Department of Biomedical Engineering, Case Western Reserve University, 2071 Martin Luther King Blvd, Cleveland, Ohio 44106, United States.
Mol Pharm. 2013 May 6;10(5):1988-97. doi: 10.1021/mp400007k. Epub 2013 Apr 24.
Photodynamic therapy (PDT) holds great promise for the treatment of head and neck (H&N) carcinomas where repeated loco-regional therapy often becomes necessary due to the highly aggressive and recurrent nature of the cancers. While interstitial light delivery technologies are being refined for PDT of H&N and other cancers, a parallel clinically relevant research area is the formulation of photosensitizers in nanovehicles that allow systemic administration yet preferential enhanced uptake in the tumor. This approach can render dual-selectivity of PDT, by harnessing both the drug and the light delivery within the tumor. To this end, we report on a cell-targeted nanomedicine approach for the photosensitizer silicon phthalocyanine-4 (Pc 4), by packaging it within polymeric micelles that are surface-decorated with GE11-peptides to promote enhanced cell-selective binding and receptor-mediated internalization in EGFR-overexpressing H&N cancer cells. Using fluorescence spectroscopy and confocal microscopy, we demonstrate in vitro that the EGFR-targeted Pc 4-nanoformulation undergoes faster and higher uptake in EGFR-overexpressing H&N SCC-15 cells. We further demonstrate that this enhanced Pc 4 uptake results in significant cell-killing and drastically reduced post-PDT clonogenicity. Building on this in vitro data, we demonstrate that the EGFR-targeted Pc 4-nanoformulation results in significant intratumoral drug uptake and subsequent enhanced PDT response, in vivo, in SCC-15 xenografts in mice. Altogether our results show significant promise toward a cell-targeted photodynamic nanomedicine for effective treatment of H&N carcinomas.
光动力疗法(PDT)在治疗头颈部(H&N)癌方面具有很大的应用前景,由于癌症具有高度侵袭性和复发性,通常需要反复进行局部区域治疗。虽然间质光传递技术正在为 H&N 和其他癌症的 PDT 进行改进,但临床相关的一个平行研究领域是将光敏剂制成纳米载体,以实现系统给药,同时在肿瘤中优先增强摄取。这种方法可以通过在肿瘤内利用药物和光传递来实现 PDT 的双重选择性。为此,我们报告了一种针对光敏剂硅酞菁-4(Pc 4)的细胞靶向纳米医学方法,将其包装在聚合物胶束中,并用 GE11-肽进行表面修饰,以促进在 EGFR 过表达的 H&N 癌细胞中增强的细胞选择性结合和受体介导的内化。通过荧光光谱和共聚焦显微镜,我们在体外证明了 EGFR 靶向的 Pc 4-纳米制剂在 EGFR 过表达的 H&N SCC-15 细胞中具有更快和更高的摄取。我们进一步证明,这种增强的 Pc 4 摄取导致显著的细胞杀伤和明显降低的 PDT 后集落形成能力。基于这些体外数据,我们证明了 EGFR 靶向的 Pc 4-纳米制剂在 SCC-15 异种移植瘤小鼠体内导致肿瘤内药物摄取增加和随后增强的 PDT 反应。总之,我们的研究结果为治疗头颈部癌的细胞靶向光动力纳米医学提供了很大的应用前景。