Jiang Yonghou, Cao Shijie, Bright Danielle K, Bever Alaina M, Blakney Anna K, Suydam Ian T, Woodrow Kim A
Department of Bioengineering, University of Washington , Seattle, Washington 98195, United States.
Department of Chemistry, Seattle University , Seattle, Washington 98122, United States.
Mol Pharm. 2015 Dec 7;12(12):4363-74. doi: 10.1021/acs.molpharmaceut.5b00544. Epub 2015 Nov 18.
Nanocarrier-based drug delivery systems are playing an emerging role in human immunodeficiency virus (HIV) chemoprophylaxis and treatment due to their ability to alter the pharmacokinetics and improve the therapeutic index of various antiretroviral (ARV) drug compounds used alone and in combination. Although several nanocarriers have been described for combination delivery of ARV drugs, measurement of drug-drug activities facilitated by the use of these nanotechnology platforms has not been fully investigated for topical prevention. Here, we show that physicochemically diverse ARV drugs can be encapsulated within polymeric nanoparticles to deliver multidrug combinations that provide potent HIV chemoprophylaxis in relevant models of cell-free, cell-cell, and mucosal tissue infection. In contrast to existing approaches that coformulate ARV drug combinations together in a single nanocarrier, we prepared single-drug-loaded nanoparticles that were subsequently combined upon administration. ARV drug-nanoparticles were prepared using emulsion-solvent evaporation techniques to incorporate maraviroc (MVC), etravirine (ETR), and raltegravir (RAL) into poly(lactic-co-glycolic acid) (PLGA) nanoparticles. We compared the antiviral potency of the free and formulated drug combinations for all pairwise and triple drug combinations against both cell-free and cell-associated HIV-1 infection in vitro. The efficacy of ARV-drug nanoparticle combinations was also assessed in a macaque cervicovaginal explant model using a chimeric simian-human immunodeficiency virus (SHIV) containing the reverse transcriptase (RT) of HIV-1. We observed that our ARV-NPs maintained potent HIV inhibition and were more effective when used in combinations. In particular, ARV-NP combinations involving ETR-NP exhibited significantly higher antiviral potency and dose-reduction against both cell-free and cell-associated HIV-1 BaL infection in vitro. Furthermore, ARV-NP combinations that showed large dose-reduction were identified to be synergistic, whereas the equivalent free-drug combinations were observed to be strictly additive. Higher intracellular drug concentration was measured for cells dosed with the triple ARV-NP combination compared to the equivalent unformulated drugs. Finally, as a first step toward evaluating challenge studies in animal models, we also show that our ARV-NP combinations inhibit RT-SHIV virus propagation in macaque cervicovaginal tissue and block virus transmission by migratory cells emigrating from the tissue. Our results demonstrate that ARV-NP combinations control HIV-1 transmission more efficiently than free-drug combinations. These studies provide a rationale to better understand the role of nanocarrier systems in facilitating multidrug effects in relevant cells and tissues associated with HIV infection.
基于纳米载体的药物递送系统在人类免疫缺陷病毒(HIV)化学预防和治疗中发挥着越来越重要的作用,因为它们能够改变药代动力学,并提高单独使用或联合使用的各种抗逆转录病毒(ARV)药物化合物的治疗指数。尽管已经描述了几种用于联合递送ARV药物的纳米载体,但利用这些纳米技术平台促进的药物-药物活性测量尚未针对局部预防进行充分研究。在这里,我们表明,物理化学性质不同的ARV药物可以封装在聚合物纳米颗粒中,以递送多药组合,从而在无细胞、细胞-细胞和粘膜组织感染的相关模型中提供有效的HIV化学预防。与在单个纳米载体中共同配制ARV药物组合的现有方法不同,我们制备了单药负载的纳米颗粒,随后在给药时将它们组合。使用乳液-溶剂蒸发技术制备ARV药物纳米颗粒,将马拉维若(MVC)、依曲韦林(ETR)和拉替拉韦(RAL)纳入聚(乳酸-共-乙醇酸)(PLGA)纳米颗粒中。我们比较了游离药物组合和配制药物组合对所有成对和三联药物组合在体外针对无细胞和细胞相关HIV-1感染的抗病毒效力。还使用含有HIV-1逆转录酶(RT)的嵌合猿猴-人类免疫缺陷病毒(SHIV)在猕猴宫颈阴道外植体模型中评估了ARV药物纳米颗粒组合的疗效。我们观察到我们的ARV纳米颗粒保持了强大的HIV抑制作用,并且联合使用时更有效。特别是,涉及ETR纳米颗粒的ARV纳米颗粒组合在体外对无细胞和细胞相关HIV-1 BaL感染表现出显著更高的抗病毒效力和剂量降低。此外,显示出大剂量降低的ARV纳米颗粒组合被确定为具有协同作用,而观察到等效的游离药物组合严格相加。与等效的未配制药物相比,用三联ARV纳米颗粒组合给药的细胞测量到更高的细胞内药物浓度。最后,作为评估动物模型挑战研究的第一步,我们还表明我们的ARV纳米颗粒组合抑制猕猴宫颈阴道组织中的RT-SHIV病毒传播,并阻断从组织中迁出的迁移细胞的病毒传播。我们的结果表明,ARV纳米颗粒组合比游离药物组合更有效地控制HIV-1传播。这些研究为更好地理解纳米载体系统在促进与HIV感染相关的相关细胞和组织中的多药作用提供了理论依据。
