Last data update: Apr 22, 2024. (Total: 46599 publications since 2009)
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Reliability of the 2021 National Youth Risk Behavior Survey Questionnaire
Jones SE , Brener ND , Queen B , Hershey-Arista M , Harris WA , Mpofu JJ , Underwood JM . Am J Health Promot 2024 8901171241239735 PURPOSE: The Youth Risk Behavior Survey (YRBS) monitors behaviors, experiences, and conditions affecting the health of high school students nationwide. This study examined the test-retest reliability of the 2021 national YRBS questionnaire. DESIGN: Respondents completed a Time 1 and Time 2 paper-and-pencil questionnaire approximately 2 weeks apart during February to May 2022. Data were linked in such a way as to preserve anonymity. SETTING: Convenience sample of high schools. SUBJECTS: High school students (N = 588). MEASURES: Health risk behaviors and experiences assessed on the 2021 national YRBS questionnaire. ANALYSIS: Time 1 and Time 2 responses were compared for each questionnaire item using the McNemar's test. Then, Cohen's kappa coefficients tested the agreement between Time 1 and Time 2 responses overall, and by sex, grade, and Black, White, and Hispanic race and ethnicity. RESULTS: Among the 74 items analyzed, 96% had at least moderate reliability, and 73% had substantial or almost perfect reliability. The mean Cohen's kappa was .68. McNemar's test findings showed Time 1 and Time 2 data significantly differed (P < .01) for 9 items (12%). CONCLUSION: Reliable health behavior measures are important in the development of youth-focused public health programs and policies. Findings suggest the national YRBS questionnaire is a reliable instrument. Such findings lend support to relying on adolescent self-reported data when monitoring health behaviors using the YRBS. |
Overview and methods for the youth risk behavior surveillance system - United States, 2021
Mpofu JJ , Underwood JM , Thornton JE , Brener ND , Rico A , Kilmer G , Harris WA , Leon-Nguyen M , Chyen D , Lim C , Mbaka CK , Smith-Grant J , Whittle L , Jones SE , Krause KH , Li J , Shanklin SL , McKinnon I , Arrey L , Queen BE , Roberts AM . MMWR Suppl 2023 72 (1) 1-12 The Youth Risk Behavior Surveillance System (YRBSS) is the largest public health surveillance system in the United States, monitoring a broad range of health-related behaviors among high school students. The system includes a nationally representative Youth Risk Behavior Survey (YRBS) and separate school-based YRBSs conducted by states, tribes, territories, and local school districts. In 2021, these surveys were conducted during the COVID-19 pandemic. The pandemic underscored the importance of data in understanding changes in youth risk behaviors and addressing the multifaceted public health needs of youths. This overview report describes 2021 YRBSS survey methodology, including sampling, data collection procedures, response rates, data processing, weighting, and analyses. The 2021 YRBS participation map, survey response rates, and a detailed examination of student demographic characteristics are included in this report. During 2021, in addition to the national YRBS, a total of 78 surveys were administered to high school students across the United States, representing the national population, 45 states, two tribal governments, three territories, and 28 local school districts. YRBSS data from 2021 provided the first opportunity since the onset of the COVID-19 pandemic to compare youth health behaviors using long-term public health surveillance. Approximately half of all student respondents represented racial and ethnic minority groups, and approximately one in four identified as lesbian, gay, bisexual, questioning, or other (a sexual identity other than heterosexual) (LGBQ+). These findings reflect shifts in youth demographics, with increased percentages of racial and ethnic minority and LGBQ+ youths compared with previous YRBSS cycles. Educators, parents, local decision makers, and other partners use YRBSS data to monitor health behavior trends, guide school health programs, and develop local and state policy. These and future data can be used in developing health equity strategies to address long-term disparities so that all youths can thrive in safe and supportive environments. This overview and methods report is one of 11 featured in this MMWR supplement. Each report is based on data collected using methods presented in this overview. A full description of YRBSS results and downloadable data are available (https://www.cdc.gov/healthyyouth/data/yrbs/index.htm). |
Overview and methods for the Youth Risk Behavior Surveillance System - United States, 2019
Underwood JM , Brener N , Thornton J , Harris WA , Bryan LN , Shanklin SL , Deputy N , Roberts AM , Queen B , Chyen D , Whittle L , Lim C , Yamakawa Y , Leon-Nguyen M , Kilmer G , Smith-Grant J , Demissie Z , Jones SE , Clayton H , Dittus P . MMWR Suppl 2020 69 (1) 1-10 Health risk behaviors practiced during adolescence often persist into adulthood and contribute to the leading causes of morbidity and mortality in the United States. Youth health behavior data at the national, state, territorial, tribal, and local levels help monitor the effectiveness of public health interventions designed to promote adolescent health. The Youth Risk Behavior Surveillance System (YRBSS) is the largest public health surveillance system in the United States, monitoring a broad range of health-related behaviors among high school students. YRBSS includes a nationally representative Youth Risk Behavior Survey (YRBS) and separate state, local school district, territorial, and tribal school-based YRBSs. This overview report describes the surveillance system and the 2019 survey methodology, including sampling, data collection procedures, response rates, data processing, weighting, and analyses presented in this MMWR Supplement. A 2019 YRBS participation map, survey response rates, and student demographic characteristics are included. In 2019, a total of 78 YRBSs were administered to high school student populations across the United States (national and 44 states, 28 local school districts, three territories, and two tribal governments), the greatest number of participating sites with representative data since the surveillance system was established in 1991. The nine reports in this MMWR Supplement are based on national YRBS data collected during August 2018-June 2019. A full description of 2019 YRBS results and downloadable data are available (https://www.cdc.gov/healthyyouth/data/yrbs/index.htm).Efforts to improve YRBSS and related data are ongoing and include updating reliability testing for the national questionnaire, transitioning to electronic survey administration (e.g., pilot testing for a tablet platform), and exploring innovative analytic methods to stratify data by school-level socioeconomic status and geographic location. Stakeholders and public health practitioners can use YRBS data (comparable across national, state, tribal, territorial, and local jurisdictions) to estimate the prevalence of health-related behaviors among different student groups, identify student risk behaviors, monitor health behavior trends, guide public health interventions, and track progress toward national health objectives. |
Epidemiology of human seasonal coronaviruses among people with mild and severe acute respiratory illness in Blantyre, Malawi, 2011-2017
Kovacs D , Mambule I , Read JM , Kiran A , Chilombe M , Bvumbwe T , Aston S , Menyere M , Masina M , Kamzati M , Ganiza TN , Iuliano D , McMorrow M , Bar-Zeev N , Everett D , French N , Ho A . J Infect Dis 2024 BACKGROUND: The aim of this study was to characterize the epidemiology of human seasonal coronaviruses (HCoVs) in southern Malawi. METHODS: We tested for HCoVs 229E, OC43, NL63, and HKU1 using real-time polymerase chain reaction (PCR) on upper respiratory specimens from asymptomatic controls and individuals of all ages recruited through severe acute respiratory illness (SARI) surveillance at Queen Elizabeth Central Hospital, Blantyre, and a prospective influenza-like illness (ILI) observational study between 2011 and 2017. We modeled the probability of having a positive PCR for each HCoV using negative binomial models, and calculated pathogen-attributable fractions (PAFs). RESULTS: Overall, 8.8% (539/6107) of specimens were positive for ≥1 HCoV. OC43 was the most frequently detected HCoV (3.1% [191/6107]). NL63 was more frequently detected in ILI patients (adjusted incidence rate ratio [aIRR], 9.60 [95% confidence interval {CI}, 3.25-28.30]), while 229E (aIRR, 8.99 [95% CI, 1.81-44.70]) was more frequent in SARI patients than asymptomatic controls. In adults, 229E and OC43 were associated with SARI (PAF, 86.5% and 89.4%, respectively), while NL63 was associated with ILI (PAF, 85.1%). The prevalence of HCoVs was similar between children with SARI and controls. All HCoVs had bimodal peaks but distinct seasonality. CONCLUSIONS: OC43 was the most prevalent HCoV in acute respiratory illness of all ages. Individual HCoVs had distinct seasonality that differed from temperate settings. |
Reliability of the 2020 school health profiles principal and lead health education teacher questionnaires
Jones SE , Brener ND , Queen B , Hershey-Arista M , Harris W , Underwood JM . J Sch Health 2024 BACKGROUND: School Health Profiles assesses school health policies and practices among US secondary schools. METHODS: The 2020 School Health Profiles principal and teacher questionnaires were used for a test-retest reliability study. Cohen's kappa coefficients tested the agreement in dichotomous responses to each questionnaire variable at 2 time points. The aggregate prevalence estimates between time 1 and time 2 were compared for each questionnaire item via overlapping 95% confidence intervals. Chi-square tests examined whether the prevalence at time 2 differed between paper and web administration for both questionnaires. RESULTS: For the principal (N = 50) and teacher (N = 34) data, there were no significant differences in the prevalence of any items between time 1 and time 2. For the principal survey, the mean kappa for 191 variables was 0.49. For the teacher survey, the mean kappa for 260 variables was 0.65. Overall, 60.7% of principal and 91.1% of teacher questionnaire items had at least "moderate" reliability. CONCLUSIONS: School Health Profiles offers education and health agencies a reliable tool to monitor school policies and practices. |
One Health Investigation of SARS-CoV-2 Infection and Seropositivity among Pets in Households with Confirmed Human COVID-19 Cases — Utah and Wisconsin, 2020 (preprint)
Goryoka GW , Cossaboom CM , Gharpure R , Dawson P , Tansey C , Rossow J , Mrotz V , Rooney J , Torchetti M , Loiacono CM , Killian ML , Jenkins-Moore M , Lim A , Poulsen K , Christensen D , Sweet E , Peterson D , Sangster AL , Young EL , Oakeson KF , Taylor D , Price A , Kiphibane T , Klos R , Konkle D , Bhattacharyya S , Dasu T , Chu VT , Lewis NM , Queen K , Zhang J , Uehara A , Dietrich EA , Tong S , Kirking HL , Doty JB , Murrell LS , Spengler JR , Straily A , Wallace R , Barton Behravesh C . bioRxiv 2021 2021.04.11.439379 Background Approximately 67% of U.S. households have pets. Limited data are available on SARS-CoV-2 in pets. We assessed SARS-CoV-2 infection in pet cohabitants as a sub-study of an ongoing COVID-19 household transmission investigation.Methods Mammalian pets from households with ≥1 person with laboratory-confirmed COVID-19 were eligible for inclusion from April–May 2020. Demographic/exposure information, oropharyngeal, nasal, rectal, and fur swabs, feces, and blood were collected from enrolled pets and tested by rRT-PCR and virus neutralization assays.Findings We enrolled 37 dogs and 19 cats from 34 of 41 eligible households. All oropharyngeal, nasal, and rectal swabs tested negative by rRT-PCR; one dog’s fur swabs (2%) tested positive by rRT-PCR at the first animal sampling. Among 47 pets with serological results from 30 households, eight (17%) pets (4 dogs, 4 cats) from 6 (20%) households had detectable SARS-CoV-2 neutralizing antibodies. In households with a seropositive pet, the proportion of people with laboratory-confirmed COVID-19 was greater (median 79%; range: 40–100%) compared to households with no seropositive pet (median 37%; range: 13–100%) (p=0.01). Thirty-three pets with serologic results had frequent daily contact (≥1 hour) with the human index patient before the person’s COVID-19 diagnosis. Of these 33 pets, 14 (42%) had decreased contact with the human index patient after diagnosis and none (0%) were seropositive; of the 19 (58%) pets with continued contact, 4 (21%) were seropositive.Interpretations Seropositive pets likely acquired infection from humans, which may occur more frequently than previously recognized. People with COVID-19 should restrict contact with animals.Funding Centers for Disease Control and Prevention, U.S. Department of AgricultureCompeting Interest StatementThe authors have declared no competing interest. |
Rapid, sensitive, full genome sequencing of Severe Acute Respiratory Syndrome Virus Coronavirus 2 (SARS-CoV-2) (preprint)
Paden CR , Tao Y , Queen K , Zhang J , Li Y , Uehara A , Tong S . bioRxiv 2020 2020.04.22.055897 SARS-CoV-2 recently emerged, resulting a global pandemic. Rapid genomic information is critical to understanding transmission and pathogenesis. Here, we describe validated protocols for generating high-quality full-length genomes from primary samples. The first employs multiplex RT-PCR followed by MinION or MiSeq sequencing. The second uses singleplex, nested RT-PCR and Sanger sequencing.Competing Interest StatementThe authors have declared no competing interest. |
From people to Panthera: Natural SARS-CoV-2 infection in tigers and lions at the Bronx Zoo (preprint)
McAloose D , Laverack M , Wang L , Killian ML , Caserta LC , Yuan F , Mitchell PK , Queen K , Mauldin MR , Cronk BD , Bartlett SL , Sykes JM , Zec S , Stokol T , Ingerman K , Delaney MA , Fredrickson R , Ivančić M , Jenkins-Moore M , Mozingo K , Franzen K , Bergeson NH , Goodman L , Wang H , Fang Y , Olmstead C , McCann C , Thomas P , Goodrich E , Elvinger F , Smith DC , Tong S , Slavinski S , Calle PP , Terio K , Torchetti MK , Diel DG . bioRxiv 2020 2020.07.22.213959 We describe the first cases of natural SARS-CoV-2 infection detected in animals in the United States. In March 2020, four tigers and three lions at the Bronx Zoo developed mild respiratory signs. SARS-CoV-2 RNA was detected by rRT-PCR in respiratory secretions and/or feces from all seven affected animals; viral RNA and/or antibodies were detected in their keepers. SARS-CoV-2 was isolated from respiratory secretions or feces from three affected animals; in situ hybridization co-localized viral RNA with cellular damage. Whole genome sequence and haplotype network analyses showed tigers and lions were infected with two different SARS-CoV-2 strains, suggesting independent viral introductions. The source of SARS-CoV-2 infection in the lions is unknown. Epidemiological data and genetic similarities between keeper and tiger viruses indicate human to animal transmission.Competing Interest StatementThe authors have declared no competing interest. |
Surface-aerosol stability and pathogenicity of diverse MERS-CoV strains from 2012 - 2018 (preprint)
van Doremalen N , Letko M , Fischer RJ , Bushmaker T , Yinda CK , Schulz J , Seifert SN , Kim NJ , Hemida MG , Kayali G , Park WB , Perera RA , Tamin A , Thornburg NJ , Tong S , Queen K , van Kerkhove MD , Choi YK , Oh MD , Assiri AM , Peiris M , Gerber SI , Munster VJ . bioRxiv 2021 Middle East Respiratory Syndrome coronavirus (MERS-CoV) is a coronavirus that infects both humans and dromedary camels and is responsible for an ongoing outbreak of severe respiratory illness in humans in the Middle East. While some mutations found in camel-derived MERS-CoV strains have been characterized, the majority of natural variation found across MERS-CoV isolates remains unstudied. Here we report on the environmental stability, replication kinetics and pathogenicity of several diverse isolates of MERS-CoV as well as SARS-CoV-2 to serve as a basis of comparison with other stability studies. While most of the MERS-CoV isolates exhibited similar stability and pathogenicity in our experiments, the camel derived isolate, C/KSA/13, exhibited reduced surface stability while another camel isolate, C/BF/15, had reduced pathogenicity in a small animal model. These results suggest that while betacoronaviruses may have similar environmental stability profiles, individual variation can influence this phenotype, underscoring the importance of continual, global viral surveillance. |
Characteristics of Nursing Home Residents and Healthcare Personnel with Repeat Positive SARS-CoV-2 Tests ≥ 90 Days After Initial Infection: 4 U.S. Jurisdictions, July 2020 - March 2021.
Wilson WW , Hatfield KM , Tressler S , BickingKinsey C , Parra G , Zell R , Denson A , Williams C , Spicer KB , Kamal-Ahmed I , Abdalhamid B , Gemechu M , Folster J , Thornburg NJ , Tamin A , Harcourt JL , Queen K , Tong S , Jernigan JA , Crist M , Perkins KM , Reddy SC . Infect Control Hosp Epidemiol 2023 44 (5) 809-812 One in six nursing home residents and staff with positive SARS-CoV-2 tests 90 days after initial infection had specimen cycle thresholds (Ct) <30. Individuals with specimen Ct<30 were more likely to report symptoms but were not different from individuals with high Ct value specimens by other clinical and testing data. |
Cryptic transmission of SARS-CoV-2 in Washington State.
Bedford T , Greninger AL , Roychoudhury P , Starita LM , Famulare M , Huang ML , Nalla A , Pepper G , Reinhardt A , Xie H , Shrestha L , Nguyen TN , Adler A , Brandstetter E , Cho S , Giroux D , Han PD , Fay K , Frazar CD , Ilcisin M , Lacombe K , Lee J , Kiavand A , Richardson M , Sibley TR , Truong M , Wolf CR , Nickerson DA , Rieder MJ , Englund JA , Hadfield J , Hodcroft EB , Huddleston J , Moncla LH , Müller NF , Neher RA , Deng X , Gu W , Federman S , Chiu C , Duchin J , Gautom R , Melly G , Hiatt B , Dykema P , Lindquist S , Queen K , Tao Y , Uehara A , Tong S , MacCannell D , Armstrong GL , Baird GS , Chu HY , Shendure J , Jerome KR . medRxiv 2020 Following its emergence in Wuhan, China, in late November or early December 2019, the SARS-CoV-2 virus has rapidly spread throughout the world. On March 11, 2020, the World Health Organization declared Coronavirus Disease 2019 (COVID-19) a pandemic. Genome sequencing of SARS-CoV-2 strains allows for the reconstruction of transmission history connecting these infections. Here, we analyze 346 SARS-CoV-2 genomes from samples collected between 20 February and 15 March 2020 from infected patients in Washington State, USA. We found that the large majority of SARS-CoV-2 infections sampled during this time frame appeared to have derived from a single introduction event into the state in late January or early February 2020 and subsequent local spread, strongly suggesting cryptic spread of COVID-19 during the months of January and February 2020, before active community surveillance was implemented. We estimate a common ancestor of this outbreak clade as occurring between 18 January and 9 February 2020. From genomic data, we estimate an exponential doubling between 2.4 and 5.1 days. These results highlight the need for large-scale community surveillance for SARS-CoV-2 introductions and spread and the power of pathogen genomics to inform epidemiological understanding. |
Travel history among persons infected with SARS-CoV-2 variants of concern in the United States, December 2020-February 2021.
Dunajcik A , Haire K , Thomas JD , Moriarty LF , Springer Y , Villanueva JM , MacNeil A , Silk B , Nemhauser JB , Byrkit R , Taylor M , Queen K , Tong S , Lee J , Batra D , Paden C , Henderson T , Kunkes A , Ojo M , Firestone M , Martin Webb L , Freeland M , Brown CM , Williams T , Allen K , Kauerauf J , Wilson E , Jain S , McDonald E , Silver E , Stous S , Wadford D , Radcliffe R , Marriott C , Owes JP , Bart SM , Sosa LE , Oakeson K , Wodniak N , Shaffner J , Brown Q , Westergaard R , Salinas A , Hallyburton S , Ogale Y , Offutt-Powell T , Bonner K , Tubach S , Van Houten C , Hughes V , Reeb V , Galeazzi C , Khuntia S , McGee S , Hicks JT , Dinesh Patel D , Krueger A , Hughes S , Jeanty F , Wang JC , Lee EH , Assanah-Deane T , Tompkins M , Dougherty K , Naqvi O , Donahue M , Frederick J , Abdalhamid B , Powers AM , Anderson M . PLOS Glob Public Health 2023 3 (3) e0001252 The first three SARS-CoV-2 phylogenetic lineages classified as variants of concern (VOCs) in the United States (U.S.) from December 15, 2020 to February 28, 2021, Alpha (B.1.1.7), Beta (B.1.351), and Gamma (P.1) lineages, were initially detected internationally. This investigation examined available travel history of coronavirus disease 2019 (COVID-19) cases reported in the U.S. in whom laboratory testing showed one of these initial VOCs. Travel history, demographics, and health outcomes for a convenience sample of persons infected with a SARS-CoV-2 VOC from December 15, 2020 through February 28, 2021 were provided by 35 state and city health departments, and proportion reporting travel was calculated. Of 1,761 confirmed VOC cases analyzed, 1,368 had available data on travel history. Of those with data on travel history, 1,168 (85%) reported no travel preceding laboratory confirmation of SARS-CoV-2 and only 105 (8%) reported international travel during the 30 days preceding a positive SARS-CoV-2 test or symptom onset. International travel was reported by 92/1,304 (7%) of persons infected with the Alpha variant, 7/55 (22%) with Beta, and 5/9 (56%) with Gamma. Of the first three SARS-CoV-2 lineages designated as VOCs in the U.S., international travel was common only among the few Gamma cases. Most persons infected with Alpha and Beta variant reported no travel history, therefore, community transmission of these VOCs was likely common in the U.S. by March 2021. These findings underscore the importance of global surveillance using whole genome sequencing to detect and inform mitigation strategies for emerging SARS-CoV-2 VOCs. |
When a Touch of Gold Was Used to Heal the King’s Evil
Krugman J , Chorba T . Emerg Infect Dis 2022 28 (3) 765-7 Throughout history, divine approval has been claimed by many rulers in establishing legitimacy of their monarchy and has been integral to governance in the development of many cultures. In ancient and Imperial China, a tradition of a mandate of heaven, as the will of the universe or natural law, was used to justify the position of the ruler. In the Inca Empire, the traditional ruler was considered the progeny of the sun god and in that capacity had to be accorded absolute power over the people, such as the sun itself has. European history is replete with similar traditions of monarchical claims for legitimacy. In Britain and in France, the evolution of the concept of “the divine right of kings” and the resultant philosophic traditions favoring or opposing such a concept shaped much of the history of the past millennium. Both monarchies claimed to rule by divine will, and to this day, the British Coronation service includes a sacred anointing of the new king or queen. | | Many religious traditions have had thaumaturgic (relating to supernatural powers) touch as a tradition. In Britain, reference to the monarch as having divine power in “the royal touch” dates to the 11th century, when it was believed that Edward the Confessor, last of the Anglo-Saxon kings, possessed powers to heal the sick through some form of laying on of hands. In official ceremonies in his and subsequent reigns, subjects could approach the monarch to seek the imperial touch, hoping to cure their ailments or diseases. For centuries, the disease that most readily lent itself to the occasional appearance of success in this regard was scrofula (i.e., lymphadenitis—most commonly tuberculous cervical lymphadenitis), which would manifest itself with painful and visible sores that could go into remission and even go into resolution, giving the impression of a royally induced cure. Scrofula is a term that has fallen into disuse like many other medical terms in English (e.g., catarrh, ague, quinsy, dropsy, and grippe), principally because of diagnostic advances and more precise disease characterization. However, because of the association of its spontaneous remission with the royal touch, tuberculous lymphadenitis was also called “the king's evil,” and throughout most of the past millennium, its presence in European populations was very common. |
Electronic versus paper and pencil survey administration mode comparison: 2019 Youth Risk Behavior Survey
Bryan LN , Smith-Grant J , Brener N , Kilmer G , Lo A , Queen B , Underwood JM . J Sch Health 2022 92 (8) 804-811 BACKGROUND: Since the inception of the Youth Risk Behavior Surveillance System in 1991, all surveys have been conducted in schools, using paper and pencil instruments (PAPI). For the 2019 YRBSS, sites were offered the opportunity to conduct their surveys using electronic data collection. This study aimed to determine whether differences in select metrics existed between students who completed the survey electronically versus using PAPI. METHODS: Thirty risk behaviors were examined in this study. Data completeness, response rates and bivariate comparisons of risk behavior prevalence between administration modes were examined. RESULTS: Twenty-nine of 30 questions examined had more complete responses among students using electronic surveys. Small differences were found for student and school response rates between modes. Twenty-five of 30 adolescent risk behaviors showed no mode effect. CONCLUSIONS: Seven of 44 states and DC participated electronically. Because survey data were more complete; school and student response rates were consistent; and minor differences existed in risk behaviors between modes, the acceptability of collecting data electronically was demonstrated. |
SARS-CoV-2 Outbreak among Malayan Tigers and Humans, Tennessee, USA, 2020.
Grome HN , Meyer B , Read E , Buchanan M , Cushing A , Sawatzki K , Levinson KJ , Thomas LS , Perry Z , Uehara A , Tao Y , Queen K , Tong S , Ghai R , Fill MM , Jones TF , Schaffner W , Dunn J . Emerg Infect Dis 2022 28 (4) 833-836 We report an outbreak of severe acute respiratory syndrome coronavirus 2 involving 3 Malayan tigers (Panthera tigris jacksoni) at a zoo in Tennessee, USA. Investigation identified naturally occurring tiger-to-tiger transmission; genetic sequence change occurred with viral passage. We provide epidemiologic, environmental, and genomic sequencing data for animal and human infections. |
Surface‒Aerosol Stability and Pathogenicity of Diverse Middle East Respiratory Syndrome Coronavirus Strains, 2012‒2018.
van Doremalen N , Letko M , Fischer RJ , Bushmaker T , Schulz J , Yinda CK , Seifert SN , Kim NJ , Hemida MG , Kayali G , Park WB , Perera Rapm , Tamin A , Thornburg NJ , Tong S , Queen K , van Kerkhove MD , Choi YK , Oh MD , Assiri AM , Peiris M , Gerber SI , Munster VJ . Emerg Infect Dis 2021 27 (12) 3052-3062 Middle East respiratory syndrome coronavirus (MERS-CoV) infects humans and dromedary camels and is responsible for an ongoing outbreak of severe respiratory illness in humans in the Middle East. Although some mutations found in camel-derived MERS-CoV strains have been characterized, most natural variation found across MERS-CoV isolates remains unstudied. We report on the environmental stability, replication kinetics, and pathogenicity of several diverse isolates of MERS-CoV, as well as isolates of severe acute respiratory syndrome coronavirus 2, to serve as a basis of comparison with other stability studies. Although most MERS-CoV isolates had similar stability and pathogenicity in our experiments, the camel-derived isolate C/KSA/13 had reduced surface stability, and another camel isolate, C/BF/15, had reduced pathogenicity in a small animal model. These results suggest that although betacoronaviruses might have similar environmental stability profiles, individual variation can influence this phenotype, underscoring the need for continual global viral surveillance. |
One Health Investigation of SARS-CoV-2 Infection and Seropositivity among Pets in Households with Confirmed Human COVID-19 Cases-Utah and Wisconsin, 2020.
Goryoka GW , Cossaboom CM , Gharpure R , Dawson P , Tansey C , Rossow J , Mrotz V , Rooney J , Torchetti M , Loiacono CM , Killian ML , Jenkins-Moore M , Lim A , Poulsen K , Christensen D , Sweet E , Peterson D , Sangster AL , Young EL , Oakeson KF , Taylor D , Price A , Kiphibane T , Klos R , Konkle D , Bhattacharyya S , Dasu T , Chu VT , Lewis NM , Queen K , Zhang J , Uehara A , Dietrich EA , Tong S , Kirking HL , Doty JB , Murrell LS , Spengler JR , Straily A , Wallace R , Barton Behravesh C . Viruses 2021 13 (9) Approximately 67% of U.S. households have pets. Limited data are available on SARS-CoV-2 in pets. We assessed SARS-CoV-2 infection in pets during a COVID-19 household transmission investigation. Pets from households with ≥1 person with laboratory-confirmed COVID-19 were eligible for inclusion from April-May 2020. We enrolled 37 dogs and 19 cats from 34 households. All oropharyngeal, nasal, and rectal swabs tested negative by rRT-PCR; one dog's fur swabs (2%) tested positive by rRT-PCR at the first sampling. Among 47 pets with serological results, eight (17%) pets (four dogs, four cats) from 6/30 (20%) households had detectable SARS-CoV-2 neutralizing antibodies. In households with a seropositive pet, the proportion of people with laboratory-confirmed COVID-19 was greater (median 79%; range: 40-100%) compared to households with no seropositive pet (median 37%; range: 13-100%) (p = 0.01). Thirty-three pets with serologic results had frequent daily contact (≥1 h) with the index patient before the person's COVID-19 diagnosis. Of these 33 pets, 14 (42%) had decreased contact with the index patient after diagnosis and none were seropositive; of the 19 (58%) pets with continued contact, four (21%) were seropositive. Seropositive pets likely acquired infection after contact with people with COVID-19. People with COVID-19 should restrict contact with pets and other animals. |
Genomic Surveillance for SARS-CoV-2 Variants Circulating in the United States, December 2020-May 2021.
Paul P , France AM , Aoki Y , Batra D , Biggerstaff M , Dugan V , Galloway S , Hall AJ , Johansson MA , Kondor RJ , Halpin AL , Lee B , Lee JS , Limbago B , MacNeil A , MacCannell D , Paden CR , Queen K , Reese HE , Retchless AC , Slayton RB , Steele M , Tong S , Walters MS , Wentworth DE , Silk BJ . MMWR Morb Mortal Wkly Rep 2021 70 (23) 846-850 SARS-CoV-2, the virus that causes COVID-19, is constantly mutating, leading to new variants (1). Variants have the potential to affect transmission, disease severity, diagnostics, therapeutics, and natural and vaccine-induced immunity. In November 2020, CDC established national surveillance for SARS-CoV-2 variants using genomic sequencing. As of May 6, 2021, sequences from 177,044 SARS-CoV-2-positive specimens collected during December 20, 2020-May 6, 2021, from 55 U.S. jurisdictions had been generated by or reported to CDC. These included 3,275 sequences for the 2-week period ending January 2, 2021, compared with 25,000 sequences for the 2-week period ending April 24, 2021 (0.1% and 3.1% of reported positive SARS-CoV-2 tests, respectively). Because sequences might be generated by multiple laboratories and sequence availability varies both geographically and over time, CDC developed statistical weighting and variance estimation methods to generate population-based estimates of the proportions of identified variants among SARS-CoV-2 infections circulating nationwide and in each of the 10 U.S. Department of Health and Human Services (HHS) geographic regions.* During the 2-week period ending April 24, 2021, the B.1.1.7 and P.1 variants represented an estimated 66.0% and 5.0% of U.S. SARS-CoV-2 infections, respectively, demonstrating the rise to predominance of the B.1.1.7 variant of concern(†) (VOC) and emergence of the P.1 VOC in the United States. Using SARS-CoV-2 genomic surveillance methods to analyze surveillance data produces timely population-based estimates of the proportions of variants circulating nationally and regionally. Surveillance findings demonstrate the potential for new variants to emerge and become predominant, and the importance of robust genomic surveillance. Along with efforts to characterize the clinical and public health impact of SARS-CoV-2 variants, surveillance can help guide interventions to control the COVID-19 pandemic in the United States. |
Isolation and characterization of novel reassortant mammalian orthoreovirus from pigs in the United States.
Wang L , Li Y , Walsh T , Shen Z , Li Y , Nath ND , Lee J , Zheng B , Tao Y , Paden CR , Queen K , Zhang S , Tong S , Ma W . Emerg Microbes Infect 2021 10 (1) 1-43 Mammalian orthoreovirus (MRV) infects multiple mammalian species including humans. A United States Midwest swine farm with approximately one thousand 3-month-old pigs experienced an event, in which more than 300 pigs showed neurological signs, like "down and peddling", with approximately 40% mortality. A novel MRV was isolated from the diseased pigs. Sequence and phylogenetic analysis revealed that the isolate was a reassortant virus containing viral gene segments from three MRV serotypes that infect human, bovine and swine. The M2 and S1 segment of the isolate showed 94% and 92% nucleotide similarity to the M2 of the MRV2 D5/Jones and the S1 of the MRV1 C/bovine/Indiana/MRV00304/2014, respectively; the remaining eight segments displayed 93%-94% nucleotide similarity to those of the MRV3 FS-03/Porcine/USA/2014. Pig studies showed that both MRV-infected and native contact pigs displayed fever, diarrhea and nasal discharge. MRV RNA was detected in different intestinal locations of both infected and contact pigs, indicating that the MRV isolate is pathogenic and transmissible in pigs. Seroconversion was also observed in experimentally infected pigs. A prevalence study on more than 180 swine serum samples collected from two states without disease revealed 40-52% positive to MRV. All results warrant the necessity to monitor MRV epidemiology and reassortment as the MRV could be an important pathogen for the swine industry and a novel MRV might emerge to threaten animal and public health. |
Epidemiologic characteristics associated with SARS-CoV-2 antigen-based test results, rRT-PCR cycle threshold values, subgenomic RNA, and viral culture results from university testing.
Ford L , Lee C , Pray IW , Cole D , Bigouette JP , Abedi GR , Bushman D , Delahoy MJ , Currie DW , Cherney B , Kirby M , Fajardo G , Caudill M , Langolf K , Kahrs J , Zochert T , Kelly P , Pitts C , Lim A , Aulik N , Tamin A , Harcourt JL , Queen K , Zhang J , Whitaker B , Browne H , Medrzycki M , Shewmaker P , Bonenfant G , Zhou B , Folster J , Bankamp B , Bowen MD , Thornburg NJ , Goffard K , Limbago B , Bateman A , Tate JE , Gieryn D , Kirking HL , Westergaard R , Killerby M . Clin Infect Dis 2021 73 (6) e1348-e1355 BACKGROUND: Real-time reverse transcription polymerase chain reaction (rRT-PCR) and antigen tests are important diagnostics for SARS-CoV-2. Sensitivity of antigen tests has been shown to be lower than that of rRT-PCR; however, data to evaluate epidemiologic characteristics that affect test performance are limited. METHODS: Paired mid-turbinate nasal swabs were collected from university students and staff and tested for SARS-CoV-2 using both Quidel Sofia SARS Antigen Fluorescent Immunoassay (FIA) and rRT-PCR assay. Specimens positive by either rRT-PCR or antigen FIA were placed in viral culture and tested for subgenomic RNA (sgRNA). Logistic regression models were used to evaluate characteristics associated with antigen results, rRT-PCR cycle threshold (Ct) values, sgRNA, and viral culture. RESULTS: Antigen FIA sensitivity was 78.9% and 43.8% among symptomatic and asymptomatic participants respectively. Among rRT-PCR positive participants, negative antigen results were more likely among asymptomatic participants (OR 4.6, CI:1.3-15.4) and less likely among participants reporting nasal congestion (OR 0.1, CI:0.03-0.8). rRT-PCR-positive specimens with higher Ct values (OR 0.5, CI:0.4-0.8) were less likely, and specimens positive for sgRNA (OR 10.2, CI:1.6-65.0) more likely, to yield positive virus isolation. Antigen testing was >90% positive in specimens with Ct values <29. Positive predictive value of antigen test for positive viral culture (57.7%) was similar to that of rRT-PCR (59.3%). CONCLUSIONS: SARS-CoV-2 antigen test advantages include low cost, wide availability and rapid turnaround time, making them important screening tests. The performance of antigen tests may vary with patient characteristics, so performance characteristics should be accounted for when designing testing strategies and interpreting results. |
Clinical and Laboratory Findings in Patients with Potential SARS-CoV-2 Reinfection, May-July 2020.
Lee JT , Hesse EM , Paulin HN , Datta D , Katz LS , Talwar A , Chang G , Galang RR , Harcourt JL , Tamin A , Thornburg NJ , Wong KK , Stevens V , Kim K , Tong S , Zhou B , Queen K , Drobeniuc J , Folster JM , Sexton DJ , Ramachandran S , Browne H , Iskander J , Mitruka K . Clin Infect Dis 2021 73 (12) 2217-2225 BACKGROUND: We investigated patients with potential SARS-CoV-2 reinfection in the United States during May-July 2020. METHODS: We conducted case finding for patients with potential SARS-CoV-2 reinfection through the Emerging Infections Network. Cases reported were screened for laboratory and clinical findings of potential reinfection followed by requests for medical records and laboratory specimens. Available medical records were abstracted to characterize patient demographics, comorbidities, clinical course, and laboratory test results. Submitted specimens underwent further testing, including RT-PCR, viral culture, whole genome sequencing, subgenomic RNA PCR, and testing for anti-SARS-CoV-2 total antibody. RESULTS: Among 73 potential reinfection patients with available records, 30 patients had recurrent COVID-19 symptoms explained by alternative diagnoses with concurrent SARS-CoV-2 positive RT-PCR, 24 patients remained asymptomatic after recovery but had recurrent or persistent RT-PCR, and 19 patients had recurrent COVID-19 symptoms with concurrent SARS-CoV-2 positive RT-PCR but no alternative diagnoses. These 19 patients had symptom recurrence a median of 57 days after initial symptom onset (interquartile range: 47 - 76). Six of these patients had paired specimens available for further testing, but none had laboratory findings confirming reinfections. Testing of an additional three patients with recurrent symptoms and alternative diagnoses also did not confirm reinfection. CONCLUSIONS: We did not confirm SARS-CoV-2 reinfection within 90 days of the initial infection based on the clinical and laboratory characteristics of cases in this investigation. Our findings support current CDC guidance around quarantine and testing for patients who have recovered from COVID-19. |
Rapid Transmission of Severe Acute Respiratory Syndrome Coronavirus 2 in Detention Facility, Louisiana, USA, May-June, 2020.
Wallace M , James AE , Silver R , Koh M , Tobolowsky FA , Simonson S , Gold JAW , Fukunaga R , Njuguna H , Bordelon K , Wortham J , Coughlin M , Harcourt JL , Tamin A , Whitaker B , Thornburg NJ , Tao Y , Queen K , Uehara A , Paden CR , Zhang J , Tong S , Haydel D , Tran H , Kim K , Fisher KA , Marlow M , Tate JE , Doshi RH , Sokol T , Curran KG . Emerg Infect Dis 2021 27 (2) 421-429 To assess transmission of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) in a detention facility experiencing a coronavirus disease outbreak and evaluate testing strategies, we conducted a prospective cohort investigation in a facility in Louisiana, USA. We conducted SARS-CoV-2 testing for detained persons in 6 quarantined dormitories at various time points. Of 143 persons, 53 were positive at the initial test, and an additional 58 persons were positive at later time points (cumulative incidence 78%). In 1 dormitory, all 45 detained persons initially were negative; 18 days later, 40 (89%) were positive. Among persons who were SARS-CoV-2 positive, 47% (52/111) were asymptomatic at the time of specimen collection; 14 had replication-competent virus isolated. Serial SARS-CoV-2 testing might help interrupt transmission through medical isolation and quarantine. Testing in correctional and detention facilities will be most effective when initiated early in an outbreak, inclusive of all exposed persons, and paired with infection prevention and control. |
Performance of an Antigen-Based Test for Asymptomatic and Symptomatic SARS-CoV-2 Testing at Two University Campuses - Wisconsin, September-October 2020.
Pray IW , Ford L , Cole D , Lee C , Bigouette JP , Abedi GR , Bushman D , Delahoy MJ , Currie D , Cherney B , Kirby M , Fajardo G , Caudill M , Langolf K , Kahrs J , Kelly P , Pitts C , Lim A , Aulik N , Tamin A , Harcourt JL , Queen K , Zhang J , Whitaker B , Browne H , Medrzycki M , Shewmaker P , Folster J , Bankamp B , Bowen MD , Thornburg NJ , Goffard K , Limbago B , Bateman A , Tate JE , Gieryn D , Kirking HL , Westergaard R , Killerby M . MMWR Morb Mortal Wkly Rep 2021 69 (5152) 1642-1647 Antigen-based tests for SARS-CoV-2, the virus that causes coronavirus disease 2019 (COVID-19), are inexpensive and can return results within 15 minutes (1). Antigen tests have received Food and Drug Administration (FDA) Emergency Use Authorization (EUA) for use in asymptomatic and symptomatic persons within the first 5-12 days after symptom onset (2). These tests have been used at U.S. colleges and universities and other congregate settings (e.g., nursing homes and correctional and detention facilities), where serial testing of asymptomatic persons might facilitate early case identification (3-5). However, test performance data from symptomatic and asymptomatic persons are limited. This investigation evaluated performance of the Sofia SARS Antigen Fluorescent Immunoassay (FIA) (Quidel Corporation) compared with real-time reverse transcription-polymerase chain reaction (RT-PCR) for SARS-CoV-2 detection among asymptomatic and symptomatic persons at two universities in Wisconsin. During September 28-October 9, a total of 1,098 paired nasal swabs were tested using the Sofia SARS Antigen FIA and real-time RT-PCR. Virus culture was attempted on all antigen-positive or real-time RT-PCR-positive specimens. Among 871 (79%) paired swabs from asymptomatic participants, the antigen test sensitivity was 41.2%, specificity was 98.4%, and in this population the estimated positive predictive value (PPV) was 33.3%, and negative predictive value (NPV) was 98.8%. Antigen test performance was improved among 227 (21%) paired swabs from participants who reported one or more symptoms at specimen collection (sensitivity = 80.0%; specificity = 98.9%; PPV = 94.1%; NPV = 95.9%). Virus was isolated from 34 (46.6%) of 73 antigen-positive or real-time RT-PCR-positive nasal swab specimens, including two of 18 that were antigen-negative and real-time RT-PCR-positive (false-negatives). The advantages of antigen tests such as low cost and rapid turnaround might allow for rapid identification of infectious persons. However, these advantages need to be balanced against lower sensitivity and lower PPV, especially among asymptomatic persons. Confirmatory testing with an FDA-authorized nucleic acid amplification test (NAAT), such as RT-PCR, should be considered after negative antigen test results in symptomatic persons, and after positive antigen test results in asymptomatic persons (1). |
From People to Panthera : Natural SARS-CoV-2 Infection in Tigers and Lions at the Bronx Zoo.
McAloose D , Laverack M , Wang L , Killian ML , Caserta LC , Yuan F , Mitchell PK , Queen K , Mauldin MR , Cronk BD , Bartlett SL , Sykes JM , Zec S , Stokol T , Ingerman K , Delaney MA , Fredrickson R , Ivančić M , Jenkins-Moore M , Mozingo K , Franzen K , Bergeson NH , Goodman L , Wang H , Fang Y , Olmstead C , McCann C , Thomas P , Goodrich E , Elvinger F , Smith DC , Tong S , Slavinski S , Calle PP , Terio K , Torchetti MK , Diel DG . mBio 2020 11 (5) Despite numerous barriers to transmission, zoonoses are the major cause of emerging infectious diseases in humans. Among these, severe acute respiratory syndrome (SARS), Middle East respiratory syndrome (MERS), and ebolaviruses have killed thousands; the human immunodeficiency virus (HIV) has killed millions. Zoonoses and human-to-animal cross-species transmission are driven by human actions and have important management, conservation, and public health implications. The current SARS-CoV-2 pandemic, which presumably originated from an animal reservoir, has killed more than half a million people around the world and cases continue to rise. In March 2020, New York City was a global epicenter for SARS-CoV-2 infections. During this time, four tigers and three lions at the Bronx Zoo, NY, developed mild, abnormal respiratory signs. We detected SARS-CoV-2 RNA in respiratory secretions and/or feces from all seven animals, live virus in three, and colocalized viral RNA with cellular damage in one. We produced nine whole SARS-CoV-2 genomes from the animals and keepers and identified different SARS-CoV-2 genotypes in the tigers and lions. Epidemiologic and genomic data indicated human-to-tiger transmission. These were the first confirmed cases of natural SARS-CoV-2 animal infections in the United States and the first in nondomestic species in the world. We highlight disease transmission at a nontraditional interface and provide information that contributes to understanding SARS-CoV-2 transmission across species.IMPORTANCE The human-animal-environment interface of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is an important aspect of the coronavirus disease 2019 (COVID-19) pandemic that requires robust One Health-based investigations. Despite this, few reports describe natural infections in animals or directly link them to human infections using genomic data. In the present study, we describe the first cases of natural SARS-CoV-2 infection in tigers and lions in the United States and provide epidemiological and genetic evidence for human-to-animal transmission of the virus. Our data show that tigers and lions were infected with different genotypes of SARS-CoV-2, indicating two independent transmission events to the animals. Importantly, infected animals shed infectious virus in respiratory secretions and feces. A better understanding of the susceptibility of animal species to SARS-CoV-2 may help to elucidate transmission mechanisms and identify potential reservoirs and sources of infection that are important in both animal and human health. |
Cryptic transmission of SARS-CoV-2 in Washington state.
Bedford T , Greninger AL , Roychoudhury P , Starita LM , Famulare M , Huang ML , Nalla A , Pepper G , Reinhardt A , Xie H , Shrestha L , Nguyen TN , Adler A , Brandstetter E , Cho S , Giroux D , Han PD , Fay K , Frazar CD , Ilcisin M , Lacombe K , Lee J , Kiavand A , Richardson M , Sibley TR , Truong M , Wolf CR , Nickerson DA , Rieder MJ , Englund JA , Hadfield J , Hodcroft EB , Huddleston J , Moncla LH , Müller NF , Neher RA , Deng X , Gu W , Federman S , Chiu C , Duchin JS , Gautom R , Melly G , Hiatt B , Dykema P , Lindquist S , Queen K , Tao Y , Uehara A , Tong S , MacCannell D , Armstrong GL , Baird GS , Chu HY , Shendure J , Jerome KR . Science 2020 370 (6516) 571-575 Following its emergence in Wuhan, China, in late November or early December 2019, the SARS-CoV-2 virus has rapidly spread globally. Genome sequencing of SARS-CoV-2 allows reconstruction of its transmission history, although this is contingent on sampling. We have analyzed 453 SARS-CoV-2 genomes collected between 20 February and 15 March 2020 from infected patients in Washington State, USA. We find that most SARS-CoV-2 infections sampled during this time derive from a single introduction in late January or early February 2020 which subsequently spread locally before active community surveillance was implemented. |
Rapid, Sensitive, Full-Genome Sequencing of Severe Acute Respiratory Syndrome Coronavirus 2.
Paden CR , Tao Y , Queen K , Zhang J , Li Y , Uehara A , Tong S . Emerg Infect Dis 2020 26 (10) 2401-2405 We describe validated protocols for generating high-quality, full-length severe acute respiratory syndrome coronavirus 2 genomes from primary samples. One protocol uses multiplex reverse transcription PCR, followed by MinION or MiSeq sequencing; the other uses singleplex, nested reverse transcription PCR and Sanger sequencing. These protocols enable sensitive virus sequencing in different laboratory environments. |
COVID-19 in Americans aboard the Diamond Princess cruise ship.
Plucinski MM , Wallace M , Uehara A , Kurbatova EV , Tobolowsky FA , Schneider ZD , Ishizumi A , Bozio CH , Kobayashi M , Toda M , Stewart A , Wagner RL , Moriarty LF , Murray R , Queen K , Tao Y , Paden C , Mauldin MR , Zhang J , Li Y , Elkins CA , Lu X , Herzig CTA , Novak R , Bower W , Medley AM , Acosta AM , Knust B , Cantey PT , Pesik NT , Halsey ES , Cetron MS , Tong S , Marston BJ , Friedman CR . Clin Infect Dis 2020 72 (10) e448-e457 BACKGROUND: The Diamond Princess cruise ship was the site of a large outbreak of coronavirus disease 2019 (COVID-19). Of 437 Americans and their travel companions on the ship, 114 (26%) tested positive for severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). METHODS: We interviewed 229 American passengers and crew after disembarkation following a ship-based quarantine to identify risk factors for infection and characterize transmission onboard the ship. RESULTS: The attack rate for passengers in single-person cabins or without infected cabinmates was 18% (58/329), compared with 63% (27/43) for those sharing a cabin with an asymptomatic infected cabinmate, and 81% (25/31) for those with a symptomatic infected cabinmate. Whole genome sequences from specimens from passengers who shared cabins clustered together. Of 66 SARS-CoV-2-positive American travelers with complete symptom information, 14 (21%) were asymptomatic while on the ship. Among SARS-CoV-2-positive Americans, 10 (9%) required intensive care, of whom 7 were ≥70 years. CONCLUSION: Our findings highlight the high risk of SARS-CoV-2 transmission on cruise ships. High rates of SARS-CoV-2 positivity in cabinmates of individuals with asymptomatic infections suggest that triage by symptom status in shared quarters is insufficient to halt transmission. A high rate of intensive care unit admission among older individuals complicates the prospect of future cruise travel during the pandemic, given typical cruise passenger demographics. The magnitude and severe outcomes of this outbreak were major factors contributing to the Centers for Disease Control and Prevention's decision to halt cruise ship travel in U.S. waters in March 2020. |
Detection and Genetic Characterization of Community-Based SARS-CoV-2 Infections - New York City, March 2020.
Greene SK , Keating P , Wahnich A , Weiss D , Pathela P , Harrison C , Rakeman J , Langley G , Tong S , Tao Y , Uehara A , Queen K , Paden CR , Szymczak W , Orner EP , Nori P , Lai PA , Jacobson JL , Singh HK , Calfee DP , Westblade LF , Vasovic LV , Rand JH , Liu D , Singh V , Burns J , Prasad N , Sell J , CDC COVID-19 Surge Laboratory Group , Abernathy Emily , Anderson Raydel , Bankamp Bettina , Bell Melissa , Galloway Renee , Graziano James , Kim Gimin , Kondas Ashley , Lee Christopher , Radford Kay , Rogers Shannon , Smith Peyton , Tiller Rebekah , Weiner Zachary , Wharton Adam , Whitaker Brett . MMWR Morb Mortal Wkly Rep 2020 69 (28) 918-922 To limit introduction of SARS-CoV-2, the virus that causes coronavirus disease 2019 (COVID-19), the United States restricted travel from China on February 2, 2020, and from Europe on March 13. To determine whether local transmission of SARS-CoV-2 could be detected, the New York City (NYC) Department of Health and Mental Hygiene (DOHMH) conducted deidentified sentinel surveillance at six NYC hospital emergency departments (EDs) during March 1-20. On March 8, while testing availability for SARS-CoV-2 was still limited, DOHMH announced sustained community transmission of SARS-CoV-2 (1). At this time, twenty-six NYC residents had confirmed COVID-19, and ED visits for influenza-like illness* increased, despite decreased influenza virus circulation.(†) The following week, on March 15, when only seven of the 56 (13%) patients with known exposure histories had exposure outside of NYC, the level of community SARS-CoV-2 transmission status was elevated from sustained community transmission to widespread community transmission (2). Through sentinel surveillance during March 1-20, DOHMH collected 544 specimens from patients with influenza-like symptoms (ILS)(§) who had negative test results for influenza and, in some instances, other respiratory pathogens.(¶) All 544 specimens were tested for SARS-CoV-2 at CDC; 36 (6.6%) tested positive. Using genetic sequencing, CDC determined that the sequences of most SARS-CoV-2-positive specimens resembled those circulating in Europe, suggesting probable introductions of SARS-CoV-2 from Europe, from other U.S. locations, and local introductions from within New York. These findings demonstrate that partnering with health care facilities and developing the systems needed for rapid implementation of sentinel surveillance, coupled with capacity for genetic sequencing before an outbreak, can help inform timely containment and mitigation strategies. |
Isolation and characterization of SARS-CoV-2 from the first US COVID-19 patient.
Harcourt J , Tamin A , Lu X , Kamili S , Sakthivel SK , Murray J , Queen K , Tao Y , Paden CR , Zhang J , Li Y , Uehara A , Wang H , Goldsmith C , Bullock HA , Wang L , Whitaker B , Lynch B , Gautam R , Schindewolf C , Lokugamage KG , Scharton D , Plante JA , Mirchandani D , Widen SG , Narayanan K , Makino S , Ksiazek TG , Plante KS , Weaver SC , Lindstrom S , Tong S , Menachery VD , Thornburg NJ . bioRxiv 2020 The etiologic agent of the outbreak of pneumonia in Wuhan China was identified as severe acute respiratory syndrome associated coronavirus 2 (SARS-CoV-2) in January, 2020. The first US patient was diagnosed by the State of Washington and the US Centers for Disease Control and Prevention on January 20, 2020. We isolated virus from nasopharyngeal and oropharyngeal specimens, and characterized the viral sequence, replication properties, and cell culture tropism. We found that the virus replicates to high titer in Vero-CCL81 cells and Vero E6 cells in the absence of trypsin. We also deposited the virus into two virus repositories, making it broadly available to the public health and research communities. We hope that open access to this important reagent will expedite development of medical countermeasures. |
Severe Acute Respiratory Syndrome Coronavirus 2 from Patient with Coronavirus Disease, United States.
Harcourt J , Tamin A , Lu X , Kamili S , Sakthivel SK , Murray J , Queen K , Tao Y , Paden CR , Zhang J , Li Y , Uehara A , Wang H , Goldsmith C , Bullock HA , Wang L , Whitaker B , Lynch B , Gautam R , Schindewolf C , Lokugamage KG , Scharton D , Plante JA , Mirchandani D , Widen SG , Narayanan K , Makino S , Ksiazek TG , Plante KS , Weaver SC , Lindstrom S , Tong S , Menachery VD , Thornburg NJ . Emerg Infect Dis 2020 26 (6) 1266-1273 The etiologic agent of an outbreak of pneumonia in Wuhan, China, was identified as severe acute respiratory syndrome coronavirus 2 in January 2020. A patient in the United States was given a diagnosis of infection with this virus by the state of Washington and the US Centers for Disease Control and Prevention on January 20, 2020. We isolated virus from nasopharyngeal and oropharyngeal specimens from this patient and characterized the viral sequence, replication properties, and cell culture tropism. We found that the virus replicates to high titer in Vero-CCL81 cells and Vero E6 cells in the absence of trypsin. We also deposited the virus into 2 virus repositories, making it broadly available to the public health and research communities. We hope that open access to this reagent will expedite development of medical countermeasures. |
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