治疗性单克隆抗体的体内鉴定

Xiaobin Xu
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引用次数: 8

摘要

治疗性单克隆抗体(mab)是具有高度异质性的复杂药物分子,包括电荷变异、聚集体、片段和翻译后修饰(PTMs)。ptm可以在单克隆抗体的生产、储存和体内循环过程中通过化学或酶修饰引入。单抗中常见的PTMs包括糖基化、脱酰胺、氧化、糖基化、n端谷氨酰胺环化和c端赖氨酸加工。这些与产品相关的修改被称为产品质量属性(pqa)。给定的PQA有可能影响治疗性单抗的安全性和/或有效性。PQA可增强免疫原性或脱靶结合,从而改变治疗性单抗的安全性。PQA可能改变治疗性单抗与其靶抗原的相互作用,从而改变疗效。影响药物安全性和/或有效性的pqa被认为是关键质量属性(cqa)。监管机构需要在预定义的验收标准内控制pqa,特别是cqa,以确保产品质量、一致性和稳定性。在药物开发过程中,生产过程的目标是最大限度地生产高纯度的所需产品,同时保持最小和一致的变体形式。配方开发旨在稳定单抗产品,并尽量减少储存期间额外形成的变体。在单抗生产和储存过程中发生的变化可以可靠地监测和控制。然而,在给患者施用单抗后,可能会发生额外的修饰。单克隆抗体通常是静脉注射或皮下注射,并迅速进入患者的血液循环。单抗在人体血液系统中的循环半衰期为2-3周。血液环境与制剂缓冲液和储存温度有显著不同。典型的单抗药物产品是在pH值为5-6的情况下配以多种辅料,如糖、盐、氨基酸和表面活性剂。优化了配方缓冲液、pH值和赋形剂,以提高单抗的溶解度/稳定性,降低粘度以及聚集体/颗粒的形成。相比之下,血液是一个动态环境,含有数千种蛋白质,包括许多蛋白质修饰酶,并在pH值7.4和温度37℃下受到严格调节。血液循环中单抗的清除和修饰可能导致PQA谱的改变,导致患者属性暴露增加,有效药物暴露减少,从而引起免疫反应和疗效丧失的担忧。为此,FDA最近的一项行业指南建议申办者在产品设计和开发早期就评估治疗性蛋白质产品对体内环境中修饰的敏感性,以促进产品工程,提高产品在体内条件下的稳定性[1]。因此,PQAs的体内外表征可以监测给药前后的属性稳定性。JOURNAL of APPLIED BIOANALYSIS, 2016, p. 10-15。http://dx.doi.org/10.17145/jab.16.003 (ISSN 2405-710X)第二卷,第1期
本文章由计算机程序翻译,如有差异,请以英文原文为准。
In vivo characterization of therapeutic monoclonal antibodies
Therapeutic monoclonal antibodies (mAbs) are complex drug molecules with a high degree of heterogeneity, including charge variants, aggregates, fragments, and post-translational modifications (PTMs). PTMs can be introduced by chemical or enzymatic modifications over the lifespan of mAbs during production, storage, and in vivo circulation. Common PTMs in mAbs include glycosylation, deamidation, oxidation, glycation, N-terminal glutamine cyclization, and C-terminal lysine processing. These product-related modifications are termed as product quality attributes (PQAs). A given PQA has the potential to impact the safety and/or efficacy of a therapeutic mAb. A PQA may enhance immunogenicity or off-target bindings, resulting in changes of the safety profile of a therapeutic mAb. A PQA may change the interaction of a therapeutic mAb to its target antigen, and therefore alter the efficacy. The PQAs that impact on drug safety and/or efficacy are considered as critical quality attributes (CQAs). Control of PQAs, especially CQAs, within predefined acceptance criteria is required by regulatory agencies to ensure product quality, consistency, and stability. During drug development, manufacturing processes aim to maximize the production of a desired product in high purity with minimal and consistent levels of variant forms. Formulation development seeks to stabilize mAb products and minimize additional formation of variants during storage. The modifications occurred during mAb production and storage can be reliably monitored and controlled. However, additional modifications can occur after a mAb is administered to patients. mAbs are typically administered intravenously or subcutaneously, and quickly get into the circulation of patients. The circulating half-life of a typical mAb in human blood system is 2-3 weeks. The blood environment is remarkably different from formulation buffers and storage temperatures. Typical mAb drug products are formulated at a pH of 5-6 with multiple excipients, such as sugars, salts, amino acids, and surfactants. The formulation buffer, pH, and excipients are optimized to enhance mAb solubility/stability and to reduce viscosity as well as the formation of aggregates/particulates. In contrast, blood is a dynamic environment with thousands of proteins including many protein-modifying enzymes, and is tightly regulated at a pH of 7.4 and a temperature of 37 °C. The clearance and modification of a mAb in blood circulation may result in changes of the PQA profile, leading to increased attribute exposure and decreased effective drug exposure to patients, and therefore causing the concerns of immune responses and loss of efficacy. To this end, a recent FDA guidance for industry recommends sponsors to evaluate susceptibilities of therapeutic protein products to modifications in the in vivo milieu as early as in product design and development, in order to facilitate product engineering for enhancing the product stability under in vivo conditions [1]. Therefore, in vitro and in vivo characterization of PQAs can monitor the attribute stability before and after drug administration and JOURNAL OF APPLIED BIOANALYSIS, January 2016, p. 10-15. http://dx.doi.org/10.17145/jab.16.003 (ISSN 2405-710X) Vol. 2, No. 1
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