Qualitative Behavioral Analysis in Mosquito Dynamics Model with Wolbachia

Q2 Mathematics

Communication in Biomathematical Sciences Pub Date : 2023-01-25 DOI:10.5614/cbms.2023.6.1.1

D. Suandi, F. Ilahi, Randi Ramdhani, E. S. Nugraha

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引用次数: 1

Abstract

The Aedes Aegypti mosquito is the primary vector that can transmit diseases to humans such as zika, dengue fever, chikungunya, and yellow fever. This mosquito species is controlled to reduce the frequency of its bites on humans. Several methods have been developed to control mosquito populations, ranging from natural insecticides to artificial ones. However, the impact of these insecticides leads to resistance. Wolbachiabacteria as a promising alternative in reducing the spread of viruses on humans due to free resistance. This work constructs a genetic population model in the form of differential equation system that describes mosquitopopulation dynamics by involving random mating between mosquito populations with and without Wolbachia bacteria. The stability of the equilibrium was analyzed locally here. Numerical simulations and sensitivity analyzes are presented to confirm the analytical results and investigate the effect of the parameters involved on the model. The results show that the success of the expansion of Wolbachia-infected mosquitoes depends on the fitness level of the mosquito species. The more Wolbachia mosquitoes are released into nature, the more possibility this mosquito expansion will be successful.

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Wolbachia蚊子动力学模型的定性行为分析

埃及伊蚊是可将寨卡病毒、登革热、基孔肯雅病和黄热病等疾病传播给人类的主要媒介。对这种蚊子进行控制是为了减少其叮咬人类的频率。已经开发了几种控制蚊子种群的方法，从天然杀虫剂到人工杀虫剂。然而，这些杀虫剂的影响会导致耐药性。沃尔巴赫菌是一种很有前途的替代品，可以减少由于自由抵抗而导致的病毒在人类身上的传播。这项工作以微分方程系统的形式构建了一个遗传种群模型，通过在有和没有沃尔巴克氏菌的蚊子种群之间进行随机交配来描述蚊子种群的动态。本文对平衡的稳定性进行了局部分析。数值模拟和灵敏度分析证实了分析结果，并研究了相关参数对模型的影响。结果表明，感染沃尔巴克氏体的蚊子能否成功繁殖取决于蚊子种类的适应水平。沃尔巴克氏体蚊子被释放到大自然中的数量越多，这种蚊子扩张成功的可能性就越大。

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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