Parker Daniel M, Landier Jordi, von Seidlein Lorenz, Dondorp Arjen, White Lisa, Hanboonkunupakarn Borimas, Maude Richard J, Nosten François H
Shoklo Malaria Research Unit, Mahidol-Oxford Tropical Medicine Research Unit, Faculty of Tropical Medicine, Mahidol University, Mae Sot, Tak, Thailand.
Mahidol-Oxford Tropical Medicine Research Unit, Faculty of Tropical Medicine, Mahidol University, Bangkok, Thailand.
Malar J. 2016 Nov 25;15(1):571. doi: 10.1186/s12936-016-1631-9.
Reactive case detection is an approach that has been proposed as a tool for malaria elimination in low-transmission settings. It is an intuitively justified approach based on the concept of space-time clustering of malaria cases. When an index malaria clinical case is detected, it triggers reactive screening and treatment in the index house and neighbouring houses. However, the efficacy of this approach at varying screening radii and malaria prevalence remains ill defined.
Data were obtained from a detailed demographic and geographic surveillance study in four villages on the Myanmar-Thailand border. Clinical cases were recorded at village malaria clinics and were linked back to patients' residencies. These data were used to simulate the efficacy of reactive case detection for clinical cases using rapid diagnostic tests (RDT). Simulations took clinical cases in a given month and tabulated the number of cases that would have been detected in the following month at varying screening radii around the index houses. Simulations were run independently for both falciparum and vivax malaria. Each simulation of a reactive case detection effort was run in comparison with a strategy using random selection of houses for screening.
In approximately half of the screenings for falciparum and 10% for vivax it would have been impossible to detect any malaria cases regardless of the screening strategy because the screening would have occurred during times when there were no cases. When geographically linked cases were present in the simulation, reactive case detection would have only been successful at detecting most malaria cases using larger screening radii (150-m radius and above). At this screening radius and above, reactive case detection does not perform better than random screening of an equal number of houses in the village. Screening within very small radii detects only a very small proportion of cases, but despite this low performance is better than random screening with the same sample size.
The results of these simulations indicate that reactive case detection for clinical cases using RDTs has limited ability in halting transmission in regions of low and unstable transmission. This is linked to high spatial heterogeneity of cases, acquisition of malaria infections outside the village, as well missing asymptomatic infections. When cases are few and sporadic, reactive case detection would result in major time and budgetary losses.
反应性病例检测是一种被提议作为在低传播环境中消除疟疾工具的方法。它是一种基于疟疾病例时空聚集概念的直观合理方法。当检测到首例疟疾病例时,会在该病例所在房屋及相邻房屋触发反应性筛查和治疗。然而,这种方法在不同筛查半径和疟疾流行率下的效果仍不明确。
数据来自对缅甸 - 泰国边境四个村庄进行的详细人口和地理监测研究。临床病例在村庄疟疾诊所记录,并与患者居住地相关联。这些数据用于模拟使用快速诊断测试(RDT)对临床病例进行反应性病例检测的效果。模拟选取给定月份的临床病例,并列出在次月围绕首例病例所在房屋不同筛查半径下本可检测到的病例数。分别针对恶性疟和间日疟进行独立模拟。每次反应性病例检测模拟均与随机选择房屋进行筛查的策略进行比较。
在大约一半的恶性疟筛查中以及10%的间日疟筛查中,无论采用何种筛查策略,都不可能检测到任何疟疾病例,因为筛查发生在无病例的时期。当模拟中存在地理关联病例时,反应性病例检测只有在使用较大筛查半径(半径150米及以上)时才能成功检测到大多数疟疾病例。在此筛查半径及以上,反应性病例检测并不比在村庄中随机筛查相同数量房屋的效果更好。在非常小的半径内进行筛查只能检测到极少数病例,但尽管表现不佳,仍优于相同样本量的随机筛查。
这些模拟结果表明,使用RDT对临床病例进行反应性病例检测在低传播和不稳定传播地区阻断传播的能力有限。这与病例的高度空间异质性、村庄外获得疟疾感染以及无症状感染的漏检有关。当病例稀少且呈散发性时,反应性病例检测会导致大量时间和预算损失。
Zotero 插件
