) in progress; and ii) there is 2nd degree AV block. It may be easiest to first interpret the changes of acute MI:
  • The QRS complex is narrow.
  • The axis is normal.
  • There is no chamber enlargement.
  • Q Waves/R Wave Progression: Q waves are present in each of the inferior leads (II,III,aVF). After a small (but definitely present) initial r wave in lead V1 – there is loss-of-R-wave – with a probable QS in V2 and a definite QS (with notch in downslope of S wave) by lead V3. Abnormal Q waves persist in leads V4-thru-V6.
  • ST-T Wave Changes: There is marked ST elevation in each of the inferior leads. In addition – there is ST segment coving and elevation that appears to begin in lead V2, and persist through to lead V6. T wave inversion (sometimes marked) is seen in each of the leads with ST elevation.
  • Reciprocal Changes – are seen in leads I and aVL. These reciprocal changes entail not only ST depression in lead aVL – but also T wave peaking (which is the “mirror-image” of the deep inferior symmetric T wave inversion).
-------------------------------------------------------
WHAT IS THE RHYTHM in FIGURE 1?
An extra P wave appears to be hiding in the tail portion of each QRS complex on this tracing (Figure 2). This extra P wave is most evident in lead II (RED arrows in Figure 2) – but it is also seen in other leads (BLUE arrows).
  • The underlying atrial rhythm is rapid (~140/minute) and regular.
  • The PR interval preceding each QRS complex is fixed (albeit prolonged to 0.26 second). Thus, every-other-P-wave is conducting – and the rhythm is 2nd degree AV block with 2:1 AV conduction.
Figure 2 – Addition of red and blue arrows to Figure 1 – revealing 2:1 AV conduction in the underlying rhythm (See text).
-------------------------------------------------------
IMPRESSION:  The ECG in Figure 1 suggests a large acutely evolving STEMI involving inferior, anterior and lateral precordial lead areas. Large Q waves have already developed in anterior leads (loss or r between V1-to-V2 – and QS in V2,V3). ST segment coving and elevation persists in these anterior lead areas – though ST elevation is not as marked as it is in inferior leads.
  • Whether the extensive pattern of injury seen indicates acute occlusion of a large dominant circumflex artery vs an LAD (Left Anterior Descending) artery with “wraparound” (an LAD that also supplies the inferior wall) vs some combination of lesions (perhaps with collateralization affecting distribution) – is uncertain. What is certain – is that an extremely large infarction with AV block is acutely evolving.
We define the type of AV conduction disturbance seen in Figures 1,2 as 2nd degree AV block with 2:1 AV conduction:
  • In theory – the conduction disturbance could be either Mobitz I (AV Wenckebach) or Mobitz II AV block. The reason we cannot absolutely distinguish between these two possibilities is that one never sees two beats conducted in a row (so that we can’t tell IF the PR interval would lengthen if it did have an opportunity to do so).
  • That said – we strongly suspect the conduction disturbance represents 2nd degree AV block, Mobitz Type I (Wenckebach) – because: i) Mobitz I is far more common than Mobitz II – especially in the setting of acute inferior MI when there is also 1st degree AV block for conducting beats; and  ii) the QRS complex is narrow (as it almost always is with Mobitz I – vs QRS widening that is usually seen with Mobitz II).
  • PEARL: It would be easy to overlook 2:1 AV block in this tracing. Awareness that various forms of AV Wenckebach commonly occur with acute inferior MI should increase your index of suspicion that this conduction disturbance may be “in hiding” whenever ST segment elevation is marked – and you either see: i) a pattern of grouped beating; or ii) a longer-than-expected PR interval preceding those beats that are conducting (as seen here). Use of calipers may prove invaluable for confirming your suspicion.
BOTTOM LINE: Acute reperfusion is urgently needed for this patient.
---------------------------------------------------- 

NOTE: - Relevant PDFs on ECG features in this case
---------------------------------------------------- 

Thursday, July 5, 2012

ECG Interpretation Review #47 (Normal Variants - Early Repolarization - Benign - ST Elevation - Pericarditis - ERP - STEMI)

The 12-lead ECG shown in Figure 1 was obtained from 50-year-old man with chest discomfort.
  • Is this ECG likely to reflect acute anterior STEMI?acute pericarditis? – or ERP (Early Repolarization Pattern) without acute process?
Figure 1 – 12-lead ECG from a 50-year-old man with chest discomfort. (Reproduced from ECG-2014-ePub). – NOTE – Enlarge by clicking on Figures – Right-Click to open in a separate window.
INTERPRETATION: Using our systematic sequential approach (rate-rhythm-intervals-axis-hypertrophy-QRST changes) – We interpret the 12-lead ECG in Figure 1 as follows:
  • The QRS complex is narrow.
  • There is slight but definite variability in the R-R interval throughout the tracing. The rhythm is sinus arrhythmia.
  • All intervals (PR,QRS,QT) are normal; the axis is normal (approximately +70 degrees).
  • There is voltage for LVH (deepest S in V1,2 + tallest R in V5,6 35). No other sign of chamber enlargement.
  • Q-R-S-T Changes: There are small q waves in the inferior and lateral precordial leads.  R wave progression is normal (ie, transition occurs between leads V3-to-V4 ).  T waves are peaked.  There is some J-point ST segment elevation (with upward concavity = "smiley" configuration) in multiple leads - and there is shallow symmetric T wave inversion in lead aVL.
-------------------------------------------------------
IMPRESSION: There is some baseline artifact (seen most in leads I, II, III, aVL . . . - albeit not enough to impede our interpretation). Sinus arrhythmia. Voltage for LVH. Shallow T wave inversion in lead aVL – plus – 1-2mm of J-point ST segment elevation with upward concavity in a number of leads … STOP! ...
  • Interpretation of the ECG in Figure 1 beyond the “STOP” depends greatly on the clinical setting.
  • IF this ECG was obtained from an otherwise healthy young adult without cardiac symptoms – we would interpret the isolated shallow T inversion in lead aVL as normal given the relatively vertical QRS axis and predominantly negative QRS complex in this lead (See Figure 2 below).
  • Similarly – We would interpret the slight (but real) upward concavity (“smiley”) precordial ST elevation as consistent with ERP (See Figure 3 below).
HOWEVER – The situation in this case is different – because the patient whose ECG is shown in Figure 1 is 50 years old and IS having chest discomfort ...
  • Consideration therefore HAS to be given to the possibility that the precordial lead ST elevation seen could represent an early stage of acute anterior STEMI (ST Elevation Myocardial Infarction) – especially given the T wave inversion in lead aVL.
----------------------------------------------------
NOTE: We complete our interpretation of this case (and the ECG in Figure 1) at the bottom of this Blog post. Before doing so – we address a number of key concepts relating to clinical assessment of anterior lead ST elevation.
----------------------------------------------------
Normal T Wave Inversion:
Five leads (III,aVF,aVL,aVR,V1) – may normally display moderate-to-large Q waves and/or T wave inversion in otherwise healthy adults. Thinking of a “reverse Z” (à la Zorro) may help recall which leads these are (Figure 2):
  • While we cannot rule out the possibility that the shallow T wave inversion in lead aVL of Figure 1 reflects ischemia – this T inversion is much more likely to be normal in this patient because: i) T wave inversion is isolated (it is only seen in lead aVL); ii) T inversion is shallow; iii) the QRS complex in aVL is predominantly negative in this patient with a relatively vertical QRS axis (conditions that predispose to the normal finding of some T inversion in aVL); and iv) no acute change is seen in other limb leads.
Figure 2 – Schematic tracing showing those leads that may normally manifest even large Q waves or deep T wave inversion (leads III,aVF,aVL,aVR,V1). Thinking of a “reverse Z” may facilitate recall (Figure reproduced from ECG-2014-ePub).
----------------------------------------------------
ST Segment SHAPE:
The shape of ST elevation is more important than the amount of elevation (Figure 3). Acute MI may occur with only minimal ST elevation:
  • ST elevation with an upward concavity (ie, smiley configuration) is usually benign – especially when seen in an otherwise healthy, asymptomatic individual (especially when seen with notching or slurring of the J point in one or more leads). This ST segment variant is known as ERP (Early Repolarization Pattern).
  • In contrast – ST elevation with coving or a downward convexity (frowny ) – is much more likely to be due to acute injury (from ischemia/MI).
  • KEY POINT: History is ever important. Although ST elevation with a “smiley” configuration and J-point notching often reflects a normal variant – this is only true IF the patient is asymptomatic. An identical ST-T wave pattern from a patient with chest pain must be assumed acute until proven otherwise.
  • IF in doubt – Admit the patient! Look at old tracings to compare. Repeat the ECG.
Figure 3 – Schematic showing upward concavity (smiley ) ST elevation that is usually benign – especially when J-point notching is seen in one or more leads. In contrast – ST segment coving (frowny ) – is much more likely to be due to acute injury/infarction (Figure reproduced from ECG-2014-ePub).
----------------------------------------------------
Are ST Segments Truly Elevated in Figure 1? 
ST segment elevation in Figure 1 is subtle but real (Figure 4):
  • We judge ST segment deviations with respect to the PR segment baseline. In Figure 4 – the blowup of leads V1,V2 shows the J-point to be clearly elevated above the PR segment baseline. We estimate 1-2mm of upward concavity ST elevation in lead V2 (although we admit that subtle rounding of the J-point area in this lead makes precise determination of the amount of ST elevation difficult).
Figure 4 – Second look at the ECG shown in Figure 1 from this 50 year-old man with chest discomfort. Blowup of leads V1,V2 illustrates subtle but real upward concavity ST elevation above the PR segment baseline (See text).
----------------------------------------------------
Putting It All Together:
As stated earlier – the ECG in Figure 1 shows sinus arrhythmia; voltage for LVH; shallow T wave inversion in lead aVLplus – 1-2mm of J-point ST segment elevation with upward concavity in a number of leads … Our impression is probable ERP (and not anterior STEMI or pericarditis) because:
  • ST elevation manifests and upward concavity (“smiley” ) configuration (albeit no J-point notching is seen).
  • ST elevation is seen (at least in small amount) in all precordial leads. IF acute anterior STEMI was evolving – one would expect additional ST-T wave abnormality elsewhere on this tracing given the extent of ST elevation.
  • The shallow T wave inversion in lead aVL is isolated and probably normal given the patient’s relatively vertical QRS axis and predominantly negative QRS in lead aVL.
  • The q waves seen on this tracing are small and narrow. They most probably are normal septal q waves (which are typically seen in lateral leads and sometimes also in inferior leads in patients with a vertical axis).
  • The ECG picture in Figure 1 is not suggestive of acute pericarditis (it lacks sinus tachycardia; ST elevation is absent in the limb leads; there is no PR depression).
We conclude our interpretation of the ECG in Figure 1 with the statement: Urge clinical correlation. The point to emphasize is that although we would be relatively comfortable that the ECG shown in Figure 1 is unlikely to represent early acute anterior STEMI – We can not rule out this possibility on the basis of this single tracing! How to proceed with only a ~90% comfort level that the ECG in Figure 1 is benign would depend:
  • IF this patient presented to the office with a history of chest discomfort that was relatively unconvincing for ischemic pain – we would probably manage the case on an ambulatory basis. We would be that much more inclined to do so IF history and physical exam suggested a non-cardiac cause (peptic ulcer disease; musculoskeletal chest pain, etc.).
  • Access to a prior ECG on this patient might prove invaluable (especially if it confirmed baseline anterior ST elevation and T wave inversion in aVL of similar nature to that seen in Figure 1).
  • On the other hand – IF this 50-year-old man presented to the ED (Emergency Department) with new-onset chest discomfort (and no prior tracing available) – he would almost certainly be admitted to the hospital. One simply can’t rule out the possibility of early anterior STEMI on the basis of this single tracing… (In our experience – such patients with new-onset chest discomfort are not sent home from the ED).
----------------------------------------------------
Should the Cath Lab Be Activated?
Taking the 2nd scenario presented above (ie, that this 50-year-old man presented to the ED with the ECG in Figure 1 and a history of new-onset chest discomfort) – the question arises as to whether the cath lab should be activated for possible acute reperfusion on the basis of this tracing? IF Figure 1 in fact represents an early stage of anterior STEMI – then prompt reperfusion becomes a critical determinant of optimal prognosis.
  • At what point to activate the cath lab is difficult to say from the comfort of our home computer as we view this tracing …. Sometimes – “Ya just gotta be there …”. That said – We most probably would not activate the cath lab on the basis of what we see in Figure 1.
  • Access to a prior ECG on this patient might be revealing (if a prior tracing can be found…).
  • Repeating the ECG in short order may establish the diagnosis. With acute evolving infarction – significant change may be evident on ECG in as little as 20-to-30 minutes.
  • STAT troponin values may confirm acute infarction (though even high-sensitivity troponins would not rule this possibility out if they were normal).
  • IF still in doubt after reexamining the patient and the above series of steps – Consider consulting the Cardiologist-On-Call to assist in the decision-making process. There are times when acute cath may be performed even without definitive diagnosis – although in this case, careful observation with close serial follow-up will almost certainly tell the tale over the next few hours. But at least the cardiologist is aware in the event a surprise occurs and the ECG evolves ...
----------------------------------------------------
FINAL Thoughts: Is there Help in the Literature?
Smith et al have developed a multivariate equation to assist in acute evaluation of the patient with anterior ST elevation (Ann Emerg Med 60:45, 2012). Findings from their retrospective analysis of a large data set are insightful in this case – and further support our suspicion that the ECG in Figure 1 is most probably benign. These include relatively taller R wave amplitude and a QT interval that is not prolonged in Figure 1. That said – overlap exists in the parameters used in the calculated Smith equation, such that we are still left with being unable to exclude an acute process on the basis of the number score reported.  – END OF CASE 
----------------------------------------------------

Please click on the icon below for a pdf Link to Section 09.0 (from our ECG-2014-ePub) on assessment of ST-T waves. The part on Early Repolarization begins in Section 09.14 in this pdf:


----------------------------------------------------