3 hours of chest pain. Is it STEMI or is it normal (or early repolarization)?
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This ECG looks quite normal, with only moderate ST elevation, upward concavity, good R-wave amplitude. There is no ST depression or T-wave inversion.
But one easily identified characteristic makes the ST elevation unlikely to be from early repolarization: the computerized QTc is 455 milliseconds. In my study of early repolarization (ER) (n=167), only 2 of 167 (2%) cases of ER had a QTc greater than 455ms. The mean QTc was 394ms, compared to 420ms for MI (n=125) from LAD occlusion. Conversely, only 4% of LAD occlusion, vs. 40% of ER, had a QTc less than 380 ms. These clues were not appreciated by the clinicians. A very astute interpreter would not that the T-waves are also too symmetric to be early repol, which should have a steeper downslope than upslope, as demonstrated here:
The clinicians did not appreciate these subtle differences.
The patient continued to have chest pain. 70 minutes later, they repeated the ECG, which is shown here:
These subtle Q-waves were not appreciated, but the clinicians were astute and ordered a stat echocardiogram, which confirmed anterior wall motion abnormality. The patient was taken to the cath lab and had a 100% LAD occlusion.
After reperfusion, the patients baseline ST-T complex was revealed. This is probably what they would have looked like prior to the LAD occlusion:
For those who want some more detail on differentiating ER from MI, see below:
Also useful was the mean (from V2-V4) R-wave amplitude, at a cutoff of 5 mm, with values less than 5 mm likely to represent MI. Interestingly, mean ST elevation (no matter how it was measured) was not as good a differentiator as the mean R-wave amplitude, but if mean R-wave was less than 5 mm OR the mean ST elevation (V2-V4, as measured at the J-point, STEJ) was greater than or equal to 2 mm, then it was very likely to be MI and very unlikely to be ER.
Even better was a formula derived with logistic regression, which also included the QTc :
(1.196 x STE60 in V3 in mm) + (0.059 x computerized QTc in milliseconds) - (0.326 x RA in V4 in mm), where RA is R-wave amplitude and STE60 is ST elevation at 60ms after the J-point relative to the PR interval.
If the value of the formula is greater than or equal to 23.4, it is MI (Sens, spec, accuracy all around 90%); if less, then it's ER.
For the first ECG, STE60, V3 = 2.5mm, QTc = 455, and RA V4 = 17, so: (1.196 x 2.5) + (0.059 x 455) - ( 0.326 x 17) = 24.29; this is barely greater than 23.4, thus consistent with MI but also further illustrating that this ECG is very difficult.
Read Answer Below
This ECG looks quite normal, with only moderate ST elevation, upward concavity, good R-wave amplitude. There is no ST depression or T-wave inversion.
But one easily identified characteristic makes the ST elevation unlikely to be from early repolarization: the computerized QTc is 455 milliseconds. In my study of early repolarization (ER) (n=167), only 2 of 167 (2%) cases of ER had a QTc greater than 455ms. The mean QTc was 394ms, compared to 420ms for MI (n=125) from LAD occlusion. Conversely, only 4% of LAD occlusion, vs. 40% of ER, had a QTc less than 380 ms. These clues were not appreciated by the clinicians. A very astute interpreter would not that the T-waves are also too symmetric to be early repol, which should have a steeper downslope than upslope, as demonstrated here:
The clinicians did not appreciate these subtle differences.
The patient continued to have chest pain. 70 minutes later, they repeated the ECG, which is shown here:
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After reperfusion, the patients baseline ST-T complex was revealed. This is probably what they would have looked like prior to the LAD occlusion:
For those who want some more detail on differentiating ER from MI, see below:
Also useful was the mean (from V2-V4) R-wave amplitude, at a cutoff of 5 mm, with values less than 5 mm likely to represent MI. Interestingly, mean ST elevation (no matter how it was measured) was not as good a differentiator as the mean R-wave amplitude, but if mean R-wave was less than 5 mm OR the mean ST elevation (V2-V4, as measured at the J-point, STEJ) was greater than or equal to 2 mm, then it was very likely to be MI and very unlikely to be ER.
Even better was a formula derived with logistic regression, which also included the QTc :
(1.196 x STE60 in V3 in mm) + (0.059 x computerized QTc in milliseconds) - (0.326 x RA in V4 in mm), where RA is R-wave amplitude and STE60 is ST elevation at 60ms after the J-point relative to the PR interval.
If the value of the formula is greater than or equal to 23.4, it is MI (Sens, spec, accuracy all around 90%); if less, then it's ER.
For the first ECG, STE60, V3 = 2.5mm, QTc = 455, and RA V4 = 17, so: (1.196 x 2.5) + (0.059 x 455) - ( 0.326 x 17) = 24.29; this is barely greater than 23.4, thus consistent with MI but also further illustrating that this ECG is very difficult.
