Last data update: Jun 03, 2024. (Total: 46935 publications since 2009)
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Query Trace: Holshue M [original query] |
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Notes from the field: Gastrointestinal illness among hikers on the Pacific Crest Trail - Washington, August-October 2022
Hamlet A , Begley K , Miko S , Stewart L , Tellier W , Gonzalez-De Leon J , Booth H , Lippman S , Kahler A , Roundtree A , Hatada A , Lindquist S , Melius B , Goldoft M , Mattioli M , Holshue M . MMWR Morb Mortal Wkly Rep 2023 72 (36) 997-998 On August 26, 2022, the Washington State Department of Health received informal reports of numerous Pacific Crest Trail hikers with acute gastroenteritis (AGE). The Pacific Crest Trail stretches 2,650 miles from California to Washington, attracting hikers from around the world (1). An investigation of social media postings on September 5 found 27 reports of AGE by Washington Pacific Crest Trail hikers during the previous month, 26 of whom provided information about symptom onset date (Figure). Numerous additional reports without a specific date were found, suggesting that that AGE was occurring during the 2022 hiking season |
Enhanced Contact Investigations for Nine Early Travel-Related Cases of SARS-CoV-2 in the United States (preprint)
Burke RM , Balter S , Barnes E , Barry V , Bartlett K , Beer KD , Benowitz I , Biggs HM , Bruce H , Bryant-Genevier J , Cates J , Chatham-Stephens K , Chea N , Chiou H , Christiansen D , Chu VT , Clark S , Cody SH , Cohen M , Conners EE , Dasari V , Dawson P , DeSalvo T , Donahue M , Dratch A , Duca L , Duchin J , Dyal JW , Feldstein LR , Fenstersheib M , Fischer M , Fisher R , Foo C , Freeman-Ponder B , Fry AM , Gant J , Gautom R , Ghinai I , Gounder P , Grigg CT , Gunzenhauser J , Hall AJ , Han GS , Haupt T , Holshue M , Hunter J , Ibrahim MB , Jacobs MW , Jarashow MC , Joshi K , Kamali T , Kawakami V , Kim M , Kirking HL , Kita-Yarbro A , Klos R , Kobayashi M , Kocharian A , Lang M , Layden J , Leidman E , Lindquist S , Lindstrom S , Link-Gelles R , Marlow M , Mattison CP , McClung N , McPherson TD , Mello L , Midgley CM , Novosad S , Patel MT , Pettrone K , Pillai SK , Pray IW , Reese HE , Rhodes H , Robinson S , Rolfes M , Routh J , Rubin R , Rudman SL , Russell D , Scott S , Shetty V , Smith-Jeffcoat SE , Soda EA , Spitters C , Stierman B , Sunenshine R , Terashita D , Traub E , Vahey GM , Verani JR , Wallace M , Westercamp M , Wortham J , Xie A , Yousaf A , Zahn M . medRxiv 2020 2020.04.27.20081901 Background Coronavirus disease 2019 (COVID-19), the respiratory disease caused by the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), was first identified in Wuhan, China and has since become pandemic. As part of initial response activities in the United States, enhanced contact investigations were conducted to enable early identification and isolation of additional cases and to learn more about risk factors for transmission.Methods Close contacts of nine early travel-related cases in the United States were identified. Close contacts meeting criteria for active monitoring were followed, and selected individuals were targeted for collection of additional exposure details and respiratory samples. Respiratory samples were tested for SARS-CoV-2 by real-time reverse transcription polymerase chain reaction (RT-PCR) at the Centers for Disease Control and Prevention.Results There were 404 close contacts who underwent active monitoring in the response jurisdictions; 338 had at least basic exposure data, of whom 159 had ≥1 set of respiratory samples collected and tested. Across all known close contacts under monitoring, two additional cases were identified; both secondary cases were in spouses of travel-associated case patients. The secondary attack rate among household members, all of whom had ≥1 respiratory sample tested, was 13% (95% CI: 4 – 38%).Conclusions The enhanced contact tracing investigations undertaken around nine early travel-related cases of COVID-19 in the United States identified two cases of secondary transmission, both spouses. Rapid detection and isolation of the travel-associated case patients, enabled by public awareness of COVID-19 among travelers from China, may have mitigated transmission risk among close contacts of these cases.Competing Interest StatementThe authors have declared no competing interest.Funding StatementNo external funding was sought or received.Author DeclarationsAll relevant ethical guidelines have been followed; any necessary IRB and/or ethics committee approvals have been obtained and details of the IRB/oversight body are included in the manuscript.YesAll necessary patient/participant consent has been obtained and the appropriate institutional forms have been archived.YesI understand that all clinical trials and any other prospective interventional studies must be registered with an ICMJE-approved registry, such as ClinicalTrials.gov. I confirm that any such study reported in the manuscript has been registered and the trial registration ID is provided (note: if posting a prospective study registered retrospectively, please provide a statement in the trial ID field explaining why the study was not registered in advance).YesI have followed all appropriate research reporting guidelines and uploaded the relevant EQUATOR Network research reporting checklist(s) and other pertinent material as supplementary files, if applicable.YesData may be available upon reasonable request. |
First Case of Covid-19 in the United States. Reply.
Uyeki TM , Holshue ML , Diaz G . N Engl J Med 2020 382 (21) e53 The authors reply: Weng et al. question the clinical benefit of remdesivir treatment. In our article, we noted that the decision to administer remdesivir for compassionate use was based on the patient’s worsening clinical status. No inferences are possible from the uncontrolled treatment of one patient, and we stated, “randomized, controlled trials are needed to determine the safety and efficacy of remdesivir and any other investigational agents for treatment of patients with 2019-nCoV infection.” | | Tsung notes that an increase in lymphocyte counts and subsequent clinical improvement are consistent with activation of the adaptive immune response and resolution of SARS-CoV-2 infection. IgM and IgA antibodies may be detectable early in the clinical course, and IgG antibodies can be detected a median of 14 days after the onset of illness.1 We agree that the adaptive immune response contributes to clinical recovery and clearance of SARS-CoV-2, although one study showed that seroconversion was not correlated with a rapid decline in the SARS-CoV-2 load.2 In another study that showed a good correlation between IgG and neutralizing antibody titers, an increase in IgG antibody levels was correlated with a decrease in the viral load between 1 and 3 weeks after the onset of illness, but SARS-CoV-2 RNA was still detectable for prolonged periods.3 | | Zhang inquires about detection of SARS-CoV-2 in stool and urine specimens after remdesivir treatment. In our patient, although a stool specimen collected on day 7 of illness was positive with high cycle threshold values (36 to 38) that were consistent with detection of viral RNA and probably not infectious virus, a stool specimen obtained from the patient on day 14 of illness was negative. SARS-CoV-2 RNA was not detected in urine specimens; these findings are consistent with those in a larger study.4 | | Wen et al. and Link and Hold raise the issue of fecal–oral transmission of SARS-CoV-2. Diarrhea has been reported to occur in patients with Covid-19, and it can precede the development of respiratory symptoms and progression to pneumonia. SARS-CoV-2 RNA has been detected in stool specimens, and recovery of live infectious virus from stool has been reported.4 Further studies are needed to understand the implications of SARS-CoV-2 detected in stool for transmission of the virus. | | Ren et al. argue that high-resolution low-dose chest CT should be performed instead of chest radiography in persons with fever and suspected Covid-19. The Centers for Disease Control and Prevention recommends collection of nasopharyngeal swab specimens and lower respiratory specimens, if available, for SARS-CoV-2 testing and prioritizes testing of hospitalized patients and symptomatic health care workers. Furthermore, the American College of Radiology has noted concerns regarding prevention and control of SARS-CoV-2 transmission in health care facilities, including transmission that may occur with the use of CT scanners, and has recommended that CT should not be used to screen for or diagnose Covid-19.5 |
COVID-19 Outbreak Among Farmworkers - Okanogan County, Washington, May-August 2020.
Miller JS , Holshue M , Dostal TKH , Newman LP , Lindquist S . MMWR Morb Mortal Wkly Rep 2021 70 (17) 617-621 Okanogan County, Washington, experienced increased community transmission of SARS-CoV-2, the virus that causes COVID-19, during summer 2020 (1). Multiple COVID-19 outbreaks occurred in agricultural settings, including a large outbreak among employees of a fruit grower during May-August. Because of this outbreak, Okanogan County Public Health and the Washington State Department of Health initiated one-time, on-site screening testing (2) of all orchard and warehouse employees in August 2020 and assessed risk factors for SARS-CoV-2 infection. Among 3,708 known orchard employees, a valid SARS-CoV-2 test result or information on COVID-19-like symptoms in the absence of a test was available for 3,013 (81%). Cumulative incidence of SARS-CoV-2 infection during approximately 3 months among tested orchard employees was 6%. Cumulative incidence was 12% in employees residing in the community, compared with 4% in employees residing in farmworker housing (p<0.001); point prevalence during the single screening testing event was 1% in both groups. Among 1,247 known warehouse employees, a valid result was available for 726 (58%). Cumulative incidence over approximately 3 months among tested warehouse employees was 23%, with substantial variation across job roles. Positive test results were received by 28% of employees who worked packing and sorting fruit, 24% of those in other roles in the packing and sorting area, 10% of forklift operators, 7% of employees in other warehouse roles, and 6% of office employees. Point prevalence among all warehouse workers was 1% at the screening testing event. Collaboration among employers, community groups, and public health authorities can reveal risk factors and help decrease farmworkers' risk for SARS-CoV-2 infection in the community and the workplace. Creation of a COVID-19 assessment and control plan by agricultural employers, with particular focus on indoor workers whose jobs limit physical distancing, could reduce workplace transmission. |
COVID-19 Response Efforts of Washington State Public Health Laboratory: Lessons Learned.
McLaughlin HP , Hiatt BC , Russell D , Carlson CM , Jacobs JR , Perez-Osorio AC , Holshue ML , Choi SW , Gautom RK . Am J Public Health 2021 111 (5) e1-e9 Laboratory diagnostics play an essential role in pandemic preparedness. In January 2020, the first US case of COVID-19 was confirmed in Washington State. At the same time, the Washington State Public Health Laboratory (WA PHL) was in the process of building upon and initiating innovative preparedness activities to strengthen laboratory testing capabilities, operations, and logistics. The response efforts of WA PHL, in conjunction with the Centers for Disease Control and Prevention, to the COVID-19 outbreak in Washington are described herein-from the initial detection of severe acute respiratory syndrome coronavirus 2 through the subsequent 2 months.Factors that contributed to an effective laboratory response are described, including preparing early to establish testing capacity, instituting dynamic workforce solutions, advancing information management systems, refining laboratory operations, and leveraging laboratory partnerships. We also report on the challenges faced, successful steps taken, and lessons learned by WA PHL to respond to COVID-19.The actions taken by WA PHL to mount an effective public health response may be useful for US laboratories as they continue to respond to the COVID-19 pandemic and may help inform current and future laboratory pandemic preparedness activities. (Am J Public Health. Published online ahead of print March 18, 2021: e1-e9. https://doi.org/10.2105/AJPH.2021.306212). |
Enhanced contact investigations for nine early travel-related cases of SARS-CoV-2 in the United States.
Burke RM , Balter S , Barnes E , Barry V , Bartlett K , Beer KD , Benowitz I , Biggs HM , Bruce H , Bryant-Genevier J , Cates J , Chatham-Stephens K , Chea N , Chiou H , Christiansen D , Chu VT , Clark S , Cody SH , Cohen M , Conners EE , Dasari V , Dawson P , DeSalvo T , Donahue M , Dratch A , Duca L , Duchin J , Dyal JW , Feldstein LR , Fenstersheib M , Fischer M , Fisher R , Foo C , Freeman-Ponder B , Fry AM , Gant J , Gautom R , Ghinai I , Gounder P , Grigg CT , Gunzenhauser J , Hall AJ , Han GS , Haupt T , Holshue M , Hunter J , Ibrahim MB , Jacobs MW , Jarashow MC , Joshi K , Kamali T , Kawakami V , Kim M , Kirking HL , Kita-Yarbro A , Klos R , Kobayashi M , Kocharian A , Lang M , Layden J , Leidman E , Lindquist S , Lindstrom S , Link-Gelles R , Marlow M , Mattison CP , McClung N , McPherson TD , Mello L , Midgley CM , Novosad S , Patel MT , Pettrone K , Pillai SK , Pray IW , Reese HE , Rhodes H , Robinson S , Rolfes M , Routh J , Rubin R , Rudman SL , Russell D , Scott S , Shetty V , Smith-Jeffcoat SE , Soda EA , Spitters C , Stierman B , Sunenshine R , Terashita D , Traub E , Vahey GM , Verani JR , Wallace M , Westercamp M , Wortham J , Xie A , Yousaf A , Zahn M . PLoS One 2020 15 (9) e0238342 Coronavirus disease 2019 (COVID-19), the respiratory disease caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), was first identified in Wuhan, China and has since become pandemic. In response to the first cases identified in the United States, close contacts of confirmed COVID-19 cases were investigated to enable early identification and isolation of additional cases and to learn more about risk factors for transmission. Close contacts of nine early travel-related cases in the United States were identified and monitored daily for development of symptoms (active monitoring). Selected close contacts (including those with exposures categorized as higher risk) were targeted for collection of additional exposure information and respiratory samples. Respiratory samples were tested for SARS-CoV-2 by real-time reverse transcription polymerase chain reaction at the Centers for Disease Control and Prevention. Four hundred four close contacts were actively monitored in the jurisdictions that managed the travel-related cases. Three hundred thirty-eight of the 404 close contacts provided at least basic exposure information, of whom 159 close contacts had ≥1 set of respiratory samples collected and tested. Across all actively monitored close contacts, two additional symptomatic COVID-19 cases (i.e., secondary cases) were identified; both secondary cases were in spouses of travel-associated case patients. When considering only household members, all of whom had ≥1 respiratory sample tested for SARS-CoV-2, the secondary attack rate (i.e., the number of secondary cases as a proportion of total close contacts) was 13% (95% CI: 4-38%). The results from these contact tracing investigations suggest that household members, especially significant others, of COVID-19 cases are at highest risk of becoming infected. The importance of personal protective equipment for healthcare workers is also underlined. Isolation of persons with COVID-19, in combination with quarantine of exposed close contacts and practice of everyday preventive behaviors, is important to mitigate spread of COVID-19. |
Investigation and Serologic Follow-Up of Contacts of an Early Confirmed Case-Patient with COVID-19, Washington, USA.
Chu VT , Freeman-Ponder B , Lindquist S , Spitters C , Kawakami V , Dyal JW , Clark S , Bruce H , Duchin JS , DeBolt C , Podczervinski S , D'Angeli M , Pettrone K , Zacks R , Vahey G , Holshue ML , Lang M , Burke RM , Rolfes MA , Marlow M , Midgley CM , Lu X , Lindstrom S , Hall AJ , Fry AM , Thornburg NJ , Gerber SI , Pillai SK , Biggs HM . Emerg Infect Dis 2020 26 (8) 1671-1678 We describe the contact investigation for an early confirmed case of coronavirus disease (COVID-19), caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), in the United States. Contacts of the case-patient were identified, actively monitored for symptoms, interviewed for a detailed exposure history, and tested for SARS-CoV-2 infection by real-time reverse transcription PCR (rRT-PCR) and ELISA. Fifty contacts were identified and 38 (76%) were interviewed, of whom 11 (29%) reported unprotected face-to-face interaction with the case-patient. Thirty-seven (74%) had respiratory specimens tested by rRT-PCR, and all tested negative. Twenty-three (46%) had ELISA performed on serum samples collected approximately 6 weeks after exposure, and none had detectable antibodies to SARS-CoV-2. Among contacts who were tested, no secondary transmission was identified in this investigation, despite unprotected close interactions with the infectious case-patient. |
Clinical and virologic characteristics of the first 12 patients with coronavirus disease 2019 (COVID-19) in the United States.
Kujawski SA , Wong KK , Collins JP , Epstein L , Killerby ME , Midgley CM , Abedi GR , Ahmed NS , Almendares O , Alvarez FN , Anderson KN , Balter S , Barry V , Bartlett K , Beer K , Ben-Aderet MA , Benowitz I , Biggs HM , Binder AM , Black SR , Bonin B , Bozio CH , Brown CM , Bruce H , Bryant-Genevier J , Budd A , Buell D , Bystritsky R , Cates J , Charles EM , Chatham-Stephens K , Chea N , Chiou H , Christiansen D , Chu V , Cody S , Cohen M , Conners EE , Curns AT , Dasari V , Dawson P , DeSalvo T , Diaz G , Donahue M , Donovan S , Duca LM , Erickson K , Esona MD , Evans S , Falk J , Feldstein LR , Fenstersheib M , Fischer M , Fisher R , Foo C , Fricchione MJ , Friedman O , Fry A , Galang RR , Garcia MM , Gerber SI , Gerrard G , Ghinai I , Gounder P , Grein J , Grigg C , Gunzenhauser JD , Gutkin GI , Haddix M , Hall AJ , Han GS , Harcourt J , Harriman K , Haupt T , Haynes AK , Holshue M , Hoover C , Hunter JC , Jacobs MW , Jarashow C , Joshi K , Kamali T , Kamili S , Kim L , Kim M , King J , Kirking HL , Kita-Yarbro A , Klos R , Kobayashi M , Kocharian A , Komatsu KK , Koppaka R , Layden JE , Li Y , Lindquist S , Lindstrom S , Link-Gelles R , Lively J , Livingston M , Lo K , Lo J , Lu X , Lynch B , Madoff L , Malapati L , Marks G , Marlow M , Mathisen GE , McClung N , McGovern O , McPherson TD , Mehta M , Meier A , Mello L , Moon SS , Morgan M , Moro RN , Murray J , Murthy R , Novosad S , Oliver SE , O’Shea J , Pacilli M , Paden CR , Pallansch MA , Patel M , Patel S , Pedraza I , Pillai SK , Pindyck T , Pray I , Queen K , Quick N , Reese H , Reporter R , Rha B , Rhodes H , Robinson S , Robinson P , Rolfes MA , Routh JA , Rubin R , Rudman SL , Sakthivel SK , Scott S , Shepherd C , Shetty V , Smith EA , Smith S , Stierman B , Stoecker W , Sunenshine R , Sy-Santos R , Tamin A , Tao Y , Terashita D , Thornburg NJ , Tong S , Traub E , Tural A , Uehara A , Uyeki TM , Vahey G , Verani JR , Villarino E , Wallace M , Wang L , Watson JT , Westercamp M , Whitaker B , Wilkerson S , Woodruff RC , Wortham JM , Wu T , Xie A , Yousaf A , Zahn M , Zhang J . Nat Med 2020 26 (6) 861-868 Data on the detailed clinical progression of COVID-19 in conjunction with epidemiological and virological characteristics are limited. In this case series, we describe the first 12 US patients confirmed to have COVID-19 from 20 January to 5 February 2020, including 4 patients described previously(1-3). Respiratory, stool, serum and urine specimens were submitted for SARS-CoV-2 real-time reverse-transcription polymerase chain reaction (rRT-PCR) testing, viral culture and whole genome sequencing. Median age was 53 years (range: 21-68); 8 patients were male. Common symptoms at illness onset were cough (n = 8) and fever (n = 7). Patients had mild to moderately severe illness; seven were hospitalized and demonstrated clinical or laboratory signs of worsening during the second week of illness. No patients required mechanical ventilation and all recovered. All had SARS-CoV-2 RNA detected in respiratory specimens, typically for 2-3 weeks after illness onset. Lowest real-time PCR with reverse transcription cycle threshold values in the upper respiratory tract were often detected in the first week and SARS-CoV-2 was cultured from early respiratory specimens. These data provide insight into the natural history of SARS-CoV-2. Although infectiousness is unclear, highest viral RNA levels were identified in the first week of illness. Clinicians should anticipate that some patients may worsen in the second week of illness. |
Active Monitoring of Persons Exposed to Patients with Confirmed COVID-19 - United States, January-February 2020.
Burke RM , Midgley CM , Dratch A , Fenstersheib M , Haupt T , Holshue M , Ghinai I , Jarashow MC , Lo J , McPherson TD , Rudman S , Scott S , Hall AJ , Fry AM , Rolfes MA . MMWR Morb Mortal Wkly Rep 2020 69 (9) 245-246 In December 2019, an outbreak of coronavirus disease 2019 (COVID-19), caused by the virus SARS-CoV-2, began in Wuhan, China (1). The disease spread widely in China, and, as of February 26, 2020, COVID-19 cases had been identified in 36 other countries and territories, including the United States. Person-to-person transmission has been widely documented, and a limited number of countries have reported sustained person-to-person spread.* On January 20, state and local health departments in the United States, in collaboration with teams deployed from CDC, began identifying and monitoring all persons considered to have had close contact(dagger) with patients with confirmed COVID-19 (2). The aims of these efforts were to ensure rapid evaluation and care of patients, limit further transmission, and better understand risk factors for transmission. |
First Case of 2019 Novel Coronavirus in the United States.
Holshue ML , DeBolt C , Lindquist S , Lofy KH , Wiesman J , Bruce H , Spitters C , Ericson K , Wilkerson S , Tural A , Diaz G , Cohn A , Fox L , Patel A , Gerber SI , Kim L , Tong S , Lu X , Lindstrom S , Pallansch MA , Weldon WC , Biggs HM , Uyeki TM , Pillai SK . N Engl J Med 2020 382 (10) 929-936 An outbreak of novel coronavirus (2019-nCoV) that began in Wuhan, China, has spread rapidly, with cases now confirmed in multiple countries. We report the first case of 2019-nCoV infection confirmed in the United States and describe the identification, diagnosis, clinical course, and management of the case, including the patient's initial mild symptoms at presentation with progression to pneumonia on day 9 of illness. This case highlights the importance of close coordination between clinicians and public health authorities at the local, state, and federal levels, as well as the need for rapid dissemination of clinical information related to the care of patients with this emerging infection. |
Notes from the Field: Community outbreak of measles - Clark County, Washington, 2018-2019
Carlson A , Riethman M , Gastanaduy P , Lee A , Leung J , Holshue M , DeBolt C , Melnick A . MMWR Morb Mortal Wkly Rep 2019 68 (19) 446-447 On December 31, 2018, Clark County Public Health (CCPH) in Washington was notified of a suspected case of measles in an unvaccinated child, aged 10 years, who had recently arrived from Ukraine. The patient was evaluated at an urgent care clinic for fever, cough, and a maculopapular rash. CCPH launched a case investigation, conducted contact tracing, and facilitated specimen collection and shipment to the Washington State Department of Health Public Health Laboratories. On January 3, 2019, measles virus was detected in the patient’s urine and nasopharyngeal specimens by reverse transcription–polymerase chain reaction (RT-PCR). By January 16, among 12 patients with suspected measles reported to CCPH during January 11–14, all had laboratory-confirmed measles by RT-PCR. In response to these confirmed cases and additional suspected cases, CCPH’s Incident Management Team was activated on January 15. Approximately 200 persons participated in the multiagency response, which included CCPH, the Washington State Department of Health, and CDC. As of March 28, 2019, measles had been confirmed among 71 Clark County residents, with rash onsets from December 30, 2018, to March 13, 2019. |
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