使用灌注冷却电极优化双极射频肝消融的体外实验研究。

An ex-vivo experimental study on optimization of bipolar radiofrequency liver ablation using perfusion-cooled electrodes.

作者信息

Lee J M, Han J K, Kim S H, Lee J Y, Shin K S, Choi B I

机构信息

Radiology and Institute of Radiation Medicine, Seoul National University College of Medicine, Republic of Korea.

出版信息

Acta Radiol. 2005 Aug;46(5):443-51. doi: 10.1080/02841850510021418.

DOI:10.1080/02841850510021418

PMID:16224916

Abstract

PURPOSE

To determine optimal parameters for bipolar radiofrequency ablation (RFA) using perfusion-cooled electrodes to create a large ablation volume in ex vivo bovine liver.

MATERIAL AND METHODS

Three sets of RF experiments were performed using a 200-Watt generator and two 15-gauge perfusion-cooled or internally cooled electrodes in ex vivo bovine livers. In the first set of experiments, to find the ideal inter-electrode distance for creating large coagulation necrosis, 30 ablation lesions were created by bipolar RFAs at inter-electrode spacings of 3 cm, 4 cm, and 5 cm. In the second set of experiments, to explore the ideal duration of RF application, bipolar RFAs were performed for 10 min and 20 min. In the first and second experiments, 10 lesions were made for each condition with infusion of 6% hypertonic saline (HS) at 2 ml/min. In the third set of experiments, 10 ablation lesions were created by bipolar RFAs using internally cooled electrodes without HS infusion. The mean volume of those ablation lesions was then compared to that of the lesions created by bipolar RFA using perfusion-cooled electrodes in the second experiments. Tissue impedance, dimension, and shape of the ablated areas were compared in each condition.

RESULTS

In the first set of experiments, bipolar RFA created a homogeneous oval or spherical-shaped ablation area between the electrodes at 3-5 cm spacing, but showed a more spherical-shaped lesion at 3 cm inter-electrode spacing than at 4 cm and 5 cm spacing. In the second set of experiments, RF energy delivered for 20 min created a larger dimension of coagulation necrosis than energy delivered for 10 min: 107.6 +/- 34 cm3 versus 59.5 +/- 27 cm3 (P<0.05). In addition, the mean volume of ablation regions obtained with bipolar RFA using the internally cooled electrode was 47.5+/- 17 cm3, which was significantly less than that with bipolar RFA using perfusion-cooled electrodes (P <0.05).

CONCLUSION

Bipolar RFA using perfusion-cooled electrodes achieves homogeneous areas of coagulation necrosis between two electrodes, preferably at 3 or 4 cm inter-electrode distance for 20 min, and is better in creating large coagulation necrosis than bipolar RFA using internally cooled electrodes.

摘要

目的

确定使用灌注冷却电极进行双极射频消融（RFA）的最佳参数，以便在离体牛肝中创建大的消融体积。

材料与方法

使用200瓦发生器和两个15号灌注冷却或内部冷却电极在离体牛肝上进行三组射频实验。在第一组实验中，为了找到创建大的凝固性坏死的理想电极间距，通过双极RFA在3厘米、4厘米和5厘米的电极间距处创建了30个消融灶。在第二组实验中，为了探索理想的射频施加持续时间，进行了10分钟和20分钟的双极RFA。在第一和第二个实验中，每种情况制作10个病灶，以2毫升/分钟的速度输注6%高渗盐水（HS）。在第三组实验中，使用内部冷却电极通过双极RFA创建10个消融灶，不输注HS。然后将这些消融灶的平均体积与第二个实验中使用灌注冷却电极的双极RFA创建的病灶的平均体积进行比较。比较每种情况下消融区域的组织阻抗、尺寸和形状。

结果

在第一组实验中，双极RFA在3 - 5厘米间距的电极之间创建了均匀的椭圆形或球形消融区域，但在3厘米电极间距处的病灶比4厘米和5厘米间距处的病灶更呈球形。在第二组实验中，施加20分钟的射频能量产生的凝固性坏死尺寸比施加10分钟的能量更大：分别为107.6±34立方厘米和59.5±27立方厘米（P<0.05）。此外，使用内部冷却电极的双极RFA获得的消融区域平均体积为47.5±17立方厘米，明显小于使用灌注冷却电极的双极RFA（P<0.05）。