More than 200 years ago, in one of the first demonstrations of vaccination, Edward Jenner inoculated a young English boy with cowpox material from a dairymaid and showed that the boy became resistant to smallpox. Today, cowpox is a rare disease, largely confined to small mammals on the European continent and in Great Britain, with occasional transmission to humans. Most cases present with a small number of vesicopustular lesions on the hands or face that subsequently ulcerate and develop a black eschar before spontaneously resolving. Rarely, cutaneous dissemination and even death may occur.
Cowpox is caused by the cowpox or catpox virus, a member of the orthopoxvirus family, which also includes smallpox and vaccinia.[1] The virus is believed to be acquired by direct contact with an infected animal, most often a cat in the case of humans, with lesions occurring where the virus gains access through broken skin.[2, 3] Infection generally remains localized at the initial site of inoculation, although lymphatic spread in a sporotrichoid pattern and generalized skin infection have been reported.[4, 5, 6] Human-to-human transmission of cowpox has never been reported.
As a member of the Orthopoxvirus family, cowpox is a large double-stranded DNA virus that replicates in cell cytoplasm. Viral particles bind to plasma membrane receptors on host cells and then enter into the cytoplasm, where the viral genome is replicated and viral progeny are assembled. After new viral particles are assembled, the host cell lyses, releasing infectious virus, which can enter surrounding cells. Cowpox virus has no latent stage and does not integrate its DNA into the host genome.
Poxviruses use numerous strategies to evade the host immune system. These include production of homologues of mammalian tumor necrosis factor receptor, interleukin-1beta receptor, interleukin 18–binding protein, interferon-alpha/beta receptor, and interferon-gamma receptor, as well as a complement-binding protein and a caspase inhibitor.[7] These proteins are thought to neutralize the host's antiviral response by binding to cytokines and complement proteins and inhibiting their function. In addition, cowpox virus has been shown to inhibit intracellular transport of major histocompatibility class I molecules, allowing it to evade cytotoxic T cells.[8, 9]
The natural reservoir of cowpox virus is believed to be small woodland mammals, such as bank voles and wood mice, with humans, cows, and cats being only accidental hosts.
Risk factors for infection with cowpox include exposure to potentially infected animals (eg, cats, cows, rodents) in an endemic area. Risk factors for dissemination of infection include atopic dermatitis and use of systemic corticosteroids.
United States
Cowpox has never been reported in the United States.
International
Cowpox is a rare infection of humans, with fewer than 150 human cases reported.[4, 10] Historically, most cases have been reported in Great Britain, with a smaller number from Germany, Belgium, the Netherlands, France, Sweden, Finland, Norway, and Russia. In 2001, 60 cases of possible cowpox were reported in Egypt, but this has not been confirmed.[10] Most cases occur in the late summer and fall.
No racial predilection has been reported.
Equal numbers of male and female cases have been reported.
Human cowpox is a disease of young people, with half of all cases occurring in individuals younger than 18 years. Young people may be at greater risk because of a propensity for close contact with animals, such as cats, or because of their not having been vaccinated for smallpox, which may confer some protection against cowpox.
The prognosis for patients with this condition is very good. Human cowpox is usually a self-limited disease. The host immune response is usually sufficient to control the viral infection, and the only sequelae are scars at the site of the pox lesions. Of the eight cases of severe generalized skin infection that have been reported, four of the patients had atopic dermatitis, one had Darier disease,[11] and one had hay fever.[5, 12] There have been only been two reported deaths associated with cowpox. One was in a patient with atopic dermatitis and allergic bronchial asthma who was receiving systemic steroids at the time of infection. After developing widespread cutaneous lesions, the patient died from pulmonary embolism. Autopsy failed to demonstrate viropathic effect in any internal organs, so it is unclear what role cowpox may have played in the patient's death. The second was in an adolescent renal transplant patient in Finland who developed neck swelling, tonsillitis, and widespread vesicopustular lesions after exposure to an infected cat.[13] He was found to have cowpox particles in his skin and blood by electron microscopy and polymerase chain reaction. He did not respond to cidofovir and brincidofovir antiviral therapy and died of multiorgan failure.
While patients have open lesions, they should be counseled in hygienic measures to prevent theoretical person-to-person spread of the cowpox virus.
Generally, patients are young; 50% of patients are younger than 18 years. Most cases occur in late summer to fall. Cases present in endemic areas of Europe.
Contact with rodents, cats, or cows is reported in 50% of cases.[14, 15, 16, 17, 18] One case was reported in an animal keeper who was exposed to an infected circus elephant.[19]
Usually, only 1 or a small number of lesions occur on the hands (48%) and face (33%). Patients may report having a flat red lesion that became raised and then blistered over a period of 2 weeks. The blister subsequently became crusted, with the surrounding skin becoming red and swollen. The lesions are characteristically described as quite painful.
Patients may have eye complaints. Patients may report fever, malaise, lethargy, vomiting, and sore throat, which usually lasts 3-10 days but resolves during the eschar stage of cutaneous lesions.
Physical findings generally are limited to the skin, eyes, and lymph nodes. Cutaneous findings develop as follows:
Rarely, the cutaneous lesions may become generalized before resolving. Ocular findings include conjunctivitis, periorbital edema, and corneal involvement. Enlarged painful local lymph nodes often are observed. Necrotizing lymphadenitis has been reported.[22]
Most patients will have scarring at the sites of the healed pox lesions.
Patients with underlying skin disorders, such as atopic dermatitis, are at risk for generalized skin infection, resembling eczema herpeticum. One case of facial cellulitis with necrotizing lymphadenitis requiring surgical lymph node removal has been reported.[22] One case of necrotizing cellulitis of the nose has been reported.[23]
One death from generalized cowpox has been reported in a patient with atopic dermatitis and asthma, and another death has been reported in an immunosuppressed renal transplant patient.[13]
Electron microscopy of vesicle fluid or scab extracts is the most rapid and useful technique to aid in diagnosis. Orthopoxviruses, including cowpox, have characteristic "mulberry" and "capsule" forms that allow them to be differentiated from parapoxviruses and herpes viruses. Electron microscopy does not distinguish between cowpox, smallpox, vaccinia, and molluscum viruses, so clinical information is critical.
Virus may be grown from lesional skin in cell culture and then studied by electron microscopy. Growth on chick chorioallantoic membrane produces characteristic hemorrhagic pocks.
Polymerase chain reaction may be performed on biopsy material or cell culture extracts to amplify the cowpox A36R, thymidine kinase, or hemagglutinin gene and identify it by sequencing or restriction fragment length polymorphism analysis.[24]
Serologic tests to detect antibodies to cowpox virus are not routinely available in hospital laboratories but may be performed in research laboratories. Previous vaccination with vaccinia may cause false-positive results, but these can be eliminated by the use of specific immunoglobulin M tests.[25]
Skin biopsy for routine histology, electron microscopy, culture, or molecular detection methods may be performed.
Using routine light microscopy, characteristic cytoplasmic inclusions have been observed in biopsies from feline cowpox but not in human material. Immunohistochemistry detects cowpox antigens in feline cases. Using electron microscopy, biopsy material may reveal viral particles.[26]
Because cowpox is generally a self-limited disease, treatment is largely supportive. Patients often do not feel well and require bed rest or, occasionally, hospitalization.
Antiviral medications are not routinely used in cases of human cowpox, nor are antibiotics given unless the patient has developed a secondary bacterial infection. However, studies in mice suggest a role for the viral DNA polymerase inhibitor cidofovir, given parenterally, topically, or in an aerosolized form, for disseminated cases of cowpox.[27, 28]
Patients should be made aware that their lesions are potentially infectious, but no person-to-person transmission has been reported. Occlusive bandages may be applied to avoid this risk.
In severe cases, antivaccinia gammaglobulin may be given.
Standard wound dressings may be applied to lesions. Draining of pus or removal of eschars may actually prolong infection or spread it to other body sites and is therefore not recommended.
Consult infectious disease and/or dermatology specialists for help in making a diagnosis and in differentiating it from parapoxvirus infections and other entities.
One may prevent infection with cowpox virus by avoiding exposure to sick cats or other sick animals. Recombinant vaccines against cowpox are being studied in mice and may eventually be available for human use.[29]
Because most cases of cowpox are mild and self-limited, no treatment is usually required. However, for severe cases with widespread involvement, cidofovir or antivaccinia gammaglobulin may be considered.[30]
Clinical Context: Vaccinia immune globulin is recommended only for severe cases with widespread involvement. This medication and advice on its use may be obtained from the Centers for Disease Control and Prevention Drug Services (404-639-3670). Dose information is based on the use of gammaglobulin for cases of vaccinia.
The rationale for using antivaccinia gammaglobulin is the presumed cross-reactivity of antibodies to all viruses of the orthopoxvirus family. Antibodies to vaccinia are known to be protective against smallpox and also may be protective against cowpox.