Linking Spontaneous Behavioral Changes to Disease Transmission Dynamics: Behavior Change Includes Periodic Oscillation.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Tangjuan Li, Yanni Xiao, Jane Heffernan
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Abstract

Behavior change significantly influences the transmission of diseases during outbreaks. To incorporate spontaneous preventive measures, we propose a model that integrates behavior change with disease transmission. The model represents behavior change through an imitation process, wherein players exclusively adopt the behavior associated with higher payoff. We find that relying solely on spontaneous behavior change is insufficient for eradicating the disease. The dynamics of behavior change are contingent on the basic reproduction number R a corresponding to the scenario where all players adopt non-pharmaceutical interventions (NPIs). When R a < 1 , partial adherence to NPIs remains consistently feasible. We can ensure that the disease stays at a low level or maintains minor fluctuations around a lower value by increasing sensitivity to perceived infection. In cases where oscillations occur, a further reduction in the maximum prevalence of infection over a cycle can be achieved by increasing the rate of behavior change. When R a > 1 , almost all players consistently adopt NPIs if they are highly sensitive to perceived infection. Further consideration of saturated recovery leads to saddle-node homoclinic and Bogdanov-Takens bifurcations, emphasizing the adverse impact of limited medical resources on controlling the scale of infection. Finally, we parameterize our model with COVID-19 data and Tokyo subway ridership, enabling us to illustrate the disease spread co-evolving with behavior change dynamics. We further demonstrate that an increase in sensitivity to perceived infection can accelerate the peak time and reduce the peak size of infection prevalence in the initial wave.

Abstract Image

将自发行为变化与疾病传播动力学联系起来:行为变化包括周期性振荡。
在疾病爆发期间,行为变化会对疾病传播产生重大影响。为了纳入自发的预防措施,我们提出了一个将行为变化与疾病传播相结合的模型。该模型通过模仿过程来表示行为变化,即参与者只采取与高回报相关的行为。我们发现,仅仅依靠自发的行为变化不足以根除疾病。行为变化的动态取决于基本繁殖数 R a,它对应于所有参与者都采取非药物干预措施(NPIs)的情况。当 R a 为 1 时,部分采用非药物干预措施仍然是可行的。我们可以通过提高对感知感染的敏感度,确保疾病保持在较低水平,或在较低值附近维持小幅波动。在出现波动的情况下,可以通过提高行为改变率来进一步降低一个周期内的最大感染率。当 R a > 1 时,如果玩家对感知到的感染高度敏感,几乎所有玩家都会持续采用非传染性感染。对饱和恢复的进一步考虑导致了鞍节点同线性和波格丹诺夫-塔肯斯分岔,强调了有限的医疗资源对控制感染规模的不利影响。最后,我们利用 COVID-19 数据和东京地铁乘客人数对模型进行了参数化,使我们能够说明疾病传播与行为变化动态的共同演化。我们进一步证明,提高对感知感染的敏感度可以加快感染高峰时间,并降低最初一波感染率的峰值规模。
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
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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