Department of Life Sciences, Faculty of Natural Sciences, Imperial College London, London, UK.
Expert Opin Drug Deliv. 2011 Sep;8(9):1221-36. doi: 10.1517/17425247.2011.602399.
The use of hydrophilic polymers as a substitute for the Fc-domain in immuno- or non-immuno-based binding proteins is accelerating. Chemical PEGylation has led the way and is still the most advanced and clinically-approved approach. Hydrophilic polymers act by maintaining a flexible conformation and hydrogen bonding to a network of water molecules to acquire a larger hydrodynamic volume and apparent mass than their actual molecular mass suggest. The benefits are increased blood half-life and bioavailability, stability and reduced immunogenicity. In the case of PEG, there is also evidence of enhanced targeting and reduced side effects, but drawbacks include the fact that PEG is non-biodegradable.
This report reviews the state of the art for antibody PEGylation in terms of approaches and effects. Additionally, non-biological (such as N-(2-hydroxypropyl)methacrylamide) and potentially superior biological alternatives (such as polysialylation) are described, ending with recombinant approaches (such as hydrophilic peptides and glyco-engineering), which promise to circumvent the need for chemical modification altogether.
The emergence of many small, antibody fragment-like mimics will drive the need for such technologies, and PEGylation is still the choice polymer due to its established use and track record. However, there will be a place for many alternative technologies if they can match the pharmacokinetics of PEG-conjugates and bring addition beneficial features such as easier production.
将亲水性聚合物用作免疫或非免疫结合蛋白的 Fc 结构域替代物的应用正在加速。化学 PEG 化已成为主流,并且仍然是最先进且经过临床批准的方法。亲水性聚合物通过保持灵活的构象并通过氢键与水分子网络结合来起作用,从而获得比其实际分子量所暗示的更大的流体力学体积和表观质量。其优点是增加血液半衰期和生物利用度、稳定性和降低免疫原性。在 PEG 的情况下,也有证据表明其靶向性增强和副作用减少,但缺点包括 PEG 不可生物降解。
本报告从方法和效果两方面综述了抗体 PEG 化的最新技术。此外,还描述了非生物(如 N-(2-羟丙基)甲基丙烯酰胺)和潜在更优越的生物替代品(如多唾液酸化),最后介绍了重组方法(如亲水性肽和糖工程),这些方法有望完全避免化学修饰的需要。
许多小的、抗体片段样模拟物的出现将推动对这类技术的需求,而且由于其已有的用途和良好的记录,PEG 化仍然是首选聚合物。然而,如果替代技术能够与 PEG 缀合物的药代动力学相匹配,并带来更容易生产等附加有益特性,那么它们将有一席之地。
