key: cord-272744-j4q7pcfa authors: Zhan, Xiu-Xiu; Liu, Chuang; Zhou, Ge; Zhang, Zi-Ke; Sun, Gui-Quan; Zhu, Jonathan J.H.; Jin, Zhen title: Coupling dynamics of epidemic spreading and information diffusion on complex networks date: 2018-09-01 journal: Appl Math Comput DOI: 10.1016/j.amc.2018.03.050 sha: doc_id: 272744 cord_uid: j4q7pcfa The interaction between disease and disease information on complex networks has facilitated an interdisciplinary research area. When a disease begins to spread in the population, the corresponding information would also be transmitted among individuals, which in turn influence the spreading pattern of the disease. In this paper, firstly, we analyze the propagation of two representative diseases (H7N9 and Dengue fever) in the real-world population and their corresponding information on Internet, suggesting the high correlation of the two-type dynamical processes. Secondly, inspired by empirical analyses, we propose a nonlinear model to further interpret the coupling effect based on the SIS (Susceptible-Infected-Susceptible) model. Both simulation results and theoretical analysis show that a high prevalence of epidemic will lead to a slow information decay, consequently resulting in a high infected level, which shall in turn prevent the epidemic spreading. Finally, further theoretical analysis demonstrates that a multi-outbreak phenomenon emerges via the effect of coupling dynamics, which finds good agreement with empirical results. This work may shed light on the in-depth understanding of the interplay between the dynamics of epidemic spreading and information diffusion. The interaction between disease and disease information on complex networks has facilitated an interdisciplinary research area. When a disease begins to spread in the population, the corresponding information would also be transmitted among individuals, which in turn influence the spreading pattern of the disease. In this paper, firstly, we analyze the propagation of two representative diseases ( H7N9 and Dengue fever ) in the real-world population and their corresponding information on Internet, suggesting the high correlation of the two-type dynamical processes. Secondly, inspired by empirical analyses, we propose a nonlinear model to further interpret the coupling effect based on the SIS (Susceptible-Infected-Susceptible) model. Both simulation results and theoretical analysis show that a high prevalence of epidemic will lead to a slow information decay, consequently resulting in a high infected level, which shall in turn prevent the epidemic spreading. Finally, further theoretical analysis demonstrates that a multi-outbreak phenomenon emerges via the effect of coupling dynamics, which finds good agreement with empirical results. This work may shed light on the in-depth understanding of the interplay between the dynamics of epidemic spreading and information diffusion. Recently, understanding how diseases spread among individuals has been an increasing hot research area of nonlinear studies [1] . Generally, epidemic spreading is considered to be a dynamic process in which the disease is transmitted from one individual to another via physical contact in peer-to-peer networks. To date, there is a vast amount of research tries to understand the epidemic spreading phenomenon, which could be mainly categorized into three types: (i) epidemic spreading on various types of networks [2] , such as the scale-free network [3, 4] , the small-world network [5, 6] and the interdependent network [7, 8] ; (ii) propagation mechanisms that describe the dynamic spreading process, such as the Table 1 Illustration of parameters used in the spreading processes. Susceptible-Infected-Recovered (SIR) model for influenza [9, 10] , the Susceptible-Infected-Susceptible (SIS) model for sexually transmitted disease [11, 12] and the Susceptible-Exposed-Infected-Recovered (SEIR) model for rabies [13, 14] ; (iii) data-driven modeling approaches that tackle the epidemic transmission [15] by analyzing the available real datasets, such as the scaling laws in human mobility [16, 17] , individual interactions [18, 19] , and contact patterns [20, 21] . The majority of the aforementioned studies focused on epidemic spreading independently, ignoring the fact that information diffusion of the diseases themselves may also have significant impact on epidemic outbreaks [22] . For example, the outbreak of a contagious disease may lead to quick spreading of disease information, through either medias or friends. Conversely, the information shall also drive people to take corresponding protective measures, such as staying at home, wearing face masks, and getting vaccinated [23] . Such behavioral responses may further impact epidemic outbreak in large population [24] . Therefore, studies on the coupling effect between epidemic spreading and information diffusion have attracted much attention from various disciplines. Theoretical models have been proposed to explain how both disease and information simultaneously spread in the same population [25] [26] [27] [28] [29] . In particular, the nonlinear influence of coupling parameters on the basic reproductive number ( R 0 ) is studied to show the interplay between the two spreading processes [26] . Theoretical results indicate that the coupling interaction could decrease epidemic outbreak size in a well-mixed population [25] . In some cases, enough behavioral changes would emerge in response to the diffusion of a great deal of disease information so that the severe epidemic would vanish completely, even the epidemic transmission rate was higher than the classical threshold initially [30] [31] [32] [33] [34] . In addition, the interplay between information diffusion and epidemic spreading is elucidated on multiplex networks, where each type of dynamics diffuses on respective layers (e.g., information diffusion on communication layer versus epidemic spreading on physical layer) [35] [36] [37] . As a consequence, the epidemic threshold, as related to the physical contact layer, can be increased by enhancing the diffusion rate of information on the communication layer. Therefore, the effect of behavioral changes arises in three aspects [27] : (i) disease state of the individuals, e.g., vaccination [38] [39] [40] [41] [42] ; (ii) epidemic transmission and recovery rate [35, 43] ; (iii) topological structure of contact network, e.g., the adaptive process [44] [45] [46] [47] . Besides researches from physical discipline, scholars from mass communication share similar views on the causal linkages of the two diffusion processes. The outbreak of severe diseases usually attracts heavy media coverage, subsequently resulting in massive responses from the public: (i) cognitive responses, such as the attention to the information and increased awareness of the situation [48] ; (ii) affective responses, such as anxiety, fear, or even panic [49] ; (iii) behavioral responses, such as the adoption of new practices in order to replace undesirable habits [50] . However, those assumptions are just theoretical hypotheses rather than empirical facts as it is difficult to find relevant data of one-to-one relationship in the spreading process. Even when the data is available, it is also difficult to separate the unique effect of information on the control of epidemics from interference factors, such as variation of virus, seasonal factors and improved medical treatments, etc. Present studies on the coupling dynamics mainly focus on the suppression effect of epidemic spreading by information diffusion. The occurrence of a disease prompts the sharing of corresponding information, leading to preventive measures that inhibit further epidemic spreading [25, 37] . Researchers have also pointed out that when the epidemic outbreak is under control, people shall not be very vigilant in discussing or sharing relevant information. It will lead to a consequent decrease in protection actions and may result in a recurrence of epidemics in future. For example, the spread of SARS (Severe Acute Respiratory Syndromes) is alleviated in early March 2003, however, a sudden increase appear later that month (as indicated in the evolution curve of the probable cases of SARS, see Fig. 2 in Ref. [24] ). In this work, firstly, we demonstrate a similar outbreak pattern using data on the spread of two representative diseases, i.e., avian influenza A ( H7N9 ) [51] [52] [53] and Dengue fever [54, 55] , along with the diffusion of respective disease information. Secondly, a nonlinear mathematical model is proposed to describe the coupled spreading dynamics as an SIS spreading model. Results show that information diffusion can significantly inhibit epidemic spreading. Finally, both empirical analysis and the proposed model find good agreements in revealing a multi-outbreak phenomenon in the coupled spreading dynamics. To better illustrate this work, we collected data of two representative diseases, H7N9 and Dengue fever. Each disease has two time series datasets: (i) daily number of individuals infected by the corresponding disease in China, which are collected from the Chinese Center for Disease Control and Prevention ; (ii) online diffusion messages discussing or forwarding the information of the corresponding disease during the same period of epidemic spreading. The message diffusion data was crawled from the largest micro-blogging system in China [56] , Sina Weibo ( http://www.weibo.com/ ). We have essentially obtained one-year data for the disease H7N9 from the year 2013 to 2014, and two-year data for Dengue from the year 2012 to 2014. We assume that individuals who post or retweet messages about the observed diseases are considered to be aware of the disease. Empirical analysis of H7N9: Fig. 1 (a) shows the spreading processes of both disease and disease information of H7N9 . It can be seen that the evolutionary trend of two processes are highly correlated, with Pearson correlation coefficient of 0.49. When the epidemic broke out in Apr. 2013 and Feb. 2014 ( Fig. 1 (a) ), it shows that many people were discussing it online simultaneously. Actually, public responses to H7N9, such as staying at home or wearing face masks, can also affect the spread of the epidemic. The peaks of the disease spreading and the information diffusion shown in Fig. 1 (a) suggest that the mutual influence of these two spreading processes could be significant. Interestingly, the size of the first epidemic peak (Apr. 2013) is smaller than the second one (Feb. 2014), which is inversely correlated with the information amount. That is to say, the number of individuals discussing the disease during the first outbreak is much greater than that of the second one. This might imply that the awareness of epidemics and the physical epidemics could influence each other. Empirical analysis of Dengue fever: Fig. 1 (b) describes the spreading processes of both disease and disease information of Dengue. Similar to the analysis of H7N9, the evolution trend of the two processes is also consistent with each other, with even much higher correlation coefficient of 0.89. According to the two largest peaks (in Sept. 2012 and Sept. 2013, respectively) of disease spreading, we find that the first epidemic peak is also smaller than the second one, while the corresponding information peaks show a contrary trend. Considering the two small peaks of information in Fig. 1 (b1) and (b2), we can also find the same relationship between the the two dynamic processes as that of two largest peaks, suggesting also the possible coupling effect of the awareness of epidemics and the infected cases of dengue. In the aforementioned section, we empirically showed that the spread of disease and disease information has a coupling effect with each other by analyzing the data from two contagious diseases. Inspired by the empirical results, we propose a network based nonlinear model to describe the interaction between epidemic spreading and information diffusion in this section. In this model, we assume there are two states for disease spreading: susceptible ( S ) and infected ( I ), and two states of information diffusion: aware (+) and unaware (-). As a consequence, each individual will be at one of the four states during the model evolution: • Initially, one arbitrary individual is randomly picked from the given network as the spreading seed ( I + state). The rest individuals are set to be S − state. • At each time step, the infected individuals ( I + and I − states) will spread epidemics to their susceptible network neighbors ( S + and S − states) with given spreading probability. The infected individuals ( I + and I − states) could recover to the susceptible state with given recovery probability. • At each time step, individuals that are aware of the disease ( I + and S + states) will transmit the information to their unaware neighbors ( I − and S − states) with probability α. In addition, the informed individuals ( I + and S + ) could become unaware of the disease with the probabilities of λ and δλ, respectively. Beyond the parameters given in Table 1 , we define σ as the probability of individuals taking protective measures. Thus, σ S < 1 is defined as that a susceptible aware individual ( S + ) will take protective measures to avoid becoming infected, and σ I < 1 is defined as infected aware individuals ( I + state) will reduce contact with their susceptible neighbors or adopt medical treatments. In addition, we assume the infected probabilities for these two different populations are independent with each other, hence σ SI = σ S σ I is defined as the probability of the I + state individuals infecting the S + state ones. When an I + individual is aware of the epidemic, s/he will take positive measures, leading to an increased recovery rate, which is represented by the factor ε > 1. Furthermore, I + state individuals, which could be assumed to better understand the seriousness of epidemics, would be less likely to neglect relevant information, leading to δ < 1. In this work, since the spreading processes of information and disease are primarily determined by the corresponding transmission probabilities, we fix other parameters and mainly investigate the effects of α and β. In the following analysis, we set σ S = 0 . 3 , σ I = 0 . 6 , δ = 0 . 8 , ε = 1 . 5 , λ = 0 . 15 and γ = 0 . 1 . Table 1 . Subsequently, the proposed model is performed on an ER network with a total population N = 10 , 0 0 0 and average degree k = 15 . To measure the spreading effects, we denote the infected level ( I ) as the fraction of infected individuals (both I + and I − ), and the informed level ( Info ) as the fraction of individuals who are aware of the disease (both S + and I + ). Fig. 3 shows the simulation results by fixing the infection probability β = 0 . 3 . In this model, the parameter α can be considered as the information diffusion capability, hence larger α indicates that information diffuses much easier, resulting in a monotonically increase in the number of informed individuals (see the inset of Fig. 3 ). In Fig. 3 , it also shows that the increase in α will inversely hamper the speed of epidemic spreading, hence diminish the overall epidemic outbreak size. As a consequence, appropriate publicity might be an effective strategy to inhibit further spreading of epidemics, which is also consistent with the empirical analysis shown in Fig. 1 . In Fig. 2 , the model also indicates that there is mutual influence between information diffusion and epidemic spreading. A high prevalence of epidemic would lead to a small information fading probability δ, consequently resulting in a high infected level I . It in turn inhibits the epidemic spreading ( σ { I , S , SI } < 1). This coupling effect can be clearly described by the full set of differential equations (see Appendix ). In addition, the equations are solved by mean-field and pairwise approaches, respectively. Fig. 4 shows the results of simulation, theoretical analysis of both mean-field and pairwise analysis. We find that the pairwise approach can better fit the model than the mean-field method. Therefore, we use pairwise approach to perform further studies in the following analysis. In order to investigate the effect of the mutual interaction between α and β on the spreading process, we explore the phase diagram showing the fraction of infected individuals caused by combination of such coupling effects (see Fig. 5 ). The . That is to say, epidemic outbreak will occur if the parameter combination is larger than the critical value, otherwise the epidemic will die out. The results also clearly show that more individuals will be infected with large β and small α, suggesting that the information diffusion can impede the disease spreading. It is noted that the process degenerates to the standard SIS model if α = 0 , where there is no information diffusion in the system. Thus, the epidemic outbreak threshold is β c = γ k = 0 . 0067 [1] , which is also consistent with the results of pairwise analysis and simulation shown in Fig. 5 . In addition, Fig. 5 (c) shows a detailed view of pairwise analysis for α, β ∈ [0, 0.05] in order to better observe the threshold changes. The threshold value of β is around 0.0067 when α → 0, as the epidemic information cannot spread out in this case according to the inset of Fig. 3 . When α > 0, the epidemic threshold can be significantly increased because of the effect of information diffusion. On the contrary, Fig. 3 shows that the informed level only slightly ascends when α is large enough (e.g., α > 0.3), which leads to an obscure change in the epidemic threshold. This result additionally indicates that abundant information would not always work for obstructing epidemic spreading. For example, in the case that a disease with a strong infectiveness (corresponds to large β in Fig. 5 ), enhancing the public awareness alone is insufficient to control the large outbreak of epidemics. In order to obtain better understanding of dynamics of the critical phenomenon, we observe the evolution of infection density for various values of β in Fig. 6 . From the differential equation, dI dt we can obtain I ∝ t −1 at the critical point, which shows a power-law decay. In addition, the inset of Fig. 6 also presents a power-law decay of the infection density when β ≈ 0.04 4 4. By contrast, the infection turns to break out as an endemic, namely steady state, for β > 0.04 4 4 ( β = 0 . 05 in Fig. 6 ), otherwise the epidemic will be eliminated, so-called healthy state for β < 0.04 4 4 ( β = 0 . 04 in Fig. 6 ). Therefore, it can be inferred that β c is approximately 0.04 4 4 in this case, which is consistent with the results in Fig. 5 , where β c is around 0.045 for α = 0 . 6 . Interestingly, the empirical analysis also demonstrates that a multi-outbreak phenomenon emerges for both epidemic spreading [14, [57] [58] [59] and information diffusion [22] , in which there are several outbreaks during the dynamic process of epidemic spreading. Generally, there are many complicated factors that might contribute to this phenomenon, including seasonal influence, climate change, and incubation period, etc. In this model, the periodic outbreaks can be interpreted by the influence of information diffusion. As discussed above, there is a mutual interaction as the two dynamics are coupled with each other during the process. On one hand, a larger proportion of infected individuals should result in an increase in preventive behavioral responses [30] due to the increased awareness of the disease, consequently leading to a steady decrease of further infected cases. On the other hand, when the spread of epidemic tends to be under control, people shall become less sensitive to discuss or share relevant messages, which leads to dissemination of information and simultaneously raises the possibility of a second outbreak. Notably, there are also some cases where the size of the second outbreak is smaller than the first one. For example, the eight Dengue outbreaks in Thailand over 30 years from 1973 to 1999 [60] , and there are also some cases that the second outbreak is larger than the previous one, as in the case of SARS in 2003 [24] and dengue in Taiwan in 20 01-20 02 [59] . In order to better understand the underlying mechanism that drives the multi-outbreak phenomenon of the coupled dynamics, we set two thresholds, I high and I low , to represent different infected levels. That is to say, when the fraction of infected individuals is larger than I high , the information diffusion parameter α will be set as high as α = 0 . 8 so that the information will diffuse even more quickly. Accordingly, when it is smaller than I low , the parameter will directly decay to α = 0 . 3 to represent the corresponding response to abatement effect of information. Fig. 7 shows the simulation results. It can be seen that the epidemic spreads very quickly at the beginning as there are very few people aware of it, and soon reaches the threshold I high and triggers the designed high information transmission probability α = 0 . 8 . As a consequence, as the information bursts out, the high informed level has a significant impact on inhibiting epidemic spreading (the decay period of the epidemic), which will be completely suppressed if the high informed level remains. However, when the epidemic spreading is notably controlled from the first outbreak (i.e. the infected density is smaller than I low ), people are less likely to consider the epidemic as a threat, hence ignore relevant information and no longer actively engage in taking protective measures, which will in turn lead to a subsequent epidemic outbreak in the future. Two representative outbreak patterns are shown in Fig. 7 , where the first outbreak is smaller than the second one ( Fig. 7 (a) ) and vice versa ( Fig. 7 (b) ). Moreover, Fig. 1 , where the size of the first epidemic outbreak is smaller than that of the second one, while the informed level shows to the contrary. It should be noted that, due to the difficulty in collecting data of patient-to-fans to precisely quantify the informed level in the empirical analysis, the number of messages that discuss the epidemic is alternatively used in Fig. 1 . Different from the trend shown in Fig. 1 , a high informed level( Info > 0.5) must be maintained during the period when the infected level decreases shown in Fig. 7 . Based on the model analysis, it could be concluded that it is important to raise public awareness of epidemic occurrence, especially during when the epidemic seems to be under control, otherwise, there is a likelihood of subsequent outbreak in the foreseeable future. Furthermore, we explore the evolution of the informed and infected density with different values of β in Fig. 8 . In Fig. 8 (a) , it shows that the infected density firstly achieves a small peak and then rapidly vanishes, resulting in a evolution pattern known as healthy , which means there is approximately no disease. In Fig. 8 (b) , an oscillatory pattern is revealed for 0.092 < beta ≤ 0.239. Similarly, for large β ∈ (0.239,1], the infected density firstly achieves a large peak (almost close to one), then rapidly decrease to a low level (nearly zero) and gradually raised to a steady state, showing a unimodal pattern [44] . In this paper, we have studied the coupling dynamics between epidemic spreading and relevant information diffusion. Empirical analyses from representative diseases ( H7N9 and Dengue fever ) show that the two kinds of dynamics could significantly influence each other. In addition, we propose a nonlinear model to describe such coupling dynamics based on the SIS (Susceptible-Infected-Susceptible) process. Both simulation results and theoretical analyses show the underlying coupling phenomenon. That is to say, a high prevalence of epidemic will lead to a slow information decay, consequently resulting in a high infected level, which shall in turn prevent the epidemic spreading. Further theoretical analysis demonstrates that a multi-outbreak phenomenon emerges via the effect of coupling dynamics, which finds good agreement with empirical results. The findings of this work may have various applications of network dynamics. For example, as it has been proved that preventive behaviors introduced by disease information can significantly inhibit the epidemic spreading, and information diffusion can be utilized as a complementary measure to efficiently control epidemics. Therefore, the government should make an effort to maintain the public awareness, especially during the harmonious periods when the epidemic seems to be under control. In addition, in this work, we only consider the general preventive behavioral response of crowd. However, the dynamics of an epidemic may be very different due to the behavioral responses of people, such as adaptive process [44] , migration [61] , vaccination [39] , and immunity [62] . This work just provides a starting point to understand the coupling effect between the two spreading processes, a more comprehensive and in-depth study of personalized preventive behavioral responses shall need further effort s to discover. Mean-field analysis: According to Fig. 2 , we adopt mean-field analysis for the spread of epidemic and information in a homogeneous network as follows: Where N is the number of individuals in the system, k is the average degree of the network and the other parameters are illustrated in Table 1 . Pairwise analysis: Pairwise models have recently been widely used to illustrate the dynamic process of epidemics on networks, as those models take into account of the edges of the networks [63] [64] [65] . In this study, we consider a set of evolution equations which are comprised of four types of individuals and 10 types of edges. Using the well-known closure, (assuming the neighbors of each individual obey Poisson distribution) [63] , we can get a set of differential equations as follows: (2) Epidemic processes in complex networks Some features of the spread of epidemics and information on a random graph Epidemic spreading in scale-free networks Velocity and hierarchical spread of epidemic outbreaks in scale-free networks Small world effect in an epidemiological model Searching for the most cost-effective strategy for controlling epidemics spreading on regular and small-world networks Epidemics on interconnected networks Epidemics on interconnected lattices Forecast and control of epidemics in a globalized world Mitigation strategies for pandemic influenza in the united states Spreading of sexually transmitted diseases in heterosexual populations Influence of network dynamics on the spread of sexually transmitted diseases Predicting the local dynamics of epizootic rabies among raccoons in the united states Analysis of rabies in china: transmission dynamics and control Modelling dynamical processes in complex socio-technical systems Impact of non-poissonian activity patterns on spreading processes Modeling human mobility responses to the large-scale spreading of infectious diseases Modeling human dynamics of face-to-face interaction networks Small but slow world: how network topology and burstiness slow down spreading Temporal networks How human location-specific contact patterns impact spatial transmission between populations? Dynamics of information diffusion and its applications on complex networks Epidemic spreading with information-driven vaccination World Health Organization. Consensus document on the epidemiology of severe acute respiratory syndrome (SARS) The spread of awareness and its impact on epidemic outbreaks Endemic disease, awareness, and local behavioural response Modelling the influence of human behaviour on the spread of infectious diseases: a review Interacting epidemics on overlay networks Epidemic dynamics on information-driven adaptive networks On the existence of a threshold for preventive behavioral responses to suppress epidemic spreading The impact of awareness on epidemic spreading in networks Imitation dynamics predict vaccinating behaviour Social contact networks and disease eradicability under voluntary vaccination Imitation dynamics of vaccination behaviour on social networks Dynamical interplay between awareness and epidemic spreading in multiplex networks Competing spreading processes on multiplex networks: awareness and epidemics Asymmetrically interacting spreading dynamics on complex layered networks Vaccination and the theory of games Effects of behavioral response and vaccination policy on epidemic spreading-an approach based on evolutionary-game dynamics Vaccination and epidemics in networked populationsan introduction Information cascades in complex networks Statistical physics of vaccination The impact of information transmission on epidemic outbreaks Epidemic dynamics on an adaptive network Adaptive human behavior in epidemiological models Information spreading on dynamic social networks Roles of edge weights on epidemic spreading dynamics Issue competition and attention distraction: a zero-sum theory of agenda-setting Moral Threats and Dangerous Desires: AIDS in the News Media Diffusion of Innovations H7n9 is a virus worth worrying about Determination of original infection source of h7n9 avian influenza by dynamical model Global concerns regarding novel influenza a (h7n9) virus infections Controlling dengue with vaccines in thailand Impact of human mobility on the emergence of dengue epidemics in pakistan How events determine spreading patterns: information transmission via internal and external influences on social networks Mapping spread and risk of avian influenza a (h7n9) in china Transmission characteristics of different students during a school outbreak of (h1n1) pdm09 influenza in China The effect of antibody-dependent enhancement, cross immunity, and vector population on the dynamics of dengue fever Spatial behavior of an epidemic model with migration Epidemic enhancement in partially immune populations Representing spatial interactions in simple ecological models The effects of local spatial structure on epidemiological invasions Pair approximation of the stochastic susceptible-infected-recovered-susceptible epidemic model on the hypercubic lattice