Further Accelerating Biologics Development from DNA to IND: The Journey from COVID-19 to Non-COVID-19 Programs

Q2 Medicine Antibody Therapeutics Pub Date : 2024-01-24 DOI:10.1093/abt/tbae001
Kee Wee Tan, Pengfei Ji, Hang Zhou, Sam Zhang, Weichang Zhou
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引用次数: 0

Abstract

The COVID-19 pandemic has spurred adoption of revolutionary initiatives by regulatory agencies and pharmaceutical industry worldwide to deliver therapeutic COVID-19 antibodies to patients at unprecedented speed. Among these, timeline of Chemistry, Manufacturing, and Control (CMC), which involves process development and manufacturing activities critical for the assurance of product quality and consistency before first-in-human clinical trials, was greatly reduced from typically 12-15 months (using clonal materials) to approximately 3 months (using non-clonal materials) in multiple cases. In this perspective, we briefly review the acceleration approaches published for therapeutic COVID-19 antibodies and subsequently discuss the applicability of these approaches to achieve investigational new drug (IND) timelines of ≤10 months in over 60 COVID-19 and non-COVID-19 programs performed at WuXi Biologics. We are of the view that, with demonstrated product quality and consistency, innovative approaches used for COVID-19 can be widely applied in all disease areas for greater speed to clinic.
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进一步加快从 DNA 到 IND 的生物制剂开发:从 COVID-19 到非 COVID-19 计划的历程
COVID-19 大流行促使全球监管机构和制药业采取了革命性举措,以前所未有的速度向患者提供治疗用 COVID-19 抗体。其中,化学、制造和控制(CMC)的时限从通常的 12-15 个月(使用克隆材料)大大缩短到多个案例中的约 3 个月(使用非克隆材料),而 CMC 涉及的工艺开发和制造活动对保证首次人体临床试验前的产品质量和一致性至关重要。在本文中,我们简要回顾了已发表的COVID-19治疗性抗体加速方法,随后讨论了这些方法在药明康德执行的60多个COVID-19和非COVID-19项目中实现新药临床试验(IND)时间≤10个月的适用性。我们认为,在产品质量和一致性得到证明的情况下,用于 COVID-19 的创新方法可广泛应用于所有疾病领域,以更快地进入临床。
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来源期刊
Antibody Therapeutics
Antibody Therapeutics Medicine-Immunology and Allergy
CiteScore
8.70
自引率
0.00%
发文量
30
审稿时长
8 weeks
期刊最新文献
AI-based antibody discovery platform identifies novel, diverse, and pharmacologically active therapeutic antibodies against multiple SARS-CoV-2 strains. FcRider: a recombinant Fc nanoparticle with endogenous adjuvant activities for hybrid immunization. A pan-allelic human SIRPα-blocking antibody, ES004-B5, promotes tumor killing by enhancing macrophage phagocytosis and subsequently inducing an effective T-cell response. Correction to: A case study of a bispecific antibody manufacturability assessment and optimization during discovery stage and its implications. The process using a synthetic library that generates multiple diverse human single domain antibodies.
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