Lab of Nano-biology Technology, School of Physics and Electronics, Central South University, Changsha, Hunan 410083, China.
State Key Laboratory of Natural Medicines, Jiangsu Key Laboratory of Drug Discovery for Metabolic Diseases, China Pharmaceutical University, Nanjing 210009, China.
J Control Release. 2016 May 10;229:80-92. doi: 10.1016/j.jconrel.2016.03.001. Epub 2016 Mar 3.
Pretreatment of lung cancer cells with epidermal growth factor receptor (EGFR) inhibitor erlotinib has been recently reported that could dramatically synergize their apoptotic response to DNA damage agent doxorubicin (DOX). To translate this synergistic therapy into in vivo anticancer therapy and clinical practice, we designed a novel pH-sensitive charge conversion nanocarrier (M-HHG2C18-L) that contained erlotinib/DOX combination and produced a sequential staggered drug release for synergistic lung cancer therapy. In this study, a synthetic zwitterionic oligopeptide lipid (1,5-dioctadecyl-l-glutamyl2-histidyl-hexahydrobenzoic acid, HHG2C18) was used to construct a pH-sensitive lipid bilayer (HHG2C18-L), which was subsequently applied to coat amino-functionalized mesoporous silica nanoparticles (MSN-NH2). Erlotinib and DOX were separately incorporated into HHG2C18-L and MSN-NH2 respectively to obtain pH-sensitive charge conversion erlotinib/DOX co-delivery nanoparticles (M-HHG2C18-L(E+D)). We confirmed that M-HHG2C18-L(E+D) were able to reverse surface zeta potential from negative to positive at tumor extracellular pH, thus facilitating the targeted cancer cell internalization. Furthermore, as erlotinib was sequestered in the exterior lipid bilayer and the controlled release ability of MSN-NH2, erlotinib released faster than DOX during the cellular transport. Additionally, HHG2C18-L became more positive at tumor intracellular pH and enhanced Coulombic repulsion with MSN-NH2, leading to increased sequential staggered release of erlotinib and DOX. Due to the pretreatment and time-staggered inhibition of EGFR with erlotinib and the enhanced intracellular release of DOX to the nucleus, the maximized synergistic cell killing effect was achieved. Compared to non-sensitive erlotinib/DOX co-delivery nanoparticles (M-SPC-L(E+D)) and simultaneous DRUG coadministration. M-HHG2C18-L(E+D) with sequential staggered drug release and pH-sensitive charge conversional properties showed great synergistic effects in antiproliferation and apoptosis of A549 human cancer cells in vitro. The in vivo study demonstrated that M-HHG2C18-L(E+D) exhibited considerable tumor accumulation and potent suppression of tumor growth in Lewis lung carcinoma tumor bearing mice. It was also demonstrated that M-HHG2C18-L(E+D) showed no systemic toxicity and possessed distinguished effect on extending survival period. These results suggested that M-HHG2C18-L(E+D) had great potential application in cancer treatment.
表皮生长因子受体(EGFR)抑制剂厄洛替尼预处理肺癌细胞最近被报道可以显著协同其对阿霉素(DOX)的细胞凋亡反应。为了将这种协同治疗转化为体内抗癌治疗和临床实践,我们设计了一种新型的 pH 敏感电荷转换纳米载体(M-HHG2C18-L),它包含厄洛替尼/DOX 联合,并产生顺序交错的药物释放,以实现协同肺癌治疗。在这项研究中,使用合成两性离子寡肽脂质(1,5-二辛基-L-谷氨酰基-2-组氨酰基-己二酸,HHG2C18)构建 pH 敏感脂质双层(HHG2C18-L),随后将其应用于氨基功能化介孔硅纳米粒子(MSN-NH2)。厄洛替尼和 DOX 分别被包封到 HHG2C18-L 和 MSN-NH2 中,以获得 pH 敏感的电荷转换厄洛替尼/DOX 共递药纳米粒子(M-HHG2C18-L(E+D))。我们证实,M-HHG2C18-L(E+D)在肿瘤细胞外 pH 值下能够将表面 ζ 电位从负变为正,从而有利于靶向癌细胞内化。此外,由于厄洛替尼被隔离在外部脂质双层中,并且 MSN-NH2 的控制释放能力,厄洛替尼在细胞运输过程中比 DOX 释放得更快。此外,HHG2C18-L 在肿瘤细胞内 pH 值下变得更正,并增强与 MSN-NH2 的库仑排斥,从而导致厄洛替尼和 DOX 的顺序交错释放增加。由于厄洛替尼的预处理和时间交错抑制 EGFR 以及 DOX 向细胞核的增强细胞内释放,实现了最大的协同细胞杀伤效果。与非敏感的厄洛替尼/DOX 共递药纳米粒子(M-SPC-L(E+D))和同时给药相比。具有顺序交错药物释放和 pH 敏感电荷转换特性的 M-HHG2C18-L(E+D)在体外对 A549 人癌细胞的增殖和凋亡具有很大的协同作用。体内研究表明,M-HHG2C18-L(E+D)在携带 Lewis 肺癌肿瘤的小鼠中具有相当大的肿瘤积累和强大的肿瘤生长抑制作用。还表明,M-HHG2C18-L(E+D)没有全身毒性,并具有延长生存期的显著效果。这些结果表明,M-HHG2C18-L(E+D)在癌症治疗中有很大的应用潜力。
