Univ. Grenoble Alpes, Centre de Recherches sur les Macromolécules Végétales (CERMAV-CNRS), 601, rue de la Chimie, BP 53, 38041 Grenoble Cedex 9, France.
Laboratory of technological innovation in the development of pharmaceuticals and cosmetics, State University of Maringa, Colombo Avenue, 5790, 87020-900, Maringa, Brazil.
Biomater Sci. 2019 Jul 1;7(7):2850-2860. doi: 10.1039/c9bm00443b. Epub 2019 May 9.
Glycosaminoglycans (GAGs) are important components of the extracellular matrix that have attracted great interest for drug delivery and pharmaceutical applications due to their diverse biological functions. Among GAGs, heparosan (Hep), a biosynthetic precursor of heparin, has recently emerged as a promising building block for the design of nanoparticles with stealth properties. Though this non-sulfated polysaccharide has a chemical structure very close to that of hyaluronic acid (HA), it distinguishes from HA in that it is biologically inert in the extracellular spaces in the body. In this study, we designed Hep- and HA-based nanogels (NGs) that differ only in the chemical nature of the hydrophilic shell. The nanogels were prepared in a very straightforward way from Hep and HA modified with a thermoresponsive copolymer properly designed to induce self-assembly below room temperature. This versatile synthetic approach also enabled further shell-crosslinking allowing an increase in the colloidal stability. After careful characterization of the un-crosslinked and crosslinked Hep and HA NGs in terms of size (Z-average diameters of un-crosslinked and crosslinked NGs ∼110 and 150 nm) and morphology, they were injected intravenously into tumor-bearing mice for biodistribution experiments. Interestingly, these show that the liver uptake of Hep nanogels is remarkably reduced and tumor accumulation significantly improved as compared to HA nanogels (intensity ratios of tumor-to-liver of 2.2 and 1.4 for the un-crosslinked and crosslinked Hep NGs versus 0.11 for the un-crosslinked and crosslinked HA ones). These results highlight the key role played by the shell-forming GAGs on the in vivo fate of nanogels, which correlates with the specific biological properties of Hep and HA.
糖胺聚糖(GAGs)是细胞外基质的重要组成部分,由于其具有多种生物学功能,因此在药物输送和药物应用方面引起了极大的关注。在 GAGs 中,肝素的生物合成前体肝素聚糖(Hep)最近作为具有隐身特性的纳米粒子设计的有前途的构建块出现。尽管这种非硫酸化多糖的化学结构与透明质酸(HA)非常接近,但它与 HA 的区别在于,它在体内细胞外空间中具有生物惰性。在这项研究中,我们设计了基于 Hep 和 HA 的纳米凝胶(NG),它们仅在亲水性壳的化学性质上有所不同。纳米凝胶是通过用适当设计的热响应性共聚物修饰的 Hep 和 HA 非常简单地制备的,该共聚物在室温以下诱导自组装。这种多功能的合成方法还允许进一步的壳交联,从而提高胶体稳定性。在对未交联和交联的 Hep 和 HA NG 进行了尺寸(未交联和交联的 NG 的 Z-平均直径分别约为 110 和 150nm)和形态的仔细表征之后,将它们静脉内注射到荷瘤小鼠中进行生物分布实验。有趣的是,与 HA 纳米凝胶相比,这些结果表明 Hep 纳米凝胶的肝脏摄取明显减少,并且肿瘤积聚得到了显著改善(未交联和交联的 Hep NG 的肿瘤与肝脏的强度比分别为 2.2 和 1.4,而未交联和交联的 HA NG 分别为 0.11)。这些结果突出了壳形成 GAGs 在纳米凝胶体内命运中的关键作用,这与 Hep 和 HA 的特定生物学特性相关。
