Dynamical analysis and optimal control strategy of seasonal brucellosis

IF 4.4 2区数学 Q1 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

Mathematics and Computers in Simulation Pub Date : 2025-03-12 DOI:10.1016/j.matcom.2025.03.003

Huidi Chu , Xinmiao Rong , Liu Yang , Meng Fan

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引用次数: 0

Abstract

Brucellosis exhibits typical seasonal patterns and shows a notable rising trend in recent years, posing a serious threat to public health and economic development. Experimental research indicates that increased tick activity may elevate brucellosis transmission risk although the quantitative impact of ticks remains insufficiently explored. To investigate the seasonal transmission mechanisms of Brucella, identify the key factors, and assess ticks’ potential role, a multi-population non-autonomous periodic dynamical model is developed. The global dynamics of the model such as extinction, uniform persistence, disease-free periodic solution, and endemic periodic solution are well explored in terms of the basic reproduction number. Theoretical and numerical analyses demonstrate that, while tick control helps mitigate transmission risks, it is insufficient to eliminate periodic transmission. Effective control of brucellosis requires a comprehensive approach, especially culling infected sheep and improving vaccination coverage to curb the overall rising trend. Additionally, adjusting sheep reproductive schedules within the sheep’s life cycle, such as delaying the peak time of birth and advancing the peak time of abortion, is crucial for managing seasonal transmission. Numerical simulations of the optimal control strategies reveal that adjusting interventions based on seasonal fluctuations in infections balances the cost and effectiveness while highlighting the importance of effective tick control.

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季节性布鲁氏菌病的动态分析及最优控制策略

布鲁氏菌病具有典型的季节性特征，近年来呈显著上升趋势，对公共卫生和经济发展构成严重威胁。实验研究表明，蜱活动的增加可能会增加布鲁氏菌病的传播风险，尽管蜱的定量影响尚未得到充分探讨。为了研究布鲁氏菌的季节性传播机制，识别关键因素，评估蜱的潜在作用，建立了一个多种群非自治周期动态模型。从基本繁殖数的角度探讨了模型的全局动力学，如灭绝、均匀持续、无病周期解和地方性周期解。理论和数值分析表明，虽然蜱虫控制有助于降低传播风险，但不足以消除周期性传播。有效控制布鲁氏菌病需要采取综合措施，特别是扑杀受感染的羊和提高疫苗接种覆盖率，以遏制总体上升趋势。此外，在羊的生命周期内调整羊的繁殖时间表，如推迟出生高峰时间和提前流产高峰时间，对于控制季节性传播至关重要。最优控制策略的数值模拟表明，根据感染的季节性波动调整干预措施平衡了成本和效果，同时突出了有效蜱虫控制的重要性。

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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来源期刊

Mathematics and Computers in Simulation 数学-计算机：跨学科应用

CiteScore

8.90

自引率

4.30%

发文量

335

审稿时长

54 days

期刊介绍： The aim of the journal is to provide an international forum for the dissemination of up-to-date information in the fields of the mathematics and computers, in particular (but not exclusively) as they apply to the dynamics of systems, their simulation and scientific computation in general. Published material ranges from short, concise research papers to more general tutorial articles. Mathematics and Computers in Simulation, published monthly, is the official organ of IMACS, the International Association for Mathematics and Computers in Simulation (Formerly AICA). This Association, founded in 1955 and legally incorporated in 1956 is a member of FIACC (the Five International Associations Coordinating Committee), together with IFIP, IFAV, IFORS and IMEKO. Topics covered by the journal include mathematical tools in: •The foundations of systems modelling •Numerical analysis and the development of algorithms for simulation They also include considerations about computer hardware for simulation and about special software and compilers. The journal also publishes articles concerned with specific applications of modelling and simulation in science and engineering, with relevant applied mathematics, the general philosophy of systems simulation, and their impact on disciplinary and interdisciplinary research. The journal includes a Book Review section -- and a "News on IMACS" section that contains a Calendar of future Conferences/Events and other information about the Association.