Evaluating tools to define influenza baseline and threshold values using surveillance data, Egypt, season 2016/17
Establishing influenza thresholds and transmission intensity can help evaluate seasonal changes in influenza severity and potential pandemics. We aimed to evaluate the moving epidemic method (MEM) for calculating influenza thresholds for season 2016/17 in Egypt using four parameters, to identify the...
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| Published in | Journal of infection and public health Vol. 13; no. 3; pp. 430 - 437 |
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| Main Authors | , , , , , , , , |
| Format | Journal Article |
| Language | English |
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England
Elsevier Ltd
01.03.2020
Elsevier |
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| Abstract | Establishing influenza thresholds and transmission intensity can help evaluate seasonal changes in influenza severity and potential pandemics. We aimed to evaluate the moving epidemic method (MEM) for calculating influenza thresholds for season 2016/17 in Egypt using four parameters, to identify the most useful parameter. Also to measure the agreement between both the country-specific statistical empirical method and World Health Organization method to MEM for determining the length and intensity level of activity of the influenza season.
Routinely epidemiological and laboratory data from sentinel surveillance sites for Severe Acute Respiratory Infection (SARI) and influenza-like illness (ILI) were used for calculating thresholds for seasons between 2010/11 and 2015/16 to test 2016/17 season. The parameters calculated were: screened ILI consultation rate × 1000, screened ILI composite parameter, influenza positivity percentage among sampled SARI cases, and influenza positivity percentage among sampled ILI and SARI cases. These parameters assess seasonality and intensity of influenza activity using the three proposed methods (mentioned above). Agreement between the three methods was done using several approaches.
The intensity of influenza activity by MEM was lower than the other two methods. Agreement between MEM and each of the other two techniques varied appreciably from good to very good for seasonal duration, and poor to fair for intensity level. In addition, parameters including laboratory data showed a pattern of bi-wave activity; the first wave occurred in winter mostly between epidemiological weeks 39 and 52 and the second occurred in spring mostly between weeks 12 and 17.
Parameters including laboratory data were more useful in defining seasonality of influenza. Further exploration of the MEM model in future seasons may help to provide a more comprehensive understanding of its use and application. |
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| AbstractList | Background: Establishing influenza thresholds and transmission intensity can help evaluate seasonal changes in influenza severity and potential pandemics. We aimed to evaluate the moving epidemic method (MEM) for calculating influenza thresholds for season 2016/17 in Egypt using four parameters, to identify the most useful parameter. Also to measure the agreement between both the country-specific statistical empirical method and World Health Organization method to MEM for determining the length and intensity level of activity of the influenza season. Methods: Routinely epidemiological and laboratory data from sentinel surveillance sites for Severe Acute Respiratory Infection (SARI) and influenza-like illness (ILI) were used for calculating thresholds for seasons between 2010/11 and 2015/16 to test 2016/17 season. The parameters calculated were: screened ILI consultation rate × 1000, screened ILI composite parameter, influenza positivity percentage among sampled SARI cases, and influenza positivity percentage among sampled ILI and SARI cases. These parameters assess seasonality and intensity of influenza activity using the three proposed methods (mentioned above). Agreement between the three methods was done using several approaches. Results: The intensity of influenza activity by MEM was lower than the other two methods. Agreement between MEM and each of the other two techniques varied appreciably from good to very good for seasonal duration, and poor to fair for intensity level. In addition, parameters including laboratory data showed a pattern of bi-wave activity; the first wave occurred in winter mostly between epidemiological weeks 39 and 52 and the second occurred in spring mostly between weeks 12 and 17. Conclusion: Parameters including laboratory data were more useful in defining seasonality of influenza. Further exploration of the MEM model in future seasons may help to provide a more comprehensive understanding of its use and application. Keywords: Epidemiology, Influenza, Human, Surveillance, Egypt Establishing influenza thresholds and transmission intensity can help evaluate seasonal changes in influenza severity and potential pandemics. We aimed to evaluate the moving epidemic method (MEM) for calculating influenza thresholds for season 2016/17 in Egypt using four parameters, to identify the most useful parameter. Also to measure the agreement between both the country-specific statistical empirical method and World Health Organization method to MEM for determining the length and intensity level of activity of the influenza season. Routinely epidemiological and laboratory data from sentinel surveillance sites for Severe Acute Respiratory Infection (SARI) and influenza-like illness (ILI) were used for calculating thresholds for seasons between 2010/11 and 2015/16 to test 2016/17 season. The parameters calculated were: screened ILI consultation rate × 1000, screened ILI composite parameter, influenza positivity percentage among sampled SARI cases, and influenza positivity percentage among sampled ILI and SARI cases. These parameters assess seasonality and intensity of influenza activity using the three proposed methods (mentioned above). Agreement between the three methods was done using several approaches. The intensity of influenza activity by MEM was lower than the other two methods. Agreement between MEM and each of the other two techniques varied appreciably from good to very good for seasonal duration, and poor to fair for intensity level. In addition, parameters including laboratory data showed a pattern of bi-wave activity; the first wave occurred in winter mostly between epidemiological weeks 39 and 52 and the second occurred in spring mostly between weeks 12 and 17. Parameters including laboratory data were more useful in defining seasonality of influenza. Further exploration of the MEM model in future seasons may help to provide a more comprehensive understanding of its use and application. Establishing influenza thresholds and transmission intensity can help evaluate seasonal changes in influenza severity and potential pandemics. We aimed to evaluate the moving epidemic method (MEM) for calculating influenza thresholds for season 2016/17 in Egypt using four parameters, to identify the most useful parameter. Also to measure the agreement between both the country-specific statistical empirical method and World Health Organization method to MEM for determining the length and intensity level of activity of the influenza season.BACKGROUNDEstablishing influenza thresholds and transmission intensity can help evaluate seasonal changes in influenza severity and potential pandemics. We aimed to evaluate the moving epidemic method (MEM) for calculating influenza thresholds for season 2016/17 in Egypt using four parameters, to identify the most useful parameter. Also to measure the agreement between both the country-specific statistical empirical method and World Health Organization method to MEM for determining the length and intensity level of activity of the influenza season.Routinely epidemiological and laboratory data from sentinel surveillance sites for Severe Acute Respiratory Infection (SARI) and influenza-like illness (ILI) were used for calculating thresholds for seasons between 2010/11 and 2015/16 to test 2016/17 season. The parameters calculated were: screened ILI consultation rate × 1000, screened ILI composite parameter, influenza positivity percentage among sampled SARI cases, and influenza positivity percentage among sampled ILI and SARI cases. These parameters assess seasonality and intensity of influenza activity using the three proposed methods (mentioned above). Agreement between the three methods was done using several approaches.METHODSRoutinely epidemiological and laboratory data from sentinel surveillance sites for Severe Acute Respiratory Infection (SARI) and influenza-like illness (ILI) were used for calculating thresholds for seasons between 2010/11 and 2015/16 to test 2016/17 season. The parameters calculated were: screened ILI consultation rate × 1000, screened ILI composite parameter, influenza positivity percentage among sampled SARI cases, and influenza positivity percentage among sampled ILI and SARI cases. These parameters assess seasonality and intensity of influenza activity using the three proposed methods (mentioned above). Agreement between the three methods was done using several approaches.The intensity of influenza activity by MEM was lower than the other two methods. Agreement between MEM and each of the other two techniques varied appreciably from good to very good for seasonal duration, and poor to fair for intensity level. In addition, parameters including laboratory data showed a pattern of bi-wave activity; the first wave occurred in winter mostly between epidemiological weeks 39 and 52 and the second occurred in spring mostly between weeks 12 and 17.RESULTSThe intensity of influenza activity by MEM was lower than the other two methods. Agreement between MEM and each of the other two techniques varied appreciably from good to very good for seasonal duration, and poor to fair for intensity level. In addition, parameters including laboratory data showed a pattern of bi-wave activity; the first wave occurred in winter mostly between epidemiological weeks 39 and 52 and the second occurred in spring mostly between weeks 12 and 17.Parameters including laboratory data were more useful in defining seasonality of influenza. Further exploration of the MEM model in future seasons may help to provide a more comprehensive understanding of its use and application.CONCLUSIONParameters including laboratory data were more useful in defining seasonality of influenza. Further exploration of the MEM model in future seasons may help to provide a more comprehensive understanding of its use and application. |
| Author | Abu ElSood, Hanaa Jabbour, Jean AbdElGawad, Basma Mohsen, Amira Fahim, Manal Eid, Alaa Vega, Tomás Refaey, Samir El Houssinie, Moustafa |
| Author_xml | – sequence: 1 givenname: Basma surname: AbdElGawad fullname: AbdElGawad, Basma email: basma.mostafa10@yahoo.com organization: Department of Epidemiology and Surveillance, Preventive Sector, Ministry of Health and Population, Cairo, Egypt – sequence: 2 givenname: Tomás surname: Vega fullname: Vega, Tomás organization: Dirección General de Salud Pública, Consejería de Sanidad, Valladolid, Spain – sequence: 3 givenname: Moustafa surname: El Houssinie fullname: El Houssinie, Moustafa organization: Community Medicine Department, Faculty of Medicine, Ain Shams University, Cairo, Egypt – sequence: 4 givenname: Amira surname: Mohsen fullname: Mohsen, Amira organization: World Health Organization, Egypt Country Office, Cairo, Egypt – sequence: 5 givenname: Manal surname: Fahim fullname: Fahim, Manal organization: Department of Epidemiology and Surveillance, Preventive Sector, Ministry of Health and Population, Cairo, Egypt – sequence: 6 givenname: Hanaa surname: Abu ElSood fullname: Abu ElSood, Hanaa organization: Department of Epidemiology and Surveillance, Preventive Sector, Ministry of Health and Population, Cairo, Egypt – sequence: 7 givenname: Jean surname: Jabbour fullname: Jabbour, Jean organization: World Health Organization, Egypt Country Office, Cairo, Egypt – sequence: 8 givenname: Alaa surname: Eid fullname: Eid, Alaa organization: Department of Epidemiology and Surveillance, Preventive Sector, Ministry of Health and Population, Cairo, Egypt – sequence: 9 givenname: Samir surname: Refaey fullname: Refaey, Samir organization: Department of Epidemiology and Surveillance, Preventive Sector, Ministry of Health and Population, Cairo, Egypt |
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| Cites_doi | 10.1371/journal.pone.0054445 10.1111/irv.12371 10.5365/wpsar.2017.8.1.002 10.1371/journal.pone.0077244 10.1016/j.vaccine.2007.03.046 10.1016/j.vaccine.2006.06.072 10.1111/j.1750-2659.2012.00422.x 10.1056/NEJMra052211 10.26719/2016.22.7.523 10.1093/infdis/jis467 10.1111/irv.12330 10.1017/S0950268814001757 |
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| SubjectTerms | Egypt Egypt - epidemiology Epidemiological Monitoring Epidemiology Human Humans Influenza Influenza, Human - epidemiology Respiratory Tract Infections - epidemiology Seasons Sentinel Surveillance Surveillance World Health Organization |
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| Title | Evaluating tools to define influenza baseline and threshold values using surveillance data, Egypt, season 2016/17 |
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