Frequent travelers and rate of spread of epidemics.A small proportion of air travelers make disproportionately more journeys than the rest of travelers. They also tend to interact predominantly with other frequent travelers in hotels and airport lounges An airport lounge is a lounge owned by a particular airline (or jointly operated by several carriers). Many offer private meeting rooms, phone, fax, wireless and internet access and other business services, along with provisions to enhance comfort such as free drinks and snacks. . This group has the potential to accelerate global spread of infectious respiratory diseases Noun 1. respiratory disease - a disease affecting the respiratory system respiratory disorder, respiratory illness adult respiratory distress syndrome, ARDS, wet lung, white lung - acute lung injury characterized by coughing and rales; inflammation of the . Using an epidemiologic model, we simulated exportation of cases from severe acute respiratory syndrome--like and influenza-like epidemics in a population for which a small proportion travel more frequently than the rest. Our simulations show that frequent travelers accelerate international spread of epidemics only if they are infected in·fect tr.v. in·fect·ed, in·fect·ing, in·fects 1. To contaminate with a pathogenic microorganism or agent. 2. To communicate a pathogen or disease to. 3. To invade and produce infection in. early in an outbreak and the outbreak does not expand rapidly. If the epidemic growth rate is high, as is likely for pandemic pandemic /pan·dem·ic/ (pan-dem´ik) 1. a widespread epidemic of a disease. 2. widely epidemic. pan·dem·ic adj. Epidemic over a wide geographic area. n. influenza influenza or flu, acute, highly contagious disease caused by a virus; formerly known as the grippe. There are three types of the virus, designated A, B, and C, but only types A and B cause more serious contagious infections. , heterogeneities in travel are frequently overwhelmed o·ver·whelm tr.v. o·ver·whelmed, o·ver·whelm·ing, o·ver·whelms 1. To surge over and submerge; engulf: waves overwhelming the rocky shoreline. 2. a. by the large number of infected persons in the majority population and the resulting high probability that some of these persons will take an international flight. ********** In today's world of increasing air travel for both business and pleasure, a small proportion of persons make disproportionately more journeys than the rest of the population (1,2). These frequent fliers frequent flier n. One who travels often by air, especially on one airline. fre  quent-fli tend to travel for business purposes and mix predominantly with other
business travelers, stay in particular hotels, and use specific airport
lounges. This form of assortative assortative /as·sor·ta·tive/ (ah-sor´tah-tiv) characterized by or pertaining to selection on the basis of likeness or kind. (like with like) mixing means a
respiratory infection Noun 1. respiratory infection - any infection of the respiratory tractrespiratory tract infection infection - the pathological state resulting from the invasion of the body by pathogenic microorganisms could potentially spread quickly within this group and thus be disseminated disseminated /dis·sem·i·nat·ed/ (-sem´i-nat?ed) scattered; distributed over a considerable area. dis·sem·i·nat·ed adj. Spread over a large area of a body, a tissue, or an organ. rapidly between countries. This rapid spread was illustrated early in the severe acute respiratory syndrome Severe Acute Respiratory Syndrome (SARS) Definition Severe acute respiratory syndrome (SARS) is the first emergent and highly transmissible viral disease to appear during the twenty-first century. (SARS) outbreak of 2003. The index SARS case in Hong Kong Hong Kong (hŏng kŏng), Mandarin Xianggang, special administrative region of China, formerly a British crown colony (2005 est. pop. 6,899,000), land area 422 sq mi (1,092 sq km), adjacent to Guangdong prov. Special Administrative Region A special administrative region may be:
n. A political organization founded and controlled by a national Communist party. of China, stayed in a hotel and infected 16 persons there. Of these patients with secondary cases, 6 took international flights to Australia, Canada, Singapore, the Philippines, and Vietnam (3). The arrival of these infected persons subsequently led to SARS outbreaks in Hanoi, Singapore, and Toronto within a few days of the first case in Hong Kong. Recent studies of the role of international air travel on the spread of infectious diseases infectious diseases: see communicable diseases. have highlighted the role of heterogeneities in the connectedness of different airports (4-6), the length of the latent period latent period n. 1. The period elapsing between the application of a stimulus and the obvious response, such as the contraction of a muscle. 2. of the disease in relation to the duration of the flight (7), the possible role of travel restrictions (8-11) and the role of cooperative strategies to control international spread of pandemic influenza (10,12). To date, none of these studies has taken into account the effects of heterogeneity het·er·o·ge·ne·i·ty n. The quality or state of being heterogeneous. heterogeneity the state of being heterogeneous. in the frequency of travel between persons and the potential role of such heterogeneity on the global spread of a directly transmitted infectious agent infectious agent Pathogen, see there . Also of interest is whether targeting interventions specifically at frequent travelers would slow the international spread of a defined pathogen Pathogen Any agent capable of causing disease. The term pathogen is usually restricted to living agents, which include viruses, rickettsia, bacteria, fungi, yeasts, protozoa, helminths, and certain insect larval stages. . Methods To investigate the role of frequent travelers in the exportation of asymptomatic a·symp·to·mat·ic adj. Exhibiting or producing no symptoms. Asymptomatic Persons who carry a disease and are usually capable of transmitting the disease but, who do not exhibit symptoms of the disease are said to be cases during the early stages of an epidemic, we simulated outbreaks of both a SARS-like and an influenza-like airborne respiratory infection in a population in which a small proportion of the population make many more trips than the rest of the population. In the early stages of an epidemic, chance events are important because the number of infected persons is small. We simulated these early stages by using a stochastic By guesswork; by chance; using or containing random values. stochastic - probabilistic model for which every simulation is different. We present both the mean behavior of the simulations and the range of possible outcomes across a large number of simulations. In a stochastic model, introduction of 1 infected person has a finite probability of resulting in the rapid extinction of an infectious disease Infectious disease A pathological condition spread among biological species. Infectious diseases, although varied in their effects, are always associated with viruses, bacteria, fungi, protozoa, multicellular parasites and aberrant proteins known as prions. . To increase the probability of initiating an outbreak, we introduced 3 asymptomatic persons into the population. We simulated the outbreak in a large extended metropolitan area with a population of [10.sup.7] persons. The structure of the model is illustrated schematically sche·mat·ic adj. Of, relating to, or in the form of a scheme or diagram. n. A structural or procedural diagram, especially of an electrical or mechanical system. in Figure 1A. The population is divided into 2 subpopulations with different frequencies of taking international flights. A small proportion of the population, r, are high-frequency fliers. Most of the population, 1 - r, are low-frequency fliers. Frequent fliers have contact with other frequent fliers and with the general population. Similarly, the general population has contact with persons in the general population and with frequent fliers. Contacts are more likely to be between persons within each group (frequent fliers or general population), but the level of this assortativeness may vary (parameterized by [phi]). Contacts may be made completely randomly, with the likelihood of meeting a person from the frequent-flying group or the general population being proportional to the number of persons in each population ([phi] = 1). At the other extreme, persons may only have contact with other persons in the same group ([phi] = 0). The true mixing pattern is likely to lie between these 2 extremes. [FIGURE 1 OMITTED] The extent to which the high-frequency and low-frequency fliers mix will determine how quickly a disease will spread from the general population to the frequent fliers and vice versa VICE VERSA. On the contrary; on opposite sides. . We simulated the model for a selection of mixing parameters, ranging from wholly random ([phi] = 1) to moderate and high levels of assortativeness ([phi] = 0.5, 0.25, respectively). For comparison, we also simulated a homogeneous model in which the entire population travels equally frequently. The outbreak is modeled by dividing the population into those who are still susceptible to the disease, those who have contracted the disease and are in the latent stage latent stage n. See incubative stage. , those who are infectious and symptomatic, and those who have recovered from the disease (Figure 1). This division is similar to the basic structure used in several recent papers on the role of international travel in the spread of infectious diseases (8,9,12). This model structure can be adapted to many airborne infections because it allows for an asymptomatic period, which may or may not be infectious, followed by a potentially symptomatic period during which transmission can also occur. In our stochastic model, events (such as infection or a person leaving the source area) occur by chance. For example, the time after symptom onset at which a person recovers from infection with SARS is not a fixed quantity; rather, it is a randomly chosen time from an exponential 1. (mathematics) exponential - A function which raises some given constant (the "base") to the power of its argument. I.e. f x = b^x If no base is specified, e, the base of natural logarthims, is assumed. 2. probability distribution Probability distribution A function that describes all the values a random variable can take and the probability associated with each. Also called a probability function. probability distribution with a mean of 10 days. Table 1 shows the average latent and infectious periods infectious period The period during which an infected person can transmit a pathogen to a susceptible host used. The probability of leaving the country is constant for all persons (Table 1). The probability of a susceptible person becoming infected increases as a larger proportion of the population becomes infected and is chosen so that the average number of new infections caused by each infected person in the early stages of the epidemic is equal to the basic reproductive number [R.sub.0] (2.5 for SARS, 1.8 for influenza; Table 1). The epidemic is simulated by evaluating the probability that any person is infected, becomes symptomatic, or recovers in any short time interval (we divide time into sequential short intervals of one fiftieth of a day), and then testing whether that event occurs. The simulation can be thought of as generating a random number between 0 and 1 for each person in each time step. If this random number is less than the probability of a particular event occurring to that person, then the event occurs. Otherwise, the person is left in his or her current state. The model does not store the details of every person separately but keeps track of the number of persons who are susceptible (S), latently infected (E), infectious (I), and recovered (R) at any point in time. As events occur, these variables change. For example, when a person becomes infected, S decreases by 1 and E increases by 1. Because the events occur by chance, the total number of persons who are in each state, including the number of infected persons taking flights, varies stochastically sto·chas·tic adj. 1. Of, relating to, or characterized by conjecture; conjectural. 2. Statistics a. Involving or containing a random variable or variables: stochastic calculus. . In our model, we assume that those who are in the latent stage of the disease are not infectious for SARS and influenza. This is generally accepted to be a good model for SARS because isolation of symptomatic persons prevented onward on·ward adj. Moving or tending forward. adv. also on·wards In a direction or toward a position that is ahead in space or time; forward. transmission of SARS, which indicated that the latent period has limited or no infectivity infectivity ability of an agent to infect. (15). We also assume that all infectious persons are symptomatic. This is a conservative assumption, but serosurveillance studies for SARS have shown low prevalence of seropositivity Seropositivity is the presence of a certain antibody in a blood sample. A patient with seropositivity for a particular antigen or agent is termed seropositive. in persons who did not show symptoms of disease (16-21). Lastly, we assume that all symptomatic persons are prevented from traveling because of symptom severity or effective screening. The model equations are shown in the online Technical Appendix (available from www.cdc.gov/EID/content/13/9/1288-Techapp.pdf). The disease course of a possible future influenza pandemic
Little data are available across a population for the relative frequency of flying. The mean probability of flying for the whole population can be approximated by the number of airline passengers divided by the population of a country or city. This calculation gives estimates of 0.005 for Hong Kong, 0.0005 for Beijing, and 0.0002 for Thailand (9). We modeled a population of 10 million persons with a 0.005 probability of flying per day as an example of an outbreak in a well-connected city. A study on domestic flying in Norway suggested that [approximately equal to] 2% of a survey population who take domestic flights in Norway make >20 journeys a year (1). This survey did not include persons who do not take flights. Therefore, the proportion of the total population who make this many journeys is likely to be lower. On the basis of this data, we present results for a population in which 1% of the population travel 20x more frequently than the rest of the population and discuss results for different values of these parameters. We investigated the effect of setting where the outbreak is initiated by using 2 scenarios. In the first scenario, the outbreak begins among the general, infrequently in·fre·quent adj. 1. Not occurring regularly; occasional or rare: an infrequent guest. 2. flying population. Cases subsequently occur among high-frequency fliers as a result of contact between the 2 subpopulations. The mean time until the first high-frequency flier becomes infected is a function of the incidence rate in the main population and level of mixing between the 2 groups. In the second scenario, the outbreak begins among the high-frequency fliers. The disease again spreads to the main population because of contacts between the groups, with the mean time until this occurs being a function of the incidence rate in the main population and the level of mixing between the 2 groups. The mean cumulative number of cases exported (across 50,000 simulations) is presented for both SARS-like and influenza-like parameters (Table 1), for initiation of the epidemic among the low-frequency and high-frequency fliers, and for a range of mixing between the high-frequency and low-frequency travelers. We also illustrate variability in simulated outcomes by presenting snapshots of the distributions of the cumulative number of exported cases. Results As an epidemic progresses, the cumulative number of cases increases, and therefore the number of asymptomatic cases exported from a source area increases for all travel patterns (Figure 2). If a SARS-like epidemic is seeded in the group of frequent fliers, then the initial rate of international spread is accelerated relative to the rate for the homogeneous case (Figure 2, panel A, open symbols). If the frequent travelers contract the infection early, more exclusivity of mixing (smaller [phi]) serves to speed international spread, and this effect may last well into the epidemic (Figure 2, panel A, open triangles). If the epidemic is initiated in the low-frequency fliers, the mean number of exported cases is similar to results of the homogeneous model (Figure 2, panel A, closed symbols). Heterogeneities in travel patterns increase the variability between simulated epidemics; higher variability results from more assortative mixing Assortative/disassortative mixing in graph theory is the extent to which nodes connect preferentially to other nodes with similar characteristics. For example, in a sexual network individuals tend to choose partners who are similar in age, race, sexual orientation, marital (Table 2; online Appendix Figure 1, available from www. cdc.gov/EID/content/13/9/1288-appG1.htm). [FIGURE 2 OMITTED] In an outbreak in which the infection spreads rapidly, such as could potentially occur with pandemic influenza A influenza A n. Influenza caused by infection with a strain of influenza virus type A. influenza A Infectious disease An avian virus, especially of ducks–which in China live near the pig reservoir and 'vector'; (Figure 2, panel B), heterogeneities in travel patterns have less effect on the rate of exportation of cases early in the epidemic than they would for SARS (Figure 2, panel A), particularly after the first weeks of the epidemic. The overall pattern of the exportation of cases is similar for SARS and influenza, but the time scale for influenza is much shorter because of the short doubling time doubling time Oncology A parameter used to determine tumor aggressiveness, which serves to prognosticate, measure therapeutic success, and quantify tumor kinetics and growth rate. Cf Gompertzian growth curve. (Table 1). For example, the number of exported cases is in the thousands for influenza by day 50 (Figure 2, panel B), when it is <20 for SARS (Figure 2, panel A). Later in an epidemic, the mean number of exported cases is similar, regardless of where the epidemic is seeded or the mixing patterns Mixing patterns refer to systematic tendencies of one type of nodes in a network to connect to another type. For instance, nodes might tend to link to others that are very similar or very different. of the high-frequency fliers and low-frequency fliers (Figure 2, panel B, inset for influenza, not shown for SARS). The variability between simulated epidemics becomes large, with some simulations resulting in hundreds of exported cases and many resulting in only a few exported cases (Table 2; online Appendix Figure 1, panel D). Heterogeneities in travel patterns increase the number of exported cases to a greater extent and for a longer period if the relative frequency of flying of the high-frequency fliers, f, is higher or if the proportion of the population who are high-frequency fliers, r, is smaller (online Appendix Figure 2, available from www.cdc.gov/EID/content/13/9/1288-appG2.htm) because the probability that any frequent flier will fly per day is higher (Table 1, [[epsilon].sub.H]). However, if r becomes small, the epidemic among this group peaks and then decreases quickly because of the limited number in the group. In this case, the period in which there are enough infected persons in this group who can contribute to an increased rate of spread of exportation of cases is short (online Appendix Figure 2, panel B). Discussion The probability that an infected person will make an international flight while still incubating infection and nonsymptomatic is higher for a high-frequency flier than for a low-frequency flier (Table 1). In the early stages of an epidemic in which most cases occur in high-frequency fliers, the expected number of cases exported will therefore be higher than if the early cases occur in predominantly low-frequency fliers (Figure 2). Heterogeneity in flying patterns also increases the variability between simulated outbreaks (Table 2; online Appendix Figure 1). Wherever the epidemic is initially concentrated, the disease will spread to all parts of the population because of contacts between persons in both groups. The speed with which this occurs will be a function of the level of mixing between the groups. If high-frequency fliers mix almost exclusively among themselves, they are unlikely to acquire cases early in an epidemic in which the first cases emerge in the general population. If, however, they contract the infection early, this exclusivity serves to speed international spread and this effect may last well into the epidemic (Figure 2, open triangles). If mixing is less assortative, then the epidemic will spread to the general population more rapidly. Because most of the population are low-frequency fliers, the number of infected persons in the main population will quickly exceed those in the small group of high-frequency fliers. When the number of cases becomes large, the expected number of exported cases (which may be approximated as the probability of flying while asymptomatic multiplied by cumulative incidence [9]) will be large, even if the probability that any person travels is small. Once the epidemic takes hold in the general population, the number of cases being exported from the majority low-frequency flier population exceeds those being exported from the much smaller group of high-frequency fliers. Regardless of where most initial cases occur, the contribution of high-frequency fliers to international spread is eventually overwhelmed by the large epidemic in the general population, despite their lower probability of flying per day. Thus, the average behavior of epidemics is eventually similar, whether they start in high-frequency fliers, or in groups with no heterogeneities in travel (Figure 2, panel B, inset), but the variability between simulations is large (Table 2; online Appendix Figure 1). The latent period for influenza is likely to be shorter than that for SARS, which reduces the probability that any infected person will travel before exhibiting symptoms (Table 1). However, the doubling time for an influenza pandemic is less than half that for SARS because of the much shorter generation time for influenza (Table 1). Therefore, the number of cases exported from a local influenza epidemic influenza epidemic caused 500,000 deaths in U.S. alone (1918–1919). [Am. Hist.: Van Doren, 403] See : Disease will increase far more rapidly than those from a SARS epidemic (Figure 2, panel B). This rapid growth means that any increased rate of export caused by early concentration of infection among the high-frequency fliers will be quickly overcome by the number of cases being exported from the general population (Figure 2, panel B), which indicates that heterogeneities in travel have little effect. We have simulated an outbreak in a single population by using a relatively simple model. Similar models have been used for the dynamics of single epidemics in a network of countries or areas connected by a complex airline network (6,8,12), and more complex, person-based, within-country models have been used to simulate epidemics within smaller groups of countries (10,14). Our results show that in the event of an influenza pandemic, interventions such as travel restrictions will have to be implemented rapidly and effectively to have a substantial effect (8-10,12). We have shown that high-frequency fliers have the potential to spread infection even more rapidly than previously indicated by models that assume homogenous homogenous - homogeneous travel behavior Travel behavior is the study of what people do over space, and how people use transport. The questions studied in travel behavior are broad, and are very much related to activity analysis and time use studies. . Our study and the relatively simple structure of the model were limited by the lack of available data on the travel patterns of persons. Travel patterns may vary with age, sex, occupation, and district or country of origin. To increase our knowledge of these patterns, existing surveys of airline passengers at airports could be extended to ask additional questions on number of journeys per year. However, these surveys would necessarily omit o·mit tr.v. o·mit·ted, o·mit·ting, o·mits 1. To fail to include or mention; leave out: omit a word. 2. a. To pass over; neglect. b. those persons who do not take international flights, who are believed to make up a large proportion of many populations. Any additional information could be valuable for assessing the risk for international spread of diseases from affected areas. The SARS epidemic in Hong Kong satisfied the criteria we have identified for frequent travelers to accelerate the international spread of an outbreak. The first case-patient with SARS in Hong Kong had contact with other frequent travelers in a hotel and seeded the epidemic in high-frequency travelers. However, SARS has long incubation incubation /in·cu·ba·tion/ (in?ku-ba´shun) 1. the provision of proper conditions for growth and development, as for bacterial or tissue cultures. 2. and infectious periods and only moderate transmissibility trans·mis·si·ble adj. That can be transmitted: transmissible signals. trans·mis . For influenza A, which has much shorter incubation and infectious periods, such heterogeneities have a limited effect on the rate of exportation of cases. Because frequent travelers play a role mainly in the early stages of an epidemic, targeting interventions to these persons is unlikely to be an effective control strategy because such a plan would have to be in place almost immediately. Finally, estimates of the rate of international spread of respiratory infections that do not consider heterogeneities in behavior may be misleading. If an outbreak begins in a rural area, where persons have a low probability of traveling abroad and mixing with frequent fliers, the time until cases are exported is longer than in outbreaks in which frequent travelers contract infection early in the course of the outbreak. When combined with the vagaries of chance early in the evolution of a new epidemic and the complexities of the international airline network, this variability makes early prediction of the pattern and speed of global spread difficult. This difficulty in predicting whether a particular country is likely to import cases from a currently unknown source area highlights the need for developing a strategy for controlling an outbreak caused by imported cases. This study was supported by the European Union European Union (EU), name given since the ratification (Nov., 1993) of the Treaty of European Union, or Maastricht Treaty, to the European Community , the Wellcome Trust The Wellcome Trust is a United Kingdom-based charity established in 1936 to administer the fortune of the American-born pharmaceutical magnate Sir Henry Wellcome. Its income was derived from what was originally called Burroughs Wellcome & Co, later renamed in the UK as the , and the Medical Research Council. Dr Hollingsworth is a mathematical modeler at Imperial College London History Imperial College was founded in 1907, with the merger of the City and Guilds College, the Royal School of Mines and the Royal College of Science (all of which had been founded between 1845 and 1878) with these entities continuing to exist as "constituent colleges". . 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Table 1. Parameter descriptions and values for epidemiologic model
that simulates exportation of cases from SARS-like and influenza-like
epidemics *
Description Parameter
Infection
Basic reproductive number [R.sub.0]
Latent period, d [T.sub.L]
Infectious period, d [T.sub.i]
Generation time, d [T.sub.g] = [T.sub.L] + [T.sub.i]
Epidemic doubling time, d [t.sub.d] = [T.sub.g/
([R.sub.0] - 1) In2
International travel
Proportion of population r
who are high-frequency
fliers
Mixing between groups: [phi]
[PHI] = 1, random
mixing; [PHI] = 0,
assortative mixing
Relative probability of f
flying of high-frequency
fliers
Mean probability of [epsilon]
flying per day
Probability of flying [[epsilon].sub.H] = f /
per day of high- 1 + (f-1)r [epsilon]
frequency fliers
Probability of flying [[epsilon].sub.L] = 1 /
per day of low- 1 + (f-1)r [epsilon]
frequency fliers
Probability of a case
being exported
Homogeneous flying L = [T.sub.L][epsilon]
patterns
High-frequency fliers [I.sub.H] = [T.sub.L]
[[epsilon].sub.H]
Low-frequency fliers [I.sub.L] = [T.sub.L]
[[epsilon].sub.L]
Value (reference)
Description SARS Influenza
Infection
Basic reproductive number 2.5 (13) 1.8 (14)
Latent period, d 4 (13) 1.5 (14)
Infectious period, d 10 (13) 1.1 (14)
Generation time, d 14 2.6 (14)
Epidemic doubling time, d 6.5 2.3 (14)
International travel
Proportion of population 0-0.5
who are high-frequency
fliers
Mixing between groups: 0-1
[PHI] = 1, random
mixing; [PHI] = 0,
assortative mixing
Relative probability of 20
flying of high-frequency
fliers
Mean probability of 0.005 (9)
flying per day
Probability of flying 0.084
per day of high-
frequency fliers
Probability of flying 0.042
per day of low-
frequency fliers
Probability of a case
being exported
Homogeneous flying 0.02 0.008
patterns
High-frequency fliers 0.34 0.13
Low-frequency fliers 0.017 0.006
* SARS, severe acute respiratory syndrome.
Table 2. Variability between runs in an epidemiologic model that
simulates exportation of cases from SARS-like and influenza-like
epidemics *
No. cases exported, mean,
median (5th-95th percentile)
First
Mixing pattern case Day 10 Day 20
SARS
Homogeneous 0, 0 (0-0) 0, 0 (0-1)
flying patterns
Random mixing High 1, 0 (0-2) 2, 0 (0-2)
Low 0, 0 (0-0) 0, 0 (0-1)
Moderately High 2, 1 (0-3) 3, 2 (1-4)
assortative Low 0, 0 (0-0) 0, 0 (0-1)
Highly High 2, 1 (0-3) 4, 2 (1-7)
assortative Low 0, 0 (0-0) 0, 0 (0-1)
Influenza
Homogeneous 1, 0 (0-1) 8, 5 (0-20)
flying patterns
Random mixing High 1, 0 (0-2) 7, 5 (0-18)
Low 0, 0 (0-1) 7, 5 (0-18)
Moderately High 2, 0 (0-3) 8, 6 (0-32)
assortative
Low 1, 0 (0-1) 7, 5 (0-20)
Highly High 3, 2 (0-7) 15, 10 (2-41)
assortative
Low 0, 0 (0-2) 12, 0 (0-33)
No. cases exported, mean,
median (5th-95th percentile)
First
Mixing pattern case Day 30 Day 40
SARS
Homogeneous 1, 0 (0-3) 3, 1 (0-7)
flying patterns
Random mixing High 2, 1 (0-3) 4, 2 (1-7)
Low 1, 0 (0-3) 3, 1 (0-6)
Moderately High 4 (3, 1-7) 6 (4, 2-12)
assortative Low 1, 0 (0-2) 3, 1 (0-6)
Highly High 5, 5 (2-13) 10, 8 (3-22)
assortative Low 1, 0 (0-2) 3, 1 (0-6)
Influenza
Homogeneous 107, 85 (1-251) 1,268 1,069
flying patterns (7-3, 118)
Random mixing High 89, 74 (1-233) 1,341 940
(1-3, 049)
Low 95, 78 (1-246) 1,264 1,057
(7-3, 256)
Moderately High 93, 72 (1-231) 1,288 1,138
assortative (1-3, 387)
Low 104, 83 (0-264) 1,411 1,213
(0-3, 526)
Highly High 106, 81 (2-291) 1,166, 840
assortative (2-2, 923)
Low 164, 139 (0-246) 1,312, 967
(1-3, 231)
No. cases exported, mean,
median (5th-95th percentile)
First
Mixing pattern case Day 50
SARS
Homogeneous 7, 5 (1-16)
flying patterns
Random mixing High 7, 5 (2-14)
Low 7, 5 (1-15)
Moderately High 9, 7 (2-20)
assortative Low 7, 5 (0-15)
Highly High 16, 12 (4-38)
assortative Low 6, 4 (1-15)
Influenza
Homogeneous 15,729 13,541
flying patterns (73-35, 132)
Random mixing High 14,592 11,990
(1-35, 632)
Low 15,668 13,651
(74-35, 231)
Moderately High 15,505 14,362
assortative (1-32, 134)
Low 17,081 15,850
(0-35, 403)
Highly High 14,145 10,770
assortative (2-34, 351)
Low 16,592 12,607
(28-36, 643)
* Means are shown in Figure 2 and distributions in online Appendix
Figure 1. SARS, severe acute respiratory syndrome.
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