Roberts Brian J, Mattei Aimee E, Howard Kristina E, Weaver James L, Liu Hao, Lelias Sandra, Martin William D, Verthelyi Daniela, Pang Eric, Edwards Katie J, De Groot Anne S
EpiVax Inc., Providence, RI, United States.
Division of Applied Regulatory Sciences, Office of Clinical Pharmacology, Office of Translational Sciences, Center for Drug Evaluation and Research, U.S. Food and Drug Administration, Silver Spring, MD, United States.
Front Pharmacol. 2024 Aug 9;15:1363139. doi: 10.3389/fphar.2024.1363139. eCollection 2024.
Advances in synthetic peptide synthesis have enabled rapid and cost-effective peptide drug manufacturing. For this reason, peptide drugs that were first produced using recombinant DNA (rDNA) technology are now being produced using solid- and liquid-phase peptide synthesis. While peptide synthesis has some advantages over rDNA expression methods, new peptide-related impurities that differ from the active pharmaceutical ingredient (API) may be generated during synthesis. These impurity byproducts of the original peptide sequence feature amino acid insertions, deletions, and side-chain modifications that may alter the immunogenicity risk profile of the drug product. Impurities resulting from synthesis have become the special focus of regulatory review and approval for human use, as outlined in the FDA's Center for Drug Evaluation and Research guidance document, "ANDAs for Certain Highly Purified Synthetic Peptide Drug Products That Refer to Listed Drugs of rDNA Origin," published in 2021. This case study illustrates how and methods can be applied to assess the immunogenicity risk of impurities that may be present in synthetic generic versions of the salmon calcitonin (SCT) drug product. Sponsors of generic drug abbreviated new drug applications (ANDAs) should consider careful control of these impurities (for example, keeping the concentration of the immunogenic impurities below the cut-off recommended by FDA regulators). Twenty example SCT impurities were analyzed using tools and assessed as having slightly more or less immunogenic risk potential relative to the SCT API peptide. Class II human leukocyte antigen (HLA)-binding assays provided independent confirmation that a 9-mer sequence present in the C-terminus of SCT binds promiscuously to multiple HLA DR alleles, while T-cell assays confirmed the expected T-cell responses to SCT and selected impurities. analysis combined with assays that directly compare the API to each individual impurity peptide may be a useful approach for assessing the potential immunogenic risk posed by peptide impurities that are present in generic drug products.
合成肽合成技术的进步使得肽类药物能够快速且经济高效地生产。因此,最初使用重组DNA(rDNA)技术生产的肽类药物现在正采用固相和液相肽合成法进行生产。虽然肽合成相对于rDNA表达方法具有一些优势,但在合成过程中可能会产生与活性药物成分(API)不同的新型肽相关杂质。这些原始肽序列的杂质副产物具有氨基酸插入、缺失和侧链修饰,可能会改变药品的免疫原性风险特征。如美国食品药品监督管理局(FDA)药品评价和研究中心2021年发布的指导文件《某些参考rDNA来源上市药物的高度纯化合成肽类药品的仿制药申请》所述,合成产生的杂质已成为人类用药监管审评和批准的特别关注重点。本案例研究说明了如何应用[具体方法1]和[具体方法2]来评估鲑鱼降钙素(SCT)药品仿制药版本中可能存在的杂质的免疫原性风险。仿制药简略新药申请(ANDA)的申办者应考虑仔细控制这些杂质(例如,将免疫原性杂质的浓度保持在FDA监管机构建议的临界值以下)。使用[具体工具]对20种SCT杂质示例进行了分析,并评估其相对于SCT API肽的免疫原性风险潜力略高或略低。II类人类白细胞抗原(HLA)结合试验提供了独立确认,即SCT C末端存在的一个9聚体序列可与多个HLA DR等位基因发生非特异性结合,而T细胞试验证实了对SCT和选定杂质的预期T细胞反应。将[具体分析方法]与直接将API与每个单独杂质肽进行比较的[具体试验]相结合,可能是评估仿制药中存在的肽杂质所带来的潜在免疫原性风险的有用方法。
