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LINZ, AUSTRIA. Radiofrequency-powered catheter ablation with the intent of curing atrial
fibrillation (AF) involves the creation of lesions on the inside of heart tissue, primarily
as rings encircling the areas where the pulmonary veins enter the left atrium (pulmonary vein
isolation). In order to ensure a lasting cure, it is essential that lesions are created in
the right locations, that there are no gaps in the lesion rings, and that transmurality is
achieved � that is, that the depth of the lesions is as close to the outer wall of the
pericardium as possible without penetrating it (cardiac tamponade). Thus, a successful
ablation requires great tactile skill, an innate feel for just how much power to apply
to any particular point and, of course, the support of sophisticated imaging equipment.
It is clear that the force (contact force) with which the catheter is pressed against a
particular area of heart tissue is of crucial importance in determining the ultimate lesion quality.
Biosense Webster recently released a new variation of its 3.5-mm, 8-hole, open-irrigated
tip ablation catheter (Thermocool SmartTouch) which measures the force exerted by the catheter
when pressed against the heart wall. A group of Austrian cardiologists/electrophysiologists
now reports the results of the first clinical evaluation of the new catheter.
Fifty patients with paroxysmal AF were assigned to receive a circumferential pulmonary vein
isolation procedure using either a standard 3.5 mm irrigated catheter (Thermocool) or the
new force-sensing catheter (Thermocool SmartTouch). The average age of the patients was 59
years, 56% were male, 44% had hypertension, but none were reported as having cardiovascular
disease. The average left atrial diameter was 38 mm. The ablation procedure was carried out
using anatomically-guided mapping with the Carto3 system, which has a built-in feature showing
catheter position and contact force on a continuous basis.
The total average procedure time for the conventional catheter group was 185 minutes as
compared to 154 minutes for the contact force catheter group � a saving of 31 minutes.
Similarly, the ablation time (minutes of actual radiofrequency application) was reduced
by 11 minutes from 50 to 39 minutes. Total energy delivered during the procedure was reduced
from 71,000 watt-seconds to 59,000 watt-seconds. Acute pulmonary vein connections following
�first pass� ablation declined from 36% in the conventional catheter group to 12% in the contact
force group. Complications were rare with one atrioventricular fistula, one pseudoaneurysm,
and minimal pericardial effusion documented in the conventional catheter group, and one atrioventricular
fistula and one case of pericardial tamponade documented in the contact force catheter group.
The Austrian researchers conclude that the use of contact force sensing technology is able to
significantly reduce ablation and overall procedure time in pulmonary vein isolation procedures.
However, they caution that the use of the new technology may actually increase perforation rate.
Thus, whilst �40 g of force applied to a rigid thick tissue may be perfectly safe, the same
force applied to thin pliable tissues will result in pouching and further tissue thinning which,
coupled with radiofrequency application, may result in perforation�.
Editor�s comment: The use of a contact force-sensing catheter would, at first glance, seem to
be a substantial improvement. However, it may be of value primarily for relatively inexperienced
operators who have not developed the superior tactile skills characterizing the �top-gun�
electrophysiologists performing ablations.
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