Binder Uli, Skerra Arne
XL-protein GmbH, Freising, Germany.
Lehrstuhl für Biologische Chemie, Technische Universität München, Freising, Germany.
Expert Opin Biol Ther. 2025 Jan;25(1):93-118. doi: 10.1080/14712598.2024.2436094. Epub 2024 Dec 11.
Engineering of the drug half-life in vivo has become an integral part of modern biopharmaceutical development due to the fact that many proteins/peptides with therapeutic potential are quickly cleared by kidney filtration after injection and, thus, circulate only a few hours in humans (or just minutes in mice).
Looking at the growing list of clinically approved biologics that have been modified for prolonged activity, and also the plethora of such drugs under preclinical and clinical development, it is evident that not one solution fits all needs, owing to the vastly different structural features and functional properties of the pharmacologically active entities. This article provides an overview of established half-life extension strategies, as well as of emerging novel concepts for extending the in vivo stability of biologicals, and their pros and cons.
Beyond the classical and still dominating technologies for improving drug pharmacokinetics and bioavailability, Fc fusion and PEGylation, various innovative approaches that offer advantages in different respects have entered the clinical stage. While the Fc fusion partner may be gradually superseded by engineered albumin-binding domains, chemical PEGylation may be replaced by biodegradable recombinant amino-acid polymers like PASylation, thus also offering a purely biotechnological manufacturing route.
由于许多具有治疗潜力的蛋白质/肽在注射后会通过肾脏滤过迅速清除,因此在人体内仅循环数小时(在小鼠体内仅数分钟),所以体内药物半衰期的工程化已成为现代生物制药开发不可或缺的一部分。
鉴于临床上已批准的经修饰以延长活性的生物制品清单不断增加,以及大量处于临床前和临床开发阶段的此类药物,显然由于药理活性实体的结构特征和功能特性差异巨大,没有一种解决方案能满足所有需求。本文概述了已确立的半衰期延长策略,以及延长生物制品体内稳定性的新兴概念及其优缺点。
除了用于改善药物药代动力学和生物利用度的经典且仍占主导地位的技术,即Fc融合和聚乙二醇化之外,各种在不同方面具有优势的创新方法已进入临床阶段。虽然Fc融合伙伴可能会逐渐被工程化白蛋白结合域取代,但化学聚乙二醇化可能会被诸如PASylation等可生物降解的重组氨基酸聚合物取代,从而也提供了一条纯粹的生物技术制造途径。
