A Machine Learning Approach to Predict HIV Viral Load Hotspots in Kenya Using Real-World Data.

Health data science Pub Date : 2023-10-02 eCollection Date: 2023-01-01 DOI:10.34133/hds.0019
Nancy Kagendi, Matilu Mwau
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Abstract

Background: Machine learning models are not in routine use for predicting HIV status. Our objective is to describe the development of a machine learning model to predict HIV viral load (VL) hotspots as an early warning system in Kenya, based on routinely collected data by affiliate entities of the Ministry of Health. Based on World Health Organization's recommendations, hotspots are health facilities with ≥20% people living with HIV whose VL is not suppressed. Prediction of VL hotspots provides an early warning system to health administrators to optimize treatment and resources distribution.

Methods: A random forest model was built to predict the hotspot status of a health facility in the upcoming month, starting from 2016. Prior to model building, the datasets were cleaned and checked for outliers and multicollinearity at the patient level. The patient-level data were aggregated up to the facility level before model building. We analyzed data from 4 million tests and 4,265 facilities. The dataset at the health facility level was divided into train (75%) and test (25%) datasets.

Results: The model discriminates hotspots from non-hotspots with an accuracy of 78%. The F1 score of the model is 69% and the Brier score is 0.139. In December 2019, our model correctly predicted 434 VL hotspots in addition to the observed 446 VL hotspots.

Conclusion: The hotspot mapping model can be essential to antiretroviral therapy programs. This model can provide support to decision-makers to identify VL hotspots ahead in time using cost-efficient routinely collected data.

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利用真实世界数据预测肯尼亚HIV病毒载量热点的机器学习方法
背景:机器学习模型尚未被常规用于预测艾滋病毒感染状况。我们的目标是根据卫生部下属机构日常收集的数据,介绍肯尼亚开发机器学习模型预测艾滋病病毒载量(VL)热点的情况,并将其作为一种预警系统。根据世界卫生组织的建议,热点地区是指艾滋病毒感染者中 VL 未得到抑制的人数≥20% 的医疗机构。VL 热点预测为卫生管理人员提供了一个预警系统,以优化治疗和资源分配:从 2016 年开始,我们建立了一个随机森林模型来预测医疗机构下个月的热点状态。在建立模型之前,对数据集进行了清理,并检查了患者层面的异常值和多重共线性。在建立模型之前,我们将患者层面的数据汇总到医疗机构层面。我们分析了来自 400 万次检验和 4265 家医疗机构的数据。医疗机构层面的数据集分为训练数据集(75%)和测试数据集(25%):该模型区分热点和非热点的准确率为 78%。模型的 F1 得分为 69%,Brier 得分为 0.139。2019 年 12 月,除观测到的 446 个 VL 热点外,我们的模型还正确预测了 434 个 VL 热点:热点绘图模型对于抗逆转录病毒治疗项目至关重要。该模型可为决策者提供支持,帮助他们利用具有成本效益的常规收集数据提前确定 VL 热点。
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