Last data update: Jan 13, 2025. (Total: 48570 publications since 2009)
Records 1-10 (of 10 Records) |
Query Trace: Rudolph KM[original query] |
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Acceptability of household practices to prevent boils in rural Alaska
Plumb ID , Dobson J , Seeman S , Bruce MG , Reasonover A , Lefferts B , Rudolph KM , Klejka J , Hennessy TW . J Environ Health 2021 84 (1) 26-34 Boils are a major health problem affecting rural Alaska Native communities. Boils result from transmission of Staphylococcus aureus from steam bath surfaces, infected skin, and household environments. To assess the acceptability of practices to prevent boils within one community, we surveyed 57 households before and after distribution of supplies and educational materials. Before distribution, 64% of households cleaned steam baths with bleach (23/36), 72% used steam bath seat barriers (41/57), 74% did not share scrubbers (42/57), 35% added recommended bleach to laundry (20/57), and 30% used hand sanitizer (17/57). After distribution, 75% households used new scrubbers (43/57), 88% used new seat barriers (50/57), and 25% used new antiseptic skin cleanser (14/57). Additionally, after the intervention, more households used seat barriers in steam baths (from 72% to 86%, p = .046) and hand sanitizer (from 30% to 60%, p < .001). This study supports development of a household-based intervention as a potential strategy to prevent boils in Alaska Native communities. |
Increasing non-susceptibility to antibiotics within carried pneumococcal serotypes - Alaska, 2008-2015
Plumb ID , Gounder PP , Bruden DJT , Bulkow LR , Rudolph KM , Singleton RJ , Hennessy TW , Bruce MG . Vaccine 2020 38 (27) 4273-4280 BACKGROUND: In Alaska, while introduction of 13-valent pneumococcal conjugate vaccine led to declines in invasive pneumococcal disease, carriage prevalence remained stable because of replacement with non-vaccine serotypes. We assessed antibiotic non-susceptibility of carried pneumococci during serotype redistribution, determined the contributions of within-serotype shifts, and assessed factors that could explain changes in non-susceptibility. METHODS: Each year from 2008 to 2015, at multiple sites in Alaska, we collected nasopharyngeal swabs and completed surveys for a convenience sample of participants. Pneumococcal serotyping and antimicrobial susceptibility testing for penicillin and erythromycin were performed. We described changes in non-susceptibility of isolates from 2008-2011 to 2012-2015, and assessed the contributions of serotype redistribution and within-serotype changes in non-susceptibility by comparing observed data to modeled data removing either factor. We used weighted logistic regression to assess whether reported risk factors could explain changes over time in non-susceptibility within serotypes. RESULTS: From 2008-2011 to 2012-2015, the overall proportion of isolates non-susceptible to penicillin or erythromycin increased by 3%, from 23% (n = 1,183) to 26% (n = 1,589; P < 0.05). However, a decrease of 3% would be expected if serotype redistribution occurred without within-serotype changes in non-susceptibility. Standardization by either factor produced hypothetical data significantly different to observed data. Within serotypes, the average annual increase in odds of non-susceptibility to penicillin or erythromycin was 1.08 (95% CI 1.05-1.11). Recent antibiotic exposure, urban residence and increased household size of participants predicted isolate non-susceptibility but did not explain the increase over time. DISCUSSION: An overall increase in non-susceptibility of carried pneumococcal isolates to penicillin or erythromycin resulted from increases in non-susceptibility within serotypes, which outweighed a protective effect of serotype redistribution. Characterization of emerging resistant clones within carried non-vaccine serotypes, including risk factors for colonization and disease, would support disease prevention efforts and inform vaccine strategies. |
Presence of cagPAI genes and characterization of vacA s, i and m regions in Helicobacter pylori isolated from Alaskans and their association with clinical pathologies.
Miernyk KM , Bruden D , Rudolph KM , Hurlburt DA , Sacco F , McMahon BJ , Bruce MG . J Med Microbiol 2020 69 (2) 218-227 Introduction. Gastric cancer is a health disparity in the Alaska Native people. The incidence of Helicobacter pylori infection, a risk factor for non-cardia gastric adenocarcinoma, is also high. Gastric cancer is partially associated with the virulence of the infecting strain.Aim. To genotype the vacA s, m and i and cag pathogenicity island (cagPAI) genes in H. pylori from Alaskans and investigate associations with gastropathy.Methodology. We enrolled patients with gastritis, peptic ulcer disease (PUD) and intestinal metaplasia (IM) in 1998-2005 and patients with gastric cancer in 2011-2013. Gastric biopsies were collected and cultured and PCR was performed to detect the presence of the right and left ends of the cagPAI, the cagA, cagE, cagT and virD4 genes and to genotype the vacA s, m and i regions.Results. We recruited 263 people; 22 (8 %) had no/mild gastritis, 121 (46 %) had moderate gastritis, 40 (15%) had severe gastritis, 38 (14 %) had PUD, 30 (11 %) had IM and 12 (5 %) had gastric cancer. H. pylori isolates from 150 (57%) people had an intact cagPAI; those were associated with a more severe gastropathy (P</=0.02 for all comparisons). H. pylori isolates from 77 % of people had either the vacA s1/i1/m1 (40 %; 94/234) or s2/i2/m2 (37 %; 86/234) genotype. vacA s1/i1/m1 was associated with a more severe gastropathy (P</=0.03 for all comparisons).Conclusions. In this population with high rates of gastric cancer, we found that just over half of the H. pylori contained an intact cagPAI and 40 % had the vacA s1/i1/m1 genotype. Infection with these strains was associated with a more severe gastropathy. |
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. |
Evaluation of Two Matrices for Long-Term, Ambient Storage of Bacterial DNA.
Miernyk KM , DeByle CK , Rudolph KM . Biopreserv Biobank 2017 15 (6) 529-534 BACKGROUND: Culture-independent molecular analyses allow researchers to identify diverse microorganisms. This approach requires microbiological DNA repositories. The standard for DNA storage is liquid nitrogen or ultralow freezers. These use large amounts of space, are costly to operate, and could fail. Room temperature DNA storage is a viable alternative. In this study, we investigated storage of bacterial DNA using two ambient storage matrices, Biomatrica DNAstable(R) Plus and GenTegra(R) DNA. METHODS: We created crude and clean DNA extracts from five Streptococcus pneumoniae isolates. Extracts were stored at -30 degrees C (our usual DNA storage temperature), 25 degrees C (within the range of temperatures recommended for the products), and 50 degrees C (to simulate longer storage time). Samples were stored at -30 degrees C with no product and dried at 25 degrees C and 50 degrees C with no product, in Biomatrica DNAstable Plus or GenTegra DNA. We analyzed the samples after 0, 1, 2, 4, 8, 16, 32, and 64 weeks using the Nanodrop 1000 to determine the amount of DNA in each aliquot and by real-time PCR for the S. pneumoniae genes lytA and psaA. Using a 50 degrees C storage temperature, we simulated 362 weeks of 25 degrees C storage. RESULTS: The average amount of DNA in aliquots stored with a stabilizing matrix was 103%-116% of the original amount added to the tubes. This is similar to samples stored at -30 degrees C (average 102%-121%). With one exception, samples stored with a stabilizing matrix had no change in lytA or psaA cycle threshold (Ct) value over time (Ct range ≤2.9), similar to samples stored at -30 degrees C (Ct range ≤3.0). Samples stored at 25 degrees C with no stabilizing matrix had Ct ranges of 2.2-5.1. CONCLUSION: DNAstable Plus and GenTegra DNA can protect dried bacterial DNA samples stored at room temperature with similar effectiveness as at -30 degrees C. It is not effective to store bacterial DNA at room temperature without a stabilizing matrix. |
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). |
A case-study of implementation of improved strategies for prevention of laboratory-acquired Brucellosis
Castrodale LJ , Raczniak GA , Rudolph KM , Chikoyak L , Cox RS , Franklin TL , Traxler RM , Guerra M . Saf Health Work 2015 6 (4) 353-6 BACKGROUND: In 2012, the Alaska Section of Epidemiology investigated personnel potentially exposed to a Brucella suis isolate as it transited through three laboratories. METHODS: We summarize the first implementation of the United States Centers for Disease Control and Prevention 2013 revised recommendations for monitoring such exposures: (1) risk classification; (2) antimicrobial postexposure prophylaxis; (3) serologic monitoring; and (4) symptom surveillance. RESULTS: Over 30 people were assessed for exposure and subsequently monitored for development of illness. No cases of laboratory-associated brucellosis occurred. Changes were made to gaps in laboratory biosafety practices that had been identified in the investigation. CONCLUSION: Achieving full compliance for the precise schedule of serologic monitoring was challenging and resource intensive for the laboratory performing testing. More refined exposure assessments could inform decision making for follow-up to maximize likelihood of detecting persons at risk while not overtaxing resources. |
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. |
MRSA USA300 at Alaska Native Medical Center, Anchorage, Alaska, USA, 2000-2006
David MZ , Rudolph KM , Hennessy TW , Zychowski DL , Asthi K , Boyle-Vavra S , Daum RS . Emerg Infect Dis 2012 18 (1) 105-8 To determine whether methicillin-resistant Staphylococcus aureus (MRSA) USA300 commonly caused infections among Alaska Natives, we examined clinical MRSA isolates from the Alaska Native Medical Center, Anchorage, during 2000-2006. Among Anchorage-region residents, USA300 was a minor constituent among MRSA isolates in 2000-2003 (11/68, 16%); by 2006, USA300 was the exclusive genotype identified (10/10). |
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). |
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