Last data update: Jan 13, 2025. (Total: 48570 publications since 2009)
Records 1-7 (of 7 Records) |
Query Trace: Keck JW[original query] |
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Nirsevimab effectiveness against medically attended respiratory syncytial virus illness and hospitalization among Alaska native children - Yukon-Kuskokwim Delta Region, Alaska, October 2023-June 2024
Lefferts B , Bressler S , Keck JW , Desnoyers C , Hodges E , January G , Morris K , Herrmann L , Singleton R , Aho S , Rogers J , Newell K , Ohlsen E , Link-Gelles R , Dawood FS , Bruden D , Fischer M , Klejka J , Scobie HM . MMWR Morb Mortal Wkly Rep 2024 73 (45) 1015-1021 Respiratory syncytial virus (RSV) is a leading cause of hospitalization among young children. Historically, American Indian and Alaska Native (AI/AN) children have experienced high rates of RSV-associated hospitalization. In August 2023, a preventive monoclonal antibody (nirsevimab) was recommended for all infants aged <8 months (born during or entering their first RSV season) and for children aged 8-19 months (entering their second RSV season) who have increased risk for severe RSV illness, including all AI/AN children. This evaluation in Alaska's Yukon-Kuskokwim Delta region estimated nirsevimab effectiveness among AI/AN children in their first or second RSV seasons during 2023-2024. Among 472 children with medically attended acute respiratory illness (ARI), 48% overall had received nirsevimab ≥7 days earlier (median = 91 days before the ARI-related visit). For children in their first RSV season (292), nirsevimab effectiveness was 76% (95% CI = 42%-90%) against medically attended RSV illness and 89% (95% CI = 32%-98%) against RSV hospitalization. For children in their second RSV season (180), effectiveness against medically attended RSV illness was 88% (95% CI = 48%-97%). Nirsevimab is effective for preventing severe RSV illness among infants entering their first RSV season and children entering their second season with increased risk for severe RSV, including all AI/AN children. |
COVID-19 infection and incident diabetes in American Indian and Alaska Native people: a retrospective cohort study
Keck JW , Lacy ME , Bressler S , Blake I , Chukwuma U , Bruce MG . Lancet Reg Health Am 2024 33 100727 BACKGROUND: Evidence suggests an increased risk of new-onset diabetes following COVID-19 infection. American Indian/Alaska Native (AI/AN) people were disparately impacted by the COVID-19 pandemic and historically have had higher diabetes incidence than other racial/ethnic groups in the US. We measured the association between COVID-19 infection and incident diabetes in AI/AN people. METHODS: We conducted a retrospective cohort study using de-identified patient data from the Indian Health Service's (IHS) National Patient Information Reporting System. We estimated age-adjusted diabetes incidence rates, incidence rate ratios, and adjusted hazard ratios among three cohorts spanning pre-pandemic (1/1/2018-2/28/2020) and pandemic (3/1/2020-12/31/2021) timeframes: 1) pre-pandemic cohort (1,503,085 individuals); 2) no-COVID-19 pandemic cohort (1,344,339 individuals); and 3) COVID-19 cohort (176,483 individuals). FINDINGS: The COVID-19 cohort had an increased hazard of diabetes compared to the no-COVID-19 group (adjusted hazard ratio (aHR) = 1.56; 95% CI: 1.50-1.62) and the pre-pandemic group (aHR = 1.27; 95% CI: 1.22-1.32). The association between COVID-19 infection and new-onset diabetes was stronger in those with severe COVID-19 illness. A sensitivity analysis comparing the COVID-19 cohort to members of other cohorts that had acute upper respiratory infections showed an attenuated but higher risk of new-onset diabetes in those with COVID-19. INTERPRETATION: AI/AN people diagnosed with COVID-19 had an elevated risk of a new diabetes diagnosis when compared to the no-COVID-19 group and the pre-pandemic group. The increased diabetes risk in the COVID-19 group remained in a sensitivity analysis that limited the comparator groups to individuals with an AURI diagnosis. FUNDING: US National Institute of Diabetes and Digestive and Kidney Diseases. |
Invasive Haemophilus influenzae serotype A infection in children: Clinical description of an emerging pathogen - Alaska, 2002-2014
Plumb ID , Lecy D , Singleton R , Engel MC , Hirschfeld M , Keck JW , Klejka J , Rudolph KM , Hennessy TW , Bruce MG . Pediatr Infect Dis J 2017 37 (4) 298-303 BACKGROUND: Invasive infections from Haemophilus influenzae serotype a (Hia) have been reported with increasing frequency, especially among indigenous populations. However there are limited population-based-studies of clinical severity. We studied invasive Hia infections in Alaska to determine clinical characteristics, mortality, and sequelae. METHODS: We defined an invasive Hia infection as the first detection of Hia from a usually sterile site in a child <10 years of age from Alaska. We identified cases using the Alaska Invasive Bacterial Diseases Surveillance System and reviewed medical charts up to 2 years after reported illness. RESULTS: We identified invasive Hia infections in 36 children, 28 (78%) <1 year old, 34 (94%) living in an Alaskan village, and 25 (69%) without documented underlying illness. Overlapping clinical presentations included meningitis in 15 children (42%); bacteremia and pneumonia in 10 children (28%); and bone, joint or soft tissue infections in 10 children (22%). In four other children, no source of invasive infection was identified. Intensive care was provided for 11 children (31%); 12 children (33%) required surgical intervention. One year after infection, 4 children (11%) had died from Hia, and 5 children (14%) had ongoing neurologic sequelae. CONCLUSIONS: Invasive Hia infections in Alaska occurred predominantly in Alaska Native infants in rural communities. Although one-third of children had pre-existing conditions, most cases occurred without known comorbidity. Clinical syndromes were frequently severe. One year after infection, one in four children had either died or had neurologic sequelae. An effective vaccine would prevent significant morbidity and mortality in affected populations. |
PCV7-induced changes in pneumococcal carriage and invasive disease burden in Alaskan children
Keck JW , Wenger JD , Bruden DL , Rudolph KM , Hurlburt DA , Hennessy TW , Bruce MG . Vaccine 2014 32 (48) 6478-84 BACKGROUND: Changes in pneumococcal serotype-specific carriage and invasive pneumococcal disease (IPD) after the introduction of pneumococcal conjugate vaccine (PCV7) could inform serotype epidemiology patterns following the introduction of newer conjugate vaccines. METHODS: We used data from statewide IPD surveillance and annual pneumococcal carriage studies in four regions of Alaska to calculate serotype-specific invasiveness ratios (IR; odds ratio of a carried serotype's likelihood to cause invasive disease compared to other serotypes) in children <5 years of age. We describe changes in carriage, disease burden, and invasiveness between two time periods, the pre-PCV7 period (1996-2000) and the late post-PCV7 period (2006-2009). RESULTS: Incidence of IPD decreased from the pre- to post-vaccine period (95.7 vs. 57.2 cases per 100,000 children, P<0.001), with a 99% reduction in PCV7 disease. Carriage prevalence did not change between the two periods (49% vs. 50%), although PCV7 serotype carriage declined by 97%, and non-vaccine serotypes increased in prevalence. Alaska pre-vaccine IRs corresponded to pooled results from eight pre-vaccine comparator studies (Spearman's rho=0.44, P=0.002) and to the Alaska post-vaccine period (Spearman's rho=0.28, P=0.029). Relatively invasive serotypes (IR>1) caused 66% of IPD in both periods, although fewer serotypes with IR>1 remained in the post-vaccine (n=9) than the pre-vaccine period (n=13). CONCLUSIONS: After PCV7 introduction, serotype IRs changed little, and four of the most invasive serotypes were nearly eliminated. If PCV13 use leads to a reduction of carriage and IPD for the 13 vaccine serotypes, the overall IPD rate should further decline. |
Hepatitis B antibody levels seven to nine years following booster vaccination in Alaska Native persons
Keck JW , Bulkow LR , Raczniak GA , Negus SE , Zanis CL , Bruce MG , Spradling PR , Teshale EH , McMahon BJ . Clin Vaccine Immunol 2014 21 (9) 1339-42 BACKGROUND: Hepatitis B antibody persistence was assessed in individuals who had previously received a vaccine booster. METHODS: We measured hepatitis B surface antigen antibody (anti-HBs) levels 7-9 years post-hepatitis B booster in individuals with primary vaccination at birth. RESULTS: While 95 (91.3%) of 104 participants had detectable anti-HBs (minimum 0.1 mIU/mL, maximum 1029 mIU/mL), only 43 (41%) had protective levels ≥10mIU/mL. Pre- and four week post-booster anti-HBs levels were significant predictors of hepatitis B immunity at follow-up (P <0.001). CONCLUSIONS: Almost all participants had detectable anti-HBs 7-9 years after hepatitis B vaccine booster, but less than half had levels ≥10mIU/mL. |
Influenza surveillance using electronic health records in the American Indian and Alaska Native population
Keck JW , Redd JT , Cheek JE , Layne LJ , Groom AV , Kitka S , Bruce MG , Suryaprasad A , Amerson NL , Cullen T , Bryan RT , Hennessy TW . J Am Med Inform Assoc 2013 21 (1) 132-8 OBJECTIVE: Increasing use of electronic health records (EHRs) provides new opportunities for public health surveillance. During the 2009 influenza A (H1N1) virus pandemic, we developed a new EHR-based influenza-like illness (ILI) surveillance system designed to be resource sparing, rapidly scalable, and flexible. 4 weeks after the first pandemic case, ILI data from Indian Health Service (IHS) facilities were being analyzed. MATERIALS AND METHODS: The system defines ILI as a patient visit containing either an influenza-specific International Classification of Disease, V.9 (ICD-9) code or one or more of 24 ILI-related ICD-9 codes plus a documented temperature ≥100 degrees F. EHR-based data are uploaded nightly. To validate results, ILI visits identified by the new system were compared to ILI visits found by medical record review, and the new system's results were compared with those of the traditional US ILI Surveillance Network. RESULTS: The system monitored ILI activity at an average of 60% of the 269 IHS electronic health databases. EHR-based surveillance detected ILI visits with a sensitivity of 96.4% and a specificity of 97.8% based on chart review (N=2375) of visits at two facilities in September 2009. At the peak of the pandemic (week 41, October 17, 2009), the median time from an ILI visit to data transmission was 6 days, with a mode of 1 day. DISCUSSION: EHR-based ILI surveillance was accurate, timely, occurred at the majority of IHS facilities nationwide, and provided useful information for decision makers. EHRs thus offer the opportunity to transform public health surveillance. |
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. |
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