使用内部灌注射频导管进行消融：学习如何避免蒸汽爆发现象。

Ablation with an internally irrigated radiofrequency catheter: learning how to avoid steam pops.

作者信息

Cooper Joshua M, Sapp John L, Tedrow Usha, Pellegrini Christine P, Robinson David, Epstein Laurence M, Stevenson William G

机构信息

University of Pennsylvania Health System, Philadelphia, Pennsylvania, USA.

出版信息

Heart Rhythm. 2004 Sep;1(3):329-33. doi: 10.1016/j.hrthm.2004.04.019.

DOI:10.1016/j.hrthm.2004.04.019

PMID:15851179

Abstract

OBJECTIVES

The aim of this study was to assess the feasibility of using electrode temperature, impedance, and power to predict and thereby potentially prevent steam pops during cooled radiofrequency (RF) ablation.

BACKGROUND

When myocardial temperature reaches 100 degrees C during RF catheter ablation, steam explosions are seen. Saline-cooled RF ablation reduces temperatures at the electrode-tissue interface, but excessive intramyocardial heating still may occur.

METHODS

In anesthetized swine, 26 cooled RF applications were made in the right and left atria while observing with intracardiac echocardiography (ICE). Power delivery was increased gradually until a steam explosion was seen or a maximum output of 50 W was reached.

RESULTS

ICE identified steam explosions in 21 RF applications. Steam explosions were associated with a large impedance increase, >25 Omega in only three cases, whereas small increases <10 Omega (mean 5.3 +/- 2.6 Omega) occurred in 18 cases. Mean electrode temperature at the time of steam explosion was 43.6 degrees C +/- 5.3; 18 of 21 explosions occurred when temperature reached >/=40 degrees C. Mean power and impedance drop were similar for applications with and without steam explosions. Five steam explosions were associated with a sudden drop in electrode temperature.

CONCLUSIONS

Steam explosions are common when cooled electrode temperature exceeds 40 degrees C and are not predictable from power or impedance drop. Small impedance rises and sudden drops in measured electrode temperature indicate possible steam formation. Maintaining cooled electrode temperature <40 degrees C during RF likely will reduce the risk of steam explosions.

摘要

目的

本研究旨在评估利用电极温度、阻抗和功率来预测并从而潜在预防冷循环射频（RF）消融期间蒸汽泡形成的可行性。

背景

在射频导管消融期间，当心肌温度达到100摄氏度时，会出现蒸汽爆炸。盐水冷却的射频消融可降低电极-组织界面处的温度，但心肌内仍可能发生过度加热。

方法

在麻醉的猪身上，在左右心房进行26次冷循环射频应用，同时用心内超声心动图（ICE）观察。逐渐增加功率输送，直至出现蒸汽爆炸或达到50W的最大输出。

结果

ICE在21次射频应用中识别出蒸汽爆炸。蒸汽爆炸与较大的阻抗增加相关，仅3例阻抗增加>25Ω，而18例阻抗增加<10Ω（平均5.3±2.6Ω）。蒸汽爆炸时的平均电极温度为43.6℃±5.3；21次爆炸中有18次发生在温度达到≥40℃时。有蒸汽爆炸和无蒸汽爆炸的应用的平均功率和阻抗下降相似。5次蒸汽爆炸与电极温度突然下降有关。

结论

当冷却电极温度超过40℃时，蒸汽爆炸很常见，且无法通过功率或阻抗下降来预测。阻抗小幅上升和测量的电极温度突然下降表明可能形成蒸汽。在射频期间将冷却电极温度维持在<40℃可能会降低蒸汽爆炸的风险。

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使用内部灌注射频导管进行消融：学习如何避免蒸汽爆发现象。

Ablation with an internally irrigated radiofrequency catheter: learning how to avoid steam pops.

作者信息

机构信息

出版信息

OBJECTIVES

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

目的

背景

方法

结果

结论

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