Aedes aegypti larval indices and risk for dengue epidemics.We assessed in a case-control study case-control study, n an investigation employing an epidemiologic approach in which previously existing incidents of a medical condition are used in lieu of gathering new information from a randomized population. the test-validity of Aedes larval larval 1. pertaining to larvae. 2. larvate. larval migrans see cutaneous and visceral larva migrans. indices for the 2000 Havana outbreak. "Cases" were blocks where a dengue fever dengue fever (dĕng`gē, –gā), acute infectious disease caused by four closely related viruses and transmitted by the bite of the Aedes mosquito; it is also known as breakbone fever and bone-crusher disease. patient lived during the outbreak. "Controls" were randomly sampled blocks. Before, during, and after the epidemic, we calculated Breteau index (BI) and house index at the area, neighborhood, and block level. We constructed receiver operating characteristic (ROC) curves to determine their performance as predictors of dengue dengue or breakbone fever or dandy fever Infectious, disabling mosquito-borne fever. Other symptoms include extreme joint pain and stiffness, intense pain behind the eyes, a return of fever after brief pause, and a characteristic rash. transmission. We observed a pronounced effect of the level of measurement. The [BI.sub.max] (maximum block BI in a radius of 100 m) at 2-month intervals had an area under the ROC curve ROC curve acronym for receiver operating characteristic curve. A graphical method of assessing the characteristic of a diagnostic test. of 71%. At a cutoff of 4.0, it significantly (odds ratio 6.00, p<0.05) predicted transmission with 78% sensitivity and 63% specificity. Analysis of BI at the local level, with human-defined boundaries, could be introduced in control programs to identify neighborhoods at high risk for dengue transmission. ********** While a vaccine is under research, without immediate prospect for success, vector control Vector control is any method to limit or eradicate the vectors of vector born diseases, for which the pathogen (e.g. virusor parasite) is transmitted by a vector which can be mammals, birds or arthropods, especially insects, and more specifically mosquitoes. remains the only way to prevent dengue transmission (1-3). Vector control programs are essentially based on source reduction, eliminating Aedes aegypti larval habitats from the domestic environment, with increasing community involvement and intersectoral action in recent decades (4,5). However, current entomologic en·to·mol·o·gy n. The scientific study of insects. en  to·mo·log indicators do not seem to reliably assess transmission
risks, define thresholds for dengue epidemic alerts, or set targets for
vector control programs (6,7). Therefore, defining new indicators for
entomologic surveillance, monitoring, and evaluation are among the
research priorities of the World Health Organization Special Programme
for Research and Training in Tropical Diseases Tropical diseases are infectious diseases that either occur uniquely in tropical and subtropical regions (which is rare) or, more commonly, are either more widespread in the tropics or more difficult to prevent or control. .Although only adult female Aedes mosquitos are directly involved in dengue transmission, entomologic surveillance has been based on different larval indices (8,9). The house index (HI, percentage of houses positive for larvae Larvae, in Roman religion Larvae: see lemures. ) and the Breteau index (BI, number of positive containers per 100 houses) have become the most widely used indices (6), but their critical threshold Critical threshold, a notion derived from the percolation theory, refers to a threshold, that summons up to a critical mass. Under the threshold the phenomenon tends to abort, above the threshold, it tends to grow exponentially. has never been determined for dengue fever transmission (9,10). Since HI [less than or equal to] l% or BI [less than or equal to] 5 was proposed to prevent yellow fever yellow fever, acute infectious disease endemic in tropical Africa and many areas of South America. Epidemics have extended into subtropical and temperate regions during warm seasons. transmission, these values have also been applied to dengue transmission but without much evidence (8,11). The Pan American Health Organization The Pan American Health Organization (PAHO) is an international public health agency with 100 years of experience in working to improve health and living standards of the countries of the Americas. It serves as the specialized organization for health of the Inter-American System. described 3 levels of risk for dengue transmission: low (HI<0.1%), medium (HI 0.1%-5%), and high (HI>5%) (12), but these values need to be verified (13). The vector density, below which dengue transmission does not occur, continues to be a topic of much debate and conflicting empiric evidence. For example, dengue outbreaks occurred in Singapore when the national overall HI was <1% (14). In contrast, researchers from Fortaleza, Brazil, found that dengue outbreaks never occurred when HI was <1% (15). However, different geographic levels are used to calculate the indices in the various studies, and the appropriated level for entomologic indices is in itself an issue of debate (16). Furthermore, the appropriateness of larval indices has been questioned; recently, as an alternative, pupal pu·pa n. pl. pu·pae or pu·pas The nonfeeding stage between the larva and adult in the metamorphosis of holometabolous insects, during which the larva typically undergoes complete transformation within a protective cocoon or indices were developed by Focks et al. (7) to better reflect the risk for transmission. Still, their utility for source reduction programs is controversial, and the feasibility of pupal collection in routine Aedes surveillance is untested (17). In this study, we assessed the usefulness of larval indices for identifying high-risk areas for dengue virus dengue virus n. A virus of the genus Flavivirus that is the cause of dengue. transmission. We examine the influence of measurements at different geographic levels, establish a threshold for epidemic outbreaks, and discuss their utility for community-based Aedes control programs. Methods Context The Cuban dengue prevention program has been hailed as among the few success stories in Aedes control (18,19). It was initiated in 1981, during the first dengue hemorrhagic fever hemorrhagic fever (hĕm'ərăj`ĭk), any of a group of viral diseases characterized by sudden onset, muscle and joint pain, fever, bleeding, and shock from loss of blood. epidemic in the Americas (20). As a result of this effort, Cuba was free of dengue from 1982 to 1996, although Aedes was reported again from 1992 (21). In 1997, dengue transmission occurred in Santiago de Cuba Santiago de Cuba (säntyä`gō thā k  `bä), city (1994 est. pop. 385,800), capital of Santiago de Cuba prov., SE Cuba. , a municipality MUNICIPALITY. The body of officers, taken collectively, belonging to a city, who are appointed to manage its affairs and defend its interests. located in the
eastern part of the country (22). The epidemic remained limited to this
city, but Aedes mosquitoes were observed in 29 other municipalities,
including Havana, the capital city, in the northwest of the country.
After intensification of vector control activities in the entire country
(22), His from 0.05% to 0.91% were observed in Havana between 1997 and
2001 (23). In spite of these low indices, an outbreak of 138 cases of
dengue fever occurred in September and October 2000; both dengue 3 and
dengue 4 viruses were isolated (1). Dengue serotypes 3 and 4 had never
circulated in Cuba, and we can assume low or nonexistent non·ex·is·tence n. 1. The condition of not existing. 2. Something that does not exist. non immunity in the population. From June 2001 to February 2002, a new outbreak occurred, and 12,889 new dengue cases were confirmed (23). Study Area The study was conducted in Playa playa or pan or flat or dry lake Flat-bottomed depression that is periodically covered by water. Playas occur in interior desert basins and adjacent to coasts in arid and semiarid regions. Municipality, in the northwest of Havana. The municipality has an area of 34.90 [km.sup.2] and a population of 182,485 inhabitants
The game is based loosely on the concepts from SameGame. . It has an average annual temperature of 25[degrees]C and precipitation of 132.9 mm in the rainy season (May-October). The population density is 5,228 habitants Habitants is the name used to refer to both the French settlers and the America-born inhabitants of French origin who farmed the land along the two shores of the St. Lawrence waterway in what is the present-day Province of Quebec in Canada. per square kilometer. The municipality has a noncontinuous water supply (every 2 days) and irregular garbage collection A software routine that searches memory for areas of inactive data and instructions in order to reclaim that space for the general memory pool (the heap). Operating systems may or may not provide this feature. . It is divided into 9 health areas, each providing primary care to [approximately equal to] 30,000 people. We performed an in-depth study in the 5 health areas where dengue transmission occurred in the September-October 2000 epidemic. Study Design We conducted a case-control study. Two units of analysis were used: blocks of houses (a block has on average 50 houses) and neighborhoods, which were defined as a block plus surrounding blocks (this definition generally results in clusters of 9 blocks with a radius of [approximately equal to] 100 m). These units are defined by manmade boundaries and not by ecologic determinants, per se, to usefully guide community-based control. We defined a "case" as a block (or neighborhood) of houses in the study area where [greater than or equal to] 1 inhabitant INHABITANT. One who has his domicil in a place is an inhabitant of that place; one who has an actual fixed residence in a place. 2. A mere intention to remove to a place will not make a man an inhabitant of such place, although as a sign of such intention he was detected with confirmed dengue fever during the September-October 2000 outbreak. "Control" blocks (or neighborhoods) were randomly sampled from those in the study area where no dengue case was reported. Data Collection Dengue Fever Dengue cases were defined as patients with fever and [greater than or equal to] 2 symptoms of dengue fever such as myalgia myalgia /my·al·gia/ (mi-al´jah) muscular pain.myal´gic epidemic myalgia see under pleurodynia. my·al·gia n. , arthralgia arthralgia /ar·thral·gia/ (ahr-thral´jah) pain in a joint. ar·thral·gia n. Severe pain in a joint. Also called arthrodynia. , headache, and rash, with serologic se·rol·o·gy n. pl. se·rol·o·gies 1. The science that deals with the properties and reactions of serums, especially blood serum. 2. confirmation by immunoglobulin immunoglobulin: see antibody; immunity; immunology. Immunoglobulin Any of the glycoproteins in the blood serum that are induced in response to invasion by foreign antigens and that protect the host by eradicating pathogens. M-capture enzyme-linked immunosorbent assay enzyme-linked immunosorbent assay n. ELISA. Enzyme-linked immunosorbent assay (ELISA) A diagnostic blood test used to screen patients for AIDS or other viruses. (1,12) at the national reference laboratory of viral diseases viral diseases Diseases caused by viruses. Long-term immunity usually follows viral childhood diseases (see chickenpox). The common cold recurs into adulthood because many different viruses cause its symptoms, and immunity against one does not protect against others. in the Institute of Tropical Medicine tropical medicine, study, diagnosis, treatment, and prevention of certain diseases prevalent in the tropics. The warmth and humidity of the tropics and the often unsanitary conditions under which so many people in those areas live contribute to the development and , Havana. During the epidemic, suspected cases were identified through the health services health services Managed care The benefits covered under a health contract . Additionally, a seroepidemiologic survey was conducted in the study area at the end of October 2000; all family physicians made home visits to families under their responsibility, searching for recent denguelike illnesses. Blood samples were collected from all persons with a history of fever. All confirmed dengue patients (passively and actively found) were interviewed by their family physician, supervised by an epidemiologist of the health area, to determine the exact date of symptom onset and places visited in the 10 preceding days. The completeness of the collected information was verified by epidemiologists of the Institute of Tropical Medicine, and if necessary, patients were revisited. Entomologic Information We used entomologic surveillance data that were independently recorded by the National Vector Control Program. At 2-month intervals, vector control technicians exhaustively inspected every house in the Playa Municipality for larval stages of Ae. aegypti. We used data collected in 3 cycles, July-August 2000 (before the epidemic), September-October 2000 (during the epidemic), and November-December 2000 (after the epidemic). We extracted information on the number of inspected houses, positive containers (with Ae. aegypti pupae or larvae), and houses with [greater than or equal to] 1 positive container. We eliminated 4.8% of the blocks from the study because they were not inspected in the 3 inspection cycles. Data Analysis We related all data collected to geographic coordinates The quantities of latitude and longitude which define the position of a point on the surface of the Earth with respect to the reference spheroid. See also coordinates. by a unique house block code and introduced it in MapInfo software (MapInfo Corporation, Troy, NY, USA). Case-patients were located by their address in the corresponding block. For the 3 entomologic inspection cycles, HI and BI were calculated at the block, neighborhood, and health area level. Additionally, we identified the [BI.sub.max], which is the highest or maximum BI at the block level for each neighborhood of the case and control blocks included in the study. This variable is derived with the following equation: [MATHEMATICAL EXPRESSION A group of characters or symbols representing a quantity or an operation. See arithmetic expression. NOT REPRODUCIBLE IN ASCII ASCII or American Standard Code for Information Interchange, a set of codes used to represent letters, numbers, a few symbols, and control characters. Originally designed for teletype operations, it has found wide application in computers. ], where [BI.sub.i] is the BI of the ith block belonging to the concerned neighborhood N, and [for all]i[subset]N indicates that all [BI.sub.i] of N are considered to identify the BI with the highest value as [BI.sub.max]. All data were exported to SPSS A statistical package from SPSS, Inc., Chicago (www.spss.com) that runs on PCs, most mainframes and minis and is used extensively in marketing research. It provides over 50 statistical processes, including regression analysis, correlation and analysis of variance. (SPSS Inc., Chicago, IL, USA) for analysis. We calculated the Spearman spear·man n. A man, especially a soldier, armed with a spear. rank correlation In statistics, rank correlation is the study of relationships between different rankings on the same set of items. It deals with measuring correspondence between two rankings, and assessing the significance of this correspondence. coefficient between the different indices in the 3 inspection cycles. The entomologic indices were transformed to approximately normal distributions (by using square root transformation) for calculating means, 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. , and 95% confidence intervals 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%. . Differences in the distribution of the indices were assessed with the Mann-Whitney test. We assessed the discriminative dis·crim·i·na·tive adj. 1. Drawing distinctions. 2. Marked by or showing prejudice: discriminative hiring practices. power of the indices by using receiver operating characteristic (ROC) curves. Their accuracy to discriminate between case and control blocks (and neighborhoods) was classified according to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. the value of the area under the ROC curve (AUC AUC area under curve ) (24) as noninformative (AUC [less than or equal to] 0.5), less accurate (0.5<AUC [less than or equal to] 0.7), moderately accurate (0.7<AUC [less than or equal to] 0.9), highly accurate (0.9<AUC<I) and perfect (AUC = 1). The value of the indices with the highest sensitivity, >50% specificity, for discriminating case and control geographic units was taken as the optimal cutoff point Cutoff point The lowest rate of return acceptable on investments. . The lower limit of 50% specificity was set to safeguard positive predictive value Positive predictive value (PPV) The probability that a person with a positive test result has, or will get, the disease. Mentioned in: Genetic Testing positive predictive value and decrease the number of units falsely classified at high risk for dengue transmission, which triggers unnecessary action and generates unproductive costs. The association between the entomologic indices and dengue transmission was further explored by logistic regression In statistics, logistic regression is a regression model for binomially distributed response/dependent variables. It is useful for modeling the probability of an event occurring as a function of other factors. models. Results During the epidemic, health services assisted 4,679 febrile febrile /feb·rile/ (feb´ril) pertaining to or characterized by fever. feb·rile adj. Of, relating to, or characterized by fever; feverish. patients in the 5 health areas included in the study. All patients were serologically tested 5 days after onset of fever, and dengue infection was confirmed in 47. In the seroepidemiologic survey, 82.5% of the families were effectively visited by their family physician. The survey found 7,008 persons with symptoms of fever between September and October 2000 who had not previously attended the health services. Serum specimens were collected from all of them, and dengue infection was confirmed in 22. As a result, 69 (47 passively identified plus 22 actively identified) dengue cases were confirmed, all patients were interviewed, and 4 cases epidemiologically related to outbreaks in other municipalities were excluded from the study. The final sample consisted of 65 confirmed dengue fever patients who lived in 38 different blocks in the 5 health areas included in the study. In the July to August inspection cycle, before the outbreak, the overall municipal BI and HI were 0.92 and 0.87%, respectively (Table 1). The mean values of the indices calculated at the health area level were also [approximately equal to] 1 for areas with or without dengue cases during the subsequent epidemic. However, the mean BI and HI were >1 for case neighborhoods and substantially <1 for neighborhoods without cases. During the epidemic, the effect of the level of measurement of the indices was still more pronounced. The HI and BI at the municipality level were 1.53% and 1.73, respectively, but all health areas with dengue cases attained a BI >1. Even more marked differences existed at the block and neighborhood levels, and after the outbreak the indices returned to average values <1 at all levels of measurement. The mean values for case blocks and neighborhoods were, in all instances, consistently substantially and significantly higher (all p<0.05) than those for corresponding control units. A high correlation was observed between block-level BI and HI values (r [greater than or equal to] 0.94, p<0.05). In most positive houses (89.6%), only 1 container with Aedes larvae or pupae was found. The Figure shows the spatial distribution of Ae. aegypti larval infestation infestation /in·fes·ta·tion/ (-fes-ta´shun) parasitic attack or subsistence on the skin and/or its appendages, as by insects, mites, or ticks; sometimes used to denote parasitic invasion of the organs and tissues, as by helminths. during the inspection cycles before, during, and after the epidemic and the location of the dengue fever cases in the first (September) and second (October) month of dengue virus transmission. In most blocks (70%), no Aedes infestation was present before the epidemic period epidemic period Epidemiology A timespan when the number of cases of a disease reported is greater than expected , but 8.8% of blocks had BI values >4, with a maximum BI of 50. Of the 17 confirmed dengue patients in September, only 3 (18%) lived in a block with BI [greater than or equal to] 4 in the July-August inspection cycle. However, 15 (88%) lived in a neighborhood with at least 1 block with BI [greater than or equal to] 4. The Aedes infestation increased during the second inspection cycle and then decreased again, concurrent with the intensified vector control activities during the epidemic. From November to December, after the outbreak, 71.6% of house blocks were Aedes-free, while 6.3% had BI>4. [FIGURE OMITTED] The mean block BI, the mean neighborhood BI, and the mean [BI.sub.max] for case and control blocks are given in Table 2. Before the epidemic, the mean BI values were approximately equal for case and control units. However, the [BI.sub.max] values were significantly higher for neighborhoods of case blocks. While transmission started in neighborhoods with high [BI.sub.max] infestation levels, it spread into blocks and neighborhoods with lower mean BI values in October. Still, during the epidemic, the indices remained systematically and significantly higher in case blocks. After the epidemic, they returned to similar values for case and control units. The entomologic indices from inspection cycles before and during the epidemic were less to moderately accurate at predicting subsequent transmission. The highest AUC value, 0.71, was attained with the [BI.sub.max] from the July to August inspection cycle. At the cutoff of 4.07, it reached a sensitivity of 77.8% and a specificity of 63.2% for predicting September transmission. A neighborhood BI [greater than or equal to] 1.30 gave similar results. Block-level BIs were less accurate. Comparable cutoff points for the indices in the September to October inspection cycle discriminate best for predicting transmission in October (data not shown). After the epidemic, in the November to December inspection cycle, the indices had a high specificity: 89.6% for BI<1 and 85.7% for [BI.sub.max]<4, which points toward their usefulness in nonepidemic periods. Table 3 shows the odds ratios (OR) for dengue transmission at optimal BI cutoff values. From July to August, consistent with previous results, only [BI.sub.max] [greater than or equal to] 4 was a significant predictor for identifying blocks with a case in September (OR 6.00, p<0.05). In contrast, the OR for all the different September-October BIs were significant; blocks above threshold had 3-5 times the chance of having a dengue case in October. Additionally, during the outbreak, the presence of a single positive container in a block was associated with a higher risk for dengue transmission (OR 3.49, p<0.05). Discussion We show that entomologic indices, BI in particular, allow identification of geographic units at high risk for dengue transmission. However, in regions with low Ae. aegypti density, identifying such units requires analysis at different levels, i.e., for blocks and neighborhoods, and short intervals between inspection cycles. Optimal cutoff values were identified for our study setting. The existence of detailed surveillance data before, during, and after the dengue epidemic in Playa Municipality offered a unique opportunity to analyze entomologic information at different geographic levels. Entomologic data collected through routine systems, however, has some limitations. First, larval prevalence was possibly slightly underestimated: blocks were inspected by different vector control technicians, procedures used may not have been completely standardized, and few data are (randomly) missing. Second, when dengue cases were reported, the control program intensified, and more Aedes foci may have been detected. Third, sampling Aedes aegypti can be time sensitive (25), and our inspection cycles at 2-month intervals may not have fully captured the temporal variability of the entomologic indices. Besides, we may not have been able to identify all dengue patients who were infected outside their area of residence. Also, the study design did not allow us to detect 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 dengue infections, which likely occurred in some control blocks and neighborhoods. However, we expect the potential misclassification to be nondifferential, i.e., independent of the entomologic indices. Furthermore, the experience of the technicians of the vector control program, their close supervision (including systematic revisiting of 33.3% of the inspected houses), and the interviews conducted with all dengue patients to exclude outside infection guarantee that biases, if any, are minimal. Various researchers have investigated the relationship between dengue transmission and the Aeries population, expressed as larval (15,26-31), pupal (7,13,32), and adult indices (33). Moore (28) in Puerto Rico Puerto Rico (pwār`tō rē`kō), island (2005 est. pop. 3,917,000), 3,508 sq mi (9,086 sq km), West Indies, c.1,000 mi (1,610 km) SE of Miami, Fla. and Pontes pon·tes n. Plural of pons. (15) in Fortaleza, Brazil, used temporal graphics to compare the seasonal fluctuation of rainfall, Aedes larval indices, and dengue incidence. They observed a strong relation in the patterns of the 3 series. In Puerto Rico, the peak incidence of confirmed infection followed the peak larval density by [approximately equal to] 1 month. In Salvador, Brazil, sentinel surveillance in 30 areas detected a significant 1.4 x higher seroincidence when the HI was >3% (31). Recently, Scott and Morrison (16) showed that traditional larval indices in Peru are correlated with the prevalence of human dengue infections. The variety of thresholds proposed in these and other studies could be partially explained by different methods and geographic levels of analysis used, but other factors influence the relationship between Aedes density and transmission risk, such as herd immunity herd immunity n. 1. Resistance to the spread of infectious disease in a group because susceptible members are few, making transmission from an infected member unlikely. 2. (11), population density (31), mosquito-human interaction (34), virus strain, and climate, which affects mosquito biology and mosquito-virus interactions (16). Entomologic indices, however, were strongly associated with transmission, and we used ROC analysis ROC analysis Clinical decision-making The analysis of the relationship between the true positive fraction of test results and the false positive fraction for a diagnostic procedure that can take on multiple values. See 4-cell decision matrix. Cf Likelihood ratio. (24) to assess the potential of these indices to predict in which blocks transmission would occur and to select an operating point that would provide an optimum tradeoff between false-positive and false-negative results (35). [BI.sub.max] [greater than or equal to] 4 followed by neighborhood BI [greater than or equal to] 1 during the preceding [approximately equal to] 2 months provides good predictive discrimination. At longer intervals, the sensitivity of these indices becomes too low. More frequent inspection cycles might perform better since Aedes needs only 9-12 days to develop from egg to adult (36). Care should, however, be taken when extrapolating these findings to communities with other herd immunity levels or different environmental conditions. Our data also show that the geographic level of analysis determines the Aedes indices obtained. Marked heterogeneity het·er·o·ge·ne·i·ty n. The quality or state of being heterogeneous. heterogeneity the state of being heterogeneous. is not only found inside Playa Municipality but also inside smaller health areas. Indices at the neighborhood level perform best, followed by indices at the block level. Geographic scale has too often been neglected when dengue transmission is studied. In general, overall indices are calculated for communities (sometimes of different sizes) defined by administrative boundaries, which do not constitute entomologically homogeneous units. Notwithstanding, standing, local variability of larval indices can be inferred from the literature, in which it is sometimes mentioned. Chan et al. (27) noted that HI in different sections of Singapore's Chinatown varied from 10.2% to 25.0%. However, Goh et al. (30) reported an overall HI of 2.4% in Singapore, but at the level of 7 blocks taken together (approximately the same scale as our neighborhood), HI up to 17.9% were found. Tran et al. (36) defined 400 m and 40 days as the spatial and temporal boundaries of maximum dengue transmission in a dengue focus. Perez et al. (37) identified areas in Havana with heterogeneous risks for vector infestation by using a geographic information system geographic information system (GIS) Computerized system that relates and displays data collected from a geographic entity in the form of a map. The ability of GIS to overlay existing data with new information and display it in colour on a computer screen is used primarily to . Spatial heterogeneity Environments with a wide variety of habitats such as different topographies, soil types and climates are able to accommodate a greater amount of species. Spatial heterogeneity has also been observed at the household level for both Aedes populations (10,38,39) and dengue transmission (26,29,40), but this level seems less suitable for identifying areas for intervention. Blocks or neighborhoods, given the epidemiologic situation in our study area, are a more appropriate scale. The unit of analysis used in our study, the block, is based on manmade boundaries. While these may not describe the ecology of risk, they seem to be useful markers from the perspective of community-based control interventions. In most settings, appropriately sized and locally meaningful geographic units could be similarly defined for entomologic surveillance, but the use of different boundaries or different analytical techniques could produce different results. In our study, BI [greater than or equal to] 1 and [BI.sub.max][greater than or equal to] 4 seemed to be a suitable action threshold and target, respectively, in community based dengue prevention. However, these results are derived from the analysis of 1 epidemic, and the thresholds identified may not constitute suitable targets in another epidemic or in locations where different ecologic conditions prevail. Similar studies in future epidemics and in other settings are necessary to verify the general applicability of our results. Acknowledgments We gratefully acknowledge the role played by the health sector staff involved in dengue prevention and control activities. We also thank the people of Playa Municipality who participated in the study. This study was partially funded through the framework agreement between the Institute of Tropical Medicine and the Belgium Directorate-General for Development Cooperation. Dr Sanchez is an epidemiologist at the Department of Informatics Same as information technology and information systems. The term is more widely used in Europe. and Biostatistics biostatistics /bio·sta·tis·tics/ (-stah-tis´tiks) biometry. bi·o·sta·tis·tics n. The science of statistics applied to the analysis of biological or medical data. in the Tropical Medicine Institute "Pedro Kouri." Her research interests include field epidemiology, mathematical modeling, and prevention and control of infectious diseases infectious diseases: see communicable diseases. . References (1.) Guzman MG, Kouri G. Dengue: an update. Lancet Infect Dis. 2002;2:33-42. (2.) Deen JL. The challenge of dengue vaccine development and introduction. Trop Med Int Health. 2004;9:1-3. (3.) Guzman MG, Mune M, Kouri G. Dengue vaccine: priorities and progress. Expert Rev Anti Infect Ther. 2004;2:895-911. (4.) Gubler D J, Clark GG. Community involvement in the control of Aedes aegypti. Acta Trop. 1996;61:169-79. (5.) Guzman MG, Kouri G. Dengue and dengue hemorrhagic fever in the Americas: lessons and challenges. J Clin Virol. 2003;27:1-13. (6.) Reiter P, Gubler DJ. Surveillance and control of urban dengue vectors. In: Gubler D J, Kuno G, editors. Dengue and dengue hemorrhagic fever. New York New York, state, United States New York, Middle Atlantic state of the United States. 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Ecological aspects for application of genetically modified genetically modified Adjective (of an organism) having DNA which has been altered for the purpose of improvement or correction of defects genetically modified genetic adj [food etc] → mosquitoes. Dordrecht (the Netherlands): Kluwer Academic Publishers; 2004. p. 187-206. (17.) Morrison AC, Astete H, Chapilliquen F, Ramirez-Prada C, Diaz G, Getis A, et al. Evaluation of a sampling methodology for rapid assessment of Aedes aegypti infestation levels in Iquitos, Peru. J Med Entomol. 2004;41:502-10. (18.) Gubler DJ, Clark GG Community-based integrated control of Aedes aegypti: a brief overview of current programs. Am J Trop Med Hyg. 1994;50:50-60. (19.) Arias J. Dengue in Cuba [article in Spanish]. Rev Panam Salud Publica. 2002;11:221-2. (20.) Armada An earlier brand name for laptop computers from Compaq. The line was noted for its quality and innovative features. Gessa JA, Figueredo GR. Application of environmental management principles in the program for eradication of Aedes (Stegomyia) aegypti (Linneus, 1762) in the Republic of Cuba, 1984. Bull Pan Am Health Organ. 1986;20:186-93. (21.) Guzman MG, Kouri G, Valdes L, Ramirez-Prada C, Diaz G, Getis A, et al. Epidemiologic studies epidemiologic study A study that compares 2 groups of people who are alike except for one factor, such as exposure to a chemical or the presence of a health effect; the investigators try to determine if any factor is associated with the health effect on Dengue in Santiago de Cuba, 1997. Am J Epidemiol. 2000;152:793-9. (22.) Kouri G, Guzman MG, Valdes L, Carbonel I, del Rosario D, Vazquez S, et al. Reemergence of dengue in Cuba: a 1997 epidemic in Santiago de Cuba. Emerg Infect Dis. 1998;4:89-92. (23.) Pelaez O, Guzman MG, Kouri G, Perez R, San Martin JL, Vazquez S, et al. Dengue 3 epidemic, Havana, 2001. Emerg Infect Dis. 2004; 10:719-22. (24.) Greiner M, Pfeiffer D, Smith RD. Principles and practical application of the receiver-operating characteristic analysis for diagnostic tests. Prev Vet Med. 2000;45:23-41. (25.) Morrison AC, Gray K, Getis A, Astete H, Sihuincha M, Focks D, et al. Temporal and geographic patterns geographic pattern A general descriptor for lesions in which large areas of one color, histologic pattern, or radiologic density with variably scalloped borders sharply interface with another color, pattern or density, fancifully likened to national boundaries of Aedes aegypti (Diptera: Culicidae) production in Iquitos, Peru. J Med Entomol. 2004;41 : 1123-42. (26.) Neff JM, Morris L, Gonzalez-Alcover R, Coleman PH, Lyss SB, Negron H. Dengue fever in a Puerto Rican Puer·to Ri·co Abbr. PR or P.R. A self-governing island commonwealth of the United States in the Caribbean Sea east of Hispaniola. community. Am J Epidemiol. 1967;86:162-84. (27.) Chan YC, Chan KL, Ho BC. Aedes aegypti (L.) and Aedes albopictus Noun 1. Aedes albopictus - striped native of Japan thriving in southwestern and midwestern United States and spreading to the Caribbean; potential carrier of serious diseases Asian tiger mosquito (Skuse) in Singapore City. 1. Distribution and density. Bull World Health Organ. 1971;44:617-27. (28.) Moore CG, Cline cline, in biology, any gradual change in a particular characteristic of a population of organisms from one end of the geographical range of the population to the other. BL, Ruiz-Tiben E, Lee D, Romney-Joseph H, Rivera-Correa E. Aedes aegypti in Puerto Rico: environmental determinants of larval abundance and relation to dengue virus transmission. Am J Trop Med Hyg. 1978;27:1225-31. (29.) Waterman SH, Novak R J, Sather GE, Bailey RE, Rios I, Gubler DJ. Dengue transmission in two Puerto Rican communities in 1982. Am J Trop Med Hyg. 1985;34:625-32. (30.) Goh KT, Ng SK, Chan YC, Lim SJ, Chua EC. Epidemiological aspects of an outbreak of dengue fever/dengue haemorrhagic fever Noun 1. haemorrhagic fever - a group of illnesses caused by a viral infection (usually restricted to a specific geographic area); fever and gastrointestinal symptoms are followed by capillary hemorrhage in Singapore. Southeast Asian J Trop Med Public Health. 1987;18:295-302. (31.) Teixeira Mda G, Barreto ML, Costa Mda C, Ferreira LD, Vasconcelos PF, Caimcross S. Dynamics of dengue virus circulation: a silent epidemic in a complex urban area. Trop Med Int Health. 2002;7:757-62. (32.) Strickman D, Kittayapong E Dengue and its vectors in Thailand: calculated transmission risk from total pupal counts of Aedes aegypti and association of wing-length measurements with aspects of the larval habitat. Am J Trop Med Hyg. 2003;68:209-17. (33.) Rodriguez-Figueroa L, Rigau-Perez JG, Suarez EL, Reiter P. Risk factors for dengue infection during an outbreak in Yanes, Puerto Rico in 1991. Am J Yrop Med Hyg. 1995;52:496-502. (34.) Espinoza Gomez F, Hemandez Suarez CM, Coll CR. Factors that modify the larval indices ofAedes aegypti in Colima, Mexico [article in Spanish]. Rev Panam Salud Publica. 2001;10:6-12. 35. Zweig MH, Campbell G. Receiver-operating characteristic (ROC) plots: a fundamental evaluation tool in clinical medicine. Clin Chem. 1993;39:561-77. (36.) Tran A, Deparis X, Dussart P, Morvan J, Rabarison P, Remy F, et al. Dengue spatial and temporal patterns, French Guiana French Guiana (gēăn`ə, –än`–), Fr. La Guyane française, officially Department of Guiana, French overseas department (2005 est. pop. , 2001. Emerg Infect Dis. 2004;10:615-21. (37.) Perez T, Iniguez L, Sanchez L, Remond R. Vulnerabilidad espacial al dengue: Una aplicacion de los sistemas de informacion geografica en el municipio Playa de Ciudad de La Habana Ciudad de la Habana (sy thäth` thā lä häbä`nä, hävä`–) or La Habana, province (1994 est. pop. . Rev Cubana
Salud Pfiblica [serial on the Internet]. 2003;29:344-54 [cited 2006 Mar
10]. Available from http://scielo.sld.cu/scielo.php?script=sci_arttext& pid=S0864-34662003000400009&1ng=es&nrm=iso&tlng=es(38.) Tun-Lin W, Kay BH, Barnes A. Understanding productivity, a key to Aedes aegypti surveillance. Am J Trop Med Hyg. 1995;53:595-601. (39.) Scott TW, Morrison AC, Lorenz LH, Clark GG, Strickman D, Kittayapong P, et al. Longitudinal studies longitudinal studies, n.pl the epidemiologic studies that record data from a respresentative sample at repeated intervals over an extended span of time rather than at a single or limited number over a short period. of Aedes aegypti (Diptera: Culicidae) in Thailand and Puerto Rico: population dynamics Population dynamics is the study of marginal and long-term changes in the numbers, individual weights and age composition of individuals in one or several populations, and biological and environmental processes influencing those changes. . J Med Entomol. 2000;37:77-88. (40.) Morrison AC, Getis A, Santiago M, Rigau-Perez JG, Reiter P. Exploratory space-time analysis of reported dengue cases during an outbreak in Florida, Puerto Rico Florida (flo'ɾida) is a municipality of Puerto Rico located north of Utuado and Ciales, south of Barceloneta, east of Arecibo, and west of Manatí. , 1991-1992. Am J Trop Med Hyg. 1998;58:287-98. Lizet Sanchez,* Veerle Vanlerberghe, ([dagger]) Lazara Alfonso, * Maria del Carmen Carmen throws over lover for another. [Fr. Lit.: Carmen; Fr. Opera: Bizet, Carmen, Westerman, 189–190] See : Faithlessness Carmen the cards repeatedly spell her death. [Fr. Marquetti, * Maria Guadalupe Guzman, * Juan Bisset, * and Patrick van der Stuyft ([dagger]) * Tropical Medicine Institute "Pedro Kouri," Havana, Cuba; and ([dagger]) Institute of Tropical Medicine, Antwerp, Belgium Address for correspondence: Lizet Sanchez, Tropical Medicine Institute "Pedro Kouri" Department of Informatics and Biostatistics, Autopista See also:limited access highway Autopista is a Spanish language word designating a limited access highway. Autopistas exist in many Spanish speaking countries, including Mexico, Chile, Spain, Cuba, Colombia, Puerto Rico, Venezuela and Argentina. Novia del Mediodia, Km 6, La Lisa AP 601, Marianao 13, Havana City, Havana AP 601, Cuba; email: 1sanchez@ipk.sld.cu
Table 1. Mean house index (HI) and Breteau index
(BI) before, during, and after the dengue outbreak
and mean area and population at different geographic
levels, Playa Municipality, Havana, 2000
July-August
2000 (before
outbreak)
Level HI (%) BI
Municipality 0.87 0.92
Health area *
With cases (n = 5) 0.92 0.99
Without cases (n = 4) 1.03 1.08
Neighborhood ([dagger])
With cases (n = 38) 1.12 1.12
Without cases (n = 38) 0.64 0.69
Block ([dagger])
With cases (n = 38) 0.33 0.34
Without cases (n = 38) 0.13 0.20
September-
October 2000
(during
outbreak)
Level HI (%) BI
Municipality 1.53 1.73
Health area *
With cases (n = 5) 1.97 2.34
Without cases (n = 4) 0.89 1.06
Neighborhood ([dagger])
With cases (n = 38) 4.00 4.53
Without cases (n = 38) 1.39 1.52
Block ([dagger])
With cases (n = 38) 2.40 2.92
Without cases (n = 38) 0.35 0.42
November-
December 2000
(after
outbreak)
Level HI (%) BI
Municipality 0.69 0.73
Health area * f
With cases (n = 5) 0.48 0.50
Without cases (n = 4) 0.87 0.93
Neighborhood ([dagger])
With cases (n = 38) 0.80 0.84
Without cases (n = 38) 0.74 0.81
Block ([dagger])
With cases (n = 38) 0.62 0.66
Without cases (n = 38) 0.32 0.33
Area
Level ([km.sup.2]) Population
Municipality 34.90 182,485
Health area *
With cases (n = 5) 2.85 21,815
Without cases (n = 4) 5.13 16,320
Neighborhood ([dagger])
With cases (n = 38) 0.078 2,057
Without cases (n = 38) 0.062 1,466
Block ([dagger])
With cases (n = 38) 0.010 271
Without cases (n = 38) 0.008 195
* For all areas in the municipality.
([dagger]) For neighborhoods/blocks
included in the study.
Table 2. Mean BI for case and control blocks before, during,
and after the dengue outbreak, Playa Municipality,
Havana, 2000 *
July-August 2000 (before
epidemic), mean (95% CI)
Block BI NBI [BI.sub.max]
September 0.53 1.52 6.28 ([dagger])
case (0.02- (0.76- (3.29-
blocks 1.75 2.53 10.23
(n = 9)
October 0.29 1.01 4.24
case (0.05- (0.60- (2.48-
blocks 0.72 1.54 6.46
(n = 29)
Control 0.20 0.69 2.96
blocks (0.02- (0.42- (1.71-
(n = 38) 0.58 1.02 4.56
September-October 2000 (during
epidemic), mean (95% CI)
Block BI NBI [BI.sub.max]
September 11.95 ([dagger]) 10.75 ([dagger]) 28.4 ([dagger])
case (2.26- (6.73- (16.1-
blocks 29.27 15.70 44.10
(n = 9)
October 1.39 ([dagger]) 3.16 ([dagger]) 12.2 ([dagger])
case (0.50- (1.99- (7.79-
blocks 2.71 4.61 17.60
(n = 29)
Control 0.42 1.52 1.52
blocks (0.07- (0.91- (3.57-
(n = 38) 1.05 2.29 8.32
November-December 2000
(afterepidemic),
mean (95% CI)
Block BI NBI [BI.sub.max]
September 0.63 0.64 2.94
case (0.04- (0.37- (1.71-
blocks 1.70 0.91 4.83
(n = 9)
October 0.66 0.76 2.87
case (0.06- (0.44- (1.50-
blocks 0.91 1.06 4.35
(n = 29)
Control 0.33 0.68 2.34
blocks (0.06- (0.36- (1.43-
(n = 38) 0.82 1.18 4.27)
* BI, Breteau index; CI, confidence interval; NBI,
neighborhood BI; [BI.sub.max] maximum BI at the
block level for each neighborhood.
([dagger]) Significantly different from corresponding
values for control blocks (p<0.05).
Table 3. OR for dengue transmission at the optimal
cutoff values of the BI, Playa Municipality,
Havana, 2000 *
Index and cutoff
value ([dagger]) OR (95% CI)
July-August 2000
inspection cycle
(before epidemic)
BI per block >0
September transmission 2.57 (0.57-11.70)
October transmission 1.69 (0.58-4.94)
BI per
neighborhood [greater
than or equal to] 1
September transmission 3.00 (0.66-14.17)
October transmission 1.08 (0.40-2.90)
[BI.sub.max]
[greater than
or equal to] 4
September transmission 6.00 (1.09-32.98) ([double dagger])
October transmission 1.21 (0.45-3.25)
September-October
2000 inspection cycle
(during epidemic)
BI per block >0
October transmission 3.49 (1.20-10.10) ([double dagger])
BI per neighborhood
[greater than
or equal to]
October transmission 5.06 (1.46-17.38) ([double dagger])
[BI.sub.max][greater
than or equal to] 4
October transmission 3.44 (1.23-9.63) ([double dagger])
* OR, odds ratio; BI, Breteau index;
CI, confidence interval; [BI.sub.max] maximum
BI at the block level for each neighborhood.
([dagger]) Optimal cutoff value determined
as specified in Methods.
([double dagger]) p<0.05.
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