用于社区疟疾病媒监测的蚊子物种快速形态学鉴定手持工具 (VectorCam):总结性可用性研究。

IF 2.6 Q2 HEALTH CARE SCIENCES & SERVICES
JMIR Human Factors Pub Date : 2024-08-16 DOI:10.2196/56605
Saisamhitha Dasari, Bhavya Gopinath, Carter James Gaulke, Sunny Mahendra Patel, Khalil K Merali, Aravind Sunil Kumar, Soumyadipta Acharya
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引用次数: 0

摘要

背景:疟疾每年影响近 2.5 亿人。其中,乌干达是疟疾发病率最高的国家之一,发病人数达 1300 万,死亡人数近 2 万。控制疟疾的传播有赖于病媒监测,即通过收集的蚊子分析农村地区病媒物种的密度,从而制定相应的干预计划。然而,这有赖于训练有素的昆虫学家,即病媒控制官员(VCO),他们通过显微镜识别病媒种类。全球昆虫学家的短缺和这一时间密集型过程造成了严重的报告延误。VectorCam 是一种基于人工智能的低成本工具,可通过图片识别蚊子的种类、性别和腹部状态,并将这些结果以电子方式从监测点发送给决策者,从而将这一过程简化为村卫生小组(VHT)的工作:本研究通过评估 VectorCam 系统的效率、有效性和满意度,评估 VectorCam 系统在村卫生队中的可用性:方法:VectorCam 系统有成像硬件和手机应用程序,用于识别蚊子种类。需要两名使用者:(1) 使用应用程序捕捉蚊子图像的成像器;(2) 从硬件上装卸蚊子的装载器。确定了这两个角色的关键成功任务,虚拟气候控制中心利用这些任务来培训和认证虚拟医疗技术人员。在第一测试阶段(第 1 阶段),一名 VCO 和一名 VHT 配对,分别扮演成像器或装载器的角色。之后,他们互换角色。在第二阶段,两台 VHT 配对,模拟实际使用。记录每位参与者给每只蚊子成像所花的时间、关键错误和系统可用性量表(SUS)得分:总共招募了 14 名男性和 6 名女性志愿服务队成员,年龄在 20 至 70 岁之间,其中 12 人(60%)有智能手机使用经验。成像仪第 1 和第 2 阶段的平均吞吐量分别为每只蚊子 70 秒(标准差 30.3)和 56.1 秒(标准差 22.9),这表明一盘蚊子的成像时间缩短了。装载机在第一和第二阶段的平均吞吐量分别为每只蚊子 50.0 秒和 55.7 秒,表明时间略有增加。就效果而言,在第 1 阶段,成像仪有 8% 的关键错误(6/80),而装载机有 13% 的关键错误(10/80)。在第 2 阶段,成像仪(用于 VHT 对)出现了 14%(11/80)的严重错误,装载机(用于 VHT 对)出现了 12%(19/160)的严重错误。系统的平均 SUS 得分为 70.25,表明可用性良好。Kruskal-Wallis 分析表明,在 SUS(H 值)得分上,有无智能手机使用经验的性别或用户之间没有明显差异:VectorCam 是一个可用的系统,可用于乌干达农村地区蚊子标本的现场鉴定。即将进行的设计更新将解决用户和观察者关心的问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Handheld Tool for the Rapid Morphological Identification of Mosquito Species (VectorCam) for Community-Based Malaria Vector Surveillance: Summative Usability Study.

Background: Malaria impacts nearly 250 million individuals annually. Specifically, Uganda has one of the highest burdens, with 13 million cases and nearly 20,000 deaths. Controlling the spread of malaria relies on vector surveillance, a system where collected mosquitos are analyzed for vector species' density in rural areas to plan interventions accordingly. However, this relies on trained entomologists known as vector control officers (VCOs) who identify species via microscopy. The global shortage of entomologists and this time-intensive process cause significant reporting delays. VectorCam is a low-cost artificial intelligence-based tool that identifies a mosquito's species, sex, and abdomen status with a picture and sends these results electronically from surveillance sites to decision makers, thereby deskilling the process to village health teams (VHTs).

Objective: This study evaluates the usability of the VectorCam system among VHTs by assessing its efficiency, effectiveness, and satisfaction.

Methods: The VectorCam system has imaging hardware and a phone app designed to identify mosquito species. Two users are needed: (1) an imager to capture images of mosquitos using the app and (2) a loader to load and unload mosquitos from the hardware. Critical success tasks for both roles were identified, which VCOs used to train and certify VHTs. In the first testing phase (phase 1), a VCO and a VHT were paired to assume the role of an imager or a loader. Afterward, they swapped. In phase 2, two VHTs were paired, mimicking real use. The time taken to image each mosquito, critical errors, and System Usability Scale (SUS) scores were recorded for each participant.

Results: Overall, 14 male and 6 female VHT members aged 20 to 70 years were recruited, of which 12 (60%) participants had smartphone use experience. The average throughput values for phases 1 and 2 for the imager were 70 (SD 30.3) seconds and 56.1 (SD 22.9) seconds per mosquito, respectively, indicating a decrease in the length of time for imaging a tray of mosquitos. The loader's average throughput values for phases 1 and 2 were 50.0 and 55.7 seconds per mosquito, respectively, indicating a slight increase in time. In terms of effectiveness, the imager had 8% (6/80) critical errors and the loader had 13% (10/80) critical errors in phase 1. In phase 2, the imager (for VHT pairs) had 14% (11/80) critical errors and the loader (for VHT pairs) had 12% (19/160) critical errors. The average SUS score of the system was 70.25, indicating positive usability. A Kruskal-Wallis analysis demonstrated no significant difference in SUS (H value) scores between genders or users with and without smartphone use experience.

Conclusions: VectorCam is a usable system for deskilling the in-field identification of mosquito specimens in rural Uganda. Upcoming design updates will address the concerns of users and observers.

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来源期刊
JMIR Human Factors
JMIR Human Factors Medicine-Health Informatics
CiteScore
3.40
自引率
3.70%
发文量
123
审稿时长
12 weeks
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