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Volume 12, Number 12—December 2006
Perspective

Qualitative Assessment of Risk for Monkeypox Associated with Domestic Trade in Certain Animal Species, United States

Author affiliations: *US Food and Drug Administration, College Park, Maryland, USA

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Abstract

In 2003, US officials identified several human monkeypox cases and traced the virus exposure to infected captive prairie dogs. The virus was likely introduced through a shipment of imported African rodents, which were kept with other mammals, including prairie dogs, in a pet distribution facility in the Midwest. To prevent the further introduction and spread of the virus, federal agencies restricted the importation of African rodents and restricted the domestic trade or movement of prairie dogs and certain other rodents. In this qualitative assessment of the risk for monkeypox associated with the 2003 outbreak, we conclude that the probability of further human infection is low; the risk is further mitigated by rodent import restrictions. Were this zoonotic disease to become established domestically, the public health effects could be substantial.

In May and June 2003, public health officials identified an outbreak of human monkeypox in the United States (13). This was the first instance of human monkeypox virus (MPXV) infection detected outside its endemic range in Africa (3). As of July 30, 2003, a total of 72 human cases had been reported (4,5). Thirty-seven (51%) cases were eventually laboratory confirmed, and 35 met the case definition set by the Centers for Disease Control and Prevention (CDC) (4,5). Among the 35 patients whose cases were laboratory confirmed before July 11, 2003 (1), 32 (91%) tested positive for MPXV by PCR, culture, immunohistochemical testing, or electron microscopy of skin lesions; 2 tested positive by PCR and/or culture of an oropharyngeal or nasopharyngeal swab; and 1 tested positive by PCR and culture of a lymph node aspirate (1). To date, no new animal or human cases have been reported.

The outbreak was relatively large compared with most reported events in Africa, but clinical features were milder than typically seen there (3,6,7). No human deaths occurred (1,8), although 2 children required intensive care (1,8). One patient received a corneal transplant due to chronic ocular infection (8).

Most patients were exposed to prairie dogs, primarily from an Illinois animal distributor (IL-1). Most of those infected had direct physical contact with infected animals; infection likely resulted from bites or scratches or through open wounds (13). Some patients were exposed to premises where prairie dogs were kept (1).

Traceback implicated rodents from a shipment of African animals imported to Texas on April 9, 2003, as the probable source of MPXV (1,4). The shipment contained ≈800 small mammals of 9 different species, including 6 genera of African rodents (762 rodents total): rope squirrels, tree squirrels, Gambian giant rats, brushtail porcupines, dormice, and striped mice (1,2), as well as cusimanses, genets, and palm civets (9). Rodents from the shipment were housed with or in close proximity to prairie dogs at IL-1. Approximately 200 prairie dogs were at IL-1 coincident with the arrival of the imported African rodents (1). Many prairie dogs from IL-1 were distributed to other states for sale as pets (1,4). CDC traced 93 infected or potentially infected prairie dogs from IL-1 (1). An additional, unknown number of prairie dogs died or were sold at animal swap meets for which records are not available (1) (Table 1).

To prevent the introduction and spread of infected animals into susceptible populations, on June 11, 2003, the Food and Drug Administration (FDA) and CDC issued an order that prohibited 1) importation of all rodents from Africa and 2) transportation, sale, or any other commercial or public distribution, including release into the environment, of prairie dogs or rodents from 6 species represented in the African shipment (10). On November 4, 2003, FDA and CDC published an interim final rule (11) that imposed import restrictions on all African rodents and established or modified restrictions on the import, capture, transport, sale, barter, exchange, distribution, and release of prairie dogs, the 6 imported species, and possibly, by order, other animals with the potential to transmit MPXV. Neither CDC nor FDA exercised its statutory authority to seize and destroy animals to prevent the spread of MPXV.

We prepared this qualitative risk analysis to help understand the impact of the domestic trade restrictions on the current risk for human monkeypox infections. We evaluated the data and uncertainties concerning monkeypox and its potential spread to animal and human populations and characterized the probability of harm on the basis of those data. Because of CDC's import restrictions on all African rodents, we did not estimate the risk posed by importation of animals into the United States. We focused only on monkeypox and did not consider other zoonotic agents that might be transmitted by the species discussed. This risk assessment follows a generally accepted 4-part framework (12). The hazards are MPXV and its potential for transmission and spread from animals to humans; the risk is human infection from prairie dogs and possibly imported rodents.

Hazard Identification

Human monkeypox is a sporadic zoonotic viral disease, caused by an orthopoxvirus that until 2003 was known to have occurred only in parts of Africa (3,7,13). The first human illness was identified in 1970 in a child (7,14). Previous cases were likely mistaken for smallpox (14). Although it was first isolated from a captive primate (3,6), rodents are its likely primary natural reservoir (7,1517); its complete mammalian host range is unknown. The mode of transmission between infected animals and humans is not well defined (18). Direct mucocutaneous contact and respiratory routes have been implicated in epidemiologic and experimental research (15,18,19).

The estimated mean human incubation period is 12 days (1,3,15,16). The disease is characterized by a rash similar to that observed with smallpox (14) or chickenpox (10,15,20). The infectious period occurs during the first week of the rash (7); symptoms include headache, fever, sweats, and severe lymphadenopathy (15,16,20). Among African patients with a history of smallpox vaccination, monkeypox is usually milder with lower numbers of deaths (3,6,16). Subclinical or very mild infection can occur in humans (16,21,22).

Case-fatality rates in African outbreaks range from 4% to 33% (6,23) and are high among children (3,6,14,23). Variability in case-fatality rates may reflect incomplete assessment of the total number of cases, variations in case definition, and variability in the virulence of MPXV strains. The US outbreak has been associated with a milder strain (3,2426). Case fatality also likely depends on differences in exposure, susceptibility, and healthcare (14).

Repeated animal reintroduction of MPXV is believed necessary to endemic infections in human populations. Human cases in disease-endemic areas tend to be sporadic and isolated and primarily associated with direct animal-to-human transmission (24,27). However, clusters associated with common source and human-to-human transmission occur and may in Africa be increasing with decreased prevalence of prior smallpox vaccination (6,7,15,16,28,29).

FDA has not approved a treatment for monkeypox. Suggested treatment options include cidofovir (3032). Efficacy of vaccinia immune globulin in humans has not been established (30,31). After the onset of symptoms, supportive therapy is usually the recommended treatment (31). Preexposure and postexposure smallpox vaccine was used during the 2003 outbreak, with only relatively minor adverse events reported (1,32).

Hazard Characterization

Much is unknown about pathogenesis and transmission dynamics of MPXV in humans and animals. Limited research suggests that at least in some host mammals latent or inapparent infection occurs (15). In addition to serologic evidence of orthopoxvirus exposure, MPXV has been recovered from the kidneys of healthy-appearing animals (15,16). The latency period is unknown, as is whether the virus can be transmitted during such periods.

The complete host range of MPXV in Africa is unknown. Animal antibody surveys in disease-endemic areas suggest infection is enzootic among squirrels, other rodents, and monkeys, although other animals may be infected (6,15,16,3335).

The number of animals exposed or infected in the United States is unknown and impossible to estimate. Approximately 800 animals were recorded in the African shipment, but disposition information is available only for rodents (Table 1) (1). A Gambian giant pouched rat, 3 dormice, and 2 rope squirrels from the shipment were tested and found to be infected with MPXV (1). Infected animals from the shipment were housed or transported with prairie dogs and other mammals. An unknown number of prairie dogs and animals from other species became infected. Although many prairie dogs became ill and several died, some infected animals survived. The secondary attack rate among susceptible animals is unknown and cannot be estimated with available data.

CDC necropsied 249 animals involved with the outbreak, confirming infection in 33 animals with PCR (36) and in 22 animals through virus isolation from various tissues. Infection was confirmed in 14 prairie dogs, 2 Gambian giant pouched rats, 9 dormice, 3 rope squirrels, 1 ground hog, 1 hedgehog, 1 jerboa, and 2 opossums.

CDC performed extensive histopathologic examination on 2 necropsied prairie dogs from IL-1 and detected MPXV DNA by using real-time PCR (18). The necropsied prairie dogs had MPXV in saliva, lesion exudates, and bronchi and lung parenchyma (18). Approximately 110 of the ≈200 prairie dogs likely exposed at IL-1 were sold after the African animals were introduced and before 15 of the prairie dogs at IL-1 became ill. Ten of the ill prairie dogs died rapidly (1,3,18).

In June 2003, CDC evaluated an unspecified number of prairie dogs, dormice, hedgehogs, jerboas, opossums, and numerous other species (a total of 18 species) from IL-1; of these, 2 prairie dogs, 7 dormice, 1 African hedgehog, 1 jerboa, and 1 gray short-tailed opossum tested positive for MPXV by PCR (36). When these animals were infected or if they could transmit disease is not known.

On June 19, 2003, CDC acquired 61 live animals from the original shipment. On August 20, 2003, CDC acquired from the state of Illinois 291 animals remaining at IL-1, including African and domestic species. Numerous other animals were acquired from Iowa, Wisconsin, Indiana, and Ohio. Of 172 animals tested from the various states as well as from the original shipment, 25 showed serologic evidence of infection without overt signs of disease (i.e., PCR and tissue culture negative). On June 24, 2003, an oral and ocular swab from a dormouse from IL-1 tested positive by PCR. After the dormouse died a month later, its tissues tested positive for MPXV by PCR and culture. A second dormouse from IL-1 that also tested positive in June appeared healthy; however, when it was euthanized in December 2003, swabs and necropsy samples of various tissues, urine, and feces were positive by PCR. No viral antigen was detected on pathologic examination of tissues (36).

Investigations of human cases from the outbreak support the hypothesis that close direct contact with infected animals was necessary for infection. Cases occurred among persons who were bitten by infected prairie dogs or infected through open wounds (3,8). The 11 Wisconsin patients included a child and parents; a meat distributor who also distributed exotic animals; his wife; 2 employees of 2 different pet stores; 2 veterinarians from different clinics; a person who had bought prairie dogs; and that person's houseguest. All of these patients reported direct contact with an infected prairie dog (3), although human-to-human transmission could not be ruled out for the parents (3).

Data on duration of infection are limited. Virus appears to be present in some animals months after infection, regardless of clinical illness. In addition to CDC's data on dormice, data derived from experimental infection of small numbers of laboratory animals documented infectious MPXV in tissues 3–6 weeks after exposure (18). Clinical and asymptomatic infections have been reported among captive primates; severity varied depending on the species and route of inoculation (16). CDC has reported elevated tissue viral loads in 2 necropsied prairie dogs (18). In another study, 10 experimentally infected North American ground squirrels died within 9 days, although no obvious signs of disease except for lethargy and anorexia developed (37). Squirrels infected intranasally had a longer incubation period and later death (36). Ten prairie dogs infected experimentally with a human MPXV isolate were highly susceptible to infection but had a lower death rate and less severe pathologic change than were seen in the squirrel study that used the same dose (19).

A human adult infected during the 2003 outbreak experienced keratitis and corneal ulceration as a complication of infection and ultimately received a corneal transplant (8). Corneal ulceration has also been reported in some African patients (16).

Exposure Assessment

In African outbreaks, capturing, handling, and eating wild animals have been associated with infection (6,23,34). In the United States, monkeypox occurred in humans who had direct contact with infected animals and were bitten or infected through open wounds (3). These persons included pet dealers, pet owners and their children, and contacts of these people at risk of coming into direct contact with the infected animal. Although potential exposure occurred in settings that included pet stores, swap meets, and wild animal trade centers (1), no evidence exists that persons casually exposed to infected animals were infected. The magnitude and scope of this pet trade are not well quantified. In 2002, ≈30,000 prairie dogs were sold at pet dealers, swap meets, flea markets, and other venues open to the public (11).

Of the 762 rodents in the African shipment, CDC traced 584 (77%) (1). The remaining 178 (≈23%) could not be traced beyond the point of entry (1). The fate of the 50 nonrodent animals on the shipment is unknown. Of the ≈200 prairie dogs that may have been exposed to MPXV at IL-1, 107 (54%) have not been accounted for. These animals will not likely be traced. A small number of animals associated with the outbreak, including some known to have been infected, are in the possession of pet dealers and private owners; their capacity to transmit infection is unknown. Animals from species other than the listed species—gerbil, hamster, chinchilla, opossum, groundhog, hedgehog, and jerboa—were discovered to be infected, although no confirmed human cases of infection were associated with contact with any animal except prairie dogs (1,9).

To evaluate the potential spread of the disease beyond the initially exposed animals, the US Geological Survey's National Wildlife Health Center trapped 237 small mammals from 14 species at 9 sites in Wisconsin and Illinois where cases of monkeypox were reported. All were negative for monkeypoxvirus or monkeypoxvirus-specific antibodies (38). These small amounts of data are insufficient to establish the absence of MPXV in the wild.

The federal restrictions on importation of high-risk species and trade in the listed species have likely substantially reduced the potential risk for exposure of uninfected animals or persons to MPXV. However, some residual risk for MPXV infection through illegal importation or infection in legally imported, nonlisted species may exist.

Risk Characterization

Table 2 provides summary information on the qualitative variables considered in the risk characterization. We evaluated the probability of human monkeypox infection that resulted from certain types of exposure or contact (direct or indirect) to animals (infected or noninfected) and qualitatively estimated the probability and, to a lesser extent, the possible severity of infection. Most confirmed human cases in the United States were associated with direct, close contact with infected prairie dogs. We characterize as type I direct contact with the animal and as type II direct contact that also involves bites, scratches, or other contact with the mucous membranes or nonintact skin of the affected person. Infection through aerosolized particles without direct animal contact, or by some other less direct method, as well as human-to-human transmission, cannot be ruled out. The probability of infection is dependent on whether the animal is infectious (shedding virus) and varies with the level of shedding and the nature of human-animal interactions (type, frequency, and duration of contact). We assume, on the basis of the data described above, that the primary means of transmission affecting the risk would be from animal to human.

Several categories were established to define and qualitatively characterize the risks. Low risk denoted no direct human contact with a captive animal(s); even if animal infection status was unknown or the animal was infected, the exposure to the animal was likely insufficient for animal-to-human disease transmission to occur. Medium risk described human contact that was direct but the exposure involved type I contact with a potentially infected animal or animal(s) of unknown infectious status. High risk designated direct human contact and involved a type II contact with a captive animal(s) infected with MPXV or with unknown infection status but likely MPXV exposure. Finally, the term severity of infection and illness denoted any individual infection with MPXV that should be considered serious and potentially fatal. The risk to the persons and the risk for the spread of the disease to others made MPXV infection a potentially serious public health matter.

The probability that any surviving animal directly involved in the outbreak may be infected must be considered high, given the possibility of latent infection. Making the unlikely assumption that all of these animals are still alive, the group includes the 178 African rodents, mostly dormice, lost to follow-up, 107 prairie dogs from IL-1 that were not traceable, and 50 nonrodent animals included in the African shipment. An unknown number, but clearly most, of the affected African rodents and IL-1 prairie dogs that were traced and identified as alive as of July 2003 (121 African rodents and ≈93 prairie dogs) have since died or been euthanized.

Some animals from other species that were in the affected pet distribution facilities during the outbreak tested positive for MPXV. An unknown number of these exposed animals are likely to be alive and in private or commercial ownership; what proportion of these animals is infected with MPXV is unknown but is assumed to be small. No confirmed cases of human infection or further cases of animal infection have been associated with these animals. However, all animals directly associated with the 2003 outbreak should be considered to pose a continued high risk for infection.

The probability of infection in rodents or other animals imported from monkeypox-endemic regions is unknown. Imported African rodents were almost certainly the source of the US outbreak. Animals imported as pets are handled by several persons as they pass from importer to owner, and they may be housed and transported in close proximity with nonimported susceptible animals. Current import restrictions on African rodents substantially reduce the risk for introduction and spread of MPXV, but a potential residual risk remains because of illegal importation as well as import of nonrestricted species that may carry the virus. Some previously imported animals from restricted species might also be infected with MPXV, although this risk is unknown and assumed to be extremely low.

For domestically bred African rodents, the risk they may pose of transmitting MPXV to humans depends on the risk that the rodents will be exposed to infected animals. Absent a tracking or pedigree system that distinguishes domestically bred from imported, wild-caught animals is impossible. Trade in domestically bred African rodents could increase the risk for human infection if illegally imported infected animals are identified as captive-bred. The monkeypox risk to humans posed by prairie dogs is a function of the animals' possible contact with infected animals and their potential for viral transmission.

The number of animals infected with or exposed to MPXV in the outbreak that might still be alive is likely small. However, these animals may be widely distributed geographically, and they may have spread the virus to other animals not currently known to pose a risk. The risk for MPXV infection and spread among prairie dogs are mitigated by current import and trade restrictions and the death or euthanization of most animals directly associated with the outbreak. The probability that an uninfected prairie dog will come into contact with an infected captive or released animal and that there will be sufficient exposure for infection is likely low. If such contact occurs, however, these animals are highly susceptible.

Little evidence about the MPXV status of wild prairie dogs exists. Given the high rates of illness and death among captive prairie dogs exposed to MPXV in 2003, anticipating that the virus would result in a die-off that would be detected may be reasonable; however, in addition to the lack of data, uncertainties about the virus and the susceptibility of the animals in the wild preclude drawing any conclusions.

The risk for new domestically acquired human cases is low with the current restrictions on import and trade in certain species in place. No new cases have been reported in humans or animals since the outbreak, despite the likelihood that some surviving infected animals have been kept alive by individual or commercial owners. Limited surveillance efforts have not identified MPXV in wild animal populations; however, the virus could possibly become enzootic here if an infected animal were released or escaped into the wild and spread the virus to susceptible mammals. Were that to occur, human cases would likely result. The risk that monkeypox could become enzootic is relevant in evaluating the risk of importing potential mammalian carriers of MPXV or in allowing contact between likely carriers and susceptible domestic mammals.

Data limitations preclude quantitative, and limit accurate qualitative, estimation of the human risk for monkeypox in the United States (Table 3). Research is needed on disease dynamics, range of host species, and the parameters of wild animal trade and ownership.

Dr Bernard is the associate director for regulations in FDA's Center for Food Safety and Applied Nutrition. Her professional and academic focus has been on population health risks, law, and policy; projects at FDA include issues such as antimicrobial drug resistance, foodborne pathogens and toxins, communicable diseases, and obesity and nutrition-related diseases.

Dr Anderson is the associate director for risk assessment in the Office of Biostatistics and Epidemiology at the FDA Center for Biologics Evaluation and Research. He uses computer modeling and risk assessment techniques to address critical scientific and policy issues pertaining to the safety of blood and blood products, vaccines and cellular, tissue, and gene therapies.

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Acknowledgment

We thank Beth Karp, Philip L. Chao, and the reviewers external to FDA, who provided expert comment on an earlier draft of this work.

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References

  1. Centers for Disease Control and Prevention. Update: multistate outbreak of monkeypox—Illinois, Indiana, Kansas, Missouri, Ohio, and Wisconsin, 2003. MMWR Morb Mortal Wkly Rep. 2003;52:6426.PubMedGoogle Scholar
  2. Centers for Disease Control and Prevention. Multistate outbreak of monkeypox–Illinois, Indiana, and Wisconsin, 2003. MMWR Morb Mortal Wkly Rep. 2003;52:53740.PubMedGoogle Scholar
  3. Reed  KD, Melski  JW, Graham  MB, Regnery  RL, Sotir  MJ, Wegner  MV, The detection of monkeypox in humans in the Western Hemisphere. N Engl J Med. 2004;350:34250. DOIPubMedGoogle Scholar
  4. Centers for Disease Control and Prevention. Monkeypox: report of cases in the United States. 2003. [cited 2006 Sept 26]. Available from http://www.cdc.gov/od/oc/media/mpv/cases.htm
  5. Di Giulio  DB, Eckburg  PB. Human monkeypox. Lancet Infect Dis. 2004;4:199. DOIPubMedGoogle Scholar
  6. Hutin  YJ, Williams  RJ, Malfait  P, Pebody  R, Loparev  VN, Ropp  SL, Outbreak of human monkeypox, Democratic Republic of Congo, 1996 to 1997. Emerg Infect Dis. 2001;7:4348.PubMedGoogle Scholar
  7. Huhn  GD, Bauer  AM, Yorita  K, Graham  MB, Sejvar  J, Likos  A, Clinical characteristics of human monkeypox, and risk factors for severe disease. Clin Infect Dis. 2005;41:174251. DOIPubMedGoogle Scholar
  8. Di Giulio  DB, Eckburg  PB. Human monkeypox: an emerging zoonosis. Lancet Infect Dis. 2004;4:1525. DOIPubMedGoogle Scholar
  9. Reynolds  MG, Cono  J, Curns  A, Holman  RC, Likos  A, Regnery  R, Human monkeypox. Lancet Infect Dis. 2004;4:6045. DOIPubMedGoogle Scholar
  10. Gerberding  JL, McClellan  MB. Joint Order of the Centers for Disease Control and Prevention and the Food and Drug Administration, Department of Health and Human Services. June 11, 2003. Available at 68 Fed Reg. 36566 (June 18, 2003).
  11. Centers for Disease Control and Prevention. Control of communicable diseases; restrictions on African rodents, prairie dogs, and certain other animals. Interim final rule. Fed Regist. 2003;68:6235369.PubMedGoogle Scholar
  12. National Research Council. Risk assessment in the federal government: managing the process. Washington: National Academy Press; 1983.
  13. Ladnyj  ID, Ziegler  P, Kima  E. A human infection caused by monkeypox virus in Basankusu Territory, Democratic Republic of the Congo. Bull World Health Organ. 1972;46:5937.PubMedGoogle Scholar
  14. Jezek  Z, Szczeniowski  M, Paluku  KM, Mutombo  M. Human monkeypox: clinical features of 282 patients. J Infect Dis. 1987;156:2938. DOIPubMedGoogle Scholar
  15. Breman  JG. Monkeypox: an emerging infection for humans? In: Scheld WM, Craig WA, Hughes JM, editors. Emerging Infections 4. Washington: ASM Press; 2000. p. 45–76.
  16. Jezek  Z, Fenner  F. Human monkeypox, in Monographs on Virology. New York: Karger; 1988.
  17. Khodakevich  L, Szczeniowski  M, Manbu-ma-Disu , Jezek  Z, Marennikova  S, Nakano  J, The role of squirrels in sustaining monkeypox virus transmission. Trop Geogr Med. 1987;39:11522.PubMedGoogle Scholar
  18. Guarner  J, Johnson  BJ, Paddock  CD, Shieh  WJ, Goldsmith  CS, Reynolds  MG, Monkeypox transmission and pathogenesis in prairie dogs. Emerg Infect Dis. 2004;10:42631.PubMedGoogle Scholar
  19. Xiao  SY, Sbrana  E, Watts  DM, Siirin  M, da Rosa  AP, Tesh  RB. Experimental infection of prairie dogs with monkeypox virus. Emerg Infect Dis. 2005;11:53945.PubMedGoogle Scholar
  20. Anderson  MG, Frenkel  LD, Homann  S, Guffey  J. A case of severe monkeypox virus disease in an American child: emerging infections and changing professional values. Pediatr Infect Dis J. 2003;22:10936. DOIPubMedGoogle Scholar
  21. Jezek  Z, Nakano  JH, Arita  I, Mutombo  M, Szczeniowski  M, Dunn  C. Serological survey for human monkeypox infections in a selected population in Zaire. J Trop Med Hyg. 1987;90:318.PubMedGoogle Scholar
  22. Jezek  Z, Marennikova  SS, Mutumbo  M, Nakano  JH, Paluku  KM, Szczeniowski  M. Human monkeypox: a study of 2,510 contacts of 214 patients. J Infect Dis. 1986;154:5515. DOIPubMedGoogle Scholar
  23. Meyer  H, Perrichot  M, Stemmler  M, Emmerich  P, Schmitz  H, Varaine  F, Outbreaks of disease suspected of being due to human monkeypox virus infection in the Democratic Republic of Congo in 2001. J Clin Microbiol. 2002;40:291921. DOIPubMedGoogle Scholar
  24. Zaucha  GM, Jahrling  PB, Geisbert  TW, Swearengen  JR, Hensley  L. The pathology of experimental aerosolized monkeypox virus infection in cynomolgus monkeys (Macaca fascicularis). Lab Invest. 2001;81:1581600.PubMedGoogle Scholar
  25. Esposito  JJ, Knight  JC. Orthopoxvirus DNA: a comparison of restriction profiles and maps. Virology. 1985;143:23051. DOIPubMedGoogle Scholar
  26. Likos  AM, Sammons  SA, Olson  VA, Frace  AM, Li  Y, Olsen-Rasmussen  M, A tale of two clades: monkeypox viruses. J Gen Virol. 2005;86:266172. DOIPubMedGoogle Scholar
  27. Arita  I, Jezek  Z, Khodakevich  L, Ruti  K. Human monkeypox: a newly emerged orthopoxvirus zoonosis in the tropical rain forests of Africa. Am J Trop Med Hyg. 1985;34:7819.PubMedGoogle Scholar
  28. Heymann  DL, Szczeniowski  M, Esteves  K. Re-emergence of monkeypox in Africa: a review of the past six years. Br Med Bull. 1998;54:693702.PubMedGoogle Scholar
  29. Antia  R, Regoes  RR, Koella  JC, Bergstrom  CT. The role of evolution in the emergence of infectious diseases. Nature. 2003;426:65861. DOIPubMedGoogle Scholar
  30. Centers for Disease Control and Prevention. Updated interim CDC guidance for use of smallpox vaccine, cidofovir, and vaccinia immunoglobulin (VIG) for prevention and treatment in the setting of an outbreak of monkeypox infections. 2003. [cited 2006 Sep 26]. Available from http://www.cdc.gov/ncidod/monkeypox/treatmentguidelines.htm
  31. Sejvar  JJ, Chowdary  Y, Schomogyi  M, Stevens  J, Patel  J, Karem  K, Human monkeypox infection: a family cluster in the midwestern United States. J Infect Dis. 2004;190:183340. DOIPubMedGoogle Scholar
  32. Edghill-Smith  Y, Golding  H, Manischewitz  J, King  LR, Scott  D, Bray  M, Smallpox vaccine–induced antibodies are necessary and sufficient for protection against monkeypox virus. Nat Med. 2005;11:7407. DOIPubMedGoogle Scholar
  33. Centers for Disease Control and Prevention. Human monkeypox—Kasai Oriental, Democratic Republic of Congo, February 1996–October 1997. MMWR Morb Mortal Wkly Rep. 1997;46:116871.PubMedGoogle Scholar
  34. Khodakevich  L, Jezek  Z, Messinger  D. Monkeypox virus: ecology and public health significance. Bull World Health Organ. 1988;66:74752.PubMedGoogle Scholar
  35. Breman  JG, Nakano  JH, Coffi  E, Godfrey  H, Gautun  JC. Human poxvirus disease after smallpox eradication. Am J Trop Med Hyg. 1977;26:27381.PubMedGoogle Scholar
  36. Hutson  CL, Lee  KN, Abel  J, Carroll  DS, Montgomery  JM, Olson  VA, Monkeypox zoonotic association: insights from laboratory evaluation of animals associated with the U.S. outbreak. Am J Trop Med Hyg. 2006. In press.
  37. Tesh  RB, Watts  DM, Sbrana  E, Siirin  M, Popov  VL, Xiao  S-Y. Experimental infection of ground squirrels (Spermophilus tridecemlineatus) with monkeypox virus. Emerg Infect Dis. 2004;10:15637.PubMedGoogle Scholar
  38. US Department of the Interior; US Geological Survey. Investigating monkeypox in the wild. Factsheet 2004–3003. July 2004. [cited 2006 Jun 13]. Available from http://www.nwhc.usgs.gov/publications/fact_sheets/pdfs/monkeypoxfinal_071504.pdf

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DOI: 10.3201/eid1212.060454

Table of Contents – Volume 12, Number 12—December 2006

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Susan M. Bernard, US Food and Drug Administration, 3100 Paint Branch Pkwy, HFS-004, College Park, MD 20740, USA

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Page created: October 04, 2011
Page updated: October 04, 2011
Page reviewed: October 04, 2011
The conclusions, findings, and opinions expressed by authors contributing to this journal do not necessarily reflect the official position of the U.S. Department of Health and Human Services, the Public Health Service, the Centers for Disease Control and Prevention, or the authors' affiliated institutions. Use of trade names is for identification only and does not imply endorsement by any of the groups named above.
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