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禽流感:从过去疫情中吸取的教训以及数据来源、数学和人工智能模型及用于预测和热点检测以应对当前疫情的早期预警系统清单

Avian Influenza: Lessons from Past Outbreaks and an Inventory of Data Sources, Mathematical and AI Models, and Early Warning Systems for Forecasting and Hotspot Detection to Tackle Ongoing Outbreaks.

作者信息

Musa Emmanuel, Nia Zahra Movahhedi, Bragazzi Nicola Luigi, Leung Doris, Lee Nelson, Kong Jude Dzevela

机构信息

Global South Artificial Intelligence for Pandemic and Epidemic Preparedness and Response Network (AI4PEP), Toronto, ON M3J 1P3, Canada.

Dahdaleh Institute for Global Health Research, York University, Toronto, ON M3J 1P3, Canada.

出版信息

Healthcare (Basel). 2024 Oct 1;12(19):1959. doi: 10.3390/healthcare12191959.

DOI:10.3390/healthcare12191959
PMID:39408139
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11476403/
Abstract

BACKGROUND/OBJECTIVES: The ongoing avian influenza (H5N1) outbreak, one of the most widespread and persistent in recent history, has significantly impacted public health and the poultry and dairy cattle industries. This review covers lessons from past outbreaks, risk factors for transmission, molecular epidemiology, clinical features, surveillance strategies, and socioeconomic impacts. Since 1997, H5N1 has infected over 900 individuals globally, with a fatality rate exceeding 50%. Key factors influencing infection rates include demographic, socioeconomic, environmental, and ecological variables. The virus's potential for sustained human-to-human transmission remains a concern. The current outbreak, marked by new viral clades, has complicated containment efforts.

METHODS

This review discusses how to integrate technological advances, such as mathematical modeling and artificial intelligence (AI), to improve forecasting, hotspot detection, and early warning systems.

RESULTS

We provide inventories of data sources, covering both conventional and unconventional data streams, as well as those of mathematical and AI models, which can be vital for comprehensive surveillance and outbreak responses.

CONCLUSION

In conclusion, integrating AI, mathematical models, and technological innovations into a One-Health approach is essential for improving surveillance, forecasting, and response strategies to mitigate the impacts of the ongoing avian influenza outbreak. Strengthening international collaboration and biosecurity measures will be pivotal in controlling future outbreaks and protecting both human and animal populations from this evolving global threat.

摘要

背景/目的:当前的禽流感(H5N1)疫情是近期历史上最广泛和持续时间最长的疫情之一,对公共卫生以及家禽和奶牛养殖业产生了重大影响。本综述涵盖了以往疫情的教训、传播的风险因素、分子流行病学、临床特征、监测策略以及社会经济影响。自1997年以来,H5N1已在全球感染了900多人,死亡率超过50%。影响感染率的关键因素包括人口统计学、社会经济、环境和生态变量。该病毒持续人际传播的可能性仍然令人担忧。当前的疫情以新的病毒分支为特征,使疫情控制工作变得复杂。

方法

本综述讨论了如何整合数学建模和人工智能(AI)等技术进步,以改进预测、热点检测和预警系统。

结果

我们提供了数据源清单,涵盖传统和非传统数据流以及数学和AI模型的数据源清单,这些对于全面监测和疫情应对至关重要。

结论

总之,将人工智能、数学模型和技术创新整合到“同一健康”方法中,对于改进监测、预测和应对策略以减轻当前禽流感疫情的影响至关重要。加强国际合作和生物安全措施对于控制未来疫情以及保护人类和动物群体免受这种不断演变的全球威胁至关重要。

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