Division of Molecular Therapeutics and Formulation, School of Pharmacy, University of Nottingham, UK.
Division of Molecular Therapeutics and Formulation, School of Pharmacy, University of Nottingham, UK; Department of Pharmaceutical and Pharmacological Sciences, University of Padova, Padova, Italy.
J Control Release. 2018 May 10;277:126-141. doi: 10.1016/j.jconrel.2018.03.011. Epub 2018 Mar 10.
In the treatment of lung cancer, there is an urgent need of innovative medicines to optimize pharmacological responses of conventional chemotherapeutics while attenuating side effects. Here, we have exploited some relatively unexplored subtle differences in reduction potential, associated with cancer cell microenvironments in addition to the well-known changes in intracellular redox environment. We report the synthesis and application of novel redox-responsive PLGA (poly(lactic-co-glycolic acid)) -PEG (polyethylene glycol) nanoparticles (RR-NPs) programmed to change surface properties when entering tumor microenvironments, thus enhancing cell internalization of the particles and their drug cargo. The new co-polymers, in which PEG and PLGA were linked by 'anchiomeric effector' dithiylethanoate esters, were synthesized by a combination of ring-opening polymerization and Michael addition reactions and employed to prepare NPs. Non redox-responsive nanoparticles (nRR-NPs) based on related PLGA-PEG copolymers were also prepared as comparators. Spherical NPs of around 120 nm diameter with a low polydispersity index and negative zeta potential as well as good drug loading of docetaxel were obtained. The NPs showed prolonged stability in relevant simulated biological fluids and a high ability to penetrate an artificial mucus layer due to the presence of the external PEG coating. Stability, FRET and drug release studies in conditions simulating intracellular reductive environments demonstrated a fast disassembly of the external shell of the NPs, thus triggering on-demand drug release. FACS measurements and confocal microscopy showed increased and faster uptake of RR-NPs in both 2D- and 3D- cell culture models of lung cancer compared to nRR-NPs. In particular, the 'designed-in' reductive instability of RR-NPs in conditioned cell media, the fast PEG release in the extracellular compartment, as well as a diminution of uptake rate in control experiments where extracellular thiols were neutralized, suggested a partial extracellular release of the PEG fringe that promoted rapid internalization of the residual NPs into cells. Taken together, these results provide further evidence of the effectiveness of PEGylated reducible nanocarriers to permeate mucus layer barriers, and establish a new means to enhance cancer cell uptake of drug carriers by extra-and intra-cellular cleavage of protein- and cell-shielding hydrophilic blocks.
在肺癌治疗中,迫切需要创新药物来优化常规化疗的药理反应,同时减轻副作用。在这里,我们利用了一些相对未被探索的还原电位差异,这些差异与癌细胞微环境有关,而不仅仅是细胞内氧化还原环境的已知变化。我们报告了新型氧化还原响应 PLGA(聚乳酸-共-乙醇酸)-PEG(聚乙二醇)纳米粒子(RR-NPs)的合成和应用,这些纳米粒子在进入肿瘤微环境时被编程改变表面特性,从而增强了粒子和药物载体的细胞内化。新型共聚物中,PEG 和 PLGA 通过“手性效应物”二硫代乙醇酸酯连接,通过开环聚合和迈克尔加成反应合成,并用于制备 NPs。还制备了基于相关 PLGA-PEG 共聚物的非氧化还原响应纳米粒子(nRR-NPs)作为对照。得到了约 120nm 直径、低多分散指数和负 zeta 电位以及良好的多西他赛负载的球形 NPs。NP 显示出在相关模拟生物流体中的延长稳定性,并且由于外部 PEG 涂层的存在而具有高穿透人工粘液层的能力。在模拟细胞内还原环境的条件下进行的稳定性、FRET 和药物释放研究表明,NP 的外部壳快速解体,从而触发按需药物释放。FACS 测量和共焦显微镜显示,与 nRR-NPs 相比,RR-NPs 在肺癌的 2D 和 3D 细胞培养模型中具有更高和更快的摄取。特别是,RR-NPs 在条件细胞培养基中的设计还原不稳定性、细胞外隔室中快速 PEG 释放以及在细胞外硫醇被中和的对照实验中摄取率降低,表明 PEG 边缘的部分细胞外释放促进了剩余 NPs 快速进入细胞的内化。总之,这些结果进一步证明了 PEG 化可还原纳米载体穿透粘液层屏障的有效性,并建立了一种通过细胞外和细胞内切割蛋白质和细胞屏蔽亲水性块来增强癌细胞对药物载体摄取的新方法。
