Leveraging Artificial Intelligence to Predict Potential TB Hotspots at the Community Level in Bangui, Republic of Central Africa.

IF 2.8 4区医学 Q2 INFECTIOUS DISEASES

Tropical Medicine and Infectious Disease Pub Date : 2025-04-03 DOI:10.3390/tropicalmed10040093

Kobto G Koura, Sumbul Hashmi, Sonia Menon, Hervé G Gando, Aziz K Yamodo, Anne-Laure Budts, Vincent Meurrens, Saint-Cyr S Koyato Lapelou, Olivia B Mbitikon, Matthys Potgieter, Caroline Van Cauwelaert

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Abstract

Tuberculosis (TB) is a global health challenge, particularly in the Central African Republic (CAR), which is classified as a high TB burden country. In the CAR, factors like poverty, limited healthcare access, high HIV prevalence, malnutrition, inadequate sanitation, low measles vaccination coverage, and conflict-driven crowded living conditions elevate TB risk. Improved AI-driven surveillance is hypothesized to address under-reporting and underdiagnosis. Therefore, we created an epidemiological digital representation of TB in Bangui by employing passive data collection, spatial analysis using a 100 × 100 m grid, and mapping TB treatment services. Our approach included estimating undiagnosed TB cases through the integration of TB incidence, notification rates, and diagnostic data. High-resolution predictions are achieved by subdividing the area into smaller units while considering influencing variables within the Bayesian model. By designating moderate and high-risk hotspots, the model highlighted the potential for precise resource allocation in TB control. The strength of our model lies in its adaptability to overcome challenges, although this may have been to the detriment of precision in some areas. Research is envisioned to evaluate the model's accuracy, and future research should consider exploring the integration of multidrug-resistant TB within the model.

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利用人工智能在中非共和国班吉社区一级预测潜在的结核病热点。

结核病是一项全球卫生挑战，特别是在被列为结核病高负担国家的中非共和国。在中非共和国，贫困、医疗服务有限、艾滋病毒流行率高、营养不良、卫生设施不足、麻疹疫苗接种覆盖率低以及冲突导致的拥挤生活条件等因素都增加了结核病风险。假设改进人工智能驱动的监测可以解决报告不足和诊断不足的问题。因此，我们通过被动数据收集、使用100 × 100米网格的空间分析以及绘制结核病治疗服务地图，创建了班吉结核病流行病学数字表示。我们的方法包括通过整合结核病发病率、通报率和诊断数据来估计未诊断的结核病病例。通过将区域细分为更小的单元，同时考虑贝叶斯模型中的影响变量，可以实现高分辨率预测。通过指定中等和高风险热点，该模型突出了在结核病控制中精确分配资源的潜力。我们模型的优势在于它能够适应挑战，尽管这可能会损害某些领域的精度。预计研究将评估该模型的准确性，未来的研究应考虑探索将耐多药结核病纳入该模型。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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