快速开发注册系统,加快 COVID-19 疫苗临床试验。

Neil F Abernethy, Kylie McCloskey, Meg Trahey, Laurie Rinn, Gail B Broder, Michele Andrasik, Rebecca Laborde, Daniel McGhan, Scott Spendolini, Senthil Marimuthu, Adam Kanzmeier, Jayson Hanes, James Kublin
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摘要

背景 2020 年,针对 SARS-Cov-2 大流行采取了前所未有的科学应对措施,这要求迅速开发和启动广泛的临床试验网络,以研究疫苗和疗法。COVID-19 预防网络(CoVPN)协调了数百个站点开展疫苗和抗体疗法的 2 期和 3 期临床试验。为了促进这些临床试验,我们创建了 CoVPN 志愿者筛选注册表 (VSR),以大规模收集志愿者信息、识别符合注册标准的 COVID-19 高危志愿者、在各临床试验点分发候选者,并监控志愿服务和注册进度。方法 我们开发了一个安全数据库,以支持三个主要的网络界面:全国志愿者问卷接收表、临床试验机构门户网站和管理门户网站。临床试验机构门户网站支持基于志愿者属性的过滤器、可视化分析、注册状态跟踪、地理搜索和临床风险预测。行政门户网站支持监督和开发,提供按地域、试验和试验场地汇总的预先指定报告;随时间变化的志愿者比率图表;志愿者风险评分计算;以及用户自定义的动态报告。研究结果 65 万多名志愿者加入了 VSR,1094 名用户接受了系统使用培训。VSR 在 Moderna、Oxford-AstraZeneca、Janssen 和 Novavax 疫苗临床试验的招募中发挥了关键作用,为辉瑞和赛诺菲的疫苗和预防性抗体临床试验提供了支持,并增强了试验参与者的多样性。临床试验基地选择了 166729 份志愿者记录进行跟踪筛查,其中 47%-7% 代表了优先增加注册人数的群体。尽管开发工作空前紧迫,但系统仍保持了 99-99% 的正常运行时间。释义 VSR 的成功表明,可以通过公私合作的方式快速安全地开发信息工具,并将其整合到分布式加速临床试验环境中。我们进一步总结了该系统的要求、设计和开发,并讨论了为未来大流行病防备工作吸取的经验教训。
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Rapid Development of a Registry to Accelerate COVID-19 Vaccine Clinical Trials.

Background: The unprecedented scientific response to the SARS-Cov-2 pandemic in 2020 required the rapid development and activation of extensive clinical trial networks to study vaccines and therapeutics. The COVID-19 Prevention Network (CoVPN) coordinated hundreds of sites conducting phase 2 and 3 clinical trials of vaccines and antibody therapeutics. To facilitate these clinical trials, the CoVPN Volunteer Screening Registry (VSR) was created to collect volunteer information at scale, identify volunteers at risk of COVID-19 who met enrollment criteria, distribute candidates across clinical trial sites, and enable monitoring of volunteering and enrollment progress.

Methods: We developed a secure database to support three primary web-based interfaces: a national volunteer questionnaire intake form, a clinical trial site portal, and an Administrative Portal. The Site Portal supported filters based on volunteer attributes, visual analytics, enrollment status tracking, geographic search, and clinical risk prediction. The Administrative Portal supported oversight and development with pre-specified reports aggregated by geography, trial, and trial site; charts of volunteer rates over time; volunteer risk score calculation; and dynamic, user-defined reports.

Findings: Over 650,000 volunteers joined the VSR, and 1094 users were trained to utilize the system. The VSR played a key role in recruitment for the Moderna, Oxford-AstraZeneca, Janssen, and Novavax vaccine clinical trials, provided support to the Pfizer and Sanofi vaccine and prophylactic antibody clinical trials, and enhanced the diversity of trial participants. Clinical trial sites selected 166,729 volunteer records for follow-up screening, and of these 47·7% represented groups prioritized for increased enrollment. Despite the unprecedented urgency of its development, the system maintained 99·99% uptime.

Interpretation: The success of the VSR demonstrates that information tools can be rapidly yet safely developed through a public-private partnership and integrated into a distributed and accelerated clinical trial setting. We further summarize the requirements, design, and development of the system, and discuss lessons learned for future pandemic preparedness.

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