Last data update: Dec 09, 2024. (Total: 48320 publications since 2009)
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COVID-19 Outbreaks in Correctional Facilities with Work-Release Programs - Idaho, July-November 2020.
Dunne EM , Morgan E , Wells-Moore B , Pierson S , Zakroff S , Haskell L , Link K , Powell J , Holland I , Elgethun K , Ball C , Haugen R , Hahn CG , Carter KK , Starr C . MMWR Morb Mortal Wkly Rep 2021 70 (16) 589-594 As of April 16, 2021, U.S. correctional and detention facilities reported 399,631 cases of COVID-19 in incarcerated persons, resulting in 2,574 deaths (1). During July 14-November 30, 2020, COVID-19 was diagnosed in 382 persons incarcerated in Idaho correctional facilities with work-release programs. Work-release programs (which place incarcerated persons in community businesses) have social and economic benefits, but might put participants at increased risk for bidirectional transmission of SARS-CoV-2, the virus that causes COVID-19. The Idaho Department of Correction (IDOC) operates 13 state-run correctional facilities, including six low-security facilities dedicated to work-release programs. This report describes COVID-19 outbreaks in five IDOC facilities with work-release programs,* provides the mitigation strategies that IDOC implemented, and describes the collaborative public health response. As of November 30, 2020, 382 outbreak-related COVID-19 cases were identified among incarcerated persons in five Idaho correctional facilities with work-release programs; two outbreaks were linked to food processing plants. Mitigation strategies that helped to control outbreaks in IDOC facilities with work-release programs included isolation of persons with COVID-19, identification and quarantine of close contacts, mass testing of incarcerated persons and staff members, and temporary suspension of work-release programs. Implementation of public health recommendations for correctional and detention facilities with work-release programs, including mass testing and identification of high-risk work sites, can help mitigate SARS-CoV-2 outbreaks. Incarcerated persons participating in work-release should be included in COVID-19 vaccination plans. |
Whole Genome Sequencing to Identify Drivers of Carbapenem-Resistant Klebsiella pneumoniae Transmission Within and Between Regional Long-Term Acute Care Hospitals.
Han JH , Lapp Z , Bushman F , Lautenbach E , Goldstein EJC , Mattei L , Hofstaedter CE , Kim D , Nachamkin I , Garrigan C , Jain T , Bilker W , Wolford HM , Slayton RB , Wise J , Tolomeo P , Snitkin ES . Antimicrob Agents Chemother 2019 63 (11) Carbapenem-resistant Klebsiella pneumoniae (CRKP) is an antibiotic resistance threat of the highest priority. Given the limited treatment options for this multidrug-resistant organism (MDRO), there is an urgent need for targeted strategies to prevent transmission. Here, we applied whole-genome sequencing to a comprehensive collection of clinical isolates to reconstruct regional transmission pathways, and analyzed this transmission network in the context of statewide patient transfer data and patient-level clinical data to identify drivers of regional transmission. We found that high regional CRKP burden was due to a small number of regional introductions, with subsequent regional proliferation occurring via patient transfers among healthcare facilities. While CRKP was predicted to be imported into each facility multiple times, there was substantial variation in the ratio of intra-facility transmission events per importation, indicating that amplification occurs unevenly across regional facilities. While myriad factors likely influence intra-facility transmission rates, an understudied one is the potential for clinical characteristics of colonized and infected patient to influence their propensity for transmission. Supporting the contribution of high-risk patients to elevated transmission rates, we observed that CRKP colonized and infected patients in high transmission facilities had higher rates of carbapenem use, malnutrition, old age and dialysis. This study highlights the potential for regional infection prevention efforts that are grounded in genomic epidemiology to identify patients and facilities that make the greatest contribution to regional MDRO prevalence, thereby facilitating the design of precision interventions of maximal impact. |
Streptococcus infantis, Streptococcus mitis , and Streptococcus oralis Strains With Highly Similar cps5 Loci and Antigenic Relatedness to Serotype 5 Pneumococci.
Pimenta F , Gertz RE Jr , Park SH , Kim E , Moura I , Milucky J , Rouphael N , Farley MM , Harrison LH , Bennett NM , Bigogo G , Feikin DR , Breiman R , Lessa FC , Whitney CG , Rajam G , Schiffer J , da Gloria Carvalho M , Beall B . Front Microbiol 2018 9 3199 Streptococcus pneumoniae is a highly impactful bacterial pathogen on a global scale. The principal pneumococcal virulence factor and target of effective vaccines is its polysaccharide capsule, of which there are many structurally distinct forms. Here, we describe four distinct strains of three Mitis group commensal species (Streptococcus infantis, Streptococcus mitis, and Streptococcus oralis) recovered from upper respiratory tract specimens from adults in Kenya and the United States that were PCR-positive for the pneumococcal serotype 5 specific gene, wzy5. For each of the four strains, the 15 genes comprising the capsular polysaccharide biosynthetic gene cluster (cps5) shared the same order found in serotype 5 pneumococci, and each of the serotype 5-specific genes from the serotype 5 pneumococcal reference strain shared 76-99% sequence identity with the non-pneumococcal counterparts. Double-diffusion experiments demonstrated specific reactivity of the non-pneumococcal strains with pneumococcal serotype 5 typing sera. Antiserum raised against S. mitis strain KE67013 specifically reacted with serotype 5 pneumococci for a positive Quellung reaction and stimulated serotype 5 specific opsonophagocytic killing of pneumococci. Four additional commensal strains, identified using PCR serotyping assays on pharyngeal specimens, revealed loci highly homologous to those of pneumococci of serotypes 12F, 15A, 18C, and 33F. These data, in particular the species and strain diversity shown for serotype 5, highlight the existence of a broad non-pneumococcal species reservoir in the upper respiratory tract for the expression of capsular polysaccharides that are structurally related or identical to those corresponding to epidemiologically significant serotypes. Very little is known about the genetic and antigenic capsular diversity among the vast array of commensal streptococcal strains that represent multiple diverse species. The discovery of serotype 5 strains within three different commensal species suggests that extensive capsular serologic overlap exists between pneumococci and other members of the diverse Mitis group. These findings may have implications for our current understanding of naturally acquired immunity to S. pneumoniae and pneumococcal serotype distributions in different global regions. Further characterization of commensal strains carrying homologs of serotype-specific genes previously thought to be specific for pneumococci of known serotypes may shed light on the evolution of these important loci. |
Active Ebola Virus Replication and Heterogeneous Evolutionary Rates in EVD Survivors.
Whitmer SLM , Ladner JT , Wiley MR , Patel K , Dudas G , Rambaut A , Sahr F , Prieto K , Shepard SS , Carmody E , Knust B , Naidoo D , Deen G , Formenty P , Nichol ST , Palacios G , Stroher U . Cell Rep 2018 22 (5) 1159-1168 Following cessation of continuous Ebola virus (EBOV) transmission within Western Africa, sporadic EBOV disease (EVD) cases continued to re-emerge beyond the viral incubation period. Epidemiological and genomic evidence strongly suggests that this represented transmission from EVD survivors. To investigate whether persistent infections are characterized by ongoing viral replication, we sequenced EBOV from the semen of nine EVD survivors and a subset of corresponding acute specimens. EBOV evolutionary rates during persistence were either similar to or reduced relative to acute infection rates. Active EBOV replication/transcription continued during convalescence, but decreased over time, consistent with viral persistence rather than viral latency. Patterns of genetic divergence suggest a moderate relaxation of selective constraints within the sGP carboxy-terminal tail during persistent infections, but do not support widespread diversifying selection. Altogether, our data illustrate that EBOV persistence in semen, urine, and aqueous humor is not a quiescent or latent infection. |
Interlaboratory standardization of the sandwich enzyme-linked immunosorbent assay designed for MATS, a rapid, reproducible method for estimating the strain coverage of investigational vaccines
Plikaytis BD , Stella M , Boccadifuoco G , Detora LM , Agnusdei M , Santini L , Brunelli B , Orlandi L , Simmini I , Giuliani M , Ledroit M , Hong E , Taha MK , Ellie K , Rajam G , Carlone GM , Claus H , Vogel U , Borrow R , Findlow J , Gilchrist S , Stefanelli P , Fazio C , Carannante A , Oksnes J , Fritzsonn E , Klem AM , Caugant DA , Abad R , Vazquez JA , Rappuoli R , Pizza M , Donnelly JJ , Medini D . Clin Vaccine Immunol 2012 19 (10) 1609-17 The meningococcal antigen typing system (MATS) sandwich enzyme-linked immunosorbent assay (ELISA) was designed to measure the immunologic cross-reactivity and quantity of antigens in target strains of a pathogen. It was first used to measure the factor H-binding protein (fHbp), neisserial adhesin A (NadA), and neisserial heparin-binding antigen (NHBA) content of serogroup B meningococcal (MenB) isolates relative to a reference strain, or "relative potency" (RP). With the PorA genotype, the RPs were then used to assess strain coverage by 4CMenB, a multicomponent MenB vaccine. In preliminary studies, MATS accurately predicted killing in the serum bactericidal assay using human complement, an accepted correlate of protection for meningococcal vaccines. A study across seven laboratories assessed the reproducibility of RPs for fHbp, NadA, and NHBA and established qualification parameters for new laboratories. RPs were determined in replicate for 17 MenB reference strains at laboratories A to G. The reproducibility of RPs among laboratories and against consensus values across laboratories was evaluated using a mixed-model analysis of variance. Interlaboratory agreement was very good; the Pearson correlation coefficients, coefficients of accuracy, and concordance correlation coefficients exceeded 99%. The summary measures of reproducibility, expressed as between-laboratory coefficients of variation, were 7.85% (fHbp), 16.51% (NadA), and 12.60% (NHBA). The overall within-laboratory measures of variation adjusted for strain and laboratory were 19.8% (fHbp), 28.8% (NHBA), and 38.3% (NadA). The MATS ELISA was successfully transferred to six laboratories, and a further laboratory was successfully qualified. |
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