Department of Pharmacy, Faculty of Health and Medical Sciences, University of Copenhagen, Universitetsparken 2, DK-2100 Copenhagen Ø, Denmark.
Laboratory of MacroMolecular Cancer Therapeutics (MMCT), Department of Pharmaceutical Chemistry, University of Vienna, Vienna A-1090, Austria.
J Control Release. 2019 Sep 28;310:82-93. doi: 10.1016/j.jconrel.2019.08.004. Epub 2019 Aug 6.
Understanding the release kinetics of siRNA from nanocarriers, their cellular uptake, their in vivo biodistribution and pharmacokinetics is a fundamental prerequisite for efficient optimisation of the design of nanocarriers for siRNA-based therapeutics. Thus, we investigated the influence of composition on the siRNA release from lipid-polymer hybrid nanoparticles (LPNs) consisting of cationic lipidoid 5 (L) and poly(DL-lactic-co-glycolic acid) (PLGA) intended for pulmonary administration. An array of siRNA-loaded LPNs was prepared by systematic variation of: (i) the L content (10-20%, w/w), and (ii) the L:siRNA ratio (10,1-30:1, w/w). For comparative purposes, L-based lipoplexes, L-based stable nucleic acid lipid nanoparticles (SNALPs). and dioleoyltrimethylammoniumpropane (DOTAP)-modified LPNs loaded with siRNA were also prepared. Release studies in buffer and lung surfactant-containing medium showed that siRNA release is dependent on the presence of both surfactant and heparin (a displacing agent) in the release medium, since these interact with the lipid shell structure thereby facilitating decomplexation of L and siRNA, as evident from the retarded siRNA release when the L content and the L:siRNA ratio were increased. This confirms the hypothesis that siRNA loaded in LPNs is predominantly present as complexes with the cationic lipid and primarily is located near the particle surface. Cellular uptake and tolerability studies in the human macrophage cell line THP-1 and the type I-like human alveolar epithelial cell line hAELVi, which together represents a monolayer-based barrier model of lung epithelium, indicated that uptake of LPNs was much higher in THP-1 cells in agreement with their primary clearance role. In vivo biodistributions of formulations loaded with Alexa Fluor® 750-labelled siRNA after pulmonary administration in mice were compared by using quantitative fluorescence imaging tomography. The L-modified LPNs, SNALPs and DOTAP-modified LPNs displayed significantly increased lung retention of siRNA as compared to L-based lipoplexes, which had a biodistribution profile comparable to that of non-loaded siRNA, for which >50% of the siRNA dose permeated the air-blood barrier within 6 h and subsequently was excreted via the kidneys. Hence, the enhanced lung retention upon pulmonary administration of siRNA-loaded LPNs represents a promising characteristic that can be used to control the delivery of the siRNA cargo to lung tissue for local management of disease.
了解 siRNA 从纳米载体中的释放动力学、细胞摄取、体内生物分布和药代动力学,是对基于 siRNA 的治疗用纳米载体进行高效优化设计的基本前提。因此,我们研究了组成对阳离子脂质体 5(L)和聚(DL-乳酸-共-乙醇酸)(PLGA)组成的用于肺部给药的脂质-聚合物杂化纳米颗粒(LPN)中 siRNA 释放的影响。通过系统改变以下参数制备了一系列负载 siRNA 的 LPN:(i)L 的含量(10-20%,w/w),和(ii)L:siRNA 比值(10、1-30:1,w/w)。为了进行比较,还制备了基于 L 的脂质体、基于 L 的稳定核酸脂质纳米颗粒(SNALP)和负载 siRNA 的二油酰基三甲基铵丙烷(DOTAP)修饰的 LPN。在缓冲液和含有肺表面活性剂的介质中的释放研究表明,siRNA 的释放依赖于释放介质中表面活性剂和肝素(置换剂)的存在,因为它们与脂质壳结构相互作用,从而促进 L 和 siRNA 的去复合物化,这从 L 含量和 L:siRNA 比增加时 siRNA 释放延迟得到证实。这证实了这样一种假设,即负载在 LPN 中的 siRNA 主要以与阳离子脂质的复合物形式存在,并且主要位于颗粒表面附近。在人巨噬细胞系 THP-1 和 I 型人肺泡上皮细胞系 hAELVi 中的细胞摄取和耐受性研究中,这些细胞共同代表了肺上皮的单层屏障模型,表明 LPN 的摄取在 THP-1 细胞中要高得多,这与它们的主要清除作用一致。通过使用定量荧光成像体层摄影术比较了负载 Alexa Fluor®750 标记的 siRNA 的制剂在小鼠肺部给药后的体内分布。与基于 L 的脂质体相比,L 修饰的 LPN、SNALP 和 DOTAP 修饰的 LPN 显示出显著增加的 siRNA 肺部保留,而基于 L 的脂质体的分布模式与未负载的 siRNA 相似,其中超过 50%的 siRNA 剂量在 6 小时内渗透到气-血屏障,随后通过肾脏排出。因此,负载 siRNA 的 LPN 肺部给药后增强的肺部保留是一种有前途的特性,可用于控制 siRNA 货物递送至肺部组织,以用于局部疾病管理。
