高能量、低流量、短消融持续时间——避免附带损伤的关键？

High-power, low-flow, short-ablation duration-the key to avoid collateral injury?

作者信息

Ali-Ahmed Fatima, Goyal Vishal, Patel Meet, Orelaru Felix, Haines David E, Wong Wai Shun

机构信息

Department of Cardiovascular Medicine, Beaumont Health, Royal Oak, MI, USA.

Oakland University William Beaumont School of Medicine, Rochester, MI, USA.

出版信息

J Interv Card Electrophysiol. 2019 Jun;55(1):9-16. doi: 10.1007/s10840-018-0473-5. Epub 2018 Oct 30.

DOI:10.1007/s10840-018-0473-5

PMID:30377925

Abstract

BACKGROUND

A common approach to ablating along the posterior wall of the left atrium in atrial fibrillation ablation is to use low power with longer duration for durable lesions and reducing thermal injury. We hypothesize that similar lesions can be safely obtained at high power with low open-irrigation flow and low duration.

METHODS

Twenty-two porcine ventricles were placed in a tissue bath with circulating 0.45% NaCl at a maintained temperature of 37 °C. Bipolar radiofrequency ablation (RFA) with a 4-mm-tip irrigated, force-sensing catheter was performed with various combinations of irrigation, power, and duration at 20g of contact force. Fiber optic temperature probes were placed at depths of 3 mm and 5 mm. Temperature was measured during and 30 s after each ablation.

RESULTS

Two hundred sixty-eight lesions were made. At a fixed power and flow rate, lesion surface diameter, maximum lesion width, and lesion depth all increased with longer ablation duration. At fixed duration and irrigation flow rate, increased power led to increased lesion dimensions. At a lower flow rate (2 ml/min), surface lesion diameter and maximum width were significantly larger compared to a higher flow rate (17 ml/min), but lesion depth was not significantly different. The maximum temperature and the rate of temperature rise at a depth of 5 mm with different power settings and ablation durations were lower as compared to a depth of 3 mm at both flow rates (2 ml/min and 17 ml/min).

CONCLUSIONS

Effective lesions can be performed with high-power and short-ablation durations, thereby reducing RFA procedure time. Higher power, shorter duration lesions result in adequate temperature for myocardial lesion formation at 3 mm, but do not result in excessive temperature at 5 mm depth, potentially reducing the risk of collateral injury. Compared to higher irrigation flow rate, larger surface lesions and comparable maximum lesion width are achieved with lower irrigation flow rate, thus resulting in better lesion contiguity.

摘要

背景

在房颤消融术中，沿左心房后壁进行消融的一种常用方法是使用低功率、较长持续时间来形成持久损伤并减少热损伤。我们假设在高功率、低开放式冲洗流量和短持续时间的情况下也能安全地获得类似的损伤。

方法

将22个猪心室置于组织浴中，用0.45%的氯化钠溶液循环灌注，维持温度为37℃。使用带有4毫米尖端冲洗、力感应导管的双极射频消融（RFA），在20克接触力下，对冲洗、功率和持续时间进行各种组合操作。将光纤温度探头置于3毫米和5毫米深度处。在每次消融过程中和消融后30秒测量温度。

结果

共制造了268个损伤灶。在固定功率和流速下，损伤灶表面直径、最大损伤宽度和损伤深度均随消融持续时间延长而增加。在固定持续时间和冲洗流速下，功率增加会导致损伤灶尺寸增大。在较低流速（2毫升/分钟）下，表面损伤灶直径和最大宽度显著大于较高流速（17毫升/分钟）时，但损伤深度无显著差异。在两种流速（2毫升/分钟和17毫升/分钟）下，不同功率设置和消融持续时间时，5毫米深度处的最高温度和温度上升速率均低于3毫米深度处。

结论

采用高功率和短消融持续时间可形成有效的损伤灶，从而减少RFA手术时间。更高功率、更短持续时间的损伤灶在3毫米处能产生足以形成心肌损伤的温度，但在5毫米深度处不会导致温度过高，可能降低附带损伤的风险。与较高冲洗流速相比，较低冲洗流速可实现更大的表面损伤灶和相当的最大损伤宽度，从而使损伤灶的连续性更好。

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高能量、低流量、短消融持续时间——避免附带损伤的关键？

High-power, low-flow, short-ablation duration-the key to avoid collateral injury?

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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