测量保护效力并量化抗药性的影响:新型疟疾化学预防试验设计与方法。

IF 15.8 1区 医学 Q1 Medicine PLoS Medicine Pub Date : 2024-05-09 eCollection Date: 2024-05-01 DOI:10.1371/journal.pmed.1004376
Andria Mousa, Gina Cuomo-Dannenburg, Hayley A Thompson, R Matthew Chico, Khalid B Beshir, Colin J Sutherland, David Schellenberg, Roly Gosling, Michael Alifrangis, Emma Filtenborg Hocke, Helle Hansson, Ana Chopo-Pizarro, Wilfred F Mbacham, Innocent M Ali, Mike Chaponda, Cally Roper, Lucy C Okell
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引用次数: 0

摘要

背景:世卫组织最近修订的疟疾化学预防指南为更有针对性的实施打开了大门。各国面临着是否更换旧药、针对更多年龄段人群以及根据当地抗药性水平和疟疾传播模式调整用药计划的选择。定期对化学预防的保护效力进行常规评估是关键所在。在此,我们采用一种新颖的建模方法来帮助设计和分析化学预防试验,并生成可适用于各种传播环境的保护措施:我们建立了一个基因型特异性药物保护模型,该模型考虑了潜在的感染风险和循环基因型。利用贝叶斯框架,我们将模型拟合到多种模拟情景中,以探索研究设计、环境和参与者特征的变化。我们发现,没有药物保护的安慰剂组或对照组很有价值,但并不总是可行。另一种方法是延长随访时间(大于 42 天)的单臂试验,这样可以在药物保护作用减弱后测量潜在的感染风险,只要传播相对稳定即可。我们的研究表明,目前单臂试验推荐的 28 天随访导致 30 天化学预防估计疗效的精确度较低,而且在确定保护期 12 天的基因型差异方面功率较低(功率 = 1.4%)。将随访时间延长至 42 天后,在该时间段内传播稳定的环境中,精确度和功率均有所提高(71.5%)。然而,在传播不稳定的环境中,如果招募发生在传播上升期,则单臂试验的保护效力被高估了 24.3%,如果招募发生在传播下降期,则保护效力被低估了 15.8%。在传播率高的情况下,对保护效力的估计更为精确,而在耐药基因型罕见或过于常见的情况下,检测耐药基因型差异的能力较低:这些研究结果对目前的化学预防疗效研究指南具有重要意义,并将为确定这些研究的最佳位置提供宝贵信息。研究结果强调了在季节性环境中设立比较组的必要性,并提供证据表明,在传播较为稳定的环境中,延长单臂试验的随访时间可提高保护效果测量的准确性。延长随访时间可能会给试验的可行性和相关成本带来后勤方面的挑战。不过,这些研究可能不需要多次重复,因为通过调整传播强度和抗药性频率,针对不同基因型的药物保护估计值可适用于不同环境。
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Measuring protective efficacy and quantifying the impact of drug resistance: A novel malaria chemoprevention trial design and methodology.

Background: Recently revised WHO guidelines on malaria chemoprevention have opened the door to more tailored implementation. Countries face choices on whether to replace old drugs, target additional age groups, and adapt delivery schedules according to local drug resistance levels and malaria transmission patterns. Regular routine assessment of protective efficacy of chemoprevention is key. Here, we apply a novel modelling approach to aid the design and analysis of chemoprevention trials and generate measures of protection that can be applied across a range of transmission settings.

Methods and findings: We developed a model of genotype-specific drug protection, which accounts for underlying risk of infection and circulating genotypes. Using a Bayesian framework, we fitted the model to multiple simulated scenarios to explore variations in study design, setting, and participant characteristics. We find that a placebo or control group with no drug protection is valuable but not always feasible. An alternative approach is a single-arm trial with an extended follow-up (>42 days), which allows measurement of the underlying infection risk after drug protection wanes, as long as transmission is relatively constant. We show that the currently recommended 28-day follow-up in a single-arm trial results in low precision of estimated 30-day chemoprevention efficacy and low power in determining genotype differences of 12 days in the duration of protection (power = 1.4%). Extending follow-up to 42 days increased precision and power (71.5%) in settings with constant transmission over this time period. However, in settings of unstable transmission, protective efficacy in a single-arm trial was overestimated by 24.3% if recruitment occurred during increasing transmission and underestimated by 15.8% when recruitment occurred during declining transmission. Protective efficacy was estimated with greater precision in high transmission settings, and power to detect differences by resistance genotype was lower in scenarios where the resistant genotype was either rare or too common.

Conclusions: These findings have important implications for the current guidelines on chemoprevention efficacy studies and will be valuable for informing where these studies should be optimally placed. The results underscore the need for a comparator group in seasonal settings and provide evidence that the extension of follow-up in single-arm trials improves the accuracy of measures of protective efficacy in settings with more stable transmission. Extension of follow-up may pose logistical challenges to trial feasibility and associated costs. However, these studies may not need to be repeated multiple times, as the estimates of drug protection against different genotypes can be applied to different settings by adjusting for transmission intensity and frequency of resistance.

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来源期刊
PLoS Medicine
PLoS Medicine MEDICINE, GENERAL & INTERNAL-
CiteScore
17.60
自引率
0.60%
发文量
227
审稿时长
4-8 weeks
期刊介绍: PLOS Medicine is a prominent platform for discussing and researching global health challenges. The journal covers a wide range of topics, including biomedical, environmental, social, and political factors affecting health. It prioritizes articles that contribute to clinical practice, health policy, or a better understanding of pathophysiology, ultimately aiming to improve health outcomes across different settings. The journal is unwavering in its commitment to uphold the highest ethical standards in medical publishing. This includes actively managing and disclosing any conflicts of interest related to reporting, reviewing, and publishing. PLOS Medicine promotes transparency in the entire review and publication process. The journal also encourages data sharing and encourages the reuse of published work. Additionally, authors retain copyright for their work, and the publication is made accessible through Open Access with no restrictions on availability and dissemination. PLOS Medicine takes measures to avoid conflicts of interest associated with advertising drugs and medical devices or engaging in the exclusive sale of reprints.
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