Slor Gadi, Olea Alis R, Pujals Sílvia, Tigrine Ali, De La Rosa Victor R, Hoogenboom Richard, Albertazzi Lorenzo, Amir Roey J
Department of Organic Chemistry, School of Chemistry, Faculty of Exact Sciences, Tel-Aviv University, Tel-Aviv 6997801, Israel.
Tel Aviv University Center for Nanoscience and Nanotechnology, Tel-Aviv University, Tel-Aviv 6997801, Israel.
Biomacromolecules. 2021 Mar 8;22(3):1197-1210. doi: 10.1021/acs.biomac.0c01708. Epub 2021 Jan 29.
Enzymatically degradable polymeric micelles have great potential as drug delivery systems, allowing the selective release of their active cargo at the site of disease. Furthermore, enzymatic degradation of the polymeric nanocarriers facilitates clearance of the delivery system after it has completed its task. While extensive research is dedicated toward the design and study of the enzymatically degradable hydrophobic block, there is limited understanding on how the hydrophilic shell of the micelle can affect the properties of such enzymatically degradable micelles. In this work, we report a systematic head-to-head comparison of well-defined polymeric micelles with different polymeric shells and two types of enzymatically degradable hydrophobic cores. To carry out this direct comparison, we developed a highly modular approach for preparing clickable, spectrally active enzyme-responsive dendrons with adjustable degree of hydrophobicity. The dendrons were linked with three different widely used hydrophilic polymers-poly(ethylene glycol), poly(2-ethyl-2-oxazoline), and poly(acrylic acid) using the CuAAC click reaction. The high modularity and molecular precision of the synthetic methodology enabled us to easily prepare well-defined amphiphiles that differ either in their hydrophilic block composition or in their hydrophobic dendron. The micelles of the different amphiphiles were thoroughly characterized and their sizes, critical micelle concentrations, drug loading, stability, and cell internalization were compared. We found that the micelle diameter was almost solely dependent on the hydrophobicity of the dendritic hydrophobic block, whereas the enzymatic degradation rate was strongly dependent on the composition of both blocks. Drug encapsulation capacity was very sensitive to the type of the hydrophilic block, indicating that, in addition to the hydrophobic core, the micellar shell also has a significant role in drug encapsulation. Incubation of the spectrally active micelles in the presence of cells showed that the hydrophilic shell significantly affects the micellar stability, localization, cell internalization kinetics, and the cargo release mechanism. Overall, the high molecular precision and the ability of these amphiphiles to report their disassembly, even in complex biological media, allowed us to directly compare the different types of micelles, providing striking insights into how the composition of the micelle shells and cores can affect their properties and potential to serve as nanocarriers.
酶可降解聚合物胶束作为药物递送系统具有巨大潜力,能够在疾病部位选择性释放其活性载药。此外,聚合物纳米载体的酶促降解有助于递送系统在完成任务后清除。尽管大量研究致力于酶可降解疏水嵌段的设计和研究,但对于胶束的亲水壳层如何影响此类酶可降解胶束的性质,人们的了解有限。在这项工作中,我们报告了对具有不同聚合物壳层和两种酶可降解疏水核的明确聚合物胶束进行的系统的直接比较。为了进行这种直接比较,我们开发了一种高度模块化的方法来制备具有可调节疏水性的可点击、具有光谱活性的酶响应树枝状分子。使用铜催化的叠氮-炔环加成(CuAAC)点击反应将树枝状分子与三种不同的广泛使用的亲水聚合物——聚乙二醇、聚(2-乙基-2-恶唑啉)和聚丙烯酸连接起来。合成方法的高模块化和分子精确性使我们能够轻松制备在亲水嵌段组成或疏水树枝状分子方面不同的明确两亲物。对不同两亲物的胶束进行了全面表征,并比较了它们的尺寸、临界胶束浓度、载药量、稳定性和细胞内化情况。我们发现胶束直径几乎完全取决于树枝状疏水嵌段的疏水性,而酶促降解速率强烈取决于两个嵌段的组成。药物包封能力对亲水嵌段的类型非常敏感,这表明除了疏水核外,胶束壳层在药物包封中也起着重要作用。在细胞存在的情况下对具有光谱活性的胶束进行孵育表明,亲水壳层显著影响胶束稳定性、定位、细胞内化动力学和载药释放机制。总体而言,这些两亲物的高分子精确性以及即使在复杂生物介质中也能报告其分解的能力,使我们能够直接比较不同类型的胶束,为胶束壳层和核的组成如何影响其性质以及作为纳米载体的潜力提供了深刻见解。
