Institute for Biomedical Sciences, Digestive Disease Research Group, Georgia State University, Atlanta, GA 30303, USA.
Institute for Biomedical Sciences, Digestive Disease Research Group, Georgia State University, Atlanta, GA 30303, USA; Institute of Medical Engineering, Department of Biophysics, School of Basic Medical Sciences, Xi'an Jiaotong University Health Science Center, Xi'an, Shaanxi 710061, China.
J Control Release. 2020 Jul 10;323:293-310. doi: 10.1016/j.jconrel.2020.04.032. Epub 2020 Apr 23.
The anti-inflammatory drug candidate, 6-shogaol, has demonstrated excellent efficacies in various in vitro studies. However, its rapid metabolism after oral administration results in poor bioavailability and undetectable in vivo pharmacokinetics. Here, we constructed a natural-lipid (NL) nanoparticle drug delivery system (NP-DDS) to encapsulate 6-shogaol and undertake its controlled release to the proposed drug target (colon). Our in vitro drug-release assay revealed that NL-encapsulated 6-shogaol (6-S-NL) exhibits a delayed drug-release profile compared to free 6-shogaol (free-6-S). Consistent with our expectations, orally administrated 6-S-NL exhibits a superior anti-inflammatory efficacy likely due to the controlled release compared to free 6-S in a dextran sulfate sodium (DSS)-induced mouse model of colitis. Although 6-S-NL treatment yields an enhanced concentration of 6-shogaol at the target site (colon), this concentration is still far below the effective level. We hypothesize that the released 6-shogaol undergoes rapid metabolism and that the metabolites of 6-shogaol may contribute to the anti-inflammatory efficacy of 6-S-NL. We thus examined the in vitro anti-inflammatory efficacies of two highly abundant colonic metabolites, M2 (a cysteine-conjugated metabolite) and M13 (a glutathione-conjugated metabolite), against macrophage cells. Reverse transcription-polymerase chain reaction (RT-PCR) data showed that both M2 and M13 (at 1.0 μg/mL) could down-regulate pro-inflammatory factors (TNF-α, IL-1β, and IL-6) and up-regulate an anti-inflammatory factor (IL-10) in inflamed Raw 264.7 cells. Subsequent in vitro wound-healing assays also confirmed that M2 and M13 accelerate the wound recovery process of Caco-2 cells at the concentrations seen in the colon (1.0 μg/mL). Further, in the DSS-induced mouse model of colitis, oral administration of M2- or M13-loaded NL nanoparticles (M2-NL, M13-NL) demonstrated excellent in vivo wound-healing effects, and these activities were better than those observed for 6-S-NL. Combined with the 6-S-NL's bio-distribution assay, our data show that: the 6-shogaol metabolites, M2 and M13, are more potent anti-inflammatory compounds than 6-shogaol itself; NL nanoparticles can effectively deliver 6-shogaol to the colon, with little accumulation seen in the kidney or liver; and the actions of M2 and M13 mostly confer the anti-inflammatory effect of 6-S-NL. Our results explained the discrepancy between the low tissue concentrations of NL delivered 6-shogaol and its effectiveness against ulcerative colitis (UC) in a mouse model. This study paved the way for further developing the NL-loaded active metabolites, M2 or M13, as novel targeted therapeutic approaches for curing UC.
候选抗炎药物 6-姜烯酚在各种体外研究中表现出优异的疗效。然而,它在口服给药后迅速代谢,导致生物利用度差,体内药代动力学不可检测。在这里,我们构建了一种天然脂质 (NL) 纳米颗粒药物递送系统 (NP-DDS) 来包裹 6-姜烯酚并进行其对拟议药物靶点(结肠)的控制释放。我们的体外药物释放试验表明,与游离 6-姜烯酚(游离-6-S)相比,NL 包裹的 6-姜烯酚(6-S-NL)表现出延迟的药物释放特征。与我们的预期一致,口服给予 6-S-NL 表现出优于游离 6-S 的抗炎疗效,这可能是由于在葡聚糖硫酸钠 (DSS) 诱导的结肠炎小鼠模型中与游离 6-S 相比具有控制释放。尽管 6-S-NL 治疗在目标部位(结肠)产生了更高浓度的 6-姜烯酚,但该浓度仍远低于有效水平。我们假设释放的 6-姜烯酚会迅速代谢,而 6-姜烯酚的代谢物可能有助于 6-S-NL 的抗炎疗效。因此,我们检查了两种在结肠中含量丰富的代谢物 M2(半胱氨酸结合代谢物)和 M13(谷胱甘肽结合代谢物)在体外对巨噬细胞的抗炎疗效。逆转录聚合酶链反应 (RT-PCR) 数据显示,M2 和 M13(在 1.0 μg/mL 时)都可以下调炎症 Raw 264.7 细胞中的促炎因子(TNF-α、IL-1β 和 IL-6)并上调抗炎因子(IL-10)。随后的体外伤口愈合试验也证实,M2 和 M13 可在结肠中观察到的浓度(1.0 μg/mL)加速 Caco-2 细胞的伤口愈合过程。此外,在 DSS 诱导的结肠炎小鼠模型中,M2 或 M13 负载的 NL 纳米颗粒(M2-NL、M13-NL)的口服给药表现出优异的体内伤口愈合作用,其活性优于 6-S-NL。结合 6-S-NL 的生物分布试验,我们的数据表明:6-姜烯酚的代谢物 M2 和 M13 比 6-姜烯酚本身更具有抗炎作用;NL 纳米颗粒可以有效地将 6-姜烯酚递送到结肠,在肾脏或肝脏中很少积累;M2 和 M13 的作用主要赋予 6-S-NL 的抗炎作用。我们的结果解释了 NL 递送的 6-姜烯酚的组织浓度低与其在结肠炎小鼠模型中的有效性之间的差异。这项研究为进一步开发 NL 负载的活性代谢物 M2 或 M13 作为治疗溃疡性结肠炎 (UC) 的新型靶向治疗方法铺平了道路。
