viernes, 8 de marzo de 2019

Ahead of Print - Diagnosis of Imported Monkeypox, Israel, 2018 - Volume 25, Number 5—May 2019 - Emerging Infectious Diseases journal - CDC

Ahead of Print - Diagnosis of Imported Monkeypox, Israel, 2018 - Volume 25, Number 5—May 2019 - Emerging Infectious Diseases journal - CDC

Centers for Disease Control and Prevention. CDC twenty four seven. Saving Lives, Protecting People





Volume 25, Number 5—May 2019

Dispatch

Diagnosis of Imported Monkeypox, Israel, 2018

Noam Erez1, Hagit Achdout1, Elad Milrot, Yuval Schwartz, Yonit Wiener-Well, Nir Paran, Boaz Politi, Hadas Tamir, Tomer Israely, Shay Weiss, Adi Beth-Din, Ohad Shifman, Ofir Israeli, Shmuel Yitzhaki, Shmuel C. Shapira, Sharon MelamedComments to Author , and Eli Schwartz
Author affiliations: Israel Institute for Biological Research, Ness-Ziona, Israel (N. Erez, A. Achdout, E. Milrot, N. Paran, B. Politi, H. Tamir, T. Israely, S. Weiss, A. Beth-Din, O. Shifman, O. Israeli, S. Yitzhaki, S.C. Shapira, S. Melamed)Shaare-Zedek Medical Center, Jerusalem, Israel (Y. Schwartz, Y. Wiener-Well)Tel Aviv University, Tel Aviv, Israel (E. Schwartz)

Abstract

We report a case of monkeypox in a man who returned from Nigeria to Israel in 2018. Virus was detected in pustule swabs by transmission electron microscopy and PCR and confirmed by immunofluorescence assay, tissue culture, and ELISA. The West Africa monkeypox outbreak calls for increased awareness by public health authorities worldwide.
Monkeypox is a zoonotic disease caused by monkeypox virus, an orthopoxvirus closely related to variola virus, the causative agent of smallpox. Human cases were first described in 1970; in subsequent decades, sporadic outbreaks were reported in Africa. Mortality rates are 1%–10% (1,2). The 2 clades, Congo-Basin and West African, each cause disease; the West African clade is considered to be less virulent and is associated with a lower mortality rate (3). Nevertheless, this clade is responsible for the largest documented monkeypox outbreak in West Africa (132 confirmed cases in Nigeria) (4). Human infection with monkeypox occurred in the United States in 2003, when imported animals from Africa infected pet prairie dogs (5). In September 2018 in the United Kingdom, 2 imported cases of monkeypox, originating from nosocomial infection of a healthcare worker (HCW), were detected in persons from Nigeria (6); a HCW acquired nosocomial infection from 1 of those patients, bringing the total to 3 cases. We report a case of monkeypox in Israel.

The Study

On October 4, 2018, a 38-year-old man sought care for generalized rash and fever at the Department of Emergency Medicine at Shaare-Zedek Medical Center, Jerusalem, Israel. This Israel resident had returned from Port Harcourt, Rivers State, Nigeria, where he had worked a desk job for the previous 10 years. On September 17, during his last trip to Nigeria, he had disposed of 2 rodent carcasses at his residence. He returned to Israel on September 23 and on September 29 noticed 2 itchy lesions on his penis shaft. The next day, he had fever (38.8°C) and chills and started self-medicating with nonsteroidal anti-inflammatories and oral penicillin. On October 1, an erythematous rash appeared first on his face and later on his trunk and extremities.
Thumbnail of Dermal manifestations of monkeypox on patient in Israel, 2018. Maculopapular rash was apparent on the face (A) and body on the day of hospital admission. A lesion on the left proximal extremity (B) was suspected to be a rickettsial eschar. After 3 days, the rash changed into vesicles and pustules on the face (C) and body (D). Skin resolution was apparent 13 days after admission; pustules and vesicles crusted and were shed (E, F). G) Timeline of disease progression.
Figure 1. Dermal manifestations of monkeypox on patient in Israel, 2018. Maculopapular rash was apparent on the face (A) and body on the day of hospital admission. A lesion on the left proximal...
Examination at Shaare-Zedek Medical Center on October 4 revealed that the patient was febrile and had a nonblanching maculopapular rash on his face (Figure 1, panel A), neck, trunk, lower and upper extremities; several lesions on his palms and soles; 2 ulcers with an erythematous base on his penis shaft; and bilateral enlarged and tender lymph nodes in his groin. Blood test results indicated moderate thrombocytopenia (98,000 platelets/μL) and mild hepatitis. One lesion on the posterior aspect of his left arm (Figure 1, panel B) was suspected to be an eschar, raising the possibility of rickettsialpox. The patient was therefore hospitalized and administered oral doxycycline. His condition improved, and the next day he was discharged with doxycycline and instructions to remain isolated at home.
At a follow-up visit 2 days later (October 7), he was afebrile. The rash was locally synchronous and had progressed from maculopapular to vesicular and pustular; some lesions displayed black umbilication and crusting (Figure 1, panels C, D). Oral examination revealed bilateral tonsillar enlargement and ulcers in the posterior pharynx. Serology results were positive for varicella IgG (past infection) and negative for Coxiella burnetii, Rickettsia conoriRickettsia typhiBrucella spp., Treponema pallidum, and antigen/antibody combination for HIV. Pustular samples were negative for herpes simplex virus by PCR. Because of the rash characteristics and the patient’s travel history, monkeypox was suspected.
Samples were sent to the Israel Institute for Biologic Research, Ness-Ziona, Israel, and processed in Biosafety Level 3 laboratories. The pustule sample was processed for PCR analysis and transmission electron microscopy. Vero cells were infected for immunofluorescence assay and monitored for cytopathic effect. For transmission electron microscopy, particles were enriched by using a Beckman Airfuge (https://www.beckman.com) before negative staining with phosphotungstic acid.
Thumbnail of Transmission electron microscopy and cell culture–based diagnosis of monkeypox in patient in Israel, 2018. Virus particles were detected in lesion samples as either virion aggregates (arrows) (A) or individual virions (B) with a typical brick shape. Infected Vero cells depicted typical cytopathic effect, exhibiting cell detachment and rounding. Scale bar in A indicates 0.2 μm; scale bar in B indicates 100 nm. C) Immunofluorescent staining of infected cells; original magnification ×1
Figure 2. Transmission electron microscopy and cell culture–based diagnosis of monkeypox in patient in Israel, 2018. Virus particles were detected in lesion samples as either virion aggregates (arrows) (A) or individual virions (B)...
The sample exhibited numerous brick-shaped particles, characteristic of orthopoxviruses. Particles were observed to be in clusters (up to 10 virions in each cluster) embedded in skin tissue and as single virions (Figure 2, panels A, B). Viral particle dimensions (± SD) were 281 ± 18 nm × 220 ± 17 nm (n = 24), in accordance with previously reported dimensions for monkeypox virus (5).
PCR diagnosis was based on specific primers to discriminate between the West African (581 bp) and the Congo-Basin (832 bp) clades by product size (7). The PCR product size corresponded to that of the West African clade currently circulating in Nigeria (8). This finding was confirmed by high-throughput sequencing.
Within 24 hours of infection, cytopathic effect was observed in Vero cells, exhibiting typical monolayer separation and cell rounding (Figure 2, panel C). The result of immunofluorescence assay with a specific antibody against orthopoxviruses was positive; some cells exhibited viral factories, typical for orthopoxvirus infection (Figure 2, panel D) (9).
The patient was instructed to remain isolated in his residence until he had fully recovered. Days after he returned home, the pustules turned to scabs (0.3–0.8 mm in diameter) and were shed (Figure 1, panels E, F). Concomitant with recovery, antibodies against orthopoxvirus and a neutralizing antibody titer (50% plaque reduction neutralization test titer = 134) developed, comparable to those of smallpox-vaccinated humans (10). Of note, scabs collected from the patient during recovery, then homogenized and tested for monkeypox virus, contained viable viral loads of 105–107 PFU/scab.
All of the patient’s contacts in Israel (5 household members and 11 HCWs) were offered smallpox vaccination, but only 1 HCW agreed. All contacts were followed up for 21 days; no virus transmission was detected.
 Top

Conclusions

Since the first documented case of human monkeypox in 1970, sporadic outbreaks have been reported, especially in the Congo Basin and western Africa. Contributing to the increased frequency of such occurrences were discontinued vaccination against smallpox; increased interaction with wildlife because of deforestation and population movement; consumption of bushmeat; and increased population density (11,12). Although most infections are acquired from wildlife, human-to-human transmission has been reported, as in the 1996–1997 outbreak in the Democratic Republic of the Congo (13) and the current outbreak in West Africa (8). The availability and speed of international transportation combined with the natural progression of the disease (long incubation and prodromal periods, up to 21 days combined) increase the risk for monkeypox spread from rural regions into urban areas and to countries outside Africa. Indeed, during September and October 2018, monkeypox was diagnosed in the United Kingdom and Israel (6,14).
Thus far, all imported cases of monkeypox in humans (United States in 2003, United Kingdom and Israel in 2018) have involved the West African clade of the virus (3,6). After a similar incubation period (12 days), all patients had fever and chills, lymphadenopathy, and skin lesions (5,6). Although the patient in Israel had numerous vesiculopustules on his face and body, the patients involved in the US outbreak had substantially fewer (1–50) and reported a persistent cough, which the patient from Israel did not report. Of note, the first sign noted by the Israel and UK patients was groin lesions (6). Although past reports considered the Congo-Basin clade to be more virulent (2,3,12), recent reports show that the West African clade can also cause disseminated disease and can be transmitted from human to human (4,8).
For this study, we used multiple diagnostic approaches. The virus was detected in pustule swab specimens by transmission electron microscopy and PCR within 3 hours of sample arrival and confirmed by immunofluorescence assay, tissue culture, and ELISA for orthopoxvirus antigens.
The very high virus titers contained by pustules and scabs, as demonstrated in this case, increase the risk for human-to-human transmission and environmental spread. To prevent further transmission, HCWs should implement safety practices and local authorities should map contacts and consider use of smallpox vaccines or antiviral drugs (14,15), according to risk assessment.
 Top
Drs. Erez and Achdout are researchers at the Department of Infectious Diseases, Israel Institute for Biological Research, Ness-Ziona, Israel. Their research interests include immune response to vaccines and viral infections.
 Top

Acknowledgment

We thank Itai Glinert for help with the manuscript.
 Top

References

  1. Di Giulio  DBEckburg  PBHuman monkeypox: an emerging zoonosis. Lancet Infect Dis2004;4:1525DOIPubMed
  2. Breman  JGKalisa-Ruti Steniowski  MVZanotto  EGromyko  AIArita  IHuman monkeypox, 1970-79. Bull World Health Organ1980;58:16582.PubMed
  3. Likos  AMSammons  SAOlson  VAFrace  AMLi  YOlsen-Rasmussen  Met al. A tale of two clades: monkeypox viruses. J Gen Virol2005;86:266172DOIPubMed
  4. Petersen  EAbubakar  IIhekweazu  CHeymann  DNtoumi  FBlumberg  Let al. Monkeypox - Enhancing public health preparedness for an emerging lethal human zoonotic epidemic threat in the wake of the smallpox post-eradication era. Int J Infect Dis2019;78:7884DOIPubMed
  5. Reed  KDMelski  JWGraham  MBRegnery  RLSotir  MJWegner  MVet al. The detection of monkeypox in humans in the Western Hemisphere. N Engl J Med2004;350:34250DOIPubMed
  6. Vaughan  AAarons  EAstbury  JBalasegaram  SBeadsworth  MBeck  CRet al. Two cases of monkeypox imported to the United Kingdom, September 2018. Euro Surveill2018;23:23DOIPubMed
  7. Shchelkunov  SNGavrilova  EVBabkin  IVMultiplex PCR detection and species differentiation of orthopoxviruses pathogenic to humans. Mol Cell Probes2005;19:18DOIPubMed
  8. Yinka-Ogunleye  AAruna  OOgoina  DAworabhi  NEteng  WBadaru  Set al. Reemergence of human monkeypox in Nigeria, 2017. Emerg Infect Dis2018;24:114951DOIPubMed
  9. Smith  GLVanderplasschen  ALaw  MThe formation and function of extracellular enveloped vaccinia virus. J Gen Virol2002;83:291531DOIPubMed
  10. Orr  NForman  MMarcus  HLustig  SParan  NGrotto  Iet al.Vaccinia Study Group, Medical Corps, Israel Defense ForceVaccinia Study Group, Israel Institute for Biological ResearchClinical and immune responses after revaccination of israeli adults with the Lister strain of vaccinia virus. J Infect Dis2004;190:1295302DOIPubMed
  11. Nolen  LDOsadebe  LKatomba  JLikofata  JMukadi  DMonroe  Bet al. Introduction of monkeypox into a community and household: risk factors and zoonotic reservoirs in the Democratic Republic of the Congo. Am J Trop Med Hyg2015;93:4105DOIPubMed
  12. McCollum  AMDamon  IKHuman monkeypox. Clin Infect Dis2014;58:2607DOIPubMed
  13. Centers for Disease Control and Prevention (CDC)Human monkeypox — Kasai Oriental, Democratic Republic of Congo, February 1996-October 1997. MMWR Morb Mortal Wkly Rep1997;46:116871.PubMed
  14. Angelo  KMPetersen  BWHamer  DHSchwartz  EBrunette  GMonkeypox transmission among international travelers—serious monkey business? J Travel Med2019DOIPubMed
  15. Melamed  SIsraely  TParan  NChallenges and achievements in prevention and treatment of smallpox. Vaccines (Basel)2018;6:E8DOIPubMed
 Top

Figures

 Top
Suggested citation for this article: Noam E, Achdout H, Milrot E, Schwartz Y, Wiener-Well Y, Paran N, et al. Diagnosis of imported monkeypox, Israel, 2018. Emerg Infect Dis. 2019 May [date cited]. https://doi.org/10.3201/eid2505.190076
DOI: 10.3201/eid2505.190076
Original Publication Date: 3/8/2019


1These authors contributed equally to this article.

No hay comentarios:

Publicar un comentario