Arrhythmias - Atrial flutter (Aflutter): Nursing

Atrial flutter, or AF for short, is a type of tachyarrhythmia, where tachy means fast, and arrhythmia means irregular rhythm. So AF is a fast, abnormal heart rhythm that causes poor, inefficient atrial contractions, which can affect the heart’s ability to pump blood. It’s called flutter because of its identifiable recurring, regular, sawtooth-shaped flutter waves that can be seen on an ECG.

Now let’s look at the normal electrical conduction pathway in the heart on an ECG, which shows how the depolarization wave flows through the heart during each heartbeat. The normal electrical activity of the heart starts in the sinoatrial or SA node, which is considered the pacemaker of the heart. Then, the impulse is conducted through the atrium, creating the P wave on an ECG.

And when the atrial muscle cells get depolarized, they contract, pushing blood from the atria into the ventricles.

From the atrium, electrical activity goes to the atrioventricular, or AV node, where the impulse propagation speed slows way down; this is the PR interval on an ECG. This pause allows the atria to contract while the ventricles fill with blood.

From the AV node, the depolarization wave 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, causing them to depolarize.

This triggers simultaneous contraction of both ventricles, pushing blood into the systemic and pulmonary circulations, and it’s represented by the QRS complex on an ECG.

Finally, the ventricles repolarize to prepare for the next cycle, which allows them to relax and fill with blood, called diastole. And on ECG, ventricular repolarization will create a T wave, while the pause between ventricular depolarization and repolarization is represented by the ST segment. Sometimes, immediately after the T wave, there’s a U wave, which represents late repolarization of the ventricles.

Now, the main cause of an atrial flutter is the occurrence of a reentry mechanism, which means an abnormal electrical circuit that forms in the atria, which makes the electrical impulse travel in a loop within the atria, instead of going to the AV node like it normally would.

Risk factors include advanced age; underlying cardiovascular disease like hypertension or cardiac surgery; diabetes; or a history of alcohol abuse, pulmonary embolism or hyperthyroidism. Interestingly, atrial flutter can also occur following the conversion of atrial fibrillation to normal sinus rhythm. In fact clients taking antiarrhythmics for other conditions can also develop atrial flutter.

Now, the pathology of atrial flutter starts with a reentrant loop that can originate in either the right or left atrium. Reentrant signals loop back on themselves, overriding the sinus node and setting up an endless cycle that causes the atria to contract again and again and again—at really fast rates.

There are actually two types of atrial flutter, depending on how this reentrant circuit arises. Type 1, or typical atrial flutter, is more common and is caused by a single reentrant circuit that moves around the annulus, or the ring of the tricuspid valve of the right atrium. See, around this area, there’s a stretch of tissue called the cavotricuspid isthmus, that propagates the signal more slowly than the surrounding tissue. Tissue that was just activated can’t be activated again until a certain amount of time has passed, which is called the refractory period; so that slow propagation gives the tissue enough time to be out of refractory, and therefore the circuit can loop on itself.

Type 2 or atypical atrial flutter is where a re-entrant circuit develops in either the right or left atrium, but the exact location is less clearly defined. Again though we’ve got a similar setup where a wave of activated tissue, or depolarization hits a bit of tissue in such a way that it creates a loop of depolarization that keeps going around and around.

Regardless of type, with atrial flutter, the atria contract inefficiently. This means that the ventricles get less blood from the atria, and they also contract at a lesser rate, which decreases cardiac output. Eventually, the inefficient emptying of the atria into the ventricles can cause the blood to stay in the atria for longer than normal, so it can form atrial clots. So with atrial flutter, there’s a chance that one of these clots can get pumped from the atria into the ventricles, and from there, into the circulation. From there, the clot can get lodged in a cerebral artery, causing a stroke; in a pulmonary artery branch, causing a pulmonary embolism; or in a coronary artery that supplies the myocardial muscle, causing a myocardial infarction.

Clients with atrial flutter may be asymptomatic, but when a client is symptomatic, clinical manifestations include palpitations, fatigue, mild dyspnea, syncope or lightheadedness, tachycardia, and diaphoresis.

Additionally, if a clot leaves the heart and gets lodged in another artery, manifestations depend on the localization. With a stroke, there could be confusion, slurred speech, and unilateral weakness or paralysis of the face or limbs; with a pulmonary embolism, there might be dyspnea and chest pain; and with a myocardial infarction, there could be severe chest pain that radiates, most commonly to the left arm.

The diagnosis of atrial flutter starts with the client's history and physical assessment, followed by cardiac monitoring using an electrocardiogram or a Holter monitor, which is basically a portable ECG that records for a 24-hour period.