Real-time estimates in early detection of SARS.We propose a Bayesian statistical framework for estimating the reproduction number R early in an epidemic. This method allows for the yet-unrecorded secondary cases if the estimate is obtained before the epidemic has ended. We applied our approach to 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) epidemic that started in February 2003 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. . Temporal patterns of R estimated after 5, 10, and 20 days were similar. Ninety-five percent credible intervals In Bayesian statistics, a credible interval is a posterior probability interval, used for purposes similar to those of confidence intervals in frequentist statistics. For example, a statement such as narrowed when more data were available but stabilized after 10 days. Using simulation studies of SARS-like outbreaks, we have shown that the method may be used for early monitoring of the effect of control measures. ********** The reproduction number R of an epidemic (the mean number of secondary cases 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. by a single infectious case) is a key parameter for the analysis of infectious diseases infectious diseases: see communicable diseases. because it summarizes the potential transmissibility trans·mis·si·ble adj. That can be transmitted: transmissible signals. trans·mis of the disease and indicates whether an epidemic is under control (R<1). Up to now, this parameter has only been estimated retrospectively for periods from which all secondary cases had been detected. In terms of policy development and evaluation during the epidemic, obtaining estimates of the temporal trends in the reproduction number relating to relating to relate prep → concernant relating to relate prep → bezüglich +gen, mit Bezug auf +acc as recent a time as possible would be critical. If all incident cases could be traced to their index cases, estimating the reproduction number would simply be a matter of counting secondary cases. However, if tracing information is incomplete or ambiguous, modeling or statistical approaches are required. For example, a mathematical model
n the number in a frequency distribution below which a certain percentage of fees will fall. E.g., the ninetieth percentile is the number that divides the distribution of fees into the lower 90% and the upper 10%, or that fee level of the distribution of the generation interval described by Lipsitch et al.) (3). In this report, we show how to estimate the reproduction number in an ongoing epidemic, which will account for yet unobserved secondary cases. The method is applied to data from the 2003 SARS outbreak in Hong Kong (4). Using simulated data, we demonstrate how the method may be used for early detection of the effect of control measures. Materials and Methods Statistical Framework We propose a Bayesian statistical framework for real-time inference on the temporal pattern of the reproduction number of an epidemic. Here, the reproduction number [R.sub.t] for day t will be defined as the mean number of secondary cases infected by a case with symptom onset at day t. Denoting [n.sub.t] as the number of cases with symptom onset at day t and [X.sub.t] as the number of secondary cases they infected, the reproduction number [R.sub.t] is the ratio [X.sub.t]/[n.sub.t], defined for [n.sub.t]>0. Assume that we would like to compute To perform mathematical operations or general computer processing. For an explanation of "The 3 C's," or how the computer processes data, see computer. the daily values [R.sub.t] from day 0 to present day T, before the epidemic has ended. Although daily incident case counts can be known up to day T, provided no delay in reporting occurs, the corresponding counts of secondary cases [X.sub.t] cannot. Secondary case-patients infected before day T, whose illness had a 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. time, may have clinical onset only after day T. Furthermore, since the exact chain of transmission is seldom observed in practice, attributing secondary cases to previous cases is difficult. Focusing on these 2 issues, we show that the daily counts of symptom onset available until day T are sufficient to estimate [R.sub.t]. A 3-step construct is necessary. We first predict the eventual number of late secondary cases (as yet unobserved), for cases reported at day t, assuming the number of early secondary cases (reported before day 7) is known. The method described by Wallinga and Teunis (2) is then used to estimate the number of early secondary cases from the daily counts of symptom onsets. These 2 steps are finally combined and yield an estimate of the predictive distribution of [R.sub.t]. Technical details are given in the online Appendix (available from http://www.cdc.gov/ncidod/ EID/vol12no01/05-0593_app.htm). The estimation procedure depends on 3 assumptions: 1) ascertainment of patients whose symptoms appear before day T is complete, 2) transmission events are independent, and 3) the generation interval, the time from symptom onset in a primary case to symptom onset in a secondary case, has a known frequency distribution. Data from Hong Kong The method was retrospectively used to analyze the SARS outbreak in Hong Kong. The data consisted of the dates of symptom onset of the 1,755 case-patients who were detected in Hong Kong in 2003 (4). Simulated Data Using simulations, we explored the ability of the method to quickly detect the effect of control measures. Five hundred epidemics were simulated with the following characteristics. During the first 20 days of the epidemics, the theoretical reproduction number was 3. Control measures were implemented at day 20. In a first scenario, control measures were completely effective (no transmission occurred after day 20). In a second scenario, the theoretical reproduction number after control measures were implemented was 0.7. Details on the simulations are available from the corresponding author. In a simulation study, the bias and precision of the real-time estimator were investigated in situations in which the theoretical reproduction number remained constant with time. We also evaluated the effect of the length of the generation interval on the results. Detailed information can be obtained from the corresponding author. Results Application to Hong Kong SARS Data Figure 1A shows the dates of symptom onset of the 1,755 SARS patients detected in Hong Kong in 2003. Figure 1B F shows the expectation and 95% credible intervals of the predictive distribution of [R.sub.t] based on data available at the end of the epidemic and after a lag of 2, 5, 10, and 20 days. [FIGURE 1 OMITTED] After a lag of 2 days, the 95% credible intervals were wide and displayed an undesirable feature: they sharply decreased to 0 as soon as no cases had been observed for 2 consecutive days (Figure 1C; note especially days 1-4 and 13). After a 5-day lag, this undesirable feature had vanished (Figure 1D). [FIGURE 1 OMITTED] With lags >5 days, the trends of expected values Expected value The weighted average of a probability distribution. Also known as the mean value. were relatively similar, with a peak around day 20, a decreasing trend after this date, and the expectation of [R.sub.t] decreasing to <1 around day 40. These observations suggest that after a lag of only 5 days, the temporal trends in the expectation of [R.sub.t] are well captured. For a lag of 5 days, the credible interval of R, was wide when <20 cases were detected (periods 0[less than or equal to]t[less than or equal to]20 and t[greater than or equal to]63), but was relatively narrow when more cases were detected (period 21[less than or equal to]t[less than or equal to]62). As expected, the width of the credible interval narrowed as the lag increased and more complete data were available. The expectations and credible intervals were very similar for lags of 10 and 20 days, 67.8th and 99.7th percentiles, respectively, of the distribution of the SARS generation interval described by Lipsitch et al. (3). No difference was detected between retrospective and 20-day estimates. Detecting the Effect of Control Measures In Figure 2, the method is used to estimate the impact of control measures implemented on day 20 in the simulated datasets with completely effective or limited control measures. The curves show the temporal pattern of [R.sub.t] based on an average over the 500 simulated datasets as a function of T. Even when control measures are completely effective, based on data available up to day 21, the average expectation of [R.sub.20] is [approximately equal to]3. Based on data available up to day 25, a downward trend is apparent, whereas based on data available up to day 29, the average expectation of [R.sub.t] is <1 from t = 27 days. Based on data available up to day 40 (20 days alter the implementation of the control measures), the estimates indicate that the threshold value 1 is crossed at day 22, which is 2 days after control measures were implemented. With limited control measures, the observed changes are qualitatively the same, although slightly more time is required for [R.sub.t] estimates to decrease to <1. Discussion Our statistical framework provided real-time estimates of the reproduction number of an epidemic, and thus quickly showed the impact of control measures. In simulations of SARS-like diseases, the derived estimator detected the decrease of [R.sub.t] only 5 days after control measures were implemented. Furthermore, the average estimate had crossed the threshold value of 1 only 9 days after control measures were implemented. In theory, the method could be applied to communicable diseases communicable diseases, illnesses caused by microorganisms and transmitted from an infected person or animal to another person or animal. Some diseases are passed on by direct or indirect contact with infected persons or with their excretions. with the following characteristics: 1) no 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; 2) no underreporting; 3) knowledge of the generation interval. The list of communicable diseases that could be monitored is therefore relatively large, although it does not include diseases such as 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. , for which the proportion of asymptomatic or unreported cases may be large. In practice, the delay until estimates of the reproduction number become reliable will depend critically on the generation interval distribution. For SARS, when the reproduction number was constant over time, our real-time estimates were almost unbiased after only 1 day. With the original estimator of Wallinga and Teunis (2), which is not intended for real-time estimation, downward bias would be a concern for at least 2 weeks after observation. However, real-time estimates obtained for recent days displayed wide 95% credible intervals and zero-width intervals when no cases had been observed or reported for a few days. Here, owing to owing to prep. Because of; on account of: I couldn't attend, owing to illness. owing to prep → debido a, por causa de the relatively short generation interval of SARS (mean 8.4 days) (3), reliable estimates were obtained after only 5 days, albeit with wide credible intervals, and they were consolidated after l0 days. These lags corresponded to the 20th and 70th percentiles of the SARS generation interval (3). When the generation interval doubled, the time delay required to detect the effect of control measures implementation or to consolidate estimates roughly doubled. We assumed that the distribution of the generation interval was known and remained unchanged during the course of the outbreak. In practice, however, this distribution is derived from a subset of traced cases. If the subset is small, e.g., the case at the beginning of an emerging disease outbreak, uncertainty will be large. Furthermore, the generation interval may decrease during the course of the outbreak because of quicker interventions, leading to possible bias in the estimates of R (2). Further developments of the method could take these issues into consideration. For example, one could use information on traced cases as it accrues to sequentially estimate the generation interval. Depending on how cases are traced during the epidemic, changes in the generation interval could also be monitored. The approach smoothed the temporal pattern of the reproduction number, leading to overestimation o·ver·es·ti·mate tr.v. o·ver·es·ti·mat·ed, o·ver·es·ti·mat·ing, o·ver·es·ti·mates 1. To estimate too highly. 2. To esteem too greatly. of R in the week after control measures were implemented. We are trying to find a correction factor for this bias in ongoing research. The method has a natural real-time implementation in which 1) a first estimate of the reproduction number is available after a lag that depends on the generation interval, and 2) while the epidemic goes on, the estimate is consolidated, and its credible interval narrows. Incorporation of such a statistical estimation framework into real-time surveillance of future 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. outbreaks would enhance the ability of epidemiologists to provide timely advice to public health policymakers. The work in Hong Kong was supported in part by a commissioned grant from the Research Fund for the Control of Infectious Diseases of the Health, Welfare and Food Bureau The Health, Welfare and Food Bureau (Traditional Chinese: 衞生福利及食物局) of Hong Kong oversees the policies on health, welfare, environmental hygiene and food issues. of the Hong Kong SAR (Segmentation And Reassembly) The protocol that converts data to cells for transmission over an ATM network. It is the lower part of the ATM Adaption Layer (AAL), which is responsible for the entire operation. See AAL. SAR - segmentation and reassembly Government. Mr Cauchemez is a doctoral student at University Pierre et Marie Curie Curie (kürē`), family of French scientists. Pierre Curie, 1859–1906, scientist, and his wife, Marie Sklodowska Curie, 1867–1934, chemist and physicist, b. , Paris, France. He develops statistical methods to analyze transmission of infectious diseases using incomplete information. References (1.) Riley S, Fraser C, Donnelly CA, Ghani AC, Abu-Raddad LJ, Hedley AJ, et al. Transmission dynamics of the etiological etiological pertaining to etiology. etiological diagnosis the name of a disease which includes the identification of the causative agent, e.g. Streptococcus agalactiae mastitis. agent of SARS in Hong Kong: impact of public health interventions health intervention Health care An activity undertaken to prevent, improve, or stabilize a medical condition . Science. 2003;300:1961-6. (2.) Wallinga J, Teunis P. Different epidemic curves for severe acute respiratory syndrome reveal similar impacts of control measures. Am J Epidemiol. 2004;160:509-16. (3.) Lipsitch M, Cohen cohen or kohen (Hebrew: “priest”) Jewish priest descended from Zadok (a descendant of Aaron), priest at the First Temple of Jerusalem. The biblical priesthood was hereditary and male. T, Cooper B, Robins JM, Ma S, James L, et al. Transmission dynamics and control of severe acute respiratory syndrome. Science. 2003:300:1966-70. (4.) Leung GM, Hedley AJ, Ho LM, Chau P, Wong IO, Thach TQ, et al. The epidemiology of severe acute respiratory syndrome in the 2003 Hong Kong epidemic: an analysis of all 1,755 patients. Ann Intern intern /in·tern/ (in´tern) a medical graduate serving in a hospital preparatory to being licensed to practice medicine. in·tern or in·terne n. Med. 2004; 141:662-73. Simon Cauchemez, * ([dagger]) Pierre-Yves Boielle, * ([dagger]) ([double dagger double dagger n. A reference mark (  ) used in printing and writing. Also called diesis.Noun 1. ]) Christi A. Donnelly, ([section]) Neil M Ferguson, ([section]) Guy Thomas, * ([dagger]) ([double dagger]) Gabriel M. Leung, ([paragraph]) Anthony J Hedley, ([paragraph]) Roy M ([section]) Anderson, ([section]) and Alain-Jacques Valleron * ([dagger]) ([double dagger]) Address for correspondence: Simon Cauchemez, Department of Infectious Disease Epidemiology The Department of Infectious Disease Epidemiology[1] is based at Imperial College London and carries out research including the modelling of infectious diseases and molecular epidemiology of pathogens. , St. Mary's Campus, Norfolk Place, London W2 IPG IPG Implantable pulse generator, see there , UK; fax: 44-20-0759-43282; email: s.cauchemez@ imperial.ac.uk * Institut National de la Sante et de la Recherche La Recherche is a monthly French language popular science magazine covering recent scientific news. It is published by the Société d'éditions scientifiques (the Scientific Publishing Group), a subsidiary of Financière Tallandier. Medicale, Paris, France; ([dagger]) Universite Pierre et Marie Curie, Paris, France; ([double dagger]) Assistance Publique-Hopitaux de Paris, Paris, France; ([section]) Imperial College, London, United Kingdom; and ([paragraph]) University of Hong Kong The University of Hong Kong (commonly abbreviated as HKU, pronounced as "Hong Kong U") is the oldest tertiary institution in Hong Kong. Its motto is "Sapientia et Virtus" in Latin, and " , Hong Kong Special Administrative Region A special administrative region may be:
n. A political organization founded and controlled by a national Communist party. of China |
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