Last data update: Dec 02, 2024. (Total: 48272 publications since 2009)
Records 1-26 (of 26 Records) |
Query Trace: Zulz T[original query] |
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Epidemiology of invasive Haemophilus influenzae serotype a disease in the North American Arctic, 2006-2017
Zulz T , Huang G , Rudolph K , DeByle C , Tsang R , Desai S , Massey S , Bruce MG . Int J Circumpolar Health 2022 81 (1) 2150382 Invasive Haemophilus influenzae type a (iHia) disease was detected in Alaska and Northern Canada in 2002 and 2000, respectively. From 2006 to 2017, 164 iHia cases (Alaska=53, Northern Canada=111) were reported. Rates of iHia disease per 100,000 persons were higher in Northern Canada compared to Alaska and were significantly higher in Indigenous (Alaska 2.8, Northern Canada 9.5) compared to non-Indigenous populations (Alaska 0.1, Northern Canada=0.4). Disease rates were highest in Indigenous children <2 years of age (Alaska 56.2, Northern Canada=144.1) and significantly higher than in non-Indigenous children <2 (Alaska 0.1, Northern Canada 0.4). The most common clinical presentation in children <5 years was meningitis of age and pneumonia in persons ≥5 years old. Most patients were hospitalised (Alaska=87%, Northern Canada=89%) and fatality was similar (Alaska=11%, Northern Canada=10%). MLST testing showed sequence types ST23 and ST576 in Northern Canada and ST576, ST23 and ST56 in Alaska. Alaska and Northern Canada have high rates of iHia disease. A vaccine is needed in these regions to protect young children. |
Invasive group A streptococcal disease in pregnant women and young children: a systematic review and meta-analysis
Sherwood E , Vergnano S , Kakuchi I , Bruce MG , Chaurasia S , David S , Dramowski A , Georges S , Guy R , Lamagni T , Levy-Bruhl D , Lyytikäinen O , Naus M , Okaro JO , Oppegaard O , Vestrheim DF , Zulz T , Steer AC , Van Beneden CA , Seale AC . Lancet Infect Dis 2022 22 (7) 1076-1088 BACKGROUND: The incidence of invasive disease caused by group A streptococcus (GAS) has increased in multiple countries in the past 15 years. However, despite these reports, to the best of our knowledge, no systematic reviews and combined estimates of the incidence of invasive GAS have been done in key high-risk groups. To address this, we estimated the incidence of invasive GAS disease, including death and disability outcomes, among two high-risk groups-namely, pregnant women and children younger than 5 years. METHODS: We did a systematic review and meta-analyses on invasive GAS outcomes, including incidence, case fatality risks, and neurodevelopmental impairment risk, among pregnant women, neonates (younger than 28 days), infants (younger than 1 year), and children (younger than 5 years) worldwide and by income region. We searched several databases for articles published from Jan 1, 2000, to June 3, 2020, for publications that reported invasive GAS outcomes, and we sought unpublished data from an investigator group of collaborators. We included studies with data on invasive GAS cases, defined as laboratory isolation of Streptococcus pyogenes from any normally sterile site, or isolation of S pyogenes from a non-sterile site in a patient with necrotising fasciitis or streptococcal toxic shock syndrome. For inclusion in pooled incidence estimates, studies had to report a population denominator, and for inclusion in pooled estimates of case fatality risk, studies had to report aggregate data on the outcome of interest and the total number of cases included as a denominator. We excluded studies focusing on groups at very high risk (eg, only preterm infants). We assessed heterogeneity with I(2). FINDINGS: Of the 950 published articles and 29 unpublished datasets identified, 20 studies (seven unpublished; 3829 cases of invasive GAS) from 12 countries provided sufficient data to be included in pooled estimates of outcomes. We did not identify studies reporting invasive GAS incidence among pregnant women in low-income and middle-income countries (LMICs) nor any reporting neurodevelopmental impairment after invasive GAS in LMICs. In nine studies from high-income countries (HICs) that reported invasive GAS in pregnancy and the post-partum period, invasive GAS incidence was 0·12 per 1000 livebirths (95% CI 0·11 to 0·14; I(2)=100%). Invasive GAS incidence was 0·04 per 1000 livebirths (0·03 to 0·05; I(2)=100%; 11 studies) for neonates, 0·13 per 1000 livebirths (0·10 to 0·16; I(2)=100%; ten studies) for infants, and 0·09 per 1000 person-years (95% CI 0·07 to 0·10; I(2)=100%; nine studies) for children worldwide; 0·12 per 1000 livebirths (95% CI 0·00 to 0·24; I(2)=100%; three studies) in neonates, 0·33 per 1000 livebirths (-0·22 to 0·88; I(2)=100%; two studies) in infants, and 0·22 per 1000 person-years (0·13 to 0·31; I(2)=100%; two studies) in children in LMICs; and 0·02 per 1000 livebirths (0·00 to 0·03; I(2)=100%; eight studies) in neonates, 0·08 per 1000 livebirths (0·05 to 0·11; I(2)=100%; eight studies) in infants, and 0·05 per 1000 person-years (0·03 to 0·06; I(2)=100%; seven studies) in children for HICs. Case fatality risks were high, particularly among neonates in LMICs (61% [95% CI 33 to 89]; I(2)=54%; two studies). INTERPRETATION: We found a substantial burden of invasive GAS among young children. In LMICs, little data were available for neonates and children and no data were available for pregnant women. Incidences of invasive GAS are likely to be underestimates, particularly in LMICs, due to low GAS surveillance. It is essential to improve available data to inform development of prevention and management strategies for invasive GAS. FUNDING: Wellcome Trust. |
Evaluating a Cluster and the Overall Trend of Invasive Haemophilus influenzae Serotype b in Alaska 2005-2019.
Nolen LD , Topaz N , Miernyk K , Bressler S , Massay SC , Geist M , Zulz T , Singleton R . Pediatr Infect Dis J 2022 41 (4) e120-e125 BACKGROUND: In 2019, 5 cases of invasive Haemophilus influenzae serotype b (Hib) occurred in the Anchorage region of Alaska over a period of 16 days. No cases had occurred in Alaska in the preceding 26 months. METHODS: Alaska Hib isolates from 2005 through 2019 were analyzed using whole-genome sequencing (WGS). Rates were compared to the CDC's Active Bacterial Core surveillance (ABCs) data. RESULTS: A total of 33 cases of invasive Hib occurred in Alaska from 2005 through 2019. Of the 5 cases associated with the cluster, 2 (40%) occurred in adults and all occurred in the Anchorage region. In contrast, only 14% (4/28) of the noncluster cases occurred in this region (P < 0.01). Two cluster cases were linked epidemiologically and the bacteria were nearly identical. The other 3 cluster cases were caused by 3 genetically distinct bacteria. When the full period was evaluated, the unadjusted rate of invasive Hib disease in Alaska was 15.5 times higher in Alaska Native (AN) people than non-AN people [1.3/100,000 vs. 0.07/100,000, 95% confidence intervals (CI): 10.2-22.5). The age-adjusted rate of invasive Hib disease in Alaska was 9.4 times higher than the ABCs rate (95% CI: 6.3-14.1). CONCLUSIONS: While clustered in time and space, the 5 cases in 2019 were not due to a single bacterial strain. AN people continue to have elevated rates of invasive Hib infection compared to both non-AN people in Alaska and the ABCs population. |
Epidemiology of invasive Haemophilus influenzae serotype a disease - United States, 2008-2017
Soeters HM , Oliver SE , Plumb ID , Blain AE , Zulz T , Simons BC , Barnes M , Farley MM , Harrison LH , Lynfield R , Massay S , McLaughlin J , Muse AG , Petit S , Schaffner W , Thomas A , Torres S , Watt J , Pondo T , Whaley MJ , Hu F , Wang X , Briere EC , Bruce MG . Clin Infect Dis 2020 73 (2) e371-e379 BACKGROUND: Haemophilus influenzae serotype a (Hia) can cause invasive disease similar to serotype b; no Hia vaccine is available. We describe the epidemiology of invasive Hia disease in the United States overall and specifically in Alaska during 2008-2017. METHODS: Active population- and laboratory-based surveillance for invasive Hia disease was conducted through Active Bacterial Core surveillance sites and from Alaska statewide invasive bacterial disease surveillance. Sterile-site isolates were serotyped via slide agglutination or real-time polymerase chain reaction. Incidences in cases per 100,000 were calculated. RESULTS: From 2008-2017, an estimated average of 306 invasive Hia disease cases occurred annually in the United States (estimated annual incidence: 0.10); incidence increased by an average of 11.1% annually. Overall, 42.7% of cases were in children aged <5 years (incidence: 0.64), with highest incidence among children aged <1 year (1.60). Case fatality was 7.8% overall and was highest among adults aged >/=65 years (15.1%). Among children aged <5 years, incidence was 17 times higher among American Indians and Alaska Native (AI/AN) children (8.29) than among children of all other races combined (0.49). In Alaska, incidences among all ages (0.68) and among children aged <1 year (24.73) were nearly 6 and 14 times higher, respectively, than corresponding U.S. incidences. Case fatality in Alaska was 10.2%, and the vast majority (93.9%) of cases occurred among AI/AN. CONCLUSIONS: Incidence of invasive Hia disease has increased since 2008, with the highest burden among AI/AN children. These data can inform prevention strategies, including Hia vaccine development. |
Risk for invasive streptococcal infections among adults experiencing homelessness, Anchorage, Alaska, USA, 2002-2015
Mosites E , Zulz T , Bruden D , Nolen L , Frick A , Castrodale L , McLaughlin J , Van Beneden C , Hennessy TW , Bruce MG . Emerg Infect Dis 2019 25 (10) 1911-8 The risk for invasive streptococcal infection has not been clearly quantified among persons experiencing homelessness (PEH). We compared the incidence of detected cases of invasive group A Streptococcus infection, group B Streptococcus infection, and Streptococcus pneumoniae (pneumococcal) infection among PEH with that among the general population in Anchorage, Alaska, USA, during 2002-2015. We used data from the Centers for Disease Control and Prevention's Arctic Investigations Program surveillance system, the US Census, and the Anchorage Point-in-Time count (a yearly census of PEH). We detected a disproportionately high incidence of invasive streptococcal disease in Anchorage among PEH. Compared with the general population, PEH were 53.3 times as likely to have invasive group A Streptococcus infection, 6.9 times as likely to have invasive group B Streptococcus infection, and 36.3 times as likely to have invasive pneumococcal infection. Infection control in shelters, pneumococcal vaccination, and infection monitoring could help protect the health of this vulnerable group. |
Tuberculosis in the circumpolar region, 2006-2012
Bourgeois AC , Zulz T , Bruce MG , Stenz F , Koch A , Parkinson A , Hennessy T , Cooper M , Newberry C , Randell E , Proulx JF , Hanley BE , Soini H , Arnesen TM , Mariandyshev A , Jonsson J , Soborg B , Wolfe J , Balancev G , De Neergaard RB , Archibald CP . Int J Tuberc Lung Dis 2018 22 (6) 641-648 Setting: The northern circumpolar jurisdictions Canada (Northwest Territories, Nunavik, Nunavut, Yukon), Finland, Greenland, Norway, Russian Federation (Arkhangelsk), Sweden and the United States (Alaska). Objective : To describe and compare demographic, clinical and laboratory characteristics, including drug resistance and treatment completion, of tuberculosis (TB) cases in the northern circumpolar populations. Design: Descriptive analysis of all active TB cases reported from 2006 to 2012 for incidence rate (IR), age and sex distribution, sputum smear and diagnostic site characteristics, drug resistance and treatment completion rates. Results : The annual IR of TB disease ranged from a low of 4.3 per 100 000 population in Northern Sweden to a high of 199.5/100 000 in Nunavik, QC, Canada. For all jurisdictions, IR was higher for males than for females. Yukon had the highest proportion of new cases compared with retreatment cases (96.6%). Alaska reported the highest percentage of laboratory-confirmed cases (87.4%). Smear-positive pulmonary cases ranged from 25.8% to 65.2%. Multidrug-resistant cases ranged from 0% (Northern Canada) to 46.3% (Arkhangelsk). Treatment outcome data, available up to 2011, demonstrated >80% treatment completion for four of the 10 jurisdictions. Conclusion: TB remains a serious public health issue in the circumpolar regions. Surveillance data contribute toward a better understanding and improved control of TB in the north. |
Outbreak of invasive infections from subtype emm26.3 group A Streptococcus among homeless adults-Anchorage, Alaska, 2016-2017.
Mosites E , Frick A , Gounder P , Castrodale L , Li Y , Rudolph K , Hurlburt D , Lecy KD , Zulz T , Adebanjo T , Onukwube J , Beall B , Van Beneden CA , Hennessy T , McLaughlin J , Bruce MG . Clin Infect Dis 2018 66 (7) 1068-1074 Background: In 2016, we detected an outbreak of group A Streptococcus (GAS) invasive infections among the estimated 1000 persons experiencing homelessness (PEH) in Anchorage, Alaska. We characterized the outbreak and implemented a mass antibiotic intervention at homeless service facilities. Methods: We identified cases through the Alaska GAS laboratory-based surveillance system. We conducted emm typing, antimicrobial susceptibility testing, and whole-genome sequencing on all invasive isolates and compared medical record data of patients infected with emm26.3 and other emm types. In February 2017, we offered PEH at 6 facilities in Anchorage a single dose of 1 g of azithromycin. We collected oropharyngeal and nonintact skin swabs on a subset of participants concurrent with the intervention and 4 weeks afterward. Results: From July 2016 through April 2017, we detected 42 invasive emm26.3 cases in Anchorage, 35 of which were in PEH. The emm26.3 isolates differed on average by only 2 single-nucleotide polymorphisms. Compared to other emm types, infection with emm26.3 was associated with cellulitis (odds ratio [OR], 2.5; P = .04) and necrotizing fasciitis (OR, 4.4; P = .02). We dispensed antibiotics to 391 PEH. Colonization with emm26.3 decreased from 4% of 277 at baseline to 1% of 287 at follow-up (P = .05). Invasive GAS incidence decreased from 1.5 cases per 1000 PEH/week in the 6 weeks prior to the intervention to 0.2 cases per 1000 PEH/week in the 6 weeks after (P = .01). Conclusions: In an invasive GAS outbreak in PEH in Anchorage, mass antibiotic administration was temporally associated with reduced invasive disease cases and colonization prevalence. |
Re-emergence of pneumococcal colonization by vaccine serotype 19F in persons aged 5 years after 13-valent pneumococcal conjugate vaccine introduction-Alaska, 2008-2013
Gounder PP , Bruden D , Rudolph K , Zulz T , Hurlburt D , Thompson G , Bruce MG , Hennessy TW . Vaccine 2017 36 (5) 691-697 BACKGROUND: The pneumococcal conjugate vaccine (PCV) was introduced in 2001. Widespread PCV use nearly eradicated pneumococcal colonization by vaccine serotypes. Since 2008, however, colonization by PCV-serotype 19F has increased in Alaska residents. We describe the epidemiology of re-emerging serotype 19F colonization. METHODS: We conducted annual cross-sectional colonization surveys from 2008 to 2013. We recruited children aged <5years at 2 urban clinics and participants of all ages from Region-A (2 villages), Region-B (4 villages), and Region-C (2 villages). We interviewed participants and reviewed their medical records to obtain demographic information and determine PCV status. We obtained nasopharyngeal swab specimens from participants to identify pneumococci and to determine the pneumococcal serotype, antimicrobial resistance, and multilocus sequence type. We used the Cochran-Armitage test to assess for significant trends in colonization across time periods. RESULTS: Among participants aged <5years, pneumococcal serotype 19F colonization remained unchanged from 2008-2009 (0.7%) to 2012-2013 (0.5%; P-value [P]=.54). Serotype 19F colonization increased from 2008-2009 to 2012-2013 among participants aged 5-11years (0.3% to 3.2%; P<.01), participants 12-17years (0.0% to 2.0%; P<.01), and participants aged >/=18years (0.1% to 0.5%; P<.01). During 2012-2013, 85 (93%) of 91 pneumococcal serotype 19F isolates were identified among participants from Region B; the majority of serotype 19F isolates belonged to an antimicrobial nonsusceptibility pattern corresponding to a novel multilocus sequence type 9074. CONCLUSIONS: PCV continues to protect against serotype 19F colonization in vaccinated children aged <5years. The direct PCV impact on serotype 19F colonization in persons aged 5-11years and indirect impact in persons aged >/=12years is waning, possibly because of a newly introduced genotype in Region-B. |
Population structure of invasive Streptococcus pneumoniae isolates among Alaskan children in the conjugate vaccine era, 2001 to 2013.
Miernyk KM , Bulkow LR , Case SL , Zulz T , Bruce MG , Harker-Jones M , Hurlburt DA , Hennessy TW , Rudolph KM . Diagn Microbiol Infect Dis 2016 86 (2) 224-30 Here we describe the relationships between serotypes, genotypes, and antimicrobial susceptibility among isolates causing invasive pneumococcal disease in Alaskan children during the pneumococcal conjugate vaccine (PCV) era. From 2001 to 2013 we received 271 isolates representing 33 serotypes. The most common serotypes were 19A (29.5%, n= 80), 7F (12.5%, n= 34), 15B/C (6.3%, n= 17), and 22F (4.8%, n= 13). Multilocus sequence typing identified 11 clonal complexes (CC) and 45 singletons. Five CCs accounted for 52% (141/271) of the total: CC199 (21% [n= 57], serotypes 19A, 15B/C), CC191 (12.2% [n= 33], serotype 7F), CC172 (10.3% [n= 28], serotypes 19A, 23A, 23B), CC433 (4.4% [n= 12], serotype 22F), and CC100 (4.4% [n= 12], serotype 33F). The proportion of isolates nonsusceptible to erythromycin and tetracycline increased after 13-valent PCV use (14% [n= 30] versus 29% [n= 14]; P= 0.010) and (4% [n= 9] versus 22% [n= 11]; P< 0.001), respectively. The genetic diversity also increased after 13-valent PCV use (Simpson's diversity index =0.95 versus 0.91; P= 0.022). |
Surveillance of infectious diseases in the Arctic
Bruce M , Zulz T , Koch A . Public Health 2016 137 5-12 OBJECTIVES: This study reviews how social and environmental issues affect health in Arctic populations and describes infectious disease surveillance in Arctic Nations with a special focus on the activities of the International Circumpolar Surveillance (ICS) project. METHODS: We reviewed the literature over the past 2 decades looking at Arctic living conditions and their effects on health and Arctic surveillance for infectious diseases. RESULTS: In regards to other regions worldwide, the Arctic climate and environment are extreme. Arctic and sub-Arctic populations live in markedly different social and physical environments compared to those of their more southern dwelling counterparts. A cold northern climate means people spending more time indoors, amplifying the effects of household crowding, smoking and inadequate ventilation on the person-to-person spread of infectious diseases. The spread of zoonotic infections north as the climate warms, emergence of antibiotic resistance among bacterial pathogens, the re-emergence of tuberculosis, the entrance of HIV into Arctic communities, the specter of pandemic influenza or the sudden emergence and introduction of new viral pathogens pose new challenges to residents, governments and public health authorities of all Arctic countries. ICS is a network of hospitals, public health agencies, and reference laboratories throughout the Arctic working together for the purposes of collecting, comparing and sharing of uniform laboratory and epidemiological data on infectious diseases of concern and assisting in the formulation of prevention and control strategies (Fig. 1). In addition, circumpolar infectious disease research workgroups and sentinel surveillance systems for bacterial and viral pathogens exist. CONCLUSIONS: The ICS system is a successful example of collaborative surveillance and research in an extreme environment. |
International circumpolar surveillance interlaboratory quality control program for emm typing of Streptococcus pyogenes, 2011-2015
Rudolph K , Martin I , Demczuk W , Kakulphimp J , Bruden D , Zulz T , Bruce M . Diagn Microbiol Infect Dis 2016 85 (4) 398-400 In 2011, an interlaboratory quality control (QC) program for emm typing group A streptococci (GAS) was incorporated into existing international circumpolar surveillance QC programs. From 2011 - 2015, 35 GAS isolates were distributed to three laboratories; emm type-level concordance was 100%, while the overall sub-type level concordance was 83%. |
Descriptive review of tuberculosis surveillance systems across the circumpolar regions
Bourgeois AC , Zulz T , Soborg B , Koch A . Int J Circumpolar Health 2016 75 30322 BACKGROUND: Tuberculosis is highly prevalent in many Arctic areas. Members of the International Circumpolar Surveillance Tuberculosis (ICS-TB) Working Group collaborate to increase knowledge about tuberculosis in Arctic regions. OBJECTIVE: To establish baseline knowledge of tuberculosis surveillance systems used by ICS-TB member jurisdictions. DESIGN: Three questionnaires were developed to reflect the different surveillance levels (local, regional and national); all 3 were forwarded to the official representative of each of the 15 ICS-TB member jurisdictions in 2013. Respondents self-identified the level of surveillance conducted in their region and completed the applicable questionnaire. Information collected included surveillance system objectives, case definitions, data collection methodology, storage and dissemination. RESULTS: Thirteen ICS-TB jurisdictions [Canada (Labrador, Northwest Territories, Nunavik, Nunavut, Yukon), Finland, Greenland, Norway, Sweden, Russian Federation (Arkhangelsk, Khanty-Mansiysk Autonomous Okrug, Yakutia (Sakha Republic), United States (Alaska)] voluntarily completed the survey - representing 2 local, 7 regional and 4 national levels. Tuberculosis reporting is mandatory in all jurisdictions, and case definitions are comparable across regions. The common objectives across systems are to detect outbreaks, and inform the evaluation/planning of public health programmes and policies. All jurisdictions collect data on confirmed active tuberculosis cases and treatment outcomes; 11 collect contact tracing results. Faxing of standardized case reporting forms is the most common reporting method. Similar core data elements are collected; 8 regions report genotyping results. Data are stored using customized programmes (n=7) and commercial software (n=6). Nine jurisdictions provide monthly, bi-annual or annual reports to principally government and/or scientific/medical audiences. CONCLUSION: This review successfully establishes baseline knowledge on similarities and differences among circumpolar tuberculosis surveillance systems. The similarity in case definitions will allow for description of the epidemiology of TB based on surveillance data in circumpolar regions, further study of tuberculosis trends across regions, and recommendation of best practices to improve surveillance activities. |
Epidemiology of invasive group A streptococcal disease in Alaska, 2001 to 2013
Rudolph K , Bruce MG , Bruden D , Zulz T , Reasonover A , Hurlburt D , Hennessy T . J Clin Microbiol 2016 54 (1) 134-41 The Arctic Investigations Program (AIP) began surveillance for invasive group A streptococcal (GAS) infections in Alaska in 2000 as part of the invasive bacterial diseases population-based laboratory surveillance program. Between 2001 and 2013, there were 516 cases of GAS infection reported, for an overall annual incidence of 5.8 cases per 100,000 persons with 56 deaths (case fatality rate, 10.7%). Of the 516 confirmed cases of invasive GAS infection, 422 (82%) had isolates available for laboratory analysis. All isolates were susceptible to penicillin, cefotaxime, and levofloxacin. Resistance to tetracycline, erythromycin, and clindamycin was seen in 11% (n = 8), 5.8% (n = 20), and 1.2% (n = 4) of the isolates, respectively. A total of 51 emm types were identified, of which emm1 (11.1%) was the most prevalent, followed by emm82 (8.8%), emm49 (7.8%), emm12 and emm3 (6.6% each), emm89 (6.2%), emm108 (5.5%), emm28 (4.7%), emm92 (4%), and emm41 (3.8%). The five most common emm types accounted for 41% of isolates. The emm types in the proposed 26-valent and 30-valent vaccines accounted for 56% and 78% of all cases, respectively. GAS remains an important cause of invasive bacterial disease in Alaska. Continued surveillance of GAS infections will help improve understanding of the epidemiology of invasive disease, with an impact on disease control, notification of outbreaks, and vaccine development. |
Monitoring invasive bacterial diseases in the North American Arctic via the International Circumpolar Surveillance Project
Desai S , Li YA , Zulz T , Bruce M . Can Commun Dis Rep 2015 41 (3) 52-54 This paper summarizes the most recent Invasive Bacterial Diseases (IBD) Working Group meeting of the International Circumpolar Surveillance (ICS) project. The ICS is a population-based surveillance network for invasive bacterial diseases that provides a mechanism to determine changes in incidence rates and antimicrobial resistance. The meeting took place in Montreal, Canada on February 12-13, 2014. Data were included from participating Canadian provincial and territorial jurisdictions as well as from the State of Alaska. This report is based on the audio records of the meeting as well as the meeting presentations. The ICS IBD Working Group focuses on invasive diseases caused by: Streptococcus pneumoniae (Sp), Neisseria meningitidis (Nm), Haemophilus influenzae (Hi), Group A Streptococcus (GAS) and Group B Streptococcus (GBS). Data on invasive disease caused by each of these organisms were reviewed through December 2012-2013. Although the incidence of some of these vaccine-preventable invasive diseases has decreased, emergence of H. influenzae serotype a (Hia) in both Alaska and Northern Canada was noted. An interlaboratory quality control (QC) program is ongoing to monitor laboratory proficiencies for serotyping. |
Impact of the 13-valent pneumococcal conjugate vaccine (pcv13) on invasive pneumococcal disease and carriage in Alaska
Bruce MG , Singleton R , Bulkow L , Rudolph K , Zulz T , Gounder P , Hurlburt D , Bruden D , Hennessy T . Vaccine 2015 33 (38) 4813-9 BACKGROUND: Alaska Native (AN) children have experienced high rates of invasive pneumococcal disease (IPD). In March 2010, PCV13 was introduced statewide in Alaska. We evaluated the impact of PCV13 on IPD in children and adults, 45 months after introduction. METHODS: Pneumococcal sterile site isolates, reported through state-wide surveillance, were serotyped using standard methods. We defined a pre-PCV13 time period 2005-2008 and post-PCV13 time period April 2010-December 2013; excluding Jan 2009-March 2010 because PCV13 was introduced pre-licensure in one high-risk region in 2009. RESULTS: Among Alaska children <5 years, PCV13 serotypes comprised 65% of IPD in the pre-PCV13 period and 26% in the PCV13 period. Among all Alaska children <5 years, IPD rates decreased from 60.9 (pre) to 25.4 (post) per 100,000/year (P<0.001); PCV13 serotype IPD decreased from 37.7 to 6.4 (P<0.001). Among AN children <5 years, IPD rates decreased from 149.2 to 60.8 (P<0.001); PCV13 serotype IPD decreased from 87.0 to 17.4 (P<0.001); non-PCV13 serotype IPD did not change significantly. Among persons 5-17 and ≥45 years, the post-vaccine IPD rate was similar to the baseline period, but declined in persons 18-44 years (39%, P<0.001); this decline was similar in AN and non-AN persons (38%, P=0.016, 43%, P=0.014, respectively). CONCLUSIONS: Forty-five months after PCV13 introduction, overall IPD and PCV13-serotype IPD rates had decreased 58% and 83%, respectively, in Alaska children <5 years of age when compared with 2005-2008. We observed evidence of indirect effect among adults with a 39% reduction in IPD among persons 18-44 years. |
Epidemiology of bacterial meningitis in the North American Arctic, 2000-2010
Gounder PP , Zulz T , Desai S , Stenz F , Rudolph K , Tsang R , Tyrrell GJ , Bruce MG . J Infect 2015 71 (2) 179-87 OBJECTIVE: To determine the incidence of meningitis caused by Haemophilus influenzae, Neisseria meningitidis, and Streptococcus pneumoniae in the North American Arctic during 2000-2010. METHODS: Surveillance data were obtained from the International Circumpolar Surveillance network. We defined a case of bacterial meningitis caused by H. influenzae, N. meningitidis, or S. pneumoniae as a culture-positive isolate obtained from a normally sterile site in a resident with a meningitis diagnosis. RESULTS: The annual incidence/100,000 persons for meningitis caused by H. influenzae, N. meningitidis, and S. pneumoniae among all North American Arctic residents was: 0.6, 0.5, and 1.5, respectively; the meningitis incidence among indigenous persons in Alaska and Canada (indigenous status not recorded in Greenland) for those three bacteria was: 2.1, 0.8, and 2.4, respectively. The percentage of pneumococcal isolates belonging to a 7-valent pneumococcal conjugate vaccine serotype declined from 2000-2004 to 2005-2010 (31% to 2%, p-value <0.01). During 2005-2010, serotype a caused 55% of H. influenzae meningitis and serogroup B caused 86% of meningococcal meningitis. CONCLUSIONS: Compared with all North American Arctic residents, indigenous people suffer disproportionately from bacterial meningitis. Arctic residents could benefit from the development of a H. influenzae serotype a vaccine and implementation of a meningococcal serogroup B vaccine. |
Molecular resistance mechanisms of macrolide-resistant invasive Streptococcus pneumoniae isolates from Alaska, 1986 to 2010.
Rudolph K , Bulkow L , Bruce M , Zulz T , Reasonover A , Harker-Jones M , Hurlburt D , Hennessy T . Antimicrob Agents Chemother 2013 57 (11) 5415-22 The rapid emergence of antibiotic-resistant pneumococcal strains has reduced treatment options. The aim of this study was to determine antimicrobial susceptibilities, serotype distributions, and molecular resistance mechanisms among macrolide-resistant invasive pneumococcal isolates in Alaska from 1986 to 2010. We identified cases of invasive pneumococcal disease in Alaska from 1986 to 2010 through statewide population-based laboratory surveillance. All invasive pneumococcal isolates submitted to the Arctic Investigations Program laboratory were confirmed by standard microbiological methods and serotyped by slide agglutination and the Quellung reaction. MICs were determined by the broth microdilution method, and macrolide-resistant genotypes were determined by multiplex PCR. Among 2,923 invasive pneumococcal isolates recovered from 1986 to 2010, 270 (9.2%) were nonsusceptible to erythromycin; 177 (66%) erythromycin-nonsusceptible isolates demonstrated coresistance to penicillin, and 167 (62%) were multidrug resistant. The most frequent serotypes among the macrolide-resistant isolates were serotypes 6B (23.3%), 14 (20.7%), 19A (16.7%), 9V (8.9%), 19F (6.3%), 6A (5.6%), and 23F (4.8%). mef and erm(B) genes were detected in 207 (77%) and 32 (12%) of the isolates, respectively. Nineteen (7%) of the erythromycin-nonsusceptible isolates contained both mef and erm(B) genotypes; 15 were of serotype 19A. There was significant year-to-year variation in the proportion of isolates that were nonsusceptible to erythromycin (P < 0.001). Macrolide resistance among pneumococcal isolates from Alaska is mediated predominantly by mef genes, and this has not changed significantly over time. However, there was a statistically significant increase in the proportion of isolates that possess both erm(B) and mef, primarily due to serotype 19A isolates. |
Haemophilus influenzae serotype a invasive disease, Alaska, USA, 1983-2011
Bruce MG , Zulz T , Debyle C , Singleton R , Hurlburt D , Bruden D , Rudolph K , Hennessy T , Klejka J , Wenger JD . Emerg Infect Dis 2013 19 (6) 932-7 Before introduction of Haemophilus influenzae type b (Hib) vaccines, rates of Hib disease in Alaska's indigenous people were among the highest in the world. Vaccination reduced rates dramatically; however, invasive H. influenzae type a (Hia) disease has emerged. Cases of invasive disease were identified through Alaska statewide surveillance during 1983-2011. Of 866 isolates analyzed for serotype, 32 (4%) were Hia. No Hia disease was identified before 2002; 32 cases occurred during 2002-2011 (p<0.001). Median age of case-patients was 0.7 years; 3 infants died. Incidence of Hia infection (2002-2011) among children <5 years was 5.4/100,000; 27 cases occurred in Alaska Native children (18/100,000) versus 2 cases in non-Native children (0.5/100,000) (risk ratio = 36, p<0.001). From 12/2009 to 12/2011, 15 cases of Hia disease occurred in southwestern Alaska (in children <5 years, rate = 204/100,000). Since introduction of the Hib conjugate vaccine, Hia infection has become a major invasive bacterial disease in Alaska Native children. |
Molecular characterization of Streptococcus pneumoniae serotype 12F isolates associated with rural community outbreaks in Alaska.
Zulz T , Wenger JD , Rudolph K , Robinson DA , Rakov AV , Bruden D , Singleton RJ , Bruce MG , Hennessy TW . J Clin Microbiol 2013 51 (5) 1402-7 Outbreaks of invasive pneumococcal disease (IPD) caused by serotype 12F Streptococcus pneumoniae were observed in two neighboring regions of rural Alaska in 2003-2006 and 2006-2008. IPD surveillance data from 1986-2009 and carriage survey data from 1998-2004 and 2008-2009 were reviewed to identify patterns of 12F transmission. Pulsed field gel electrophoresis was performed on all available isolates, and selected isolates were characterized by additional genetic subtyping methods. Serotype 12F IPD occurred in two waves in Alaska between 1986 and 2008. While cases of disease occurred nearly every year in Anchorage, in rural regions 12F IPD occurred with rates 10 to 20-fold higher than in Anchorage, often with many years between disease peaks, and generally caused by a single predominant genetic clone. Carriage occurred predominantly in adults, except early in rural outbreaks when most carriage was in persons <18 years old. In rural regions, carriage of 12F disappeared completely after outbreaks. Different 12F clones appear to have been introduced episodically into rural populations, spread widely in young, immunologically naive populations, leading to outbreaks of IPD lasting 1-3 years, then rapidly disappeared from the population. Larger population centers may have been the reservoir for these clones. This epidemiologic pattern is consistent with a highly virulent, but immunogenic, form of pneumococcus. |
Epidemiology of pneumococcal serotype 6A and 6C among invasive and carriage isolates from Alaska, 1986-2009.
Rudolph K , Bruce M , Bruden D , Zulz T , Wenger J , Reasonover A , Harker-Jones M , Hurlburt D , Hennessy T . Diagn Microbiol Infect Dis 2012 75 (3) 271-6 We investigated serotype 6A/6C invasive pneumococcal disease (IPD) incidence, genetic diversity, and carriage before and after 7-valent pneumococcal conjugate vaccine (PCV7) introduction in Alaska. IPD cases (1986-2009) were identified through population-based laboratory surveillance. Isolates were initially serotyped by conventional methods, and 6C isolates were differentiated from 6A by polymerase chain reaction. Among invasive and carriage isolates initially typed as 6A, 35% and 50% were identified as 6C, respectively. IPD rates caused by serotype 6A or 6C among children <5 years did not change from the pre- to post-PCV7 period (P = 0.71 and P = 0.09, respectively). Multilocus sequence typing of IPD isolates revealed 28 sequence types. The proportion of serotype 6A carriage isolates decreased from 7.4% pre-PCV7 to 1.8% (P < 0.001) during 2008-2009; the proportion of serotype 6C carriage isolates increased from 3.0% to 8.4% (P = 0.004) among children <5 years. Continued surveillance is warranted to monitor changes in serotype distribution and prevalence. |
International Circumpolar Surveillance interlaboratory quality control program for serotyping Haemophilus influenzae and serogrouping Neisseria meningitidis, 2005 to 2009
Tsang RS , Rudolph K , Lovgren M , Bekal S , Lefebvre B , Lambertsen L , Zulz T , Bruce M . J Clin Microbiol 2012 50 (3) 651-6 The International Circumpolar Surveillance (ICS) program was initiated in 1999 to conduct population-based surveillance for invasive pneumococcal disease in select regions of the Arctic. The program was expanded to include the surveillance of invasive diseases caused by Neisseria meningitidis and Haemophilus influenzae. An interlaboratory quality control (QC) program to monitor laboratory proficiencies in the serogrouping of N. meningitidis and serotyping of H. influenzae strains was codeveloped by the Arctic Investigations Program (Anchorage, AK) and the Public Health Agency of Canada National Microbiology Laboratory (Winnipeg, Manitoba, Canada) and introduced into the ICS program in 2005. Other participating laboratories included the Provincial Laboratory for Public Health (Edmonton, Alberta, Canada), Laboratoire Sante Publique du Quebec (Sainte-Anne-de-Bellevue, Quebec, Canada), and Statens Serum Institut (Copenhagen, Denmark). From 2005 through 2009, 50 isolates (24 N. meningitidis and 26 H. influenzae isolates) were distributed among the five participating laboratories. The overall serogroup concordance for N. meningitidis strains was 92.3% (96/104), without including three isolates that were found to express both serogroup Y and W135 specificities. Concordant results were obtained for serogroups A, B, C, and Y among all laboratories. Discrepancies were observed most frequently for serogroups W135, X, Z, and 29E. The overall serotype concordance for H. influenzae was 98% (125/127 attempts). The two discrepant results involved a serotype c strain and a serotype e strain, and in both cases, the serotypeable H. influenzae isolates were misidentified as being nontypeable. These data demonstrate a high degree of concordance for serogroup and serotype determinations of N. meningitidis and H. influenzae isolates, respectively, among the five laboratories participating in this quality control program. |
2009 pandemic influenza A H1N1 in Alaska: temporal and geographic characteristics of spread and increased risk of hospitalization among Alaska Native and Asian/Pacific Islander people
Wenger JD , Castrodale LJ , Bruden DL , Keck JW , Zulz T , Bruce MG , Fearey DA , McLaughlin J , Hurlburt D , Hummel KB , Kitka S , Bentley S , Thomas TK , Singleton R , Redd JT , Layne L , Cheek JE , Hennessy TW . Clin Infect Dis 2011 52 S189-S197 Alaska Native people have suffered disproportionately from previous influenza pandemics. We evaluated 3 separate syndromic data sources to determine temporal and geographic patterns of spread of 2009 pandemic influenza A H1N1 (pH1N1) in Alaska, and reviewed records from persons hospitalized with pH1N1 disease in 3 areas in Alaska to characterize clinical and epidemiologic features of disease in Alaskans. A wave of pH1N1 disease swept through Alaska beginning in most areas in August or early September. In rural regions, where Alaska Native people comprise a substantial proportion of the population, disease occurred earlier than in other regions. Alaska Native people and Asian/Pacific Islanders (A/PI) were 2-4 times more likely to be hospitalized than whites. Alaska Native people and other minorities remain at high risk for early and substantial morbidity from pandemic influenza episodes. These findings should be integrated into plans for distribution and use of vaccine and antiviral agents. |
Trends in hospitalization for empyema in Alaska native children yournger than 10 years of age
Singleton RJ , Holman RC , Wenger J , Christensen KY , Bulkow LR , Zulz T , Steiner CA , Cheek JE . Pediatr Infect Dis J 2010 30 (6) 528-30 We analyzed hospitalizations for empyema among Alaska Native (AN) children and the general population of US children <10 years during the years 1998 to 2007. We also analyzed invasive pneumococcal disease in AN children. Between 1998 and 2000, the average annual hospitalization rate for empyema was higher for AN children (51.8 per 100,000/yr) than that for US children (24.2 [95% confidence interval: 20.4, 27.9] per 100,000/yr), and had increased in 2004-2007 in both populations (59.6 and 36.0 [95% confidence interval: 30.1, 41.8], respectively). Pneumococcal empyema increased in AN children despite a decrease in invasive pneumococcal disease pneumonia. |
Invasive meningococcal disease caused by Neisseria meningitidis strains expressing both serogroup Y and W-135 antigenic specificities
Rudolph KM , Debyle C , Reasonover A , Zulz T , Law DK , Zhou J , Tsang RS . J Clin Microbiol 2010 49 (1) 472-3 We read with interest of three Neisseria meningitidis strains recovered in Germany that reacted with commercial (Oxoid, Wesel, Germany) serogroupY and serogroup W135 antisera (3). The molecular basis of this dual antigenic specificity has been determined to be due to a single amino acid change at position 310 in the EX7E motif of the capsule polymerase enzyme synG (also referred to as siaDY) (from glycine to serine) or synF (siaDW-135) (from proline to serine) (2). Both studies confirmed our earlier report of such unusual strains causing invasive meningococcal disease (IMD) (10). |
The international circumpolar surveillance interlaboratory quality control program for Streptococcus pneumoniae, 1999 - 2008
Reasonover A , Zulz T , Bruce MG , Bruden D , Jette L , Kaltoft M , Lambertsen L , Parkinson A , Rudolph K , Lovgren M . J Clin Microbiol 2010 49 (1) 138-43 The International Circumpolar Surveillance (ICS) Project was initiated in 1999 to conduct population-based surveillance for invasive pneumococcal disease in select regions of the Arctic. An inter-laboratory quality control (QC) program for pneumococcal serotyping and antibiotic susceptibility testing was incorporated into ICS by reference laboratories in Northern Canada (Laboratoire de Sante Publique du Quebec (LSPQ) in Sainte-Anne de Bellevue, Quebec, National Centre for Streptococcus (NCS) in Edmonton, Alberta) and Alaska (Arctic Investigations Program, (AIP). The World Health Organization's Collaborating Centre for Reference and Research on Pneumococci at Statens Serum Institute (SSI) in Copenhagen, Denmark, joined the QC Program in 2004. The Iceland Reference Laboratory (IRL) in Reykjavik joined the QC Program in 2006, but due to low sample sizes data from IRL are not included in this report. From 1999 through 2008, 190 isolates were distributed among four laboratories (AIP, NCS, LSPQ, and SSI). The overall serotype concordance was 95.8%, and overall serogroup concordance was 97.4%. The overall modal MIC concordance for testing by broth microdilution (BMD) and agar dilution was >96% for all the antibiotics except for erythromycin (92.1%) and clindamycin (89.5%). MIC comparisons between the Etest(R) and broth microdilution (BMD) resulted in lower concordance for erythromycin (73.9%), clindamycin (65.5%), and trimethoprim-sulfamethoxazole (80%); however categorical concordance (susceptible, resistant) remained high at 98.6%, 89.1%, and 90.9%, respectively. Our data demonstrate a high correlation of serotyping and antimicrobial susceptibility testing results between four participating laboratories. |
Invasive pneumococcal disease in Alaskan children: impact of the seven-valent pneumococcal conjugate vaccine and the role of water supply
Wenger JD , Zulz T , Bruden D , Singleton R , Bruce MG , Bulkow L , Parks D , Rudolph K , Hurlburt D , Ritter T , Klejka J , Hennessy T . Pediatr Infect Dis J 2009 29 (3) 251-6 BACKGROUND: Alaska Native (AN) children, especially those in the Yukon-Kuskokwim region (YK-AN children), suffer some of the highest rates of invasive pneumococcal disease (IPD) in the world. Rates of IPD declined after statewide introduction of the 7-valent pneumococcal conjugate vaccine (PCV7) in 2001, but increased in subsequent years. METHODS: Population-based laboratory surveillance data (1986-2007) for invasive Streptococcus pneumoniae infection in Alaskan children <5 years old were used to evaluate the association of IPD rates and serotype distribution with immunization, socioeconomic status, and in-home water service. RESULTS: Introduction of PCV7 vaccine resulted in elimination of IPD caused by vaccine serotypes, but was followed by increasing rates of IPD caused by nonvaccine serotypes. Among YK-AN children IPD rates dropped by 60%, but then rose due to non-PCV7 serotypes to levels 5- to 10-fold higher than rates in non-YK-AN children and non-AN children. IPD rates in YK-AN children were twice as high in villages where <10% of houses had in-home piped water compared with villages where more than 80% of houses had in-home piped water (390 cases/100,000 vs. 146 cases/100,000, P = 0.008). CONCLUSIONS: High IPD rates in Alaska are associated with lack of in-home piped water (controlling for household crowding and per capita income). The effect of in-home piped water is most likely mediated through reduced water supply leading to limitations on handwashing. |
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