We have one of the largest cardiac ablation practice in Phoenix. Our team of leading electrophysiologists, advanced practice nurses, technical staff, and other professionals allow us to tailor our therapy to each patient to reduce risks of stroke, eliminate symptoms, and improve overall quality of life.
Ordinarily, your heart beats at a regular, steady pace called a normal sinus rhythm that is regulated electrically by the sinus node. When the heart beats too rapidly, the arrhythmia is called a tachycardia. If the tachycardia originates in one of the upper chambers of the heart, it”s called a supraventricular (above the ventricles) tachycardia (SVT).
SVT may occur when an extra electrical pathway exists in or between some of the structures of the heart. These abnormal pathways can make the electrical impulses that control your heart rate travel in a circular pattern within the heart, causing a tachycardia. These arrhythmias can be treated, but not cured, with medications.
Your physician may choose to treat your arrhythmia with a non-surgical procedure called cardiac ablation. Often, this treatment permanently resolves the arrhythmia by destroying the abnormal pathway that causes it.
A cardiac ablation ablation is very similar to an Electrophysiology (EP) Study. If you haven’t already had an EP Study, the two procedures are frequently performed one after the other. The EP Study helps identify the specific type and location of the abnormal heart rhythm. Then, in a process called mapping, a catheter (small, flexible tube) is manipulated until it locates the abnormal pathway that is causing the tachycardia. At this point, an ablation is performed.
A special catheter will be used to direct energy to the abnormal pathway in the heart. Most commonly used energy is called Radiofrequency (RF). Radiofrequency energy is a form of electrical energy that causes the tissue at the tip of the catheter to heat up, permanently damaging (ablating) that small area of tissue. When the abnormal pathway is destroyed, the heart’s electrical impulses can only travel through the normal conduction pathways, and the arrhythmia is eliminated.
Radiofrequency (RF) energy is radio waves that are converted to heat to ablate and create scar tissue. It reliably achieves transmurality and is the most widely used energy source in catheter ablations. In general, high temperatures are needed to make sure that all layers of tissue are ablated. Traditional catheters use unipolar radiofrequency energy, which simply means that the radiofrequency energy is transmitted from a single point at the catheter’s tip.
Cryo energy, is intense cold that is used to form ice crystals within the tissue, causing the cells to die and creating scar tissue. It may be easier to make lesions using cryothermy since the cold temperatures cause tissue to stick to the catheter. In addition, cryo energy may have fewer major complications. Animal studieshave shown cryo energy to have a much lower incidence of thrombus (clot) formation than radiofrequency energy, which suggests that cryothermy could lower the risk of a stroke. Cryo energy can be used in single point catheters or balloon catheters.
Laser energy is light waves that are converted to heat to ablate and create scar tissue. It may be a safer heat-based energy than unipolar radiofrequency energy. With laser energy, the catheter doesn’t need to be in direct contact with tissue, which could mean it will have fewer complications than radiofrequency energy. Unlike other energy sources, contact force is not a factor in whether a laser lesion is transmural. In addition, laser energy can be adjusted when ablating tissues of varying thickness, with higher energy applied to thicker tissue and lower energy applied to thinner structures in the heart.
Other energy sources, such as microwave and high intensity focused ultrasound (HIFU), have been studied but these energy sources aren’t widely used in catheter ablation.
The design and functionality of catheters is constantly evolving. Most atrial fibrillation ablations today use single point radiofrequency energy catheters, which have a success rate—freedom from atrial fibrillation—of about 70%. It’s believed that different types of catheters could have higher success rates or fewer complications. Here are the different types of catheters available today for atrial fibrillation catheter ablations:
Single electrode radiofrequency catheters emit radiofrequency energy from a single point at the catheter tip. To make lesions, electrophysiologists ablate one spot after another, similar to drawing a line by making dots one after the other. If all the dots are not connected, afib could re-enter the heart in the unablated space (gap).
Multi-electrode radiofrequency catheters have several electrodes, each of which can deliver radiofrequency energy. These catheters can ablate a larger area of tissue than single point radiofrequency energy catheters, which could decrease procedure times. In addition, multielectrode catheters may be better at making contiguous lesions (lesion lines without any gaps) than single point catheters. Finally, these catheters can also deliver superficial bipolar radiofrequency energy, which may reduce injury to deeper tissues in certain areas of the heart. However, there is limited clinical data on multielectrode catheters, which means that complications arising from these procedures may not be fully known or understood.
LARGE TIP CATHETERS
These catheters require higher outputs, and are capable of forming larger lesions that the standard 4 mm tip catheters. Disadvantages of the 8 mm tip have included a decreased resolution of electrograms, greater catheter stiffness, and therefore decreased compliance and maneuverability.
IRRIGATED TIP CATHETERS
Saline is perfused via a pump mechanism through the catheter tip, turns around within the catheter tip, and returns back to the pump. This represents a closed system because no saline is infused into the blood pool
Open irrigation overcomes the limitations of non-irrigated ablation by lowering electrode and tissue surface temperature, bringing together the efficacy of power delivery with the safety of reduced char formation.
Open Irrigation multi-electrode catheter
nMARQ™ This new open irrigation multielectrode catheter is in clinical trail in the US for treatment of Atrial fibrillation.
Each nMARQ™ Catheter boasts 10 irrigation holes per electrode completely surrounding the electrodes for more efficient cooling.Uniform irrigation occurs immediately at the site of tissue contact reducing trade-offs between precision and safety.
CONTACT FORCE SENSING RADIOFREQUENCY CATHETERS
During cardiac ablation, the contact force sensing Catheter enables the measurement of catheter tip contact force and direction inside the heart. If there is not enough force or pressure, the lesion formation may not be deep enough, which would allow recurrence of arrhythmia. If there is too much pressure, complications, such as steam pops, can occur. These catheters tell the electrophysiologist how much pressure is being applied to the catheter and tissue.
After the balloon catheter is inserted into the left atrium, the electrophysiologist inflates the balloon at the tip of the catheter. Balloon catheters can ablate a larger area of tissue than single point radiofrequency catheters, which enhances the prospects that lesions will be contiguous (without gaps) and could shorten procedure times. There are balloon catheters using cryothermy, laser energy, and even radiofrequency energy.
Disadvantage are that balloon catheters are bulky, lesions are less precise/accurate, they may have difficulty reaching the certain areas of the heart (right pulmonary veins). These catheters do-not allow ablation of areas other than tissues around the pulmonary veins.
Atrial Fibrillation Ablation
Atrial fibrillation is the most common irregular heart rhythm, affecting about 2.5 million people in the US, with more than 200,000 new cases of atrial fibrillation are diagnosed each year. Atrial fibrillation is an abnormal heart rhythm originating in the upper chambers of the heart (atria). Several impulses begin and spread throughout the atria, causing a rapid, irregular and disorganized heartbeat.
Ablation is proving to be successful for many patients with atrial fibrillation. The procedure is indicated for those:
- with a history of chronic, persistent or paroxysmal atrial fibrillation
- those who have failed antiarrhythmic drugs
- those who have had complications from antiarrhythmic drugs
- Pulmonary vein isolation (PVI) is a minimally invasive procedure in which a flexible catheter is inserted into the heart via a vein in the leg to electrically isolate the pulmonary veins from the rest of the heart. This procedure can eliminate or significantly reduce the severity and frequency of atrial fibrillation episodes in the majority of patients.
- AF rotor ablation using rhythm view system (Topera, Inc). Rotors are considered sustaining mechanism for persistent or permanent atrial fibrillation. Our practice has been in the forefront of rotor site ablation and was one of the first sites in the country to offer this ablation in the country.
Not all patients may be appropriate candidates for catheter ablation of atrial fibrillation. A thorough evaluation will be conducted to see if this procedure is appropriate. Pre-testing includes a history and physical, electrocardiogram (ECG) and possible holter/event monitor. A transesophageal echocardiogram (TEE) may be needed within 24 hours of the procedure to rule out blood clots in the left atrium. Other tests, such as a spiral computed tomography (CT) or MRI, may be required if you have had previous procedures to treat your arrhythmia.