AssessmentsHeart blocks: Pathology review
USMLE® Step 1 style questions USMLE
A 71-year-old man presents to the emergency department with sudden onset chest pain. He was sitting at home watching television when he noticed the pain, characterized as a sharp pressure-like sensation in the left side of his chest. He is having difficulty catching his breath. Medical history is significant for hypertension, COPD, chronic kidney disease, and coronary artery disease. He takes amlodipine, lisinopril, aspirin, salmeterol, and albuterol. His father died from a heart attack at age 50. He smokes one pack of cigarettes per day and drinks occasionally. His temperature is 37.2°C (99°F), pulse is 105/min, respirations are 23/min, blood pressure is 90/60 mmHg, and oxygen saturation is 90% on room air. He appears pale and diaphoretic. Physical exam shows a holosystolic murmur at the left mid sternal border that increases with supine leg raise. Lung examination is normal. An ECG is obtained and shows the following:
Reproduced from: Wikimedia Commons
Which of the following is the most likely cause of this patient’s symptoms?
Mikey is a 22 year old male college student from Vermont who was sent to the emergency department after passing out.
His vital signs show a heart rate of 40 beats per minute and a blood pressure of 90/50. On examination, there is an erythematous circular rash with central clearing.
His friends mention they recently went on a hiking trip. His ECG is as follows.
Natasha is a 60 year old female with chronic hypertension, diabetes, and peripheral vascular disease who comes to the emergency room complaining of sudden-onset, squeezing retrosternal chest pain accompanied by shortness of breath and sweating.
Her ECG is as follows. On laboratory evaluation, her troponin levels are significantly elevated.
Alright, so the normal electrical activity of the heart starts in the sinoatrial or SA node located near the opening of the superior vena cava into the right atrium.
Electrical activity is then conducted through the atrium to the atrioventricular, or AV node, after which it goes through the Bundle of His, then the right and left branches of the Bundle, and finally through the Purkinje fibers which deliver the current to the right and left ventricles.
Now, normally there is delay in conduction at the AV node and the Bundle of His, which gives some time for ventricular filling before the ventricle contracts.
A “heart block”, or AV block, occurs when conduction is delayed for too long at the AV node or the bundle of His. Also, electrical activity may be blocked at the level of the bundle branches, which are called bundle branch blocks.
Okay, on the ECG, the normal delay in the AV node is represented by the PR interval, which is normally less than 5 small boxes, or 200 milliseconds.
There are three main types of AV block.
1st degree AV block is technically not really a block, it’s more of a delay.
Every single atrial impulse eventually makes it to the ventricles.
The high yield concept here is that the only abnormality is a prolonged PR interval, and it’s usually asymptomatic, so it does not require treatment.
2nd degree AV block has two subtypes: Mobitz 1, and Mobitz 2. In Mobitz 1, each atrial impulse encounters a longer and longer delay until one of them does not make it through to the ventricles.
The high yield concept here is that on the ECG, this is reflected as the PR interval getting progressively longer and longer until all of a sudden, the heart drops a beat.
Like Mobitz 1, the heart also drops a beat in Mobitz 2, except this time, conduction through the AV node is all-or-nothing.
Either the atrial impulse goes through with no delay, or it doesn’t at all.
There is no progressive prolongation of the PR interval in Mobitz 2. On the ECG, Mobitz 2 shows a couple of normal PR intervals followed by a dropped beat.
Also, like 1st degree AV block, Mobitz 1 is usually benign and doesn’t require treatment unless it’s causing symptoms.
On the other hand, Mobitz 2 can be dangerous and may result in severe bradycardia and decreased cardiac output.
Therefore it requires treatment with a pacemaker.
Now, Mobitz 2 blocks can sometimes progress to our next type, the dangerous 3rd degree AV block.
In this type, none of the electrical impulses are conducted through the AV node, and that’s why it’s also called complete heart block.
Now remember that all cardiomyocytes are capable of starting their own electrical activity, a property called automaticity.
So in 3rd degree AV block, the ventricles recognize that they’re not getting any impulses, and respond by generating their own electrical rhythm called a ventricular escape rhythm, just to hang on to dear life.
Because the atria and the ventricles each have their own pacemakers, they now contract independent of one another, which is called AV dissociation. This desynchronization of the heart chambers can reduce cardiac output dramatically, leading to syncope or even sudden cardiac death.
On the ECG, the P-waves and QRS complexes have nothing to do with each other, each appearing at their own rates.
The atrial rate is 60 to 100 beats per minute, whereas the ventricular rate usually ranges between 30 to 45 beats per minute.
Because of how dangerous 3rd degree blocks are, anyone diagnosed with it needs a pacemaker.
Alright, a lot of things can cause the 3 types of AV block.
This is especially common in right coronary artery occlusion because it gives off a small branch that supplies the AV node.
On the exam, a clue towards right coronary artery occlusion would be a case of inferior wall myocardial infarction, indicated by elevation of the ST segments in leads II, III and aVF.
Interestingly, congenital heart block is a complication of neonatal lupus, which could also show up on your exam.
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