Michael Barkagan1, Markus Rottmann1, Eran Leshem1, Changyu Shen2, Alfred E Buxton1, Elad Anter1. 1. Cardiovascular Division, Department of Medicine, Beth Israel Deaconess Medical Center, Harvard-Thorndike Electrophysiology Institute, Harvard Medical School, Boston, MA (M.B., M.R., E.L., A.E.B., E.A.). 2. Division of Cardiovascular Medicine, Richard A. and Susan F. Smith Center for Cardiovascular Outcomes Research, Beth Israel Deaconess Medical Center, Boston, MA (C.S.).
Abstract
BACKGROUND: Radiofrequency ablation using irrigated catheters is performed using a power-controlled mode. However, lesion size is dependent on current delivery at a particular impedance, such that a power value alone may not reflect actual energy delivery, resulting in lesion size variability at similar power settings. We hypothesized that modulating baseline impedance at fixed power settings affects ablation lesion dimensions. METHODS: In 20 ex vivo swine hearts, radiofrequency ablation was performed using an irrigated catheter at a fixed power setting of 30 W per 20 seconds and a multistepped impedance load (100-210Ω). In 4 in vivo thigh muscle preparations and right atria, ablation was performed using similar power settings at 3 baseline impedances: low (90-130Ω), intermediate (131-180Ω), and high (181-224Ω). The relationship between baseline impedance, current, and lesion dimensions was examined. RESULTS: Baseline impedance had a strong negative correlation with current squared ( I2) for all experimental models: ex vivo (R=-0.94; P<0.0001), thigh muscle (R=-0.93; P<0.0001), and right atria (R=-0.94; P<0.0001). Lesion dimensions at similar power settings were highly variable and directly related to I2 (width [R=0.853], depth [R=0.814]). In the thigh muscle, lesion depth was 8.2±0.7, 6.5±0.8, and 4.2±0.5 mm for low, intermediate, and high impedance, respectively ( P<0.0001). In right atria lines, low baseline impedance resulted in wider lines (7.2±1.4 mm) relative to intermediate (5.8±1.8 mm) and high impedance (4.7±1.7 mm; P<0.0001). CONCLUSIONS: Radiofrequency ablation in a power control mode results in variable lesion dimensions that are partially related to differences in baseline impedance and current output. Ablation at a lower baseline impedance results in increased current output and lesion dimensions.
BACKGROUND: Radiofrequency ablation using irrigated catheters is performed using a power-controlled mode. However, lesion size is dependent on current delivery at a particular impedance, such that a power value alone may not reflect actual energy delivery, resulting in lesion size variability at similar power settings. We hypothesized that modulating baseline impedance at fixed power settings affects ablation lesion dimensions. METHODS: In 20 ex vivo swine hearts, radiofrequency ablation was performed using an irrigated catheter at a fixed power setting of 30 W per 20 seconds and a multistepped impedance load (100-210Ω). In 4 in vivo thigh muscle preparations and right atria, ablation was performed using similar power settings at 3 baseline impedances: low (90-130Ω), intermediate (131-180Ω), and high (181-224Ω). The relationship between baseline impedance, current, and lesion dimensions was examined. RESULTS: Baseline impedance had a strong negative correlation with current squared ( I2) for all experimental models: ex vivo (R=-0.94; P<0.0001), thigh muscle (R=-0.93; P<0.0001), and right atria (R=-0.94; P<0.0001). Lesion dimensions at similar power settings were highly variable and directly related to I2 (width [R=0.853], depth [R=0.814]). In the thigh muscle, lesion depth was 8.2±0.7, 6.5±0.8, and 4.2±0.5 mm for low, intermediate, and high impedance, respectively ( P<0.0001). In right atria lines, low baseline impedance resulted in wider lines (7.2±1.4 mm) relative to intermediate (5.8±1.8 mm) and high impedance (4.7±1.7 mm; P<0.0001). CONCLUSIONS: Radiofrequency ablation in a power control mode results in variable lesion dimensions that are partially related to differences in baseline impedance and current output. Ablation at a lower baseline impedance results in increased current output and lesion dimensions.
Authors: Ayelet Shapira-Daniels; Michael Barkagan; Markus Rottmann; Jakub Sroubek; Derin Tugal; Michael A Carlozzi; James W McConville; Alfred E Buxton; Elad Anter Journal: Circ Arrhythm Electrophysiol Date: 2019-06
Authors: Matthew K Rowe; Andrew Claughton; Jason Davis; Lauren Yee; Gerald C Kaye; Kieran Dauber; John Hill; Paul A Gould Journal: J Arrhythm Date: 2021-12-09
Authors: Han Jo Jeon; Hyuk Soon Choi; Bora Keum; Eun Joo Bang; Kang Won Lee; Sang Hyun Kim; Sun Young Yim; Jae Min Lee; Eun Sun Kim; Yeon Seok Seo; Yoon Tae Jeen; Hong Sik Lee; Hoon Jai Chun; Hong Bae Kim; Jong Hyuk Kim Journal: Sci Rep Date: 2021-07-28 Impact factor: 4.379