Mertyna Pawel, Hines-Peralta Andrew, Liu Zheng-jun, Halpern Elkan, Goldberg Wallace, Goldberg S Nahum
Laboratory for Minimally Invasive Tumor Therapies, Department of Radiology, Beth Israel Deaconess Medical Center, 1 Deaconess Rd, WCC308B, Boston, MA 02215, USA.
J Vasc Interv Radiol. 2007 May;18(5):647-54. doi: 10.1016/j.jvir.2007.02.033.
To characterize the thermal dosimetry (ie, heating profile) of radiofrequency ablation (RFA) in multiple ex vivo tissues and in vivo tumor models.
RFA was performed for 3-24 minutes in ex vivo bovine livers (n=20), porcine kidneys (n=20), and turkey muscles (n=20) and in vivo canine venereal sarcomas (n=8). RFA was performed by using 1 and 3-cm long tips internally cooled electrodes. In addition, RFA was performed in in vivo R3220 rat mammary adenocarcinomas (n=36) and human renal cell carcinomas in nude mice (n=6) by using 1-cm monopolar electrodes. Continuous temperature monitoring was performed at multiple depths to calculate thermal dosimetry, reported as the area under the curve (AUC). Cumulative equivalent minutes at 43 degrees C (CEM43) were used for the critical ablation margin. Data were compared with analysis of variance and regression analysis.
For each tissue and/or tumor type, statistically significant temperature differences (up to 14 degrees) were observed at the ablation margin (P<.01). Temperature was dependent on the procedure duration. For 10-minute treatments, temperatures were significantly higher in the kidney compared with the R3230 tumor (72 degrees C+/-2.2) (P<.01) and lower in R3230 tumor (41.6 degrees C+/-1.4) (P<.05) but were similar for liver and muscle (51.6 degrees C+/-1.6 and 54.1 degrees C+/-1.8, respectively). Thus, a wide range of ablative temperatures were observed (41.0 degrees C+/-0.7 to 76.7 degrees C+/-1.9), with coagulation diameter correlating logarithmically with radiofrequency duration and AUC (R2=0.85-0.95). The CEM43 demonstrated an extreme range of values (10(11)).
The results of the study demonstrate a wide range of thermal sensitivity to RFA among commonly investigated tissues and tumor models, suggesting that further characterization of tissue-specific end points (ie, the duration and end temperature of ablation) is likely warranted. The AUC showed good correlation with ablation sizes, but the CEM43 proved unworkable given an extreme range of values for RFA.
描述射频消融(RFA)在多种离体组织和体内肿瘤模型中的热剂量测定(即加热曲线)。
在离体牛肝(n = 20)、猪肾(n = 20)和火鸡肌肉(n = 20)以及体内犬性病肉瘤(n = 8)中进行3 - 24分钟的RFA。使用1厘米和3厘米长的内部冷却电极尖端进行RFA。此外,使用1厘米单极电极在体内R3220大鼠乳腺腺癌(n = 36)和裸鼠人肾细胞癌(n = 6)中进行RFA。在多个深度进行连续温度监测以计算热剂量测定,报告为曲线下面积(AUC)。43℃时的累积等效分钟数(CEM43)用于关键消融边缘。数据通过方差分析和回归分析进行比较。
对于每种组织和/或肿瘤类型,在消融边缘观察到统计学上显著的温度差异(高达14℃)(P <.01)。温度取决于手术持续时间。对于10分钟的治疗,肾脏中的温度显著高于R3230肿瘤(72℃±2.2)(P <.01),R3230肿瘤中的温度较低(41.6℃±1.4)(P <.05),但肝脏和肌肉中的温度相似(分别为51.6℃±1.6和54.1℃±1.8)。因此,观察到广泛的消融温度范围(41.0℃±0.7至76.7℃±1.9),凝固直径与射频持续时间和AUC呈对数相关(R2 = 0.85 - 0.95)。CEM43显示出极大的值范围(10^11)。
该研究结果表明,在常用研究的组织和肿瘤模型中,对RFA的热敏感性范围广泛,这表明可能需要进一步表征组织特异性终点(即消融的持续时间和结束温度)。AUC与消融大小显示出良好的相关性,但鉴于RFA的值范围极大,CEM43被证明不可行。
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