Abstract
The pandemic transition is a hallmark of current epidemiological models, predicting a continuous shift from a healthy to a pandemic state, whose critical point is driven by the parameters of the disease, e.g., its infection, recovery or mortality rates. These parameters, characterizing the disease cycle, are tuned by the biological characteristics of the pathogen, capturing its natural time-scales, often considered independent of the state of the spread itself. If, however, the disease gains a population-wide impact, its prevalence may exceed the health-care system capacity, resulting in sub-optimal treatment, and hence a potential feedback mechanism, in which the disease cycle is no longer decoupled from the state of the spread. Such dependence was demonstrated during the spread of COVID-19, for instance, where hard-hit places showed elevated mortality rates, likely due to an over-stressed health-care system. We therefore introduce an infection-reduced recovery mechanism, linking an individual's rate of recovery to the prevalence of the disease. The outcome, we show, may have dramatic consequences on the observed patterns of spread. For instance, under rather broad conditions, the pandemic transition becomes discontinuous, exhibiting an abrupt shift from a healthy to a pandemic state. In some cases the disease reaches population-wide coverage even below the classically predicted critical transition point. We also observe a potential multi-stability and hysteresis, capturing an irreversible pandemic transition, in which overcoming the disease requires us to quench infection rates significantly below the critical threshold. These findings not only provide hints on the current difficulties to contain COVID-19, but more broadly, they set the bar for sustaining a stably functioning treatment capacity in the face of population-wide demand.
Original language | English |
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Article number | 110130 |
Journal | Chaos, Solitons and Fractals |
Volume | 140 |
DOIs | |
State | Published - Nov 2020 |
Bibliographical note
Publisher Copyright:© 2020 Elsevier Ltd
Funding
This research was supported by the Israel Science Foundation grant no. 499/19 and by the Israel Council for Higher Education (VATAT) Grant for data science research. This research was supported by the Israel Science Foundation grant no. 499/19 and by the Israel Council for Higher Education (VATAT) Grant for data science research.
Funders | Funder number |
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VATAT | |
Israel Science Foundation | 499/19 |
Council for Higher Education | |
Planning and Budgeting Committee of the Council for Higher Education of Israel |
Keywords
- Complex Networks
- Covid-19
- Dynamical Phase Transition
- Epidemic Spreading
- Explosive Ttransitions
- SIS Model