Seasonal patterns of invasive pneumococcal disease. (Research).Pneumococcal pneumococcal /pneu·mo·coc·cal/ (-kok´al) pertaining to or caused by pneumococci. infections increase each winter, a phenomenon that has not been well explained. We conducted population-based active surveillance for all cases of invasive pneumococcal disease in seven states; plotted annualized annualized Of or relating to a variable that has been mathematically converted to a yearly rate. Inflation and interest rates are generally annualized since it is on this basis that these two variables are ordinarily stated and compared. weekly rates by geographic location, age, and latitude; and assessed correlations by time-series analysis Time-series analysis Assessment of relationships between two or among more variables over periods of time. . In all geographic areas, invasive pneumococcal disease exhibited a distinct winter seasonality, including an increase among children in the fall preceding that for adults and a sharp spike in incidence among adults each year between December 24 and January 7. Pneumococcal disease correlated inversely with temperature (r -0.82 with a 1-week lag; p<0.0001), but paradoxically the coldest states had the lowest rates, and no threshold temperature could be identified. The pattern of disease correlated directly with the sinusoidal sinusoidal /si·nus·oi·dal/ (si?nu-soi´dal) 1. located in a sinusoid or affecting the circulation in the region of a sinusoid. 2. shaped like or pertaining to a sine wave. variations in photoperiod photoperiod /pho·to·pe·ri·od/ (fo´to-per?e-od) the period of time per day that an organism is exposed to daylight (or to artificial light).photoperiod´ic pho·to·pe·ri·od n. (r +0.85 with a 5-week lag; p<0.0001). Seemingly unrelated seasonal phenomena were also somewhat correlated. The reproducible seasonal patterns in varied geographic locations are consistent with the hypothesis that nationwide seasonal changes such as photoperiod-dependent variation in host susceptibility may underlie pneumococcal seasonality, but caution is indicated in assigning causality as a result of such correlations. ********** As with many infectious diseases infectious diseases: see communicable diseases. , the incidence of invasive pneumococcal infection rises and falls Rise and Fall redirects here. For the Belgian hardcore band, click here. Rises and falls is a category of the ballroom dance technique that refers to rises and falls of the body of a dancer achieved through actions of knees and feet (ankles). in an annual seasonal pattern that has been repeatedly documented but never well explained. The winter increase in cases has been attributed to cold weather, lower humidity, the crowding together of susceptible hosts, associated viral infections, and air pollution (1-3). Explanations for the cause of pneumococcal seasonality often appear contradictory. A temporary increase in the incidence of invasive disease was associated with two severe winters in the Netherlands (4), but in Alaska, the number of invasive cases is highest in summer months (5). The seasonal variation has been more apparent in adult invasive pneumococcal disease than in pediatric pediatric /pe·di·at·ric/ (pe?de-at´rik) pertaining to the health of children. pe·di·at·ric adj. Of or relating to pediatrics. cases (1), although some seasonal variation in acquisition of nasopharyngeal nasopharyngeal pertaining to the nasal and pharyngeal cavities. nasopharyngeal meatus see nasopharyngeal meatus. nasopharyngeal spasm see reverse sneeze. colonization also has been documented in children (6). These disparate observations have been difficult to reconcile with a unifying explanation for pneumococcal seasonality. A recent hypothesis proposes that the seasonal variation in the incidence of some infectious diseases is attributable to seasonal variation in host physiology, such as the density of a cellular receptor or the activity of the immune response immune response n. An integrated bodily response to an antigen, especially one mediated by lymphocytes and involving recognition of antigens by specific antibodies or previously sensitized lymphocytes. (7). Many mammals exhibit distinct physiologic changes with the changing seasons, typically timed to the light-dark cycle and mediated by melatonin melatonin: see pineal gland. melatonin Hormone secreted by the pineal gland of most vertebrates. It appears to be important in regulating sleeping cycles; more is produced at night, and test subjects injected with it become sleepy. (humans exhibit some such changes) (8-11). Experiments with mice provide some evidence that susceptibility to fatal pneumococcal disease varies with the animal's innate circadian rhythm circadian rhythm: see rhythm, biological. circadian rhythm Inherent cycle of approximately 24 hours in length that appears to control or initiate various biological processes, including sleep, wakefulness, and digestive and hormonal activity. (12-14). Determining the relevance, if any, of these observations to human pneumococcal infections would be advanced by a detailed description of the seasonal patterns of pneumococcal infections of various age groups and different geographic areas with distinct weather patterns. We evaluated data from a population-based surveillance system in seven geographic areas in the United States United States, officially United States of America, republic (2005 est. pop. 295,734,000), 3,539,227 sq mi (9,166,598 sq km), North America. The United States is the world's third largest country in population and the fourth largest country in area. (Active Bacterial Core Surveillance) to describe the seasonal variation in invasive pneumococcal disease and explore these hypotheses. Methods Surveillance for invasive pneumococcal disease was performed from January 1, 1996, through December 31, 1998, in the counties of seven U.S. states, as consistently defined in the Active Bacterial Core Surveillance of the Emerging Infections Program Network. Geographic location was grouped by state and by latitude (Figure 1), including eight counties in Georgia and five counties in Tennessee List of 95 counties in the U.S. state of Tennessee. The city of Nashville and Davidson County operate under a unified government. Similar arrangements exist between the City of Lynchburg and Moore County, as well as the City of Hartsville and Trousdale County. State Abbr. (latitude 33[degrees]-35[degrees] north; defined here as southern sites), one county in California and six counties in Maryland This is a list of the twenty-four counties and county-equivalents in the U.S. state of Maryland. Though an independent city rather than a county, the City of Baltimore is considered the equal of a county for most purposes and is a county-equivalent. (latitude 37[degrees]-39[degrees] north; middle sites), and the entire state of Connecticut, seven counties in Minnesota This is a List of counties in Minnesota. There are 87 counties in the U.S. state of Minnesota. There are also several historical counties. The original five Minnesota counties were Benton, Isanti, Ramsey, Wabasha, and Washington. , and three counties in Oregon List of 36 counties in the U.S. state of Oregon. Oregon counties are also listed in order of per-capita income. Oregon's postal abbreviation is OR and its FIPS state code is 41. (latitude 41[degrees]-45[degrees] north; northern sites). Invasive disease caused by group A streptococci Streptococcus (plural, streptococci) A genus of spherical-shaped anaerobic bacteria occurring in pairs or chains. Sydenham's chorea is considered a complication of a streptococcal throat infection. and group B streptococci was also assessed for comparison with pneumococcal disease. [FIGURE 1 OMITTED] Invasive disease was defined as disease in which an organism had been isolated from a normally sterile site (such as blood or cerebrospinal fluid cerebrospinal fluid (CSF) Clear, colourless liquid that surrounds the brain and spinal cord and fills the spaces in them. It helps support the brain, acts as a lubricant, maintains pressure in the skull, and cushions shocks. ) in a resident of the surveillance area. Each case was considered to have occurred on the date the culture was obtained. In each surveillance area, project personnel communicated regularly with contacts in all microbiology laboratories serving acute-care hospitals and completed standardized case-report forms. Audits were performed at least every 6 months to evaluate reporting sensitivity and identify unreported cases. All isolates were sent to the 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. or the University of Texas Health Science Center at San Antonio UTHSCSA is the largest comprehensive health sciences university in South Texas. Located in the South Texas Medical Center, it serves San Antonio and all of the 50,000 square mile (130,000 km²) area of central and south Texas. on blood agar blood agar n. A nutrient culture medium that is enriched with whole blood and used for the growth of certain strains of bacteria. slants and confirmed as pneumococci on the basis of optochin susceptibility and bile solubility. Daily surface weather data were obtained from weather stations in each surveillance site (Atlanta, Memphis, San Francisco San Francisco (săn frănsĭs`kō), city (1990 pop. 723,959), coextensive with San Francisco co., W Calif., on the tip of a peninsula between the Pacific Ocean and San Francisco Bay, which are connected by the strait known as the Golden , Baltimore, Hartford, Minneapolis, and Portland) from the National Climate Disease Center, Asheville, North Carolina Not to be confused with Ashville. Asheville is a city in Buncombe County, North Carolina, and is its county seat. As of the 2000 census, the city had a total population of 68,889. It is the largest city in western North Carolina, and continues to grow. (available 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.ncdc.noaa.gov). Sunrise and sunset Sunrise and Sunset are a pair of pegasi in the Dungeons & Dragons-based Forgotten Realms setting. The pair were rescued from giants by the moon elf Tarathiel a few years prior to 1370 DR, and after this they served as winged mounts for him and his partner, times for each surveillance week were obtained for each of the above seven sites from the U.S. Naval Observatory, Washington, D.C. (available from: URL: http:// aa.usno. navy. mil). Monthly figures for electric utility gas consumption were obtained from the Energy Information Administration, Washington, D.C. (available from: URL: http://www.eia.doe.gov), and figures for public construction expenditures were obtained from the U.S. Census Bureau, Washington, D.C. (available from: URL: http://www.census.gov). Weekly numbers of cases were converted to annualized rates by dividing by the census population in the relevant counties for the appropriate surveillance year and multiplying by 100,000 population and 52 weeks (to get cases per 100,000 population per year). We then plotted annualized rates by state, latitude group (as categorized above), and age (adults [greater than or equal to] 18 years and children). Time series analysis was performed with SAS (1) (SAS Institute Inc., Cary, NC, www.sas.com) A software company that specializes in data warehousing and decision support software based on the SAS System. Founded in 1976, SAS is one of the world's largest privately held software companies. See SAS System. software (version 8.2, SAS Institute, Inc., Cary, NC) and Epi Info software version 6.02 (Centers for Disease Control and Prevention, Atlanta, GA). Annualized weekly rate correlations with mean weekly temperature (in degrees F), total weekly precipitation (100ths of inches), and mean weekly minutes of darkness were calculated as Pearson correlation coefficients with time lags ranging from 0 to 8 weeks. Time lags were limited to an 8-week range because the highest correlations from exploratory analysis in the annualized weekly rate with the climatic data occurred within 2 months. Correlations with monthly gas consumption and construction expenditures were explored with time lags of 20 to 36 months because the data were available from 1999 to 2001, whereas the weekly pneumococcal disease rates were available from 1996 to 1998. Weather data were missing from Atlanta for 1996 and were not included; occasional missing readings were otherwise replaced by interpolation interpolation In mathematics, estimation of a value between two known data points. A simple example is calculating the mean (see mean, median, and mode) of two population counts made 10 years apart to estimate the population in the fifth year. . Results Over the 3-year period, 11,614 cases of invasive pneumococcal disease were identified among the approximately 15,221,605 residents of the surveillance areas. The annualized weekly rate of invasive pneumococcal disease was distinctly seasonal, varying from approximately 10 cases per 100,000 population during the summer to approximately 35 cases per 100,000 during the winter (Figure 2). No seasonal variation was seen in the incidence of group B streptococcal infection Infection with Group B Streptococcus (GBS), also known as Streptococcus agalactiae, can cause serious illness and sometimes death, especially in newborn infants and the elderly. , and a mild spring peak was seen in group A streptococcal infection The group A streptococcus bacterium (Streptococcus pyogenes, or GAS) is a form of Streptococcus bacteria responsible for most cases of streptococcal illness. Other types (B, C, D, and G) may also cause infection. . A prominent spike in the rate of invasive pneumococcal disease to 50-75 cases per 100,000 occurred during the last week of December and the first week of January in each of the surveillance years. [FIGURE 2 OMITTED] The seasonal patterns were similar when the data from each state were plotted separately and when the states were grouped into the three latitude groups (Figure 3). The number of weekly cases increased approximately fourfold from summer to winter, and a prominent spike in the number of weekly cases occurred during the last week of December and the first week of January. [FIGURE 3 OMITTED] The pattern of seasonal variation was somewhat different in children compared to adults (Figure 4). The annual rise in incidence among children preceded that of adults, reaching the highest incidence during September and maintaining a high incidence throughout the fall. The spike in incidence during the last week of each year and first week of the subsequent year was seen in adults but not in children. [FIGURE 4 OMITTED] We further explored the characteristics of persons with invasive pneumococcal disease during the prominent annual spike (defined as December 20-January 10 of each year) and those experiencing invasive disease during the surrounding weeks (December 1-19, and January 11-31). Patients with invasive disease occurring during the spike and nonspike periods had similar demographic characteristics, except that adults were disproportionately represented during the spike (Table). After children were excluded, the median age of adults with invasive disease during the spike was 60 years, compared with 56 years for adults in the surrounding weeks (p=0.05). No similar spike in incidence occurred for either group A or group B streptococcal streptococcal /strep·to·coc·cal/ (-kok´al) pertaining to or caused by a streptococcus. Streptococcal (Streptococcus) Pertaining to any of the Streptococcus bacteria. disease. The seasonal peaks in invasive pneumococcal disease in each of the three latitude groups correlated with increases in the number of hours of darkness and with cold temperatures in the winter, but correlation was poor with seasonal variations in total precipitation (Figure 3). Correlations were highly significant (Pearson's correlation coefficients all [less than or equal to] -0.5; p<0.0001) for pneumococcal disease and temperature, with time lags ranging from 0 to 8 weeks (highest r -0.82 with a 1-week lag). Correlations were also highly significant (r all [greater than or equal to] 0.7; p<0.0001) for minutes of darkness and pneumococcal disease (highest r +0.85 with a 5-week lag). Temperature and photoperiod were themselves highly correlated with each other (r -0.95; p<0.0001). Precipitation did not correlate well with pneumococcal disease (r all [less than or equal to] 0.3, with best correlation of 0.29 using a O-week lag). The temperature curves for the individual states showed distinct patterns (data not shown), as did the temperature curves when sites were grouped by latitude (Figure 3c), but these variations were not associated with site-specific variation in pneumococcal disease. For example, the northern sites, with temperatures averaging 10[degrees]-20[degrees] lower than the southern sites throughout the year, did not have higher rates of invasive pneumococcal disease (Figure 3a). No evidence of a longer pneumococcal season in northern sites than in southern sites was evident, a finding that might have been expected if a threshold temperature existed, below which pneumococcal disease rates increase. Seasonal variations in photoperiod, or the length of the light-dark period, also corresponded with the seasonal variation in pneumococcal disease. Photoperiod was a seasonally varying phenomenon with less site-to-site variation than temperature (Figure 3b), similar to the consistent pattern of pneumococcal disease rates across the sites. The variation in the magnitude of the photoperiod curves was slightly more pronounced for northern sites than for southern sites (Figure 3b), a pattern which was not seen in invasive pneumococcal disease (Figure 3a). Associations between the seasonal increases in invasive pneumococcal disease and seemingly unrelated phenomena were not difficult to demonstrate, such as the correlations with seasonal variation in public construction expenditures (r -0.84 with a 35-month lag) and electric utility gas consumption (r -0.92 with a 22-month lag) (Figure 5). [FIGURE 5 OMITTED] Discussion A distinctive and regular seasonal variation in the incidence of invasive pneumococcal disease was confirmed by this analysis, as has been reported by others (1,3,15-17). We found that the patterns of seasonal variation were remarkably consistent across our seven geographically distinct surveillance areas, and we used the site-specific differences in weather across these areas to evaluate proposed explanations for the cause of pneumococcal seasonality. The unique seasonal patterns in children's infections as compared to those of adults, and the peculiar spike in incidence in adults during the same 1- to 2-week period each year remain incompletely explained, although these observations should provide ample opportunities for testing hypotheses in future studies. The shapes of the invasive pneumococcal disease curves were remarkably consistent across all seven surveillance sites, including the timing of the summertime nadir, the fall upswing in incidence, and the midwinter mid·win·ter n. 1. The middle of the winter. 2. The period of the winter solstice, about December 22. midwinter Noun 1. the middle or depth of winter 2. peak. These patterns were consistent despite marked differences in rainfall patterns and, to a lesser extent, differences in air temperature across these geographically widespread sites. If colder temperature is what drives the winter increase in pneumococcal disease, we might have expected higher rates throughout the year from northern sites, but that is not what we found. Alternatively, pneumococcal disease might increase when temperatures drop below some biologic threshold. Such biologic thresholds are present in certain temperature-sensitive viruses, for example, that are useful as vaccines because they are not viable in the warmer temperatures of the human lung (18). Such a temperature threshold for pneumococcal disease might be expected to result in a longer "pneumococcal season" in northern sites, a pattern we also did not find. Temperature and photoperiod variations need to be investigated further with datasets obtained by using similar methods from regions with wider latitude and temperature variations than we used here. Preliminary review of a smaller dataset of invasive pneumococcal disease from a different surveillance system in Alaska did not identify elevated rates of pneumococcal disease associated with the colder weather and longer winter and also did not display the consistent seasonal variations seen in our continental U.S. sites (J. Butler, pers. comm.). Some of the apparent variation in incidence of invasive pneumococcal disease seen in different studies may be attributable to variations in blood-culturing patterns (19,20). Geographic variation in blood culture practices may be more likely to influence the size of seasonal peaks and less likely to affect their timing, as we observed. Strengths of this analysis include the large population under surveillance and the consistent methods used to identify cases across all seven geographically distinct surveillance areas; these factors should tend to minimize any effects of local differences in blood-culturing practices or institutional variation in case ascertainment. The similar seasonal patterns observed in our seven surveillance sites, despite their wide variations in air temperature, precipitation, and other weather patterns, argue that the signal guiding pneumococcal seasonal variations is one that is more consistently present in all sites. Photoperiod has been shown to be the most pervasive signal for seasonal changes in biologic systems (10,21-23), and we believe our findings are consistent with the proposal that photoperiod also contributes to the seasonality of invasive pneumococcal disease in humans. The sinusoidal variation in photoperiod across the sites correlated closely with the pattern of invasive pneumococcal disease. We did not find a greater magnitude of pneumococcal variation from northern sites, and definitively identifying photoperiod, rather than temperature, as the driving phenomenon was not possible from this dataset. Because temperature and photoperiod are themselves highly correlated, evaluating the relative contributions of each to invasive pneumococcal disease will likely require further exploration with more years of data from more geographically diverse sites. We emphasize that correlating seasonal variations in invasive pneumococcal disease with temperature and photoperiod provides insufficient evidence insufficient evidence n. a finding (decision) by a trial judge or an appeals court that the prosecution in a criminal case or a plaintiff in a lawsuit has not proved the case because the attorney did not present enough convincing evidence. to establish a causal link. Using brief searches of the Internet, we readily identified seasonal variations in housing construction, gas consumption, and other seemingly unrelated phenomena that were also significantly correlated with the seasonal variation in pneumococcal disease. Because so many phenomena vary seasonally, evaluating one or two hypothesized causes for seasonal variation in disease and concluding that the close correlation supports causality is a pitfall pit·fall n. 1. An unapparent source of trouble or danger; a hidden hazard: "potential pitfalls stemming from their optimistic inflation assumptions" New York Times. all investigators in this field must take care to avoid. Accumulating evidence is supporting the biologic plausibility that preceding respiratory virus infections, influenza in particular, increase susceptibility to invasive pneumococcal disease (24,25). We did not have comparable data on virologically confirmed influenza infections from each of the seven surveillance sites to include in this analysis, but such information should be sought in future evaluations. Some experimental evidence exists to support the concept that cyclical variation in susceptibility to pneumococcal infections is present in the mammalian host, and that the light-dark cycle provides the signal that entrains this cyclical pattern. Mice kept in windowless rooms with a controlled light-dark cycle are less susceptible to pneumococcal infection during the dark phase (12). When such mice were inoculated intraperitoneally with virulent pneumococci during the dark phase (0400), there was a slower increase in bacteremia bacteremia: see septicemia. bacteremia Presence of bacteria in the blood. Short-term bacteremia follows dental or surgical procedures, especially if local infection or very high-risk surgery releases bacteria from isolated sites. (13), and the mice survived significantly longer, compared to those challenged during the light phase (12). In blinded mice, this pattern of decreased susceptibility was maintained on an approximately 24-hour (circadian circadian /cir·ca·di·an/ (ser-ka´de-an) denoting a 24-hour period; see under rhythm. cir·ca·di·an adj. Relating to biological variations or rhythms with a cycle of about 24 hours. ) pattern but cycled out of phase with the room lighting. These findings indicate the presence of an endogenous rhythm of susceptibility to pneumococcal infection that is normally entrained to a strict 24-hour pattern by visual detection of the daily light-dark cycle (14). Whether this circadian variation in susceptibility is accompanied by seasonal variation has not been evaluated, although the two periodic phenomena are closely related in most biologic systems (23). Humans retain the physiologic capacity to respond to changes in photoperiod (11, 26-28), but some evidence exists that artificial lighting blunts these responses (29). Moreover, the degree to which seasonal changes in light cycles influences human physiology, if at all, is not clear. The seasonal pattern in children was distinct from that in adults, consistent with differences in clinical disease in children and with the observations of others (1,5,30,31). Children are the reservoirs for pneumococci in the community, with nasopharyngeal colonization varying slightly (6), if at all (32), throughout the year. We observed a seasonal peak in children that was broader and flatter than that in adults, with an early autumn rise to the peak and an absence of the midwinter spike. Others have described this as a biphasic bi·pha·sic adj. Having two distinct phases: a biphasic waveform; a biphasic response to a stimulus. pattern, with a flattening or drop in incidence in midwinter (30,31,33,34); we did not observe this pattern. We speculate that the early autumn rise may be associated with the return to school and exchange of new serotypes, which may then be transmitted to adult contacts. The substantial variation in invasive disease despite fairly steady carriage supports a role for increasing host susceptibility or other predisposing factors, rather than appearance and disappearance of the pathogen, as an underlying explanation. The prominent midwinter spike in incidence we observed does not appear to be an artifact of the surveillance system. The spike, present in all seven states, was not seen for group A or group B streptococcal disease, which were reported through the same system. Persons with invasive disease during the spike were significantly older but otherwise demographically similar to those with invasive disease during the surrounding weeks. The consistent timing of the spike during the weeks of December 24-January 7 is provocative. This is a time when many U.S. families gather for Christmas and New Year's holidays, perhaps providing an opportunity for exposure of older relatives to new serotypes from young children at a time when their annual susceptibility to pneumococcal disease is at its peak. Previous studies have documented an association between exposure to young children and invasive pneumococcal disease (35,36). Others have not reported such a spike, but most such analyses have grouped the data by month, an approach that would have led us to miss the spike in our data. We encourage others with similar databases to examine their data by weekly intervals, to distinguish patterns in adults from those in children, and to report information on latitude, temperature patterns, humidity, and other variables to allow for a consistent exploration of the influences on pneumococcal seasonality. Variation in susceptibility in the human host is one hypothesis that should be routinely considered.
Table. Characteristics of persons with invasive pneumococcal
disease during an annual winter spike in incidence compared
with those experiencing invasive pneumococcal disease during
the surrounding weeks, 1996-1998a
% of patients
with characteristic
Nonspike Spike
Characteristic (N=1,647) (N=1,351) p value (b)
Sex (% male) 54.9 51.4 0.07
Race (% white) 56.6 60.8 0.07
Age (% adult) 74.3 81.7 0.0000013
Survival 87.1 87.5 0.92
State 0.49
California 6.0 4.9 --
Connecticut 17.7 18.9 --
Georgia 25.6 25.3 --
Maryland 20.2 19.1 --
Minnesota 10.4 11.3 --
Oregon 6.8 5.8 --
Tennessee 13.3 14.7 --
Syndrome 0.24
Bacteremia 35.6 33.0 --
Pneumonia 56.4 59.6 --
Meningitis 4.9 4.6 --
(a) The spike period was defined as December 20-January 10 each year,
and the nonspike periods were December 1-19 and January 11-31.
(b) p value calculated by chi-square test of the 2 x N table, with
Yates correction.
References (1.) Kim PE, Musher mush 1 n. 1. A thick porridge or pudding of cornmeal boiled in water or milk. 2. Something thick, soft, and pulpy. 3. Informal Mawkish sentimentality, affection, or amorousness. tr.v. DM, Glezen WP, Rodriguez-Barradas MC, Nahm WK, Wright CE. Association of invasive pneumococcal disease with season, atmospheric conditions, air pollution, and the isolation of respiratory viruses. Clin Infect Dis 1996;22:100-6. (2.) Bell M, Archibald LK, Nwanyanwu O, Dobbie H, Tokars J, Kazembe PN, et al. Seasonal variation in the etiology of bloodstream infections in a febrile febrile /feb·rile/ (feb´ril) pertaining to or characterized by fever. feb·rile adj. Of, relating to, or characterized by fever; feverish. inpatient population in a developing country. Int J Infect Dis 2001;5:63-9. (3.) Gordon MA, Walsh AL, Chaponda M, Soko D, Mbvwinji M, Molyneux ME, et al. Bacteraemia bacteraemia see bacteremia. and mortality among adult medical admissions in Malawi--predominance of non-typhi salmonellae and Streptococcus pneumoniae Streptococcus pneu·mo·ni·ae n. Pneumococcus. Streptococcus pneumoniae Microbiology A pathogenic streptococcus with 90 serotypes associated with pneumonia, bacteremia, meningitis Transmission Person to person Incidence . J Infect 2001;42:44-9. (4.) de Neeling AJ, van Pelt W, Hol C, Ligtvoet EE, Sabbe LJ, Bartelds A, et al. Temporary increase in incidence of invasive infection due to Streptococcus pneumoniae in the Netherlands. Clin Infect Dis 1999;29:1579-80. (5.) Davidson M, Schraer CD, Parkinson AJ, Campbell JF, Facklam RR, Wainwright RB, et al. Invasive pneumococcal disease in an Alaska native population, 1980 through 1986. JAMA JAMA abbr. Journal of the American Medical Association 1989;261:715-8. (6.) Gray B, Turner M, Dillon H. Epidemiologic studies of Streptococcus pneumoniae in infants: the effects of season and age on pneumococcal acquisition and carriage in the first 24 months of life. Am J Epidemiol 1982;116:692-703. (7.) Dowell SF. Seasonal variation in host susceptibility and cycles of certain infectious diseases. Emerg Infect Dis 2001;7:369-74. (8.) Demas G, Nelson R. Exogenous melatonin enhances cell-mediated, but not humoral hu·mor·al adj. 1. Relating to body fluids, especially serum. 2. Relating to or arising from any of the bodily humors. Humoral Pertaining to or derived from a body fluid. , immune function Immune function The state in which the body recognizes foreign materials and is able to neutralize them before they can do any harm. Mentioned in: Herbalism, Traditional Chinese, Stress Reduction in adult male deer mice deer mice Peromyscus maniculatus Public health The murine vector for Hantavirus. See Hantavirus. (Peromyscus maniculatus). J Biol Rhythms 1998;13:245-52. (9.) Calvo J, Rafil-El-Idrissi M, Pozo D, Guerrero J. Immunomodulatory role of melatonin: specific binding sites in human and rodent lymphoid lymphoid /lym·phoid/ (lim´foid) resembling or pertaining to lymph or tissue of the lymphoid system. lym·phoid adj. Of or relating to lymph or the lymphatic tissue where lymphocytes are formed. cells. J Pineal pineal /pin·e·al/ (pin´e-il) 1. pertaining to the pineal body. 2. shaped like a pine cone. pin·e·al adj. 1. Having the form of a pine cone. 2. Res 1995;18:119-26. (10.) Nelson R, Drazen D. Melatonin mediates seasonal adjustments in immune function. Reprod Nutr Dev 1999;39:383-98. (11). Wehr T, Moul D, Barbato G, Giesen H, Seidel sei·del n. A beer mug. [German, from Middle High German s  del, from Latin situla, bucket.]Noun 1. J, Barker C, et al. Conservation of photoperiod-responsive mechanisms in humans. Am J Physiol 1993;265:R846-57. (12.) Feigin RD, San Joaquin VH, Haymond MW, Wyatt RG. Daily periodicity periodicity /pe·ri·o·dic·i·ty/ (per?e-ah-dis´i-te) recurrence at regular intervals of time. pe·ri·o·dic·i·ty n. 1. of susceptibility of mice to pneumococcal infection. Nature 1969;224:379-80. (13.) Wongwiwat M, Sukapanit S, Triyanond C, Sawyer WD. Circadian rhythm of the resistance of mice to acute pneumococcal infection. Infect Immun 1972;5:442-8. (14.) Shackelford PG, Feigin RD. Periodicity of susceptibility to pneumococcal infection: influence of light and adrenocortical adrenocortical /adre·no·cor·ti·cal/ (-kor´ti-k'l) pertaining to or arising from the adrenal cortex. ad·re·no·cor·ti·cal adj. Of, relating to, or derived from the adrenal cortex. secretions. Science 1973;182:285-7. (15.) Jette LP, Delage G, Ringuette L, Allard R, De Wals P, Lamothe F, et al. Surveillance of invasive Streptococcus pneumoniae infection in the province of Quebec, Canada, from 1996 to 1998: 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. distribution, antimicrobial susceptibility, and clinical characteristics. J Clin Microbiol 2001;39:733-7. (16.) Kalima P, Emmanuel FX, Riordan T. Epidemiology of Streptococcus pneumoniae infections at the Edinburgh City Hospital: 1980-95. Epidemiol Infect 1999;122:251-7. (17.) Diez-Domingo J, Pereiro I, Morant A, Gimeno C, Lerma M, Oyaguez I, et al. Epidemiology of invasive Streptococcus pneumoniae infections in children in Spain, 1996-1998. J Infect 2002;45:139-43. (18.) Belshe RB, Gruber WC. Safety, efficacy and effectiveness of cold-adapted, live, attenuated Attenuated Alive but weakened; an attenuated microorganism can no longer produce disease. Mentioned in: Tuberculin Skin Test attenuated having undergone a process of attenuation. , trivalent trivalent /tri·va·lent/ (tri-va´lent) having a valence of three. tri·va·lent adj. Having valence 3. tri·va , intranasal in·tra·na·sal adj. Within the nose. influenza vaccine influenza vaccine Flu vaccine A vaccine recommended for those at high risk for serious complications from influenza: > age 65; Pts with chronic diseases of heart, lung or kidneys, DM, immunosuppression, severe anemia, nursing home and other chronic-care in adults and children. Philos Trans R Soc Lond B Biol Sci 2001;356:1947-51. (19.) Fedson DS. Pneumococcal vaccination for older adults: the first 20 years. Drugs Aging 1999;15:21-30. (20.) Hausdorff WP, Bryant J, Kloek C, Paradiso PR, Siber GR. The contribution of specific pneumococcal serogroups to different disease manifestations: implications for conjugate vaccine formulation and use, part II. Clin Infect Dis 2000;30:122-40. (21.) Reiter RJ. Neuroendocrine neuroendocrine /neu·ro·en·do·crine/ (-en´do-krin) pertaining to neural and endocrine influence, and particularly to the interaction between the nervous and endocrine systems. neu·ro·en·do·crine adj. effects of light. Int J Biometeorol 1991;35:169-75. (22.) Hardin P, Glossop N. The CRYs of flies and mice. Science 1999;286:2460-1. (23.) Reiter RJ. The melatonin rhythm: both a clock and a calendar. Experientia 1993;49:654-64. (24.) McCullers JA, Rehg JE. Lethal synergism synergism /syn·er·gism/ (sin´er-jizm) synergy. syn·er·gism n. Synergy. synergism between influenza virus influenza virus n. Any of three viruses of the genus Influenzavirus designated type A, type B, and type C, that cause influenza and influenzalike infections. and Streptococcus pneumoniae: characterization of a mouse model and the role of platelet-activating factor receptor The platelet-activating factor receptor is a G-protein coupled receptor which binds platelet-activating factor.[1][2] References 1. ^ Seyfried CE, Schweickart VL, Godiska R, Gray PW (1992). . J Infect Dis 2002;186:341-50. (25.) LeVine AM, Koeningsknecht V, Stark JM. Decreased pulmonary clearance of S. pneumoniae following influenza A influenza A n. Influenza caused by infection with a strain of influenza virus type A. influenza A Infectious disease An avian virus, especially of ducks–which in China live near the pig reservoir and 'vector'; infection in mice. J Virol Methods 2001;94:173-86. (26.) Sack R, Brandes R, Kendall A, Lewy A. Entrainment entrainment /en·train·ment/ (en-tran´ment) 1. a technique for identifying the slowest pacing necessary to terminate an arrhythmia, particularly atrial flutter. 2. of free-running circadian rhythms by melatonin in blind people. N Engl J Med 2000;343:1070-7. (27). Rojansky N, Brzezinski A, Schenker J. Seasonality in human reproduction: an update. Hum Reprod 1992;7:735-45. (28.) Wehr TA. Photoperiodism photoperiodism Response by an animal or plant to changes in daily, seasonal, or yearly cycles of light and darkness. Among animals, sleep, migration, reproduction, and the changing of coats or plumage are regulated to some extent by day length. in humans and other primates: evidence and implications. J Biol Rhythms 2001;16:348-64. (29.) Wehr TA, Giesen HA, Moul DE, Turner EH, Schwartz PJ. Suppression of men's responses to seasonal changes in day length by modern artificial lighting. Am J Physiol 1995;269:R173-8. (30.) Kaltoft, Zeuthen N, Konradsen HB. Epidemiology of invasive pneumococcal infections in children aged 0-6 years in Denmark: a 19-year nationwide surveillance study. Acta Paediatr Suppl 2000;89:3-10. (31.) Syriopoulou V, Daikos GL, Soulis K, Michos A, Alexandrou H, Pavlopoulou I, et al. Epidemiology of invasive childhood pneumococcal infections in Greece. Acta Paediatr Suppl 2000;89:30-4. (32.) Syrjanen RK, Kilpi TM, Kaijalainen TH, Herva EE, Takala AK. Nasopharyngeal carriage of Streptococcus pneumoniae in Finnish children younger than 2 years old. J Infect Dis 2001;184:451-9. (33.) Eskola J, Takala AK, Kela E, Pekkanen E, Kalliokoski R, Leinonen M. Epidemiology of invasive pneumococcal infections in children in Finland. JAMA 1992;268:3323-7. (34.) Dagan R, Engelhard D, Piccard E, Englehard D. Epidemiology of invasive childhood pneumococcal infections in Israel: the Israeli Pediatric Bacteremia and Meningitis Group. JAMA 1992;268:3328-32. (35.) Nuorti JP, Butler JC, Farley MM, Harrison LH, McGeer A, Kolczak MS, et al. Cigarette smoking and invasive pneumococcal disease. Active Bacterial Core Surveillance Team. N Engl J Med 2000;342:681-9. (36.) Breiman RF, Keller DW, Phelan MA, Sniadack DH, Stephens DS, Rimland Rimland is the maritime fringe of a country or continent; in particular, the densely populated western, southern, and eastern edges of the Eurasian continent. According to Nicholas John Spykman, who revisited Halford Mackinder's concepts of geopolitics, the Rimland is that D, et al. Evaluation of effectiveness of the 23-valent pneumococcal capsular cap·su·lar adj. Of, relating to, or resembling a capsule. Adj. 1. capsular - resembling a capsule; "the capsular ligament is a sac surrounding the articular cavity of a freely movable joint and attached to the bones" polysaccharide polysaccharide: see carbohydrate. polysaccharide Any of a large class of long-chain sugars composed of monosaccharides. Because the chains may be unbranched or branched and the monosaccharides may be of one, two, or occasionally more kinds, vaccine for HIV-infected patients. Arch Intern Med 2000;160:2633-8. Address for correspondence: Scott Dowell, International Emerging Infections Program, Department of Medical Sciences, Building 2, Ministry of Public Health, Tivanon Road, Nonthaburi 11000, Thailand; fax: 66-2-591-5753; email: sdowell@cdc.gov Scott F. Dowell, * ([dagger]) Cynthia G. Whitney, ([dagger]) Carolyn Wright, ([dagger]) Charles E. Rose, Jr., ([dagger]) and Anne Schuchat ([dagger]) * International Emerging Infections Program, Bangkok, Thailand; and ([dagger]) Centers for Disease Control and Prevention, Atlanta, Georgia, USA Dr. Dowell is the director of the International Emerging Infections Program in Thailand, the first of a planned network of such collaborations between the Centers for Disease Control and Prevention and host country ministries of health. His research interests include the seasonality of infectious diseases and the detection and control of emerging infections. |
|
||||||||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion