Visaria Rachana K, Griffin Robert J, Williams Brent W, Ebbini Emad S, Paciotti Giulio F, Song Chang W, Bischof John C
Department of Mechanical Engineering, University of Minnesota Medical School, Minneapolis, MN 55455, USA.
Mol Cancer Ther. 2006 Apr;5(4):1014-20. doi: 10.1158/1535-7163.MCT-05-0381.
Tumor necrosis factor-alpha (TNF-alpha) is a potent cytokine with anticancer efficacy that can significantly enhance hyperthermic injury. However, TNF-alpha is systemically toxic, thereby creating a need for its selective tumor delivery. We used a newly developed nanoparticle delivery system consisting of 33-nm polyethylene glycol-coated colloidal gold nanoparticles (PT-cAu-TNF-alpha) with incorporated TNF-alpha payload (several hundred TNF-alpha molecules per nanoparticle) to maximize tumor damage and minimize systemic exposure to TNF-alpha. SCK mammary carcinomas grown in A/J mice were treated with 125 or 250 microg/kg PT-cAu-TNF-alpha alone or followed by local heating at 42.5 degrees C using a water bath for 60 minutes, 4 hours after nanoparticle injection. Increases in tumor growth delay were observed for both PT-cAu-TNF-alpha alone and heat alone, although the most dramatic effect was found in the combination treatment. Tumor blood flow was significantly suppressed 4 hours after an i.v. injection of free TNF-alpha or PT-cAu-TNF-alpha. Tumor perfusion, imaged by contrast enhanced ultrasonography, on days 1 and 5 after treatment revealed perfusion defects after the injection of PT-cAu-TNF-alpha alone and, in many regions, complete flow inhibition in tumors treated with combination treatment. The combination treatment of SCK tumors in vivo reduced the in vivo/in vitro tumor cell survival to 0.05% immediately following heating and to 0.005% at 18 hours after heating, suggesting vascular damage-mediated tumor cell killing. Thermally induced tumor growth delay was enhanced by pretreatment with TNF-alpha-coated gold nanoparticles when given i.v. at the proper dosage and timing.
肿瘤坏死因子-α(TNF-α)是一种具有抗癌功效的强效细胞因子,可显著增强热损伤。然而,TNF-α具有全身毒性,因此需要将其选择性地递送至肿瘤部位。我们使用了一种新开发的纳米颗粒递送系统,该系统由33纳米聚乙二醇包覆的胶体金纳米颗粒(PT-cAu-TNF-α)组成,其中负载了TNF-α(每个纳米颗粒包含数百个TNF-α分子),以最大程度地损伤肿瘤并最小化全身对TNF-α的暴露。将接种于A/J小鼠的SCK乳腺癌用125或250μg/kg的PT-cAu-TNF-α单独处理,或在纳米颗粒注射4小时后,使用水浴在42.5℃局部加热60分钟。单独使用PT-cAu-TNF-α和单独加热均观察到肿瘤生长延迟增加,尽管联合治疗的效果最为显著。静脉注射游离TNF-α或PT-cAu-TNF-α4小时后,肿瘤血流显著受到抑制。通过超声造影成像显示,治疗后第1天和第5天的肿瘤灌注情况表明,单独注射PT-cAu-TNF-α后出现灌注缺损,而联合治疗的肿瘤在许多区域出现完全血流抑制。体内联合治疗SCK肿瘤后,加热后立即将体内/体外肿瘤细胞存活率降低至0.05%,加热后18小时降低至0.005%,提示血管损伤介导的肿瘤细胞杀伤。当以适当的剂量和时间静脉注射TNF-α包覆的金纳米颗粒进行预处理时,热诱导的肿瘤生长延迟会增强。
