State Key Laboratory of Biotherapy, West China Hospital, West China Medical School, Sichuan University, Chengdu 610041, PR China.
Biomaterials. 2013 Nov;34(34):8726-40. doi: 10.1016/j.biomaterials.2013.07.092. Epub 2013 Aug 12.
In this study, a pH-thermal dual responsive nanogel was applied for cisplatin (CDDP) delivery. CDDP was loaded into the nanogels via conjugation with the carboxyl groups in the nanogels. The conjugation was confirmed by FTIR and XPS. The bonding between CDDP and COOH can be broken by the H(+) or Cl(-). We found that the CDDP released much faster at more acidic environment. The Cl(-) concentration in the human body is about 95-105 mm. The conjugated bond could be easily attacked by Cl(-) while the nanosystem is injected into the body. In order to diminish the Cl(-) triggering release of CDDP from the nanogels, we introduced a thermal-responsive units-NIPAm into the nanogel structure. After NIPAm introduced, the CDDP released much slower from the nanogels at 37 °C in pH = 7.38 buffer in the present of Cl(-) (150 mm) than that without NIPAm. And the CDDP also released slower from the nanogels at 37 °C than at 25 °C. By in vitro release behavior studying, we found that CDDP release from the NIPAm containing nanogels can be accelerated by H(+) attacking and reduced by temperature arising. By cellular uptake observation, we found that the nanogels were mainly localized in the cytoplasm of the cancer cells. The CDDP-loaded nanogels exhibited longer circulation time in vivo while compared to free CDDP. And it has better anti-cancer performance than free CDDP in vivo therapy of breast cancer in mice model. Furthermore, some side effects of CDDP, such as renal toxicity, phlebitis, bone marrow suppression etc. have also been reduced by nanogels loading. The in vitro and in vivo results demonstrated that the dual responsible nanogel is a suitable CDDP delivery candidate.
在这项研究中,应用了一种 pH-热双重响应纳米凝胶来递送顺铂(CDDP)。CDDP 通过与纳米凝胶中的羧基结合而被载入纳米凝胶中。FTIR 和 XPS 证实了这种结合。CDDP 与 COOH 之间的键可以被 H(+)或 Cl(-)打破。我们发现,在更酸性的环境中,CDDP 的释放速度更快。人体中的 Cl(-)浓度约为 95-105mm。当纳米系统注入体内时,共轭键很容易被 Cl(-)攻击。为了减少 Cl(-)从纳米凝胶中触发 CDDP 的释放,我们在纳米凝胶结构中引入了一种热响应单元-NIPAm。引入 NIPAm 后,在 pH = 7.38 缓冲液中,即使存在 Cl(-)(150mm),纳米凝胶中 CDDP 的释放速度也比没有 NIPAm 时慢得多。而且,在 37°C 时,CDDP 的释放速度也比在 25°C 时慢。通过体外释放行为研究,我们发现,H(+)的攻击可以加速 NIPAm 含纳米凝胶中 CDDP 的释放,而温度的升高会减少 CDDP 的释放。通过细胞摄取观察,我们发现纳米凝胶主要定位于癌细胞的细胞质中。与游离 CDDP 相比,载药纳米凝胶在体内的循环时间更长。并且在荷瘤小鼠模型中,其体内治疗效果优于游离 CDDP。此外,纳米凝胶载药还降低了 CDDP 的一些副作用,如肾毒性、静脉炎、骨髓抑制等。体外和体内结果表明,双重响应纳米凝胶是一种合适的 CDDP 递送候选物。
