A zoonosis (/zoʊˈɒnəsɪs, ˌzoʊəˈnoʊsɪs/ ;[1] pl.: zoonoses) or zoonotic disease is an infectious disease of humans caused by a pathogen (an infectious agent, such as a bacterium, virus, parasite, or prion) that can jump from a non-human vertebrate to a human. When humans infect non-humans, it is called reverse zoonosis or anthroponosis.[2][1][3][4]
Major modern diseases such as Ebola and salmonellosis are zoonoses. HIV was a zoonotic disease transmitted to humans in the early part of the 20th century, though it has now evolved into a separate human-only disease.[5][6][7] Human infection with animal influenza viruses is rare, as they do not transmit easily to or among humans.[8] However, avian and swine influenza viruses in particular possess high zoonotic potential,[9] and these occasionally recombine with human strains of the flu and can cause pandemics such as the 2009 swine flu.[10] Zoonoses can be caused by a range of disease pathogens such as emergent viruses, bacteria, fungi and parasites; of 1,415 pathogens known to infect humans, 61% were zoonotic.[11] Most human diseases originated in non-humans; however, only diseases that routinely involve non-human to human transmission, such as rabies, are considered direct zoonoses.[12]
Zoonoses have different modes of transmission. In direct zoonosis the disease is directly transmitted from non-humans to humans through media such as air (influenza) or bites and saliva (rabies).[13] In contrast, transmission can also occur via an intermediate species (referred to as a vector), which carry the disease pathogen without getting sick. The term is from Ancient Greek: ζῷον zoon "animal" and νόσος nosos "sickness".
Host genetics plays an important role in determining which non-human viruses will be able to make copies of themselves in the human body. Dangerous non-human viruses are those that require few mutations to begin replicating themselves in human cells. These viruses are dangerous since the required combinations of mutations might randomly arise in the natural reservoir.[14]
Causes
editThe emergence of zoonotic diseases originated with the domestication of animals.[15] Zoonotic transmission can occur in any context in which there is contact with or consumption of animals, animal products, or animal derivatives. This can occur in a companionistic (pets), economic (farming, trade, butchering, etc.), predatory (hunting, butchering, or consuming wild game), or research context.[citation needed]
Recently, there has been a rise in frequency of appearance of new zoonotic diseases. "Approximately 1.67 million undescribed viruses are thought to exist in mammals and birds, up to half of which are estimated to have the potential to spill over into humans", says a study[16] led by researchers at the University of California, Davis. According to a report from the United Nations Environment Programme and International Livestock Research Institute a large part of the causes are environmental like climate change, unsustainable agriculture, exploitation of wildlife, and land use change. Others are linked to changes in human society such as an increase in mobility. The organizations propose a set of measures to stop the rise.[17][18]
Contamination of food or water supply
editFoodborne zoonotic diseases are caused by a variety of pathogens that can affect both humans and animals. The most significant zoonotic pathogens causing foodborne diseases are:
Bacterial pathogens
editEscherichia coli O157:H7, Campylobacter, Caliciviridae, and Salmonella.[19][20][21]
Viral pathogens
edit- Hepatitis E: Hepatitis E virus (HEV) is primarily transmitted through pork products, especially in developing countries with limited sanitation. The infection can lead to acute liver disease and is particularly dangerous for pregnant women.[22]
- Norovirus: Often found in contaminated shellfish and fresh produce, norovirus is a leading cause of foodborne illness globally. It spreads easily and causes symptoms like vomiting, diarrhea, and stomach pain.[23]
Parasitic pathogens
edit- Toxoplasma gondii: This parasite is commonly found in undercooked meat, especially pork and lamb, and can cause toxoplasmosis. While typically mild, toxoplasmosis can be severe in immunocompromised individuals and pregnant women, potentially leading to complications.[24]
- Trichinella spp. is transmitted through undercooked pork and wild game, causing trichinellosis. Symptoms range from mild gastrointestinal distress to severe muscle pain and, in rare cases, can be fatal.[25]
Farming, ranching and animal husbandry
editContact with farm animals can lead to disease in farmers or others that come into contact with infected farm animals. Glanders primarily affects those who work closely with horses and donkeys. Close contact with cattle can lead to cutaneous anthrax infection, whereas inhalation anthrax infection is more common for workers in slaughterhouses, tanneries, and wool mills.[26] Close contact with sheep who have recently given birth can lead to infection with the bacterium Chlamydia psittaci, causing chlamydiosis (and enzootic abortion in pregnant women), as well as increase the risk of Q fever, toxoplasmosis, and listeriosis, in the pregnant or otherwise immunocompromised. Echinococcosis is caused by a tapeworm, which can spread from infected sheep by food or water contaminated by feces or wool. Avian influenza is common in chickens, and, while it is rare in humans, the main public health worry is that a strain of avian influenza will recombine with a human influenza virus and cause a pandemic like the 1918 Spanish flu.[citation needed] In 2017, free-range chickens in the UK were temporarily ordered to remain inside due to the threat of avian influenza.[27] Cattle are an important reservoir of cryptosporidiosis,[28] which mainly affects the immunocompromised. Reports have shown mink can also become infected.[29] In Western countries, hepatitis E burden is largely dependent on exposure to animal products, and pork is a significant source of infection, in this respect.[22] Similarly, the human coronavirus OC43, the main cause of the common cold, can use the pig as a zoonotic reservoir,[30] constantly reinfecting the human population.
Veterinarians are exposed to unique occupational hazards when it comes to zoonotic disease. In the US, studies have highlighted an increased risk of injuries and lack of veterinary awareness of these hazards. Research has proved the importance for continued clinical veterinarian education on occupational risks associated with musculoskeletal injuries, animal bites, needle-sticks, and cuts.[31]
A July 2020 report by the United Nations Environment Programme stated that the increase in zoonotic pandemics is directly attributable to anthropogenic destruction of nature and the increased global demand for meat and that the industrial farming of pigs and chickens in particular will be a primary risk factor for the spillover of zoonotic diseases in the future.[32] Habitat loss of viral reservoir species has been identified as a significant source in at least one spillover event.[33]
Wildlife trade or animal attacks
editThe wildlife trade may increase spillover risk because it directly increases the number of interactions across animal species, sometimes in small spaces.[34] The origin of the COVID-19 pandemic[35][36] is traced to the wet markets in China.[37][38][39][40]
Zoonotic disease emergence is demonstrably linked to the consumption of wildlife meat, exacerbated by human encroachment into natural habitats and amplified by the unsanitary conditions of wildlife markets.[41] These markets, where diverse species converge, facilitate the mixing and transmission of pathogens, including those responsible for outbreaks of HIV-1,[42] Ebola,[43] and mpox,[44] and potentially even the COVID-19 pandemic.[45] Notably, small mammals often harbor a vast array of zoonotic bacteria and viruses,[46] yet endemic bacterial transmission among wildlife remains largely unexplored. Therefore, accurately determining the pathogenic landscape of traded wildlife is crucial for guiding effective measures to combat zoonotic diseases and documenting the societal and environmental costs associated with this practice.
Insect vectors
edit- African sleeping sickness
- Dirofilariasis
- Eastern equine encephalitis
- Japanese encephalitis
- Saint Louis encephalitis
- Scrub typhus
- Tularemia
- Venezuelan equine encephalitis
- West Nile fever
- Western equine encephalitis
- Zika fever
Pets
editPets can transmit a number of diseases. Dogs and cats are routinely vaccinated against rabies. Pets can also transmit ringworm and Giardia, which are endemic in both animal and human populations. Toxoplasmosis is a common infection of cats; in humans it is a mild disease although it can be dangerous to pregnant women.[47] Dirofilariasis is caused by Dirofilaria immitis through mosquitoes infected by mammals like dogs and cats. Cat-scratch disease is caused by Bartonella henselae and Bartonella quintana, which are transmitted by fleas that are endemic to cats. Toxocariasis is the infection of humans by any of species of roundworm, including species specific to dogs (Toxocara canis) or cats (Toxocara cati). Cryptosporidiosis can be spread to humans from pet lizards, such as the leopard gecko. Encephalitozoon cuniculi is a microsporidial parasite carried by many mammals, including rabbits, and is an important opportunistic pathogen in people immunocompromised by HIV/AIDS, organ transplantation, or CD4 T-lymphocyte deficiency.[48]
Pets may also serve as a reservoir of viral disease and contribute to the chronic presence of certain viral diseases in the human population. For instance, approximately 20% of domestic dogs, cats, and horses carry anti-hepatitis E virus antibodies and thus these animals probably contribute to human hepatitis E burden as well.[49] For non-vulnerable populations (e.g., people who are not immunocompromised) the associated disease burden is, however, small.[50][citation needed] Furthermore, the trade of non domestic animals such as wild animals as pets can also increase the risk of zoonosis spread.[51][52]
Exhibition
editOutbreaks of zoonoses have been traced to human interaction with, and exposure to, other animals at fairs, live animal markets,[53] petting zoos, and other settings. In 2005, the Centers for Disease Control and Prevention (CDC) issued an updated list of recommendations for preventing zoonosis transmission in public settings.[54] The recommendations, developed in conjunction with the National Association of State Public Health Veterinarians,[55] include educational responsibilities of venue operators, limiting public animal contact, and animal care and management.
Hunting and bushmeat
editHunting involves humans tracking, chasing, and capturing wild animals, primarily for food or materials like fur. However, other reasons like pest control or managing wildlife populations can also exist. Transmission of zoonotic diseases, those leaping from animals to humans, can occur through various routes: direct physical contact, airborne droplets or particles, bites or vector transport by insects, oral ingestion, or even contact with contaminated environments.[56] Wildlife activities like hunting and trade bring humans closer to dangerous zoonotic pathogens, threatening global health.[57]
According to the Center for Diseases Control and Prevention (CDC) hunting and consuming wild animal meat ("bushmeat") in regions like Africa can expose people to infectious diseases due to the types of animals involved, like bats and primates. Unfortunately, common preservation methods like smoking or drying aren't enough to eliminate these risks.[58] Although bushmeat provides protein and income for many, the practice is intricately linked to numerous emerging infectious diseases like Ebola, HIV, and SARS, raising critical public health concerns.[57]
A review published in 2022 found evidence that zoonotic spillover linked to wildmeat consumption has been reported across all continents.[59]
Deforestation, biodiversity loss and environmental degradation
editKate Jones, Chair of Ecology and Biodiversity at University College London, says zoonotic diseases are increasingly linked to environmental change and human behavior. The disruption of pristine forests driven by logging, mining, road building through remote places, rapid urbanization, and population growth is bringing people into closer contact with animal species they may never have been near before. The resulting transmission of disease from wildlife to humans, she says, is now "a hidden cost of human economic development".[60] In a guest article, published by IPBES, President of the EcoHealth Alliance and zoologist Peter Daszak, along with three co-chairs of the 2019 Global Assessment Report on Biodiversity and Ecosystem Services, Josef Settele, Sandra Díaz, and Eduardo Brondizio, wrote that "rampant deforestation, uncontrolled expansion of agriculture, intensive farming, mining and infrastructure development, as well as the exploitation of wild species have created a 'perfect storm' for the spillover of diseases from wildlife to people."[61]
Joshua Moon, Clare Wenham, and Sophie Harman said that there is evidence that decreased biodiversity has an effect on the diversity of hosts and frequency of human-animal interactions with potential for pathogenic spillover.[62]
An April 2020 study, published in the Proceedings of the Royal Society's Part B journal, found that increased virus spillover events from animals to humans can be linked to biodiversity loss and environmental degradation, as humans further encroach on wildlands to engage in agriculture, hunting, and resource extraction they become exposed to pathogens which normally would remain in these areas. Such spillover events have been tripling every decade since 1980.[63] An August 2020 study, published in Nature, concludes that the anthropogenic destruction of ecosystems for the purpose of expanding agriculture and human settlements reduces biodiversity and allows for smaller animals such as bats and rats, which are more adaptable to human pressures and also carry the most zoonotic diseases, to proliferate. This in turn can result in more pandemics.[64]
In October 2020, the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services published its report on the 'era of pandemics' by 22 experts in a variety of fields and concluded that anthropogenic destruction of biodiversity is paving the way to the pandemic era and could result in as many as 850,000 viruses being transmitted from animals – in particular birds and mammals – to humans. The increased pressure on ecosystems is being driven by the "exponential rise" in consumption and trade of commodities such as meat, palm oil, and metals, largely facilitated by developed nations, and by a growing human population. According to Peter Daszak, the chair of the group who produced the report, "there is no great mystery about the cause of the Covid-19 pandemic, or of any modern pandemic. The same human activities that drive climate change and biodiversity loss also drive pandemic risk through their impacts on our environment."[65][66][67]
Climate change
editAccording to a report from the United Nations Environment Programme and International Livestock Research Institute, entitled "Preventing the next pandemic – Zoonotic diseases and how to break the chain of transmission", climate change is one of the 7 human-related causes of the increase in the number of zoonotic diseases.[17][18] The University of Sydney issued a study, in March 2021, that examines factors increasing the likelihood of epidemics and pandemics like the COVID-19 pandemic. The researchers found that "pressure on ecosystems, climate change and economic development are key factors" in doing so. More zoonotic diseases were found in high-income countries.[68]
A 2022 study dedicated to the link between climate change and zoonosis found a strong link between climate change and the epidemic emergence in the last 15 years, as it caused a massive migration of species to new areas, and consequently contact between species which do not normally come in contact with one another. Even in a scenario with weak climatic changes, there will be 15,000 spillover of viruses to new hosts in the next decades. The areas with the most possibilities for spillover are the mountainous tropical regions of Africa and southeast Asia. Southeast Asia is especially vulnerable as it has a large number of bat species that generally do not mix, but could easily if climate change forced them to begin migrating.[69]
A 2021 study found possible links between climate change and transmission of COVID-19 through bats. The authors suggest that climate-driven changes in the distribution and robustness of bat species harboring coronaviruses may have occurred in eastern Asian hotspots (southern China, Myanmar, and Laos), constituting a driver behind the evolution and spread of the virus.[70][71]
Secondary Transmission
editZoonotic diseases contribute significantly to the burdened public health system as vulnerable groups such the elderly, children, childbearing women and immune-compromised individuals are at risk.[citation needed] According to the World Health Organization (WHO), any disease or infection that is primarily ‘naturally’ transmissible from vertebrate animals to humans or from humans to animals is classified as a zoonosis. [72] Factors such as climate change, urbanization, animal migration and trade, travel and tourism, vector biology, anthropogenic factors, and natural factors have greatly influenced the emergence, re-emergence, distribution, and patterns of zoonoses. [72]
Zoonotic diseases generally refer to diseases of animal origin in which direct or vector mediated animal-to-human transmission is the usual source of human infection. Animal populations are the principal reservoir of the pathogen and horizontal infection in humans is rare. A few examples in this category include lyssavirus infections, Lyme borreliosis, plague, tularemia, leptospirosis, ehrlichiosis, Nipah virus, West Nile virus (WNV) and hantavirus infections. [73] Secondary transmission encompasses a category of diseases of animal origin in which the actual transmission to humans is a rare event but, once it has occurred, human-to-human transmission maintains the infection cycle for some period of time. Some examples include human immunodeficiency virus (HIV)/acquired immune deficiency syndrome (AIDS), certain influenza A strains, Ebola virus and severe acute respiratory syndrome (SARS). [73]
One example is Ebola which is spread by direct transmission to humans from handling bushmeat (wild animals hunted for food) and contact with infected bats or close contact with infected animals, including chimpanzees, fruit bats, and forest antelope. Secondary transmission also occurs from human to human by direct contact with blood, bodily fluids, or skin of patients with or who died of Ebola virus disease. [74] Some examples of pathogens with this pattern of secondary transmission are human immunodeficiency virus/acquired immune deficiency syndrome, influenza A, Ebola virus and severe acute respiratory syndrome. Recent infections of these emerging and re-emerging zoonotic infections have occurred as a results of many ecological and sociological changes globally. [73]
History
editDuring most of human prehistory groups of hunter-gatherers were probably very small. Such groups probably made contact with other such bands only rarely. Such isolation would have caused epidemic diseases to be restricted to any given local population, because propagation and expansion of epidemics depend on frequent contact with other individuals who have not yet developed an adequate immune response.[75] To persist in such a population, a pathogen either had to be a chronic infection, staying present and potentially infectious in the infected host for long periods, or it had to have other additional species as reservoir where it can maintain itself until further susceptible hosts are contacted and infected.[76][77] In fact, for many "human" diseases, the human is actually better viewed as an accidental or incidental victim and a dead-end host. Examples include rabies, anthrax, tularemia, and West Nile fever. Thus, much of human exposure to infectious disease has been zoonotic.[78]
Many diseases, even epidemic ones, have zoonotic origin and measles, smallpox, influenza, HIV, and diphtheria are particular examples.[79][80] Various forms of the common cold and tuberculosis also are adaptations of strains originating in other species.[citation needed] Some experts have suggested that all human viral infections were originally zoonotic.[81]
Zoonoses are of interest because they are often previously unrecognized diseases or have increased virulence in populations lacking immunity. The West Nile virus first appeared in the United States in 1999, in the New York City area. Bubonic plague is a zoonotic disease,[82] as are salmonellosis, Rocky Mountain spotted fever, and Lyme disease.
A major factor contributing to the appearance of new zoonotic pathogens in human populations is increased contact between humans and wildlife.[83] This can be caused either by encroachment of human activity into wilderness areas or by movement of wild animals into areas of human activity. An example of this is the outbreak of Nipah virus in peninsular Malaysia, in 1999, when intensive pig farming began within the habitat of infected fruit bats.[84] The unidentified infection of these pigs amplified the force of infection, transmitting the virus to farmers, and eventually causing 105 human deaths.[85]
Similarly, in recent times avian influenza and West Nile virus have spilled over into human populations probably due to interactions between the carrier host and domestic animals.[citation needed] Highly mobile animals, such as bats and birds, may present a greater risk of zoonotic transmission than other animals due to the ease with which they can move into areas of human habitation.
Because they depend on the human host[86] for part of their life-cycle, diseases such as African schistosomiasis, river blindness, and elephantiasis are not defined as zoonotic, even though they may depend on transmission by insects or other vectors.[citation needed]
Use in vaccines
editThe first vaccine against smallpox by Edward Jenner in 1800 was by infection of a zoonotic bovine virus which caused a disease called cowpox.[87] Jenner had noticed that milkmaids were resistant to smallpox. Milkmaids contracted a milder version of the disease from infected cows that conferred cross immunity to the human disease. Jenner abstracted an infectious preparation of 'cowpox' and subsequently used it to inoculate persons against smallpox. As a result of vaccination, smallpox has been eradicated globally, and mass inoculation against this disease ceased in 1981.[88] There are a variety of vaccine types, including traditional inactivated pathogen vaccines, subunit vaccines, live attenuated vaccines. There are also new vaccine technologies such as viral vector vaccines and DNA/RNA vaccines, which include many of the COVID-19 vaccines.[89]
Lists of diseases
editDisease[90] | Pathogen(s) | Animals involved | Mode of transmission | Emergence |
---|---|---|---|---|
African sleeping sickness | Trypanosoma brucei rhodesiense | range of wild animals and domestic livestock | transmitted by the bite of the tsetse fly | 'present in Africa for thousands of years' – major outbreak 1900–1920, cases continue (sub-Saharan Africa, 2020) |
Angiostrongyliasis | Angiostrongylus cantonensis, Angiostrongylus costaricensis | rats, cotton rats | consuming raw or undercooked snails, slugs, other mollusks, crustaceans, contaminated water, and unwashed vegetables contaminated with larvae | |
Anisakiasis | Anisakis | whales, dolphins, seals, sea lions, other marine animals | eating raw or undercooked fish and squid contaminated with eggs | |
Anthrax | Bacillus anthracis | commonly – grazing herbivores such as cattle, sheep, goats, camels, horses, and pigs | by ingestion, inhalation or skin contact of spores | |
Babesiosis | Babesia spp. | mice, other animals | tick bite | |
Baylisascariasis | Baylisascaris procyonis | raccoons | ingestion of eggs in feces | |
Barmah Forest fever | Barmah Forest virus | kangaroos, wallabies, opossums | mosquito bite | |
Avian influenza | Influenza A virus subtype H5N1 | wild birds, domesticated birds such as chickens[91] | close contact | 2003–present avian influenza in Southeast Asia and Egypt |
Bovine spongiform encephalopathy | Prions | cattle | eating infected meat | isolated similar cases reported in ancient history; in recent UK history probable start in the 1970s[92] |
Brucellosis | Brucella spp. | cattle, goats, pigs, sheep | infected milk or meat | historically widespread in Mediterranean region; identified early 20th century |
Bubonic plague, Pneumonic plague, Septicemic plague, Sylvatic plague | Yersinia pestis | rabbits, hares, rodents, ferrets, goats, sheep, camels | flea bite | epidemics like Black Death in Europe around 1347–53 during the Late Middle Age; third plague pandemic in China-Qing dynasty and India alone |
Capillariasis | Capillaria spp. | rodents, birds, foxes | eating raw or undercooked fish, ingesting embryonated eggs in fecal-contaminated food, water, or soil | |
Cat-scratch disease | Bartonella henselae | cats | bites or scratches from infected cats | |
Chagas disease | Trypanosoma cruzi | armadillos, Triatominae (kissing bug) | Contact of mucosae or wounds with feces of kissing bugs. Accidental ingestion of parasites in food contaminated by bugs or infected mammal excretae. | |
Clamydiosis / Enzootic abortion | Chlamydophila abortus | domestic livestock, particularly sheep | close contact with postpartum ewes | |
suspected: COVID-19 | Severe acute respiratory syndrome coronavirus 2 | suspected: bats, felines, raccoon dogs, minks, white-tailed deer[93] | respiratory transmission | 2019–present COVID-19 pandemic; ongoing pandemic |
Creutzfeldt-Jacob disease | PrPvCJD | cattle | eating meat from animals with Bovine spongiform encephalopathy (BSE) | 1996–2001: United Kingdom |
Crimean–Congo hemorrhagic fever | Crimean-Congo hemorrhagic fever orthonairovirus | cattle, goats, sheep, birds, multimammate rats, hares | tick bite, contact with bodily fluids | |
Cryptococcosis | Cryptococcus neoformans | commonly – birds like pigeons | inhaling fungi | |
Cryptosporidiosis | Cryptosporidium spp. | cattle, dogs, cats, mice, pigs, horses, deer, sheep, goats, rabbits, leopard geckos, birds | ingesting cysts from water contaminated with feces | |
Cysticercosis and taeniasis | Taenia solium, Taenia asiatica, Taenia saginata | commonly – pigs and cattle | consuming water, soil or food contaminated with the tapeworm eggs (cysticercosis) or raw or undercooked pork contaminated with the cysticerci (taeniasis) | |
Dirofilariasis | Dirofilaria spp. | dogs, wolves, coyotes, foxes, jackals, cats, monkeys, raccoons, bears, muskrats, rabbits, leopards, seals, sea lions, beavers, ferrets, reptiles | mosquito bite | |
Eastern equine encephalitis, Venezuelan equine encephalitis, Western equine encephalitis | Eastern equine encephalitis virus, Venezuelan equine encephalitis virus, Western equine encephalitis virus | horses, donkeys, zebras, birds | mosquito bite | |
Ebola virus disease (a haemorrhagic fever) | Ebolavirus spp. | chimpanzees, gorillas, orangutans, fruit bats, monkeys, shrews, forest antelope and porcupines | through body fluids and organs | 2013–16; possible in Africa |
Other haemorrhagic fevers (Crimean-Congo haemorrhagic fever, Dengue fever, Lassa fever, Marburg viral haemorrhagic fever, Rift Valley fever[94]) | Varies – commonly viruses | varies (sometimes unknown) – commonly camels, rabbits, hares, hedgehogs, cattle, sheep, goats, horses and swine | infection usually occurs through direct contact with infected animals | 2019–20 dengue fever |
Echinococcosis | Echinococcus spp. | commonly – dogs, foxes, jackals, wolves, coyotes, sheep, pigs, rodents | ingestion of infective eggs from contaminated food or water with feces of an infected definitive host | |
Fasciolosis | Fasciola hepatica, Fasciola gigantica | sheep, cattle, buffaloes | ingesting contaminated plants | |
Fasciolopsiasis | Fasciolopsis buski | pigs | eating raw vegetables such as water spinach | |
Foodborne illnesses (commonly diarrheal diseases) | Campylobacter spp., Escherichia coli, Salmonella spp., Listeria spp., Shigella spp. and Trichinella spp. | animals domesticated for food production (cattle, poultry) | raw or undercooked food made from animals and unwashed vegetables contaminated with feces | |
Giardiasis | Giardia lamblia | beavers, other rodents, raccoons, deer, cattle, goats, sheep, dogs, cats | ingesting spores and cysts in food and water contaminated with feces | |
Glanders | Burkholderia mallei. | horses, donkeys | direct contact | |
Gnathostomiasis | Gnathostoma spp. | dogs, minks, opossums, cats, lions, tigers, leopards, raccoons, poultry, other birds, frogs | raw or undercooked fish or meat | |
Hantavirus | Hantavirus spp. | deer mice, cotton rats and other rodents | exposure to feces, urine, saliva or bodily fluids | |
Henipavirus | Henipavirus spp. | horses, bats | exposure to feces, urine, saliva or contact with sick horses | |
Hepatitis E | Hepatitis E virus | domestic and wild animals | contaminated food or water | |
Histoplasmosis | Histoplasma capsulatum | birds, bats | inhaling fungi in guano | |
HIV | SIV Simian immunodeficiency virus | non-human primates | Blood | Immunodeficiency resembling human AIDS was reported in captive monkeys in the United States beginning in 1983.[95][96][97] SIV was isolated in 1985 from some of these animals, captive rhesus macaques who had simian AIDS (SAIDS).[96] The discovery of SIV was made shortly after HIV-1 had been isolated as the cause of AIDS and led to the discovery of HIV-2 strains in West Africa. HIV-2 was more similar to the then-known SIV strains than to HIV-1, suggesting for the first time the simian origin of HIV. Further studies indicated that HIV-2 is derived from the SIVsmm strain found in sooty mangabeys, whereas HIV-1, the predominant virus found in humans, is derived from SIV strains infecting chimpanzees (SIVcpz) |
Japanese encephalitis | Japanese encephalitis virus | pigs, water birds | mosquito bite | |
Kyasanur Forest disease | Kyasanur Forest disease virus | rodents, shrews, bats, monkeys | tick bite | |
La Crosse encephalitis | La Crosse virus | chipmunks, tree squirrels | mosquito bite | |
Leishmaniasis | Leishmania spp. | dogs, rodents, other animals[98][99] | sandfly bite | 2004 Afghanistan |
Leprosy | Mycobacterium leprae, Mycobacterium lepromatosis | armadillos, monkeys, rabbits, mice[100] | direct contact, including meat consumption. However, scientists believe most infections are spread human to human.[100][101] | |
Leptospirosis | Leptospira interrogans | rats, mice, pigs, horses, goats, sheep, cattle, buffaloes, opossums, raccoons, mongooses, foxes, dogs | direct or indirect contact with urine of infected animals | 1616–20 New England infection; present day in the United States |
Lassa fever | Lassa fever virus | rodents | exposure to rodents | |
Lyme disease | Borrelia burgdorferi | deer, wolves, dogs, birds, rodents, rabbits, hares, reptiles | tick bite | |
Lymphocytic choriomeningitis | Lymphocytic choriomeningitis virus | rodents | exposure to urine, feces, or saliva | |
Melioidosis | Burkholderia pseudomallei | various animals | direct contact with contaminated soil and surface water | |
Microsporidiosis | Encephalitozoon cuniculi | Rabbits, dogs, mice, and other mammals | ingestion of spores | |
Middle East respiratory syndrome | MERS coronavirus | bats, camels | close contact | 2012–present: Saudi Arabia |
Mpox | Monkeypox virus | rodents, primates | contact with infected rodents, primates, or contaminated materials | |
Nipah virus infection | Nipah virus (NiV) | bats, pigs | direct contact with infected bats, infected pigs | |
Orf | Orf virus | goats, sheep | close contact | |
Powassan encephalitis | Powassan virus | ticks | tick bites | |
Psittacosis | Chlamydophila psittaci | macaws, cockatiels, budgerigars, pigeons, sparrows, ducks, hens, gulls and many other bird species | contact with bird droplets | |
Q fever | Coxiella burnetii | livestock and other domestic animals such as dogs and cats | inhalation of spores, contact with bodily fluid or faeces | |
Rabies | Rabies virus | commonly – dogs, bats, monkeys, raccoons, foxes, skunks, cattle, goats, sheep, wolves, coyotes, groundhogs, horses, mongooses and cats | through saliva by biting, or through scratches from an infected animal | Variety of places like Oceanic, South America, Europe; year is unknown |
Rat-bite fever | Streptobacillus moniliformis, Spirillum minus | rats, mice | bites of rats but also urine and mucus secretions | |
Rift Valley fever | Phlebovirus | livestock, buffaloes, camels | mosquito bite, contact with bodily fluids, blood, tissues, breathing around butchered animals or raw milk | 2006–07 East Africa outbreak |
Rocky Mountain spotted fever | Rickettsia rickettsii | dogs, rodents | tick bite | |
Ross River fever | Ross River virus | kangaroos, wallabies, horses, opossums, birds, flying foxes | mosquito bite | |
Saint Louis encephalitis | Saint Louis encephalitis virus | birds | mosquito bite | |
Severe acute respiratory syndrome | SARS coronavirus | bats, civets | close contact, respiratory droplets | 2002–04 SARS outbreak; began in China |
Smallpox | Variola virus | Possible Monkeys or horses | Spread to person to person quickly | The last case was in 1977; certified by WHO to be eradicated (i.e., eliminated worldwide) as of 1980. |
Swine influenza | A new strain of the influenza virus endemic in pigs (excludes H1N1 swine flu, which is a human virus)[clarification needed] | pigs | close contact | 2009–10; 2009 swine flu pandemic; began in Mexico. |
Taenia crassiceps infection | Taenia crassiceps | wolves, coyotes, jackals, foxes | contact with soil contaminated with feces | |
Toxocariasis | Toxocara spp. | dogs, foxes, cats | ingestion of eggs in soil, fresh or unwashed vegetables or undercooked meat | |
Toxoplasmosis | Toxoplasma gondii | cats, livestock, poultry | exposure to cat feces, organ transplantation, blood transfusion, contaminated soil, water, grass, unwashed vegetables, unpasteurized dairy products and undercooked meat | |
Trichinosis | Trichinella spp. | rodents, pigs, horses, bears, walruses, dogs, foxes, crocodiles, birds | eating undercooked meat | |
Tuberculosis | Mycobacterium bovis | infected cattle, deer, llamas, pigs, domestic cats, wild carnivores (foxes, coyotes) and omnivores (possums, mustelids and rodents) | milk, exhaled air, sputum, urine, faeces and pus from infected animals | |
Tularemia | Francisella tularensis | lagomorphs (type A), rodents (type B), birds | ticks, deer flies, and other insects including mosquitoes | |
West Nile fever | Flavivirus | birds, horses | mosquito bite | |
Zika fever | Zika virus | chimpanzees, gorillas, orangutans, monkeys, baboons | mosquito bite, sexual intercourse, blood transfusion and sometimes bites of monkeys | 2015–16 epidemic in the Americas and Oceanic |
See also
edit- Animal welfare#Animal welfare organizations – Well-being of non-human animals
- Conservation medicine
- Cross-species transmission – Transmission of a pathogen between different species
- Emerging infectious disease – Infectious disease of emerging pathogen, often novel in its outbreak range or transmission mode
- Foodborne illness – Illness from eating spoiled food
- Spillover infection – Occurs when a reservoir population causes an epidemic in a novel host population
- Wildlife disease – diseases in wild animals
- Veterinary medicine – Branch of medicine for non-human animals
- Wildlife smuggling and zoonoses – Health risks associated with the trade in exotic wildlife
- List of zoonotic primate viruses
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