Invasive group A streptococcal infections, clinical manifestations and their predictors, Montreal 1995-2001.We identified 306 invasive group A streptococcal infections (IGASI) by passive population-based surveillance in Montreal, Canada, from 1995 to 2001. The average yearly reported incidence was 2.4 per 100,000 persons, with a 14% death rate. Among clinical manifestations, incidence of pneumonia increased from 0.06 per 100,000 in 1995 to 0.50 per 100,000 in 2000. Over a span of 7 years, the Years, The the seven decades of Eleanor Pargiter’s life. [Br. Lit.: Benét, 1109] See : Time odds of developing pneumonia increased (odds ratio [OR] = 1.21, 95% confidence interval confidence interval, n a statistical device used to determine the range within which an acceptable datum would fall. Confidence intervals are usually expressed in percentages, typically 95% or 99%. [CI] 1.0-1.5), while they decreased for soft-tissue infections (OR = 0.86, 95% CI 0.7-1.0). Serotypes M1 and M3 accounted for 30% of IGASI. However, neither 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. was significantly associated with specific clinical manifestations, which suggests that manifestation development among IGASI might be attributable to host or environmental factors rather than the pathogen. In our study, these factors included age, gender, underlying medical conditions See carpal tunnel syndrome, computer vision syndrome, dry eyes and deep vein thrombosis. , and living environment, yet none explained temporal changes in risk for pneumonia and soft-tissue infections. ********** Since the mid-1980s, concern has grown that invasive group A streptococcal infections (IGASI) have been increasing in incidence and severity (1-3). In particular, the emergence of streptococcal streptococcal /strep·to·coc·cal/ (-kok´al) pertaining to or caused by a streptococcus. Streptococcal (Streptococcus) Pertaining to any of the Streptococcus bacteria. toxic shock syndrome toxic shock syndrome (TSS). acute, sometimes fatal, disease characterized by high fever, nausea, diarrhea, lethargy, blotchy rash, and sudden drop in blood pressure. It is caused by Staphylococcus aureus, an exotoxin-producing bacteria (see toxin). (STSS STSS Space Tracking and Surveillance System STSS Surface Towed Search System ) during the 1980s is frequently cited as an example of increasing severity (4). Person-to-person transmission of Streptococcus pyogenes Streptococcus py·og·e·nes n. A bacterium that causes the formation of pus or of fatal septicemias. Streptococcus pyogenes A common bacterium that causes strep throat and can also cause tonsillitis. (the causative agent for IGASI) primarily occurs through respiratory droplets, although it may also spread through body secretions from an infected patient (5,6). Additionally, M serotypes or S. pyogenes that cause severe disease in a patient are more likely to cause severe disease in subsequent patients (6). These serotypes include 3 (M1, M3, and M18) that are strongly associated with pathogenicity (7). Nonetheless, some evidence indicates that persons with IGASI from the same strain of S. pyogenes may have different clinical manifestations of this disease (8,9). Other risk factors for IGASI include patient's age and underlying medical conditions (e.g., varicella varicella: see chicken pox. ). However, what factors may be associated with different clinical manifestations of IGASI is unclear (10-22). Some studies have examined the role of age, varicella, and chronic conditions such as diabetes mellitus diabetes mellitus Disorder of insufficient production of or reduced sensitivity to insulin. Insulin, synthesized in the islets of Langerhans (see Langerhans, islets of), is necessary to metabolize glucose. In diabetes, blood sugar levels increase (hyperglycemia). and alcoholism as predictors for necrotizing fasciitis necrotizing fasciitis n. Tissue death such as that associated with group A streptococcus infection. Necrotizing fasciitis , soft-tissue infections, and STSS (21-24), yet little is known regarding other IGASI determinants. In this study, we describe the status of both IGASI and their clinical manifestations on the island of Montreal The Island of Montreal (in French, île de Montréal), in extreme southwestern Quebec, Canada, is located at the confluence of the Saint Lawrence and Ottawa Rivers. It is separated from Île Jésus (Laval) by the Rivière des Prairies. . We also identify predictors for clinical manifestations and death due to IGASI, which could explain temporal fluctuations in the incidence and severity of this disease. Methods Surveillance of IGASI Data used in our study were collected during passive surveillance of IGASI among all residents of the island of Montreal (population = 1.8 million: 21,529 births per year from 1996 to 1999 [25]). Cases that occurred and were reported from January 1, 1995 (the year IGASI became a notifiable disease no·ti·fi·a·ble disease n. A disease that must be reported to public health authorities at the time it is diagnosed because it is potentially dangerous to human or animal health. Also called reportable disease. in the province of Quebec), through February 28, 2002, were included in our study. Once the public health department had been notified of a potential case, usually by a hospital laboratory, a 6-part questionnaire was completed by using information from the physician or infection control nurse of the health center where the case-patient was identified or treated. Questions included the patient's demographic information, general medical information, laboratory results, diagnostic criteria, and medical history before the IGASI. With this information, all IGASI were classified into 1 of 3 groups: confirmed cases (S. pyogenes isolated from a normally sterile site), clinical cases (S. pyogenes isolated from a nonsterile site and toxic shock not attributable to any other cause), or noncases. Data on confirmed and clinical cases were entered into the regional notifiable notifiable /no·ti·fi·a·ble/ (no?ti-fi´ah-b'l) necessary to be reported to a government health agency. notifiable necessary to be reported to the relevant government authority. Said of individual diseases. infections computer database. This database was used for our study. Laboratory Assessment of IGASI Isolates Initial laboratory confirmation of S. pyogenes was made by using standard methods (26). Isolates were then collected and sent to the Canadian National Center for Streptococcus streptococcus (strĕp'təkŏk`əs), any of a group of gram-positive bacteria, genus Streptococcus, some of which cause disease. in Edmonton for further testing of the opacity Refers to being "opaque," which means to prevent light from shining through. For example, in an image editing program, the opacity level for some function might range from completely transparent (0) to completely opaque (100). factor, as well as M, T, and R surface proteins. The methods have been described in detail elsewhere (27). Briefly, antiopacity factor (AOF AOF Academy Of Finance (New York State Department of Education) AOF Afrique Occidentale Française (French) AOF Avon Old Farms (Avon, CT school) ) typing was performed on any positive opacity factor sample. Although AOF testing does not possess the same type specificity as M typing, it is frequently used because of difficulties in producing anti-sera for certain M serotypes. Its use has been validated for most strains identified in industrialized in·dus·tri·al·ize v. in·dus·tri·al·ized, in·dus·tri·al·iz·ing, in·dus·tri·al·iz·es v.tr. 1. To develop industry in (a country or society, for example). 2. countries. However, since 2000, the national center has supplemented AOF testing with emm gene sequencing for some nontypeable M serotype samples. Data on these results were not available for this study. Classification of Outcomes For our study, we looked at 5 dichotomous di·chot·o·mous adj. 1. Divided or dividing into two parts or classifications. 2. Characterized by dichotomy. di·chot outcomes: STSS, soft-tissue infections, 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. , pneumonia, and death attributable to IGASI. All were invasive and defined in accordance with the classification of group A streptococcal infections (28). STSS was defined 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 1993 Working Group on Severe Streptococcal Infections Streptococcal Infections Definition Streptococcal (strep) infections are communicable diseases that develop when bacteria normally found on the skin or in the intestines, mouth, nose, reproductive tract, or urinary tract invade other parts of the body consensus definition for a probable or confirmed case (28). Soft-tissue outcomes included fasciitis fasciitis /fas·ci·itis/ (fas-e-i´tis) inflammation of a fascia. eosinophilic fasciitis , myositis myositis Inflammation of muscle tissue, often from bacterial, viral, or parasitic infection but sometimes of unknown origin. Most types destroy muscle and surrounding tissue. Bacteria may directly infect muscle (usually after injury) or produce substances toxic to it. , cellulitis Cellulitis Definition Cellulitis is a spreading bacterial infection just below the skin surface. It is most commonly caused by Streptococcus pyogenes or Staphylococcus aureus. , or erysipelas erysipelas (ĕrəsĭp`ələs), acute infection of the skin characterized by a sharply demarcated, shiny red swelling, accompanied by high fever and a feeling of general illness. . Bacteremia was characterized by a positive hemoculture, without any source of infection. Pneumonia attributable to IGASI was based on a clinical diagnosis made by the treating physician and could include STSS with respiratory distress Respiratory distress A condition in which patients with lung disease are not able to get enough oxygen. Mentioned in: Lung Cancer, Non-Small Cell . Classification of Independent Variables Age, calendar month, and year in which the IGASI case occurred were included in our study as continuous variables. Gender (male or female); underlying medical conditions (drug use, alcohol abuse, varicella, prior trauma or wound, cancer, and immunosuppression immunosuppression Suppression of immunity with drugs, usually to prevent rejection of an organ transplant. Its aim is to allow the recipient to accept the organ permanently with no unpleasant side effects. ); type of living environment (hospital, daycare or preschool, school, work, other, and not available); as well as M, T, and R surface protein serotypes (presence or absence of a specific serotype) were all included as dichotomous variables. For those serotypes with identical strength of association with a given outcome, a single new dichotomous variable was created to represent the presence of one or the other (e.g., presence of either serotype M12 or M28 versus absence of both serotypes). Finally, since predominant site of infection (bacteremia, fasciitis, cellulitis or erysipelas, myositis, peritonitis peritonitis (pĕr'ĭtənī`tĭs), acute or chronic inflammation of the peritoneum, the membrane that lines the abdominal cavity and surrounds the internal organs. , respiratory manifestations, septic arthritis septic arthritis Acute inflammation of one or more joints caused by infection. Suppurative arthritis may follow certain bacterial infections; joints become swollen, hot, sore, and filled with pus, which erodes their cartilage, causing permanent damage if not promptly treated , and other) was partially used in distinguishing between bacteremia, pneumonia, and soft-tissue infections, this variable was only considered a covariate of interest in models with STSS and death as their outcomes. Statistical Analysis The incidence (per 100,000), death rate attributable to IGASI, and proportion of IGASI cases due to a specific clinical manifestation were estimated by using data collected from 1995 through 2001. Incidence and proportion estimates were not calculated for 2002, given that only 2 months of data were available. Projected annual population estimates for Montreal were used when calculating the reported annual incidence of IGASI (25). Incidence and proportion of IGASI cases stratified stratified /strat·i·fied/ (strat´i-fid) formed or arranged in layers. strat·i·fied adj. Arranged in the form of layers or strata. by gender, calendar year, and age group were then calculated. Finally, temporal trends were assessed by using the chi-square test chi-square test: see statistics. for trend. For the inferential in·fer·en·tial adj. 1. Of, relating to, or involving inference. 2. Derived or capable of being derived by inference. in component of our study, we conducted unconditional 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. 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. version 8.0 (SAS Institute SAS Institute Inc., headquartered in Cary, North Carolina, USA, has been a major producer of software since it was founded in 1976 by Anthony Barr, James Goodnight, John Sall and Jane Helwig. , Cary, NC, USA). This test was initially performed by including in the model variables with a univariate likelihood ratio p value [less than or equal to] 0.20. Among these factors, those with the highest multivariate Wald chi-square p value were then individually dropped, until the lowest Akaike Information Criterion Akaike's information criterion, developed by Hirotsugu Akaike under the name of "an information criterion" (AIC) in 1971 and proposed in Akaike (1974), is a measure of the goodness of fit of an estimated statistical model. It is grounded in the concept of entropy. value was attained. The McGill University Faculty of Medicine The Faculty of Medicine is one of the constituent faculties of McGill University. It was established in 1823 as the Montreal Medical Institution, and became the first faculty of McGill College in 1829. It was the first medical faculty to be established in Canada. Institutional Review Board approved the study. Results From 1995 through 2001, a total of 306 cases of IGASI were reported on the island of Montreal. The incidence of IGASI rose from 1.05 per 100,000 (19 cases) in 1995 to 1.71 (31 cases) in 1996 and 3.32 (60 cases) in 1997. After 1997, the incidence appeared to stabilize: 2.77 (50 cases) in 1998, 2.50 (45 cases) in 1999, 3.21 (58 cases) in 2000, and 2.37 (43 cases) in 2001. The average annual incidence of IGASI was 2.4 per 100,000. Most IGASI cases occurred in persons 240 years of age (172 [56%] of 306 cases) (Figure I). The median age of patients was 46 years (range 1.5 months to 92 years). Of the 306 reported IGASI cases, 112 (37%) were soft-tissue infections, 84 (28%) bacteremia, 32 (10%) pneumonia, and 29 (10%) STSS. Among patients with soft-tissue infections, 6 (5%) of 112 cases had myositis, 31 (28%) had cellulitis, and 76 (68%) had necrotizing fasciitis; 1 patient had both cellulitis and necrotizing fasciitis. We did not identify any significant trend over time with regard to the proportion of different clinical manifestations. As for specific clinical manifestations of IGASI, we estimated that bacteremia occurred, on average, in 0.66 per 100,000 persons each year, STSS in 0.23 per 100,000, soft-tissue infections in 0.89 per 100,000, and pneumonia in 0.25 per 100,000. The predominant M serotypes included M1 (22%), M3 (12%), M28 (9%), M12 (8%), M4 (6%), and M6 (4%). Remaining serotypes accounted for <3% of isolates. Twenty percent of samples were nontypeable. Pneumonia The incidence of pneumonia appeared to significantly increase over time ([chi square chi square (kī), n a nonparametric statistic used with discrete data in the form of frequency count (nominal data) or percentages or proportions that can be reduced to frequencies. ] = 5.65, p = 0.018), with an annual incidence of 0.06 per 100,000 in 1995 and 1996, 0.28 in 1997 and 1998, 0.39 in 1999, 0.50 in 2000, and 0.22 in 2001. This finding was confirmed by the odds of having pneumonia significantly increasing with each successive calendar year (adjusted odds ratio [aOR] = 1.21, 95% confidence interval [CI] 1.0-1.5). The proportion of women and girls with pneumonia (Figure 2) also significantly increased ([chi square] = 5.03, p = 0.025), with women more likely to have pneumonia as compared to men (aOR 2.20, 95% CI 1.0-4.9). Gender was not associated with year in which the case occurred. STSS We did not detect a significant secular trend secular trend The relatively consistent movement of a variable over a long period. A stock in a secular uptrend is an indicator that the security has experienced an extended period of rising prices. in the occurrence of STSS ([chi square] = 0.54, p = 0.46). Persons who abused alcohol (aOR 7.66, 95% CI 1.9-30.3), were infected with serotype M9 (aOR 39.98, 95% CI 1.9-836), or who had fasciitis (aOR 10.21, 95% CI 4.1-25.7) were at a significantly greater risk of having STSS. Soft-tissue Infections No significant secular trend was apparent in the incidence of soft-tissue infections ([chi square] = 0.48, p = 0.49). However the odds of developing this manifestation as opposed to another significantly decreased with each successive calendar year (aOR 0.86, 95% CI 0.7-1.0). Drug use was weakly associated with soft-tissue infections (unadjusted OR 1.86, 95% CI 0.8-4.4). Given that trauma was a significant univariate risk marker for soft-tissue infections (OR 2.78, 95% CI 1.6-4.8), this association might have been attributable to injection drug use resulting in a trauma or wound. However, in our study, no correlation was seen between drug use and trauma (r = 0.002, p = 0.97). Furthermore, the association between drug use and soft-tissue infections became significant after adjusting for trauma or wound (OR 2.83, 95% CI 1.0-8.0). Varicella and serotypes M6, M12, or M22 were significant predictors for developing soft-tissue infections with aORs of 5.69 (95% CI 1.4-23.1), 4.3 (95% CI 1.1-16.7), 9.1 (95% CI 1.3-64.5), and 27.9 (95% CI 2.7-289), respectively. None of these factors were correlated with calendar year. Bacteremia The incidence of bacteremia did not appear to change over time ([chi square] = 0.56, p = 0.45). Only protective factors against bacteremia were identified: attending a school (aOR 0.15, 95% CI 0.0-0.7) and trauma or wound (aOR 0.4, 95% CI 0.2-0.9). Death Due to IGASI The death ratio from IGASI was 15% (42 deaths among 306 cases). The highest proportion of known deaths was among patients with pneumonia (38%, 12 deaths among 32 pneumonia cases), followed by STSS (35%, 10 among 29), bacteremia (17%, 14 among 84), and soft-tissue infections (10%, 11 among 112). Within soft-tissue infections, necrotizing fasciitis had the highest risk for death among all age groups (16%, 5 deaths among 31 cases) followed by cellulitis and erysipelas (8%, 6 among 76). For myositis, among the 6 cases identified during a 7-year period, no deaths were recorded. No secular trends for death ratios were seen for any of the clinical manifestations of IGASI. Among those who died of IGASI, the most common serotypes were M1 (34%) and T1 (30%); however, neither was significantly associated with death (unadjusted OR for M1: 1.86, 95% CI 0.9-4.0; T1: 1.91, 95% CI 0.9-4.1). Predictors for death, after adjustment, are presented in the Table. Discussion When the results of our study are examined, several methodologic considerations must be taken into account. First, given that the administration of questionnaires for this study was not standardized, nondifferential misclassification could explain why certain factors in this study were not identified as potential markers for clinical manifestation outcomes. An additional limitation of our study was the low statistical power. For some measures of association, the probability of detecting a true association was estimated to be as low as 3%. As a result, while this study can identify potential predictors, it cannot exclude them. Additionally, given that this study was to a certain extent hypothesis-generating, some of the predictors found in this study (particularly those with weak associations) may have occurred by chance. Considering that an [alpha] level of 0.05 was used when testing [approximately equal to] 200 associations, at least 10 significant factors would be expected to be identified by chance. In our study, we identified 25 factors to be significantly associated with specific IGASI manifestations. IGASI and STSS may be increasing in both incidence and severity (4). In particular, increasing trends in the IGASI incidence 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. have been recorded in several hospital-based studies (29). Furthermore, past European studies European studies is a field of study offered by many academic colleges and universities that focuses on the current development of European integration. It basically consists of a combination of several subjects, including European history, European law, economics and sociology. noted a general increase in the incidence, although little evidence shows a trend occurring in the United States (14,30-32). While we documented a trend in the annual incidence of IGASI in Montreal during the first 3 years of our study, the incidence stabilized from 1997 onwards, which suggests that an initial rise in incidence might be attributable to underreporting immediately after IGASI became a notifiable disease. During the 7 years of our study, mortality did not appear to significantly change. Additionally, we could not identify any significant trends in the incidence and mortality of STSS. We did, however, ascertain that pneumonia attributable to IGASI significantly increased during 6 of the 7 years of our study. This finding was particularly evident among women. Our findings agree with those of a study in Ontario, which identified an increasing trend for pneumonia attributable to GAS from 1992 to 1999 (33). To the best of our knowledge, no research has been published on transmission rates for the different clinical manifestations of IGASI. However, the primary mode of person-to-person transmission of S. pyogenes is through respiratory droplets (5,6). Additionally, S. pyogenes that causes severe disease in one patient is more likely to cause severe disease in subsequent patients (6). Considering these previous study findings, one could hypothesize hy·poth·e·size v. hy·poth·e·sized, hy·poth·e·siz·ing, hy·poth·e·siz·es v.tr. To assert as a hypothesis. v.intr. To form a hypothesis. that secondary contacts of patients with respiratory manifestations might be more likely to acquire an infection leading to severe disease, compared to contacts of patients with other IGASI manifestations. Even though IGASI is a reportable disease re·port·a·ble disease n. See notifiable disease. , our results for pneumonia may be an underestimate of the true values. Given that <1% of community-acquired pneumonia community-acquired pneumonia Pneumonia caused by an infection currently present in the community; CAP is the most common cause of infectious death–US, and number 6 killer overall; of the 57% of CAPs in which a pathogen is identified, S pneumoniae is attributed to S. pyogenes (34), pneumonia caused by this bacterium may have been ascribed to other causes and hence not reported. Our findings are further complicated by difficulties in defining pneumonia (33). No standard clinical definition distinguishes IGAS IGAS I've Got A Secret (game show) IGAS International Graphic Arts Society pneumonia from respiratory distress caused by STSS. Although both clinical manifestations might differ with regard to pathophysiology pathophysiology /patho·phys·i·ol·o·gy/ (-fiz?e-ol´ah-je) the physiology of disordered function. path·o·phys·i·ol·o·gy n. 1. , given that prophylaxis prophylaxis (prō'fĭlăk`sĭs), measures designed to prevent the occurrence of disease or its dissemination. Some examples of prophylaxis are immunization against serious diseases such as smallpox or diphtheria; quarantine to confine is required for secondary contacts of either manifestation in Quebec, difficulties in distinguishing between these manifestations will probably not affect the public health implications of our findings. With regard to the generalizability of our results, when comparing our findings with previously published studies, we did not detect any geographic differences in the incidence of IGASI (17). Our data showed that the yearly incidence of IGASI in Montreal (1.0-3.3 per 100,000) was similar to the incidence of IGASI in British Columbia British Columbia, province (2001 pop. 3,907,738), 366,255 sq mi (948,600 sq km), including 6,976 sq mi (18,068 sq km) of water surface, W Canada. Geography (20), Ontario (16), Israel (35), Sweden (19,22), and the United States (14,18). Furthermore, death rates from IGASI in Montreal were comparable to death rates calculated for British Colombia (20) and Sweden (19,22). Only Arizona appeared to have a higher death rate due to IGASI, at 20% (3). This difference might be attributable to the elevated prevalence of diabetes (a risk factor for IGASI) in the Arizona community studied (3). Along with these descriptive findings, we identified several factors associated with clinical manifestations of IGAS and associated death. Having varicella before IGASI increased the risk of developing a soft-tissue infection 6 times and the risk of dying 5 times. Although we could not identify any literature linking varicella infection with soft-tissue infections, given that soft-tissue infections are the predominant clinical manifestation of IGASI, our findings support previous research that suggests that varicella might be an important risk factor for developing IGASI (16,36). Soft-tissue infections were almost twice as likely to develop in persons using drugs. This association could be attributable to injection drug use; however, it remains even after controlling for trauma. One explanation for this unexpected finding could be nondifferential misclassification. A subanalysis of drug use showed that 23% of patients indicated a trauma or wound. However, we were unable to determine the reliability of reporting. While a patient could have affirmatively answered to drug use, a wound inflicted by intravenous drug use intravenous drug use Intravenous drug abuse The habitual IV injection of drugs of abuse Epidemiology In the US ± 2.5 million–population ± 235 million have used IVDs Infections Pyogenic–eg, endocarditis, pneumonia, sepsis Common agents may not have been considered sufficiently severe to indicate a trauma or wound. Our descriptive analysis appears to support previous research findings that those <1 year of age and those 260 years of age have the highest incidence of IGASI (3,21-23). However, previous studies also suggest that children might have a lower incidence of STSS and be at a decreased risk of dying of IGASI (21). This research includes a study that identified a nonsignificant non·sig·nif·i·cant adj. 1. Not significant. 2. Having, producing, or being a value obtained from a statistical test that lies within the limits for being of random occurrence. 5-fold rise in risk for death per year increase in age. In contrast, our study showed a 2%-4% increase. Our study finding that M1 and M3 accounted for >30% of all isolates tested for M surface proteins was consistent with previous studies that reported these 2 M serotypes as the most common for IGASI (3,15,16,23,24). This finding is also consistent with the choice of serotypes to include in streptococcal vaccines being evaluated at the moment. The hexavalent hexavalent having a valence of six. vaccine (37) is composed of serotypes 1, 3, 5, 6, 19, and 24; these types represent 38% of isolates in our study. The types in the 26-valent vaccine (38) represent 70% of our isolates. This number includes M1 with 22%; M3 with 12%; M28 with 9%; M12 with 8%; M6 with 4%; M22 and M11 each with 3%; M89 with 2%; and M75, M2, M77, M43, M5, M76, and M33 each with 1%. Furthermore, our study confirmed univariate model findings from a study by O'Brien et al. that found M3 to be significantly associated with STSS (14). However, this association did not remain in our multivariate analysis multivariate analysis, n a statistical approach used to evaluate multiple variables. multivariate analysis, n a set of techniques used when variation in several variables has to be studied simultaneously. . Our findings would thus appear to concur with those of a another (case-control) study that found while M1 and M3 may be significant risk factors for IGASI, once a person is infected, environmental and host factors might have a role in determining the type of invasive disease manifestations (8,9). This finding could explain why IGASI may develop in patients infected with the same strain of GAS but have different clinical manifestations of the disease (e.g., STSS versus pneumonia) (9). Future epidemiologic studies of risk factors for clinical manifestations of IGASI might be designed to look at risk factors separately in patients identified with M1 and M3 serotypes. By doing so, nondifferential misclassification might be minimized and risk factors with weaker associations might be more easily identified.
Table. Adjusted odds ratio (OR) for factors associated
with death attributable to invasive group A streptococcal
infections, Montreal, Canada, 1995-2002
Variable OR (95% CI) *
Age (y) 1.04 (1.0-1.1)
([dagger])
Underlying medical conditions
No cancer Referent
Cancer 4.14 (1.6-10.5)
Primary site of infection
Not cellulitis Referent
Cellulitis 0.38 (0.1-1.0)
Not pneumonia Referent
Pneumonia 3.62 (1.4-9.0)
Living environment
Not working or living Referent
in hospital
Working or living 3.71 (1.0-13.6)
in hospital
M serotypes
Not M2 Referent
M2 10.69 (0.5-220)
* CI, confidence interval.
([dagger]) Increase in risk per increase in year of age.
Acknowledgments We thank Lucie Bedard for providing permission to use the database to conduct this study and for her helpful comments on an initial draft of the protocol, Louise Marcotte for preparing the dataset, Gilles Paradis for his helpful comments on an initial draft of this paper, Paul Rivest for being available for questions regarding the surveillance procedure, and Agnes Beaume for her administrative assistance. References (1.) Stevens DL, Tanner MH, Winship J, Swans R, Ries KM, Schlievert PM, et al. Severe group A streptococcal infections associated with a toxic shock-like syndrome toxic shock-like syndrome 'Jim Henson's' disease An epidemic infection caused by a highly virulent, antibiotic-resistant strain of group A streptococcus, which begins as a mild skin infection or 'strep throat' and rapidly progresses to high fever, hypotension, . N Engl J Med. 1989;321:1-7. (2.) Stevens DL. Invasive group A streptococcus group A streptococcus n. 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Maria-Graciela Hollm-Delgado, * ([dagger]) Robert Allard, * ([dagger])([double dagger double dagger n. A reference mark (  ) used in printing and writing. Also called diesis.Noun 1. ]) and Pierre A. Pilon * ([double dagger]) * Direction de Sante Publique, Montreal, Quebec, Canada; ([dagger]) McGill University, Montreal, Quebec, Canada; and ([double dagger]) Universite de Montreal, Quebec, Canada Address for correspondence: Maria-Graciela Hollm, Departement de Medecine Sociale et Preventive, Universite de Montreal, C.P. 6128, succ Centre-ville, Montreal (Quebec), H3C 3J7, Canada: fax: 511-464-0781; email: maria-graciela.hollm@mail.mcgill.ca Ms. Hollm-Delgado is a doctoral student in public health at the Universite de Montreal. This paper originates from research she completed at the Direction de Sante Publique (Montreal, Canada) while earning her Masters degree in epidemiology from McGill University. Her current research interests include respiratory infections and antimicrobial resistance. |
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