Leeds Institute of Medical Research, Wellcome Trust Brenner Building, St James's University Hospital, Leeds, LS9 7TF, United Kingdom.
Molecular and Nanoscale Physics Group, School of Physics and Astronomy, University of Leeds, LS2 9JT, United Kingdom.
Theranostics. 2020 Sep 1;10(24):10973-10992. doi: 10.7150/thno.49670. eCollection 2020.
Most cancer patients receive chemotherapy at some stage of their treatment which makes improving the efficacy of cytotoxic drugs an ongoing and important goal. Despite large numbers of potent anti-cancer agents being developed, a major obstacle to clinical translation remains the inability to deliver therapeutic doses to a tumor without causing intolerable side effects. To address this problem, there has been intense interest in nanoformulations and targeted delivery to improve cancer outcomes. The aim of this work was to demonstrate how vascular endothelial growth factor receptor 2 (VEGFR2)-targeted, ultrasound-triggered delivery with therapeutic microbubbles (thMBs) could improve the therapeutic range of cytotoxic drugs. Using a microfluidic microbubble production platform, we generated thMBs comprising VEGFR2-targeted microbubbles with attached liposomal payloads for localised ultrasound-triggered delivery of irinotecan and SN38 in mouse models of colorectal cancer. Intravenous injection into tumor-bearing mice was used to examine targeting efficiency and tumor pharmacodynamics. High-frequency ultrasound and bioluminescent imaging were used to visualise microbubbles in real-time. Tandem mass spectrometry (LC-MS/MS) was used to quantitate intratumoral drug delivery and tissue biodistribution. Finally, Zr PET radiotracing was used to compare biodistribution and tumor accumulation of ultrasound-triggered SN38 thMBs with VEGFR2-targeted SN38 liposomes alone. ThMBs specifically bound VEGFR2 and significantly improved tumor responses to low dose irinotecan and SN38 in human colorectal cancer xenografts. An ultrasound trigger was essential to achieve the selective effects of thMBs as without it, thMBs failed to extend intratumoral drug delivery or demonstrate enhanced tumor responses. Sensitive LC-MS/MS quantification of drugs and their metabolites demonstrated that thMBs extended drug exposure in tumors but limited exposure in healthy tissues, not exposed to ultrasound, by persistent encapsulation of drug prior to elimination. Zr PET radiotracing showed that the percentage injected dose in tumors achieved with thMBs was twice that of VEGFR2-targeted SN38 liposomes alone. thMBs provide a generic platform for the targeted, ultrasound-triggered delivery of cytotoxic drugs by enhancing tumor responses to low dose drug delivery via combined effects on circulation, tumor drug accumulation and exposure and altered metabolism in normal tissues.
大多数癌症患者在治疗过程的某个阶段都会接受化疗,因此提高细胞毒性药物的疗效是一个持续且重要的目标。尽管已经开发出大量有效的抗癌药物,但将治疗剂量递送到肿瘤而不引起不可耐受的副作用仍然是临床转化的一个主要障碍。为了解决这个问题,人们对纳米制剂和靶向递药产生了浓厚的兴趣,以改善癌症治疗效果。本工作旨在展示血管内皮生长因子受体 2(VEGFR2)靶向、超声触发治疗微泡(thMBs)如何改善细胞毒性药物的治疗范围。 使用微流控微泡制备平台,我们生成了包含 VEGFR2 靶向微泡的 thMBs,这些微泡上连接有载 liposomal 有效载荷,用于在结直肠癌的小鼠模型中进行局部超声触发递送伊立替康和 SN38。将其静脉注射到荷瘤小鼠中,以检查靶向效率和肿瘤药效动力学。高频率超声和生物发光成像用于实时可视化微泡。串联质谱(LC-MS/MS)用于定量肿瘤内药物递送和组织生物分布。最后,使用 Zr PET 放射性示踪来比较超声触发 SN38 thMBs 与单独的 VEGFR2 靶向 SN38 脂质体的生物分布和肿瘤积累。 thMBs 特异性结合 VEGFR2,并显著改善了人结直肠癌异种移植模型中低剂量伊立替康和 SN38 的肿瘤反应。超声触发是实现 thMBs 选择性作用的关键,因为如果没有超声触发,thMBs 就无法延长肿瘤内药物递送或表现出增强的肿瘤反应。药物及其代谢物的灵敏 LC-MS/MS 定量表明,thMBs 通过在消除之前持续包裹药物来延长肿瘤内的药物暴露,但限制了未暴露于超声的健康组织中的暴露。Zr PET 放射性示踪显示,thMBs 实现的肿瘤注射剂量百分比是单独使用 VEGFR2 靶向 SN38 脂质体的两倍。 thMBs 通过增强低剂量药物递送的肿瘤反应,为细胞毒性药物的靶向、超声触发递药提供了一个通用平台,其作用机制包括对循环、肿瘤药物积累和暴露的综合影响,以及正常组织中代谢的改变。
