Every time the heart squeezes it requires an electrical impulse. The impulse originates from an area in the top right corner of the heart known as the sinus node. Electricity then spreads across the upper two chambers of the heart. It travels to the lower two chambers through a specialized conducting pathway known as the atrioventricular (AV) node. Normally the only way for electricity to travel from the upper to the lower chambers is through the AV node.
A small percentage of people, about 1 in 1000, have extra conducting tissue from the top to the bottom chambers. This extra conducting tissue is termed an “accessory pathway.” The majority of the time the accessory pathway does not conduct electricity. However, if circumstances are just right, it is possible for electricity to travel down the normal pathway through the AV node and then immediately travel back up the accessory pathway. Subsequently, an electrical circuit can be established between the AV node and the accessory pathway. When electricity enters this circuit, supraventricular tachycardia (SVT) results. This is almost always a sudden event, which explains why the onset of SVT is usually sudden and random in most patients.
The heart rate with SVT varies based on a number of factors. Generally it is faster in younger children. In newborns and young infants it can be 250 to 300 beats per minute. In older patients it is usually less than 250 and may be in the range of 180 to 200 in teenagers. In general, the faster the heart rate, the worse the individual tends to feel. Fortunately, SVT is very rarely life-threatening. Most individuals complain of their heart racing but little else. Occasionally they may feel dizzy or lightheaded. It is fairly unusual for SVT to cause an individual to pass out. Episodes of SVT can last anywhere from a few seconds to days at a time. Children beyond the toddler age can generally verbalize that something is not right in the heart which leads to medical attention. Occasionally in infants, SVT can go unnoticed for days and result in symptoms of heart failure.
The definitive diagnosis of SVT is made by a recording of the heart rhythm when an individual is having symptoms. Usually this is done by what is termed an event monitor. An event monitor is a small monitor which records a patient's heart rhythm for review by the doctor. An event monitor can be taken anywhere, even to school.
Different maneuvers can help an individual break or terminate an episode of SVT. One of the most useful is termed a valsalva maneuver. A valsalva maneuver increases the pressure in the chest. This triggers a nerve impulse which transiently slows conduction through the normal conducting pathways. This can often break the electrical circuit and thereby stop an episode of SVT. A valsalva maneuver can be performed in a number of ways. The easiest way is to bear down by squatting or blowing into an occluded straw. If these maneuvers do not work, then an individual with SVT should be taken promptly to the emergency room for further treatment. Usually in the emergency room SVT is terminated by the use of a medicine called adenosine. Adenosine transiently slows conduction through the normal pathway and thus terminates the circuit.
Once SVT is diagnosed, there are a number of different treatment options. Some patients have SVT so rarely (once or twice a year) that no treatment at all may be needed. If episodes are happening frequently, are extremely fast, or are worrisome to the patient, then treatment is usually indicated. A number of medicines have been devised to prevent SVT from starting in the first place. The most common class of medications are beta-blockers. Beta-blockers slow conduction through the normal pathways and prevent SVT from ever starting. They are about 75-90% effective in preventing SVT. Most beta-blockers have very few side effects. They are contraindicated in patients with asthma.
A potential cure for SVT can be achieved through a procedure called a radiofrequency ablation. This procedure involves a cardiac catheterization. A specialized catheter is passed through a vein in the leg into the heart. Using advanced electrical mapping techniques, the accessory pathway is located. High-frequency energy is then applied to the pathway to destroy it. Occasionally the pathway may be frozen using a technique termed cryoablation. These procedures are approximately 95% effective. In most cases there are very few if any side effects or risks.