Publication date: Aug 27, 2024
Data mining and artificial intelligence algorithms can estimate the probability of future occurrences with defined precision. Yet, the prediction of infectious disease outbreaks remains a complex and difficult task. This is demonstrated by the limited accuracy and sensitivity of current models in predicting the emergence of previously unknown pathogens such as Zika, Chikungunya, and SARS-CoV-2, and the resurgence of Mpox, along with their impacts on global health, trade, and security. Comprehensive analysis of infectious disease risk profiles, vulnerabilities, and mitigation capacities, along with their spatiotemporal dynamics at the international level, is essential for preventing their transnational propagation. However, annual indexes about the impact of infectious diseases provide a low level of granularity to allow stakeholders to craft better mitigation strategies. A quantitative risk assessment by analytical platforms requires billions of near real-time data points from heterogeneous sources, integrating and analyzing univariable or multivariable data with different levels of complexity and latency that, in most cases, overwhelm human cognitive capabilities. Autonomous biosurveillance can open the possibility for near real-time, risk- and evidence-based policymaking and operational decision support.
Concepts | Keywords |
---|---|
Biothreats | artificial intelligence |
Future | biosurveillance |
Mining | biothreats |
Pathogens | open source data |
Zoonotic | predictive analytics |
risk-based modeling |
Semantics
Type | Source | Name |
---|---|---|
disease | MESH | infectious disease |
pathway | REACTOME | Infectious disease |
drug | DRUGBANK | Tropicamide |
disease | VO | time |