Catheter ablation for atrioventricular nodal reentry tachycardia in children: A time to freeze, and a time to burn

Cryoablation with an 8-mm-Tip Catheter for Right-Sided Accessory Pathways in Children

BACKGROUND

Cryoablation is increasingly utilized in children because of its safety profile. Recently, larger catheter tips have been more widely used to improve long-term success rates. The aim of this study was to assess the safety and efficacy of 8-mm-tip catheters for cryoablation of right-sided accessory pathways (APs) in children.

METHODS

Electrophysiological procedures were performed using the EnSite™ system (St. Jude Medical Inc., St. Paul, MN, USA).

RESULTS

Between July 2010 and July 2014, 54 patients (mean age: 13.1 ± 3.7 years) underwent cryoablation using an 8-mm-tip catheter. In 18 of 54 (33%) patients where an 8-mm-tip catheter was the first-choice catheter, the success rate was 18 of 18 (100%). There was a history of previous failed attempts or recurrence with radiofrequency ablation and/or 6-mm-tip cryoablation in 36 of 54 (67%) patients. The success rate in these patients was 24 of 36 (67%). No fluoroscopy was used in 34 of 54 procedures. The recurrence rate was six of 42 (14%) during a mean follow-up period of 32 ± 15 months. In one patient, transient atrioventricular block occurred.

CONCLUSIONS

Cryoablation with an 8-mm-tip catheter for right-sided APs in children who weigh over 40 kg appears to be safe and acutely effective in cases where conventional ablation methods fail and also as a first choice for ablation procedure. However, the recurrence rate still seems to be high.

Contrasting effects of convective flow on catheter ablation lesion size: cryo versus radiofrequency energy

BACKGROUND

Cryoablation has now become an alternative to treat many cardiac arrhythmias, and may be the treatment of choice in some patient populations. We compared the effects of convective flow on large-tip cryo and radiofrequency (RF) lesions dimensions.

METHODS

Cryoablation and RF ablation were performed on porcine heart sections in a saline bath with varying directed flow rates. Cryoablation was performed for 4 minutes on 50 tissue pieces with tip temperature controlled at -80 degrees C. RF ablation was performed on 50 tissue pieces for 60 seconds at 60 degrees C tip temperature. The pieces were placed in culture media for 24 hours, and then sectioned, stained, and measured.

RESULTS

Cryoablation and RF lesion sizes varied significantly with flow such that higher flow rates produced smaller cryoablation lesions and larger RF lesions (mean cryoablation volumes: 854 +/- 402, 808 +/- 217, 781 +/- 217, 359 +/- 114, and 292 +/- 117 mm(3), and mean RF volumes: 211 +/- 35, 304 +/- 79, 439 +/- 125, 525 +/- 187, and 597 +/- 126 mm(3) for 0, 1, 2, 3, and 5 L/min flow rates, respectively, P < 0.0005). Trabeculated pieces had larger cryoablation lesions and smaller RF lesions than nontrabeculated ones at higher flow rate (P < 0.005). Cryoablation lesion volume increased as the time to reach -80 degrees C decreased (r(2)= 0.72).

CONCLUSION

In contrast to RF ablation, cryoablation lesion size is smaller at high flow rates, and larger at low flow rates due to the warming effects of local convective flow. The effects of high flow are reduced in areas of trabeculation, and the time to reach -80 degrees C predicts cryoablation lesion size.

Convective cooling affects cardiac catheter cryoablation and radiofrequency ablation in opposite directions

Recently, cryoablation has received increased attention as a safer alternative to radiofrequency (RF) ablation. The purpose of this study was to compare the effect of convective cooling at physiologic flow rates on RF lesion size and on cryo lesion size. Porcine hearts were sectioned into 40 pieces and placed in a temperature-controlled saline bath (37 degrees C) with varying directed flow rates (0, 1, 2 and 3 L/min). Large-tip cryoablation (8 mm tip) was performed for 4 minutes on 20 tissue sections at -80 degrees C tip temperature. Large-tip RF catheter ablation (10 mm tip) was performed at 60 degrees C target temperature for 1 minute on 20 tissue sections. For each catheter, flow rates were randomized between applications. The tissue pieces were placed in culture medium for 24 hrs, sectioned, stained and measured to determine lesion depth, width and volume. Average lesion geometry was estimated from the data. Lesion dimensions were dependent on the flow rate for RF ablation with larger lesions at higher flow rates (mean volumes: 211+/-35, 304+/-79, 439+/-125 and 525.7+/-187 mm3 for 0, 1, 2 and 3 L/min flow rate, respectively, p<0.01). Also for cryoablation lesion size varied significantly with flow, such that lower flow rates produced larger lesions (mean volumes: 855+/-402, 809+/-218, 658+/-91 and 360+/-14 mm3 for 0, 1, 2 and 3 L/min flow rate respectively, p<0.01). While RF ablation creates larger lesions at high flow rates (3 L/min), cryoablation creates larger lesions at low flow rates (0-1 L/min, p<0.05).