Automated, laboratory-based system using the Internet for disease outbreak detection, the Netherlands.Rapid detection of outbreaks is recognized as crucial for effective control measures and has particular relevance with the recently increased concern about bioterrorism bi·o·ter·ror·ism n. The use of biological agents, such as pathogenic organisms or agricultural pests, for terrorist purposes. Bioterrorism . Automated analysis of electronically collected laboratory data can result in rapid detection of widespread outbreaks or outbreaks of pathogens with common signs and symptoms. In the Netherlands, an automated outbreak detection system for all types of pathogens has been developed within an existing electronic laboratory-based surveillance system called ISIS. Features include the use of a flexible algorithm for daily analysis of data and presentation of signals on the Internet for interpretation by health professionals. By 2006, the outbreak detection system will analyze laboratory-reported data on all pathogens and will cover 35% of the Dutch population. ********** Rapid detection of outbreaks on a time scale compatible with disease incubation periods incubation period n. 1. See latent period. 2. See incubative stage. Incubation period is recognized as crucial to maximize the effect of control measures. Most outbreaks are rapidly detected and controlled locally. However, outbreaks involving cases over a wider area or in several local health jurisdictions may have only few local cases and thus be easily missed, especially if the outbreak has a slowly rising number of cases. Outbreaks of certain pathogens with common signs and symptoms (e.g., gastroenteric gas·tro·en·ter·ic adj. Relating to the gastrointestinal tract. gastroenteric pertaining to the stomach and intestines. disease) can also be missed. The role of national laboratory data in detecting such outbreaks has been increasingly recognized in the last few years as modern typing techniques give more precision on the 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. type and subtype (programming) subtype - If S is a subtype of T then an expression of type S may be used anywhere that one of type T can and an implicit type conversion will be applied to convert it to type T. , routinely unearthing outbreaks by linking cases either locally, nationally, or internationally (1-4) that otherwise would probably not be detected. In addition, surveillance of a wide range of pathogens is essential in identifying emerging disease threats (5,6). The increasingly perceived threat of bioterrorism recently has made more urgent the need for rapid detection of increases in laboratory diagnoses of common and uncommon pathogens to complement clinician-based reporting systems. Increasing computational power in the last 10 years has resulted in the development of mathematical algorithms to routinely and rapidly detect significant clusters within large amounts of surveillance data (7-12). Automated electronic laboratory reporting is frequently promoted to improve data quality and timeliness of collection (13). More recently, the general availability of the Internet permits feedback to many users, who can have continuous, simultaneous, and even interactive access to information. The Internet allows for immediate communication of signals of possible outbreaks to relevant professionals for interpretation and action. In the Netherlands, these developments have led to the implementation of automated laboratory-based surveillance system integrated with the Internet in a project named the 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. Surveillance Information System (ISIS). We describe the development of an automated outbreak detection system within ISIS for all laboratory-reported pathogens in the Netherlands. The system is updated daily with Web-based feedback. Overview of National Laboratory Surveillance In the Netherlands, >90% of the 76 microbiologic laboratories are associated with public hospitals; <10% are private laboratories not associated with hospitals. Other than 10 notifiable notifiable /no·ti·fi·a·ble/ (no?ti-fi´ah-b'l) necessary to be reported to a government health agency. notifiable necessary to be reported to the relevant government authority. Said of individual diseases. infectious diseases infectious diseases: see communicable diseases. , microbiologic laboratories have no legal requirement to provide data for surveillance. Since 1994, ISIS has collected anonymous positive and negative test results on more than 350 pathogens directly from voluntarily participating laboratories on a daily basis in a fully automated system that uses electronic data interchange See EDI. (application, communications) electronic data interchange - (EDI) The exchange of standardised document forms between computer systems for business use. EDI is part of electronic commerce. . The raw information is then processed by applying a set of criteria based on the diagnosis of a particular infection. Laboratory results are thus combined into surveillance diagnoses by the removal of results of duplicate testing duplicate testing Lab medicine The inappropriate repeating of lab or other diagnostic evaluations–eg, CBC, U/A, CK-MB, BMP, more often than allowed by Medicare or third party payers of the same case by the same or a different microbiologic technique and then classified by the type of infection.(1) Surveillance diagnoses are then presented as feedback on a password-protected Internet site within 24 hours. At present, information on 40 of the 350 pathogens is presented on this site (Table) (available with password from: URL URL in full Uniform Resource Locator Address of a resource on the Internet. The resource can be any type of file stored on a server, such as a Web page, a text file, a graphics file, or an application program. : http://www.isis.rivm.nl). Currently, 11 laboratories located throughout the country are connected to ISIS, covering 16% of the total Dutch population of 16 million. The coverage of each laboratory is calculated from the coverage of each hospital exclusively served by that laboratory, which in turn is calculated by a national organization that calculates the government subsidy to each hospital. One laboratory (the National Institute for Public Health and the Environment [RIVM]) is also the national reference laboratory for Salmonella salmonella Any of the rod-shaped, gram-negative, non-oxygen-requiring bacteria that make up the genus Salmonella. Their main habitat is the intestinal tract of humans and other animals. , Escherichia coli Escherichia coli (ĕsh'ərĭk`ēə kō`lī), common bacterium that normally inhabits the intestinal tracts of humans and animals, but can cause infection in other parts of the body, especially the urinary tract. , and Mycobacterium tuberculosis Mycobacterium tuberculosis n. Tubercic bacillus. Mycobacterium tuberculosis , for which the coverage is much higher. The coverage of the Salmonella reference laboratory, for example, is estimated to be 64% of the national population. Since 1996, an algorithm has been used to detect outbreaks in the surveillance data resulting from Salmonella (sub)typing (14). Apart froth ISIS, two other systems collect laboratory data. Fifteen regional public health laboratories provide a weekly report of aggregated data of positive diagnoses for nine bacterial pathogens. These same laboratories and two other laboratories form a network of 17 virologic laboratories that report weekly aggregated numbers of positive diagnoses of 37 virologic pathogens. Four of the 15 public health laboratories contribute data electronically to ISIS. Design of the Outbreak Detection System The overall objective of the system was the automated detection of an unexpected national increase of any one pathogen reported by laboratories in a determined period, for feedback to all interested parties by means of the Internet, followed by interpretation and communication to relevant authorities for decisions on control to be taken. The system thus comprises three components: detection of clusters in time or unusual disease events (e.g., one case of rabies rabies (rā`bēz, ră`–) or hydrophobia (hī'drəfō`bēə), acute viral infection of the central nervous system in dogs, foxes, raccoons, skunks, bats, and other animals, and in ) and signal generation; feedback of the signals on the Internet to relevant professionals; and interpretation of signals on a weekly basis with communication to relevant authorities. Cluster Detection and Generation of Signals Approach Our approach was to design a system to detect outbreaks that otherwise would probably be missed altogether and detect more rapidly the outbreaks that would also probably be eventually detected by other means. We designed the system with sensitivity and timeliness as the priority features, especially since small increases in laboratory data often indicate larger communitywide outbreaks. Sensitivity in this context would be defined as the number of relevant outbreaks found from all relevant outbreaks. Clearly, this distinction depends on how "relevant" is defined. All relevant outbreaks, however, should include those outbreaks of public health importance that are missed by conventional means; therefore, the denominator denominator the bottom line of a fraction; the base population on which population rates such as birth and death rates are calculated. denominator will always be unknown. Thus, absolute sensitivity of the automated system will be impossible to calculate. The system, however, can be designed to maximize sensitivity and detect more outbreaks than other mechanisms such as clinical observation, without resulting in an unmanageable number of signals. The system was also intended to be more timely, by detecting the same outbreaks as other mechanisms but more quickly. The specificity of the system was considered less important in the initial phase, since false-positive results could be filtered out when signals were interpreted. We also decided that the system should be sensitive enough to detect even one case of certain critical infectious diseases (e.g., hantavirus hantavirus, any of a genus (Hantavirus) of single-stranded RNA viruses that are carried by rodents and transmitted to humans when they inhale vapors from contaminated rodent urine, saliva, or feces. There are many strains of hantavirus. infection) or Unusual infections of current interest (e.g., hepatitis E Hepatitis E Definition The hepatitis E virus (HEV) is a common cause of hepatitis that is transmitted via the intestinal tract, and is not caused by the hepatitis A virus. virus infection), which might indicate an outbreak, and to detect expected seasonal increases of diseases caused by selected pathogens (e.g., 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. ) as they occur. This design would allow for rapid action to verify the signal and institute case-finding or put in place certain public health measures (e.g., prompting nursing homes to vaccinate vac·ci·nate v. To inoculate with a vaccine in order to produce immunity to an infectious disease such as diphtheria or typhus. vac residents against influenza). Generation of Signals Signals generated by the system are produced by comparing observed values with a predefined threshold value. Threshold values are calculated from values expected from historical data (for most pathogens) or are fixed, user-defined thresholds, set by epidemiologists for detecting seasonal increases or monitoring critical pathogens. Algorithms Using Historical Data Several algorithm types applied to outbreak detection have been described in the literature, based either on Cumulative Sums (12,15) linear regression Linear regression A statistical technique for fitting a straight line to a set of data points. (7), or Fourier regression and autocorrelative models such as Box-Jenkins (8,9). Fourier analysis Fourier analysis n. The branch of mathematics concerned with the approximation of periodic functions by the Fourier series and with generalizations of such approximations to a wider class of functions. and autocorrelative methods require model building or the setting of many parameters, processes considered too labor-intensive for a generic algorithm for all type of pathogens. We decided to base the ISIS system on the algorithm currently run each week on Salmonella data, which has been successfully detecting outbreaks since 1998 in the Netherlands (14,16-20) but is not automatic and requires an operator to periodically update data. The algorithm is a simple linear regression Simple linear regression A regression analysis between only two variables, one dependent and the other explanatory. model, adjusted for seasonality, secular trends secular trend The relatively consistent movement of a variable over a long period. A stock in a secular uptrend is an indicator that the security has experienced an extended period of rising prices. , and past outbreaks in a similar manner as described by Farrington et al. (7) and requires little parameter resetting or model checking. Briefly, to calculate an expected total value for the current epidemiologic week, a regression line Noun 1. regression line - a smooth curve fitted to the set of paired data in regression analysis; for linear regression the curve is a straight line regression curve is plotted through the totals in the nine epidemiologic weeks centered on the same epidemiologic week in the previous 5 years. For example, to calculate an expected value Expected value The weighted average of a probability distribution. Also known as the mean value. for week 20, a regression line is plotted through the values at weeks 16-24 of the previous 5 years. To maximize sensitivity we decided, after preliminary testing with Salmonella data, on two variations of the same algorithm, using two different window periods. The first is a 7-day total calculated daily. This variation is based on an algorithm that calculates expected week totals of a certain pathogen and a threshold value of 2.56 standard deviations In statistics, the average amount a number varies from the average number in a series of numbers. (statistics) standard deviation - (SD) A measure of the range of values in a set of numbers. from the mean (equivalent to a 99% confidence interval confidence interval, n a statistical device used to determine the range within which an acceptable datum would fall. Confidence intervals are usually expressed in percentages, typically 95% or 99%. ). A 7-day window advances day-by-day as new data enter the system and a new 7-day observed total is calculated daily and compared with the expected value for that epidemiologic week (Monday to Sunday). If the observed total is over the threshold, a signal is generated. The second algorithm variation is a 4-week total calculated daily. Each week, this algorithm calculates an expected total for the previous 4 weeks and a 99% threshold value. A 4-week window advances day-by-day and a new 4-week observed total is compared with the expected total for the four epidemiologic weeks ending with the current week. Most outbreaks would be detected in a timely manner by the 7-day total system. However, comparison of the two algorithms using Salmonella data has shown that small sustained increases [greater than or equal to] 1 month would be missed by a 7-day total system, since the threshold value would not be exceeded in any one 7-day period. Including a 4-week total algorithm in the system produces 10% extra signals of outbreaks with slowly increasing numbers of cases, which otherwise would not be detected. If the 4-week total is <5, or the 7-day total is <3, no signals are generated, even if above threshold. Though reducing sensitivity, this cutoff greatly reduces the number of signals of sporadic cases oh infrequent infections that are of little public health significance. The system uses the date the sample was taken for calculation of observed and expected totals since for any one pathogen a variable delay between date of disease onset and date of reporting of result to ISIS is likely. In the case of an outbreak, the use of date of reporting for surveillance would result in a lower peak number of cases spread over a longer period (a "smeared" epidemiologic curve), reducing the sensitivity of the system. Using date of sampling entails retrospective examination of data to ensure that data reported in 1 week and plotted by date of sampling do not produce a signal in weeks previous to reporting. The "look-back" period (i.e., the period of retrospective examination) has been set at 10 epidemiologic weeks. This window allows enough time for most pathogens to be sampled, tested, and reported. New signals of an excess of cases at time of sampling >10 weeks previous to reporting are unlikely to signify unrecognised outbreaks that can still be investigated and controlled. User-Defined or Fixed Threshold Algorithms depending on automated evaluation of historical data are often unreliable in detecting seasonal increases in pathogens whose seasonality shifts. A flexible, user-defined, fixed threshold was chosen to detect such increases in selected pathogens. For instance, with present historical data on respiratory syncytial virus respiratory syncytial virus (sĭnsĭsh`əl): see cold, common. , 10 positive laboratory results in any epidemiologic week have always indicated the beginning of the epidemic season. Thus, the threshold for that virus is set at 10 positives in a 7-day period. Some pathogens (e.g., hantavirus) have been defined as zero-tolerance, where one positive result is considered worth a signal. Although such cases are often communicated faster by other means, in some of these situations the system can be considered as a backup. Data Used At present, signals are generated from both the Salmonella database (data from the national reference laboratory stored in ISIS but not processed into surveillance diagnoses and presented only internally) and the database of 38 surveillance diagnoses (data on pathogens stored in ISIS and processed into surveillance diagnoses for Internet feedback). Signals are generated from the Salmonella database with algorithms that use historical data and from the surveillance diagnoses database with both user-defined and algorithm-defined thresholds (Figure 1). [FIGURE 1 OMITTED] Internet Feedback of Signals Currently, signals from the Salmonella database are presented only on an internal RIVM site. Signals are listed and incidence by municipality MUNICIPALITY. The body of officers, taken collectively, belonging to a city, who are appointed to manage its affairs and defend its interests. mapped. The signals generated from surveillance diagnoses, however, are available on the Internet for all local health authorities, Ministry of Public Health staff, and all registered microbiologists to access. The signals are presented first in a table (Figure 2) that displays, for each signaled pathogen, the week in which the increase occurred (by week of sampling), the type of algorithm used, and the epidemiologic week in which the signal was generated. Signals remain in this table for one epidemiologic week after they are signaled. For each signaled pathogen, a link can be made to a graph showing the observed and threshold for the previous 2 years. Historical signals by week of signaling are also listed on the site. Age and sex breakdown of all cases of a pathogen in the previous 4 weeks can he compared with that of all data, allowing an idea of which age or sex may be affected in an outbreak. Those with access to the site can also subscribe to Verb 1. subscribe to - receive or obtain regularly; "We take the Times every day" subscribe, take buy, purchase - obtain by purchase; acquire by means of a financial transaction; "The family purchased a new car"; "The conglomerate acquired a new company"; automatically receive an email of a new signal. Signal Interpretation and Action Signals that were produced during the previous 7 days are interpreted formally on a weekly basis in a meeting of members of RIVM and the National Co-ordination Centre far Communicable Disease communicable disease n. A disease that is transmitted through direct contact with an infected individual or indirectly through a vector. Also called contagious disease. Outbreak Management. Since 1999, this group has interpreted all signals of potential national importance, from informal and formal sources. In addition, the algorithm-generated signals are monitored on a daily basis. The accessibility of the site allows input from many other health professionals who can contact ISIS should they have some information to help interpret any signal. Every week a meeting report is written and disseminated to all 46 regional health authorities as well as to the Ministry of Health and other interested parties. The investigation and control of outbreaks within one area is the legal responsibility of that area's health authority. For outbreaks that span one or more health authorities, the RIVM coordinates and supports investigation, while RIVM and the National Co-ordination Centre for Communicable Disease Outbreak Management coordinate implementation of control measures. The early-warning system was implemented in January 2002. In early March 2002, the system signaled an increase in diagnoses of syphilis syphilis (sĭf`əlĭs), contagious sexually transmitted disease caused by the spirochete Treponema pallidum (described by Fritz Schaudinn and Erich Hoffmann in 1905). . This increase was subsequently found to represent a sustained outbreak of syphilis that had begun the previous year in a large Dutch city. The outbreak was subsequently investigated, and prevention strategies were implemented (21) (Figures 2 and 3). [FIGURE 3 OMITTED] Limitations This system is designed to complement, not replace, any conventional methods of outbreak detection (e.g., clinician-based surveillance of notifiable diseases The following is a list of notifiable diseases arranged by country. Australia Source:[1]
Paralysis characterized by limp, unresponsive muscles. Mentioned in: Botulism flaccid paralysis Neurology Paralysis characterized by complete loss of muscle tone and tendon reflexes. Cf Spastic paralysis. in a polio polio: see poliomyelitis. outbreak). Local outbreaks may also be more rapidly detected from local, not national, laboratory data. In addition, though expansion is planned, many laboratories are likely never to participate in ISIS, limiting the coverage of the electronic system. Analysis of large amounts of laboratory data will likely signal many clusters of no significance, and the work generated in interpreting signals meaningfully may be overwhelming and so mask true signals. Thoroughly evaluating and adjusting parameters Such as the minimum number required to trigger a signal may be required to prevent this but at a cost of losing sensitivity. Conversely, the ability to detect clusters of commonly reported pathogens that are not routinely subtyped (e.g., Compylobacter) will always be limited because the signal will be likely smaller than the variability of the large amount of data routinely submitted. One solution to this problem is to apply the algorithm to subsets of reduced amounts of data on common pathogens such as data collected by a group of regional laboratories. Future Work Evaluation of the System The ISIS outbreak detection system needs to be evaluated to demonstrate a clear advantage over conventional means for detecting outbreaks of infection of all types of pathogens, not just salmonellae (for which the algorithm has already proved its usefulness). The sensitivity and timeliness of algorithms in other outbreak detection systems relative to a variety of standards such as formal records of investigated outbreaks or informal epidemiologic judgment, have been assessed retrospectively (11, 12). However, no records of investigated outbreaks in the Netherlands exist, and the minutes from the signals meeting have only recently been put in a format that allows easy interpretation of signal outcome. In addition, retrospective analysis does not allow evaluation of the extra sensitivity nor of the specificity of an algorithm. This limitation exists because any signals from historical data produced by the algorithm, and not detected by other means, are classified as false positives, when many may have been genuine. Nonetheless, some idea of the value of the algorithm is given by the fact that since 1998, no national outbreak of Salmonella has been detected by means other than by the Salmonella outbreak detection system. Additionally, the feedback on the Internet and comments from the public health community are important factors that affect the sensitivity, specificity, and timeliness of the whole system since they will impact the eventual interpretation of a signal. ISIS will, therefore, be evaluated prospectively at the weekly signal meeting, comparing signals detected by the algorithm to signals detected by other means. This comparison will allow assessment of the following: 1) how many signals detected by the algorithm are not of public health interest, as decided in the weekly meeting (a measure of specificity), and 2) the number of relevant signals detected by other means that should have been detected by the algorithm (a measure of relative sensitivity and timeliness). Assessing the number of outbreaks that the algorithm detects that would not have been detected otherwise will not be possible, since once a signal is detected by algorithm it can never be known with certainty that it would not have been detected later by other means. However, if the first detection of a signal is by algorithm, this will give some measure of timeliness of the system. Expansion At present, 40 surveillance diagnoses in ISIS are available for use in the automated outbreak detection system. Much incoming data are as yet not formatted for daily signal generation and feedback as described. A priority, therefore, is to adapt the system to directly analyze raw data (those not processed as surveillance diagnoses) on the other 300 pathogens currently collected, and, in particular, to make the current Salmonella outbreak detection system part of the automated ISIS. By 2004, a total of 25 laboratories are scheduled to be connected, increasing the coverage of the system for all pathogens to at least 35% of the Dutch population. We also hope that regional health authorities will eventually have access to their own Web page, presenting the results of applying the algorithms to their data. This improvement would allow smaller regional outbreaks of common pathogens to be detected. Conclusion We describe an automated outbreak detection system that uses laboratory data electronically collected in the Netherlands by ISIS. The system assesses data as soon as they are made available and disseminates the information by means of the Internet to all involved health professionals to help in the rapid interpretation and subsequent action to control any suspected outbreak. Much still needs to be done, and efforts are now concentrated on increasing the data available to ISIS, system evaluation, and subsequent modifications, with the aim of having a flexible, automated outbreak detection system for all laboratory-reported pathogens in the Netherlands by 2006.
Table. List of 40 current surveillance diagnoses
generated on ISIS with type of threshold (a)
Surveillance diagnosis Threshold
type
Adenovirus infection H
Entamoeba histolytica, intestinal infection H
E. histolytica, extraintestinal infection H
Campylobacter spp. Infection H
Campylobacter jejuni infection H
Chlamydia trachomatis infection H
Enterovirus infection H
Escherichia coli O157 infection F (4)
Giardia lamblia infection H
Neisseria gonorroeae infection H
Haemophilus influenzae, invasive infection H
Hepatitis A virus infection H
Hepatitis B virus infection H
Hepatitis C virus infection H
Bordetella parapertussis infection H
B. pertussis infection H
Hantavirus infection F (0)
Listeria monocytogenes infection H
Malaria, Plasmodium spp. Infection H
Malaria, P. ovale infection H
Malaria, P. malaria infection H
Malaria, P. falciparum infection H
Malaria, P. vivax infection H
N. meningitis, invasive infection H
Parainfluenza virus infection H
Salmonella enterica Paratyphii group A infection H
S. Paratyphii group B infection H
S. Paratyphii group C infection H
S. Typhi infection F (3)
Respiratory syncytial virus infection F (10)
Rhinovirus infection F (10)
Salmonella spp. (nontyphoid) infection H
S. Typhi infection H
Shigella spp. Infection F
Staphylococcus aureus, invasive infection H
Streptococcus group A, invasive infection H
Streptococcus group B, invasive infection H
Streptococcus pneumoniae infection H
Yersinia spp., non-pestis H
Yersinia enterocolitica H
(a) ISIS, Infectious Disease Surveillance Information
System; H, historical algorithm-defined threshold; F,
fixed user-defined threshold (cases/week); F(0),
zero threshold where one case is signaled.
Figure 2. View of Web page listing
surveillance diagnoses ("onderwerp")
flagged on week 9 of 2002.
The asterisks in the columns
labeled "verheffingsweek" indicate
the week of sampling when the
number of a particular surveillance
diagnosis exceeded the
threshold defined by a historical
algorithm ("historische drempel").
The surveillance diagnosis for
syphilis ("syphilis, vroege") is
flagged at the end of 2001 (weeks
51 and 52) and 2002 (weeks 4-9).
Actuele signalen
Overzicht van actuele signalen naar verheffingsweek
Signaal Onderwerp Database Soort
generatie drempel
week
09 Yersiniose - infectie SD historische
met Y. enterocolitica drempel
09 Yersiniose non-pestis SD historische
drempel
09 Chlamydia trachomatis SD historische
infecties drempel
09 Syfilis, vroege SD historische
drempel
08 Kinkhoest - pertussis SD historische
drempel
08 Gonorroe SD historische
drempel
Onderwerp 50 51 52 01 02 03 04
Yersiniose - infectie * *
met Y. enterocolitica
Yersiniose non-pestis * *
Chlamydia trachomatis * * *
infecties
Syfilis, vroege * * *
Kinkhoest - pertussis * * *
Gonorroe * * *
Onderwerp 05 06 07 08 09
Yersiniose - infectie * * * *
met Y. enterocolitica
Yersiniose non-pestis * * * *
Chlamydia trachomatis * * * *
infecties
Syfilis, vroege * * * * *
Kinkhoest - pertussis * * * *
Gonorroe * * * * *
Databse:
Surveillance Diagnoses (SD)
(1) Example 1: A surveillance diagnosis for a case of respiratory syncytial virus infection Respiratory Syncytial Virus Infection Definition Respiratory syncytial virus (RSV) is a virus that can cause severe lower respiratory infections in children under the age of two, and milder upper respiratory infections in older children and adults. is a positive culture or positive polymerase chain reaction polymerase chain reaction (pŏl`ĭmərās') (PCR), laboratory process in which a particular DNA segment from a mixture of DNA chains is rapidly replicated, producing a large, readily analyzed sample of a piece of DNA; the process is (PCR PCR polymerase chain reaction. PCR abbr. polymerase chain reaction Polymerase chain reaction (PCR) ) or positive direct immunofluorescence Immunofluorescence A technique that uses a fluorochrome to indicate the occurrence of a specific antigen-antibody reaction. The fluorochrome labels either an antigen or an antibody. or positive enzyme immunoassay Immunoassay An assay that quantifies antigen or antibody by immunochemical means. The antigen can be a relatively simple substance such as a drug, or a complex one such as a protein or a virus. , with all positive tests on the same case-patient within a 6-week period reported as one surveillance diagnosis. Example 2: A surveillance diagnosis for a case of invasive Haemophilus influenza infection is a positive culture from a normally sterile site, with all positive results from the same case in 3 months considered one surveillance diagnosis. Acknowledgments We thank the laboratories participating in the Infectious Disease Surveillance Information System and the Ministry of Health for their support of this project and T. Grein for critical review of the manuscript. Marc-Alain Widdowson was funded by European Programme for Intervention Epidemiology and Directorate-General V of the European Commission European Commission, branch of the governing body of the European Union (EU) invested with executive and some legislative powers. Located in Brussels, Belgium, it was founded in 1967 when the three treaty organizations comprising what was then the European Community . References (1.) Taha MK, Achtman M, Alonso JM, Greenwood B, Ramsay M, Fox A, et al. Serogroup W135 meningococcal disease in Hajj hajj (häj), the pilgrimage to Mecca, Saudi Arabia, one of the five basic requirements (arkan or "pillars") of Islam. Its annual observance corresponds to the major holy day id al-adha, pilgrims. Lancer 2000;356:2159. (2.) Threlfall EJ, Ward LR, Hampton MD, Ridley AM, Rowe B, Roberts D, et al. Molecular fingerprinting defines a strain of Salmonella enterica Salmonella enterica is a rod shaped, flagellated, Gram-negative bacterium, and a member of the genus Salmonella.[1] Serovars S. enterica has an extraordinarily large number of serovars serotype serotype /se·ro·type/ (ser´o-tip) the type of a microorganism determined by its constituent antigens; a taxonomic subdivision based thereon. se·ro·type n. See serovar. v. Anatum responsible for an international outbreak associated with formula-dried milk. Epidemiol Infect infect /in·fect/ (in-fekt´) 1. to invade and produce infection in. 2. to transmit a pathogen or disease to. in·fect v. 1. 1998;121:289-93. (3.) Dentinger CM, Bower AB, Nainan OM, Cotter cot·ter n. 1. A bolt, wedge, key, or pin inserted through a slot in order to hold parts together. 2. A cotter pin. [Origin unknown. SM, Myers G, Dubusky LM, et al. An outbreak of hepatitis A Hepatitis A Definition Hepatitis A is an inflammation of the liver caused by a virus, the hepatitis A virus (HAV). It varies in severity, running an acute course, generally starting within two to six weeks after contact with the virus, and lasting no associated with green onions. J Infect Dis 2001;183:1273-6. (4.) Barrett TJ, Lior H, Green JH, Wells JG, Bell BP, Greene KD, et al. Laboratory investigation of a multistate mul·ti·state adj. Of, relating to, or involving several states: a multistate environmental campaign. food-borne outbreak of Eschenchia coli O157:H7 by using pulsed-field gel electrophoresis gel electrophoresis n. Electrophoresis performed in a gel composed of agarose, polyacrylamide, or starch. and phage phage: see bacteriophage. phage - A program that modifies other programs or databases in unauthorised ways; especially one that propagates a virus or Trojan horse. See also worm, mockingbird. The analogy, of course, is with phage viruses in biology. typing. J Clin Microbiol 1994;32:3013-7. (5.) Berkelman RL, Bryan RT, Osterholm MT, LeDuc JW, Hughes JM. Infectious disease surveillance: a crumbling foundation. Science 1994;264:368-70. (6.) Gellert GA. Preparing for emerging infections. Nature 1994;370:409-10. (7.) Farrington CP, Andrews NJ, Beale AD, Catchpole CATCHPOLE, officer. A name formerly given to a sheriff's deputy, or to a constable, or other officer whose duty it is to arrest persons. He was a sort of serjeant. The word is not now in use as an official designation. Minshew ad verb. MA. A statistical algorithm for the early detection of outbreaks of infectious disease. Journal of the Royal Statistical Society The Journal of the Royal Statistical Society is a series of three peer-reviewed statistics journals published by Blackwell Publishing for the London-based Royal Statistical Society. Series A 1996;159:547-63. (8.) Allard R. Use of time-series analysis Time-series analysis Assessment of relationships between two or among more variables over periods of time. in infectious disease surveillance. Bull World Health Organ 1998;76:327-33. (9.) Watier L, Richardson S Richardson, city (1990 pop. 74,840), Dallas and Collins counties, N Tex., a suburb of Dallas; founded in the 1850s, inc. as a city 1956. Richardson manufactures telecommunications equipment, medical devices, supercomputers, computer chips, and fiber optics. , Hubert B. A time series construction of an alert threshold The introduction to this article provides insufficient context for those unfamiliar with the subject matter. Please help [ improve the introduction] to meet Wikipedia's layout standards. You can discuss the issue on the talk page. with application to S. bovismorbificans in France. Stat Med 1991;10:1493-509. (10.) Hashimoto S Hashimoto is a Japanese surname and place name. Places:
(11.) Stern L, Lightfoot D. Automated outbreak detection: a quantitative retrospective analysis. Epidemiol Infect 1999;122:103-10. (12.) Hutwagner LC, Maloney EK, Bean NH, Slutsker L, Martin SM. Using laboratory-based surveillance data for prevention: an algorithm for detecting Salmonella outbreaks. Emerg Infect Dis 1997;3:395-400. (13.) Centers for Disease Control and Prevention Centers for Disease Control and Prevention (CDC), agency of the U.S. Public Health Service since 1973, with headquarters in Atlanta; it was established in 1946 as the Communicable Disease Center. . Electronic reporting of laboratory data for public health: meeting report and recommendations; 1997. Available from: URL: http://www.phppo.cdc.gov (14.) van Pelt van Pelt is the surname of several people: People
(15.) O'Brien SJ, Christie P. Do CuSums have a role in routine communicable disease surveillance? Public Health 1997;111:255-8. (16.) van Pelt W, Duynhoven YTHP, Leenwen WJ, Esveld MI. Explosie van Shigellose veroorzaakt door Shigella sonnei Shigella son·ne·i n. Sonne bacillus. Shigella sonnei Shigella group D Microbiology The most commonly isolated, least virulent Shigella serotype . Infectieziekten Bulletin 1998;9:23-8. (17.) van Pelt W, van Leeuwen WJ, van Duynhoven YTHP. Explosie van Salmonella Typhimurium Salmonella ty·phi·mu·ri·um n. A bacterium that causes food poisoning. 20 infecties [In Dutch]. Infectieziekten Bulletin 1998;9:7-10. (18.) van Pelt W, Widdowson M-A. Outbreak of Salmonella Typhimurium PT 204 (Dutch phage type) infection: the Netherlands. Eurosurveillance Weekly 2000;4. Available from: URL: http://www.eurosurv.org/update/ (19.) Wannet WJB WJB William Jennings Bryan (US lawyer, statesman, and politician, 1860-1925) WJB Wem Jubilee Band , van Pelt W, van Leeuwen WJ, Verbruggen AJ, Maas HME HME Home Medical Equipment HME Home Media Engine (TiVo) HME Heat and Moisture Exchange HME Hierarchical Mixtures-of-Experts HME Happy Meal Ethernet (UNIX driver) HME Honeymoon Experience , Duynhoven YTHP. Explosie van Salmonella Brandenburg infectie. Infectieziekten Bulletin 2000;11:32-3. (20.) van Duynhoven YTPH, Widdowson M-A, de Jager CM, Fernandes T, Neppelenbroek S, van den Brandhof W, et al. Salmonella Enteritidis Salmonella en·ter·it·i·dis n. Gärtner's bacillus. phage type 4b outbreak associated with bean sprouts bean sprouts pl.n. The tender, edible seedlings of certain bean plants, especially those of the mung bean. . Emerg Infect Dis 2002:8:440-3. (21.) van der Meijden W, van der Snoek snoek n. pl. snoek or snoeks A large, small-scaled marine food fish (Thyristes atun) of the family Gempylidae, widely distributed in the Southern Hemisphere. , E, Haks K, van der Larr M. Outbreak of syphilis in Rotterdam, the Netherlands. Eurosurveillance Weekly 2002;6. Available from: URL: http;//www.eurosurv.org/ update/ Dr. Widdowson is a veterinary public health epidemiologist now based at the Centers for Disease Control and Prevention. He is responsible for the foodborne virus epidemiology program, with a particular focus on Norwalk-like viruses Norwalk-like virus Virology Any of a group of viruses with biologic, clinical, and immunologic findings similar to those of the Norwalk agent(s). see Gastroenteritis, Hawaii agent, Norwalk agent(s), Otofuke virus, Snow Mountain virus . His other research interests include all aspects of zoonotic Zoonotic A disease which can be spread from animals to humans. Mentioned in: Zoonosis infections. Address for correspondence: Marc-Alain Widdowson, Viral Gastroenteritis viral gastroenteritis Intestinal flu Infectious disease A generic term for GE induced by viruses Clinical presentations 1. Epidemic VGE, most often caused by the Norwalk agent or Norwalk-like viruses Clinical N&V, diarrhea, abdominal pain, anorexia, Section, Centers for Disease Control and Prevention, Mailstop G04, 1600 Clifton Road Clifton Road is main street in Clifton neighborhood of Saddar Town in Karachi, Sindh, Pakistan. Its name dates from the British Colonial rule, and its market is posh areas of Karachi. N.E., Atlanta, GA 30333, USA; fax: 404 639 3645; email:zux5@cdc.gov Mare-Alain Widdowson, * ([dagger]) Arnold Bosman, ([dagger]) Edward van Straten, ([dagger]) Mark Tinga, ([dagger]) Sandra Chaves, ([dagger]) Liesbeth van Eerden, ([dagger]) Wilfred van Pelt ([dagger]) * European Programme for Intervention Epidemiology and Training, Bilthoven, the Netherlands, and ([dagger]) National Institute for Public Health and the Environment (RIVM), Bilthoven, the Netherlands |
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