|Female (sow) breastfeeding piglet|
S. s. domesticus
|Sus scrofa domesticus|
The domestic pig (Sus scrofa domesticus or only Sus domesticus), often called swine, hog, or simply pig when there is no need to distinguish it from other pigs, is a domesticated large, even-toed ungulate. It is variously considered a subspecies of the Eurasian boar or a distinct species. The domestic pig's head-plus-body-length ranges from 0.9 to 1.8 m (35 to 71 in), and adult pigs typically weigh between 50 and 350 kg (110 and 770 lb), with well-fed individuals often exceeding this weight range. The size and weight of a hog largely depends on its breed. Compared to other artiodactyls, its head is relatively long, pointed, and free of warts. Even-toed ungulates are generally herbivorous, but the domestic pig is an omnivore, like its wild relative.
When used as livestock, domestic pigs are farmed primarily for the consumption of their flesh, called pork. The animal's bones, hide, and bristles are also used in commercial products. Domestic pigs, especially miniature breeds, are kept as pets.
- 1 Biology
- 2 Taxonomy
- 3 History
- 4 Reproduction
- 5 Behaviour
- 6 Breeds
- 7 In agriculture
- 8 As pets
- 9 In human medical applications
- 10 Glossary of terms
- 11 See also
- 12 Footnotes
- 13 References
- 14 External links
The domestic pig typically has a large head, with a long snout which is strengthened by a special prenasal bone and a disk of cartilage at the tip. The snout is used to dig into the soil to find food, and is a very acute sense organ. The dental formula of adult pigs is 126.96.36.199, giving a total of 44 teeth. The rear teeth are adapted for crushing. In the male the canine teeth can form tusks, which grow continuously and are sharpened by constantly being ground against each other.
Pigs possess both apocrine and eccrine sweat glands, although the latter appear limited to the snout and dorsonasal areas. Pigs, however, like other "hairless" mammals (e.g. elephants, rhinos, and mole-rats), do not use thermal sweat glands in cooling. Pigs are also less able than many other mammals to dissipate heat from wet mucous membranes in the mouth through panting. Their thermoneutral zone is 16 to 22 °C (61 to 72 °F). At higher temperatures, pigs lose heat by wallowing in mud or water via evaporative cooling; although it has been suggested that wallowing may serve other functions, such as protection from sunburn, ecto-parasite control, and scent-marking.
Pigs are one of four known mammalian species which possess mutations in the nicotinic acetylcholine receptor that protect against snake venom. Mongooses, honey badgers, hedgehogs, and pigs all have modifications to the receptor pocket which prevents the snake venom α-neurotoxin from binding. These represent four separate, independent mutations.
The domestic pig is most often considered to be a subspecies of the wild boar, which was given the name Sus scrofa by Carl Linnaeus in 1758; following from this, the formal name of the domestic pig is Sus scrofa domesticus. However, in 1777, Johann Christian Polycarp Erxleben classified the domestic pig as a separate species from the wild boar. He gave it the name Sus domesticus, which is still used by some taxonomists.
Archaeological evidence suggests that pigs were domesticated from wild boar as early as 13,000–12,700 BC in the Near East in the Tigris Basin,[page needed] Çayönü, Cafer Höyük, Nevalı Çori being managed in the wild in a way similar to the way they are managed by some modern New Guineans. Remains of pigs have been dated to earlier than 11,400 BC in Cyprus. Those animals must have been introduced from the mainland, which suggests domestication in the adjacent mainland by then. There was also a separate domestication in China which took place about 8000 years ago.
DNA evidence from subfossil remains of teeth and jawbones of Neolithic pigs shows that the first domestic pigs in Europe had been brought from the Near East. This stimulated the domestication of local European wild boar, resulting in a third domestication event with the Near Eastern genes dying out in European pig stock. Modern domesticated pigs have involved complex exchanges, with European domesticated lines being exported, in turn, to the ancient Near East. Historical records indicate that Asian pigs were introduced into Europe during the 18th and early 19th centuries.
In August 2015, a study looked at over 100 pig genome sequences to ascertain their process of domestication, which was assumed to have been initiated by humans, involved few individuals, and relied on reproductive isolation between wild and domestic forms. The study found that the assumption of reproductive isolation with population bottlenecks was not supported. The study indicated that pigs were domesticated separately in Western Asia and China, with Western Asian pigs introduced into Europe, where they crossed with wild boar. A model that fitted the data included a mixture with a now extinct ghost population of wild pigs during the Pleistocene. The study also found that despite back-crossing with wild pigs, the genomes of domestic pigs have strong signatures of selection at DNA loci that affect behavior and morphology. The study concluded that human selection for domestic traits likely counteracted the homogenizing effect of gene flow from wild boars and created domestication islands in the genome. The same process may also apply to other domesticated animals.
The adaptable nature and omnivorous diet of the wild boar allowed early humans to domesticate it readily. Pigs were mostly used for food, but early civilizations also used the pigs' hides for shields, bones for tools and weapons, and bristles for brushes. In India, pigs have been domesticated for a long time, mostly in Goa and some rural areas, for pig toilets. Though ecologically logical as well as economical, pig toilets are waning in popularity as use of septic tanks and sewage systems is increasing in rural areas.
Among the animals that the Spanish introduced to the Chiloé Archipelago in the 16th century, pigs were the most successful to adapt. The pigs benefited from abundant shellfish and algae exposed by the large tides of the archipelago. Pigs were brought to southeastern North America from Europe by de Soto and other early Spanish explorers. Escaped pigs became feral and caused a great deal of disruption to Native Americans, who had no domesticated animals, with the exception of dogs. Feral pig populations in the southeastern United States have since migrated north and are a growing concern in the Midwest. Considered an invasive species, many state agencies have programs to trap or hunt feral pigs as means of removal. Domestic pigs have become feral in many other parts of the world (e.g. New Zealand and northern Queensland) and have caused substantial environmental damage. Feral hybrids of the European wild boar with the domestic pig are also very disruptive to both environment and agriculture (among the 100 most damaging animal species), especially in southeastern South America from Uruguay to Brazil's Mato Grosso do Sul (Center-West Region), and São Paulo (state) (Southeast Region), where they are known as javaporcos (from javali and porco, thus "boar-pigs").
Female pigs reach sexual maturity at 3–12 months of age, and come into estrus every 18–24 days if they are not successfully bred. The variation in ovulation rate can be attributed to intrinsic factors such as age and genotype,as well as extrinsic factors like nutrition, environment and the supplementation of exogenous hormones. The gestation period averages 112–120 days. Estrus lasts two to three days, and the female's displayed receptiveness to mate is known as standing heat. Standing heat is a reflexive response that is stimulated when the female is in contact with the saliva of a sexually mature boar. Androstenol is one of the pheromones produced in the submaxillary salivary glands of boars that will trigger the female's response. The female cervix contains a series of five interdigitating pads, or folds, that will hold the boar's corkscrew-shaped penis during copulation. Females have bicornuate uteruses and two conceptuses must be present in both uterine horns for pregnancy to be established. Maternal recognition of pregnancy in pigs occurs on days 11 to 12 of pregnancy and is marked by progesterone production from a functioning corpus luteum (CL). To avoid luteolysis by PGF2α, rescuing of the CL must occur via embryonic signaling of estradiol 17β and PGE2. This signaling acts on both the endometrium and luteal tissue to prevent the regression of the CL by activation of genes that are responsible for CL maintenance. During mid to late pregnancy, the CL relies primarily on luteinizing hormone (LH) for maintenance until parturition. Animal nutrition is important prior to reproduction and during gestation to ensure optimum reproductive performance is achieved.
In many ways, their behaviour appears to be intermediate between that of other artiodactyls and of carnivores. Domestic pigs seek out the company of other pigs, and often huddle to maintain physical contact, although they do not naturally form large herds. They typically live in groups of about 8-10 adult sows, some young individuals, and some single males.
Because of their relative lack of sweat glands, pigs often control their body temperature using behavioural thermoregulation. Wallowing, which often consists of coating the body with mud, is a behaviour frequently exhibited by pigs. They do not submerge completely under the mud, but vary the depth and duration of wallowing depending on environmental conditions. Typically, adult pigs start wallowing once the ambient temperature is around 17-21 °C. They cover themselves from head to toe in mud. Pigs may use mud as a sunscreen, or as a method of keeping parasites away. Most bristled pigs will "blow their coat", meaning that they shed most of the longer, more-coarse stiff hair once a year, usually in spring or early summer, to prepare for the warmer months ahead.
If conditions permit, domestic pigs feed continuously for many hours and then sleep for many hours, in contrast to ruminants which tend to feed for a short time and then sleep for a short time. Pigs are omnivorous, and are highly versatile in their feeding behaviour. As they are foraging animals, they primarily eat leaves, stems, roots, fruits, and flowers. Domestic pigs are highly intelligent animals, on par with dogs, and according to David DiSalvo's writing in Forbes, they are "widely considered the smartest domesticated animal in the world. Pigs can move a cursor on a video screen with their snouts and even learn to distinguish between the scribbles they knew from those they saw for the first time."[a]
Rooting is an instinctual behavior in pigs that is characterized by a pig nudging its snout into something. Similar to a cat’s kneading, rooting is found comforting, first happens when they are born in order to obtain their mother’s milk, and can become a habitual, obsessive behavior which is most prominent in animals weaned too early. Often, pigs will root and dig into the ground to forage for food. Rooting is known to also be used as a means of communication. A nose ring is sometimes put through the septum: it discourages rooting because that is painful.
The breed known as the kunekune hardly ever roots, as it sustains itself feeding on nothing other than grass leaves. Not having to root around in the soil to find underground food (e.g. tubers), it thus has evolved to, for the most part, not possess these instincts.
A behavioural characteristic of domestic pigs which they share with carnivores is nest-building. Sows root in the ground to create depressions and then build nests in which to give birth. First, the sow digs a depression about the size of her body. She then collects twigs and leaves, and carries these in her mouth to the depression, building them into a mound. She distributes the softer, finer material to the centre of the mound using her feet. When the mound reaches the desired height, she places large branches, up to 2 metres in length, on the surface. She enters into the mound and roots around to create a depression within the gathered material. She then gives birth in a lying position, which, again, is different from other artiodactyls, which usually give birth in a standing position.
Nest-building behaviour is an important part in the process of pre and post-partum maternal behaviour. Nest-building will occur during the last 24 hours before the onset of farrowing, and becomes most intense during 12 to 6 hours before farrowing. Nest-building is divided into two phases: one of which is the initial phase of rooting in ground while the second phase is the collecting, carrying and arranging of the nest material. The sow will separate from the group and seek a suitable nest site with some shelter from rain and wind that has well-drained soil. This nest-building behaviour is performed to provide the offspring with shelter, comfort, and thermoregulation. The nest will provide protection against weather and predators, while keeping the piglets close to the sow and away from the rest of the herd. This ensures they do not get trampled on and that other piglets are not stealing milk from the sow. Nest-building can be influenced by internal and external stimuli. Internal hormonal changes and the completion of one nesting phase are indicators of this maternal behaviour. The onset is triggered by the rise in prolactin levels, which is caused by a decrease in progesterone and an increase in prostaglandin, while the gathering of the nest material seems to be regulated more by external stimuli such as temperature. The longer time spent on nest-building will increase pre-partum oxytocin.
Nursing and suckling behaviour
Compared to most other mammals, pigs display complex nursing and suckling behaviour. Nursing occurs every 50–60 minutes, and the sow requires stimulation from piglets before milk let-down. Sensory inputs (vocalisation, odours from mammary and birth fluids and hair patterns of the sow) are particularly important immediately post-birth to facilitate teat location by the piglets. Initially, the piglets compete for position at the udder, then each piglet massages around its respective teat with its snout, during which time the sow grunts at slow, regular intervals. Each series of grunts varies in frequency, tone and magnitude, indicating the stages of nursing to the piglets.
The phase of competition for teats and of nosing the udder lasts for about one minute, and ends when milk flow begins. In the third phase, the piglets hold the teats in their mouths and suck with slow mouth movements (one per second), and the rate of the sow’s grunting increases for approximately 20 seconds. The grunt peak in the third phase of suckling does not coincide with milk ejection, but rather the release of oxytocin from the pituitary into the bloodstream. Phase four coincides with the period of main milk flow (10–20 seconds) when the piglets suddenly withdraw slightly from the udder and start sucking with rapid mouth movements of about three per second. The sow grunts rapidly, lower in tone and often in quick runs of three or four, during this phase. Finally, the flow stops and so does the grunting of the sow. The piglets may then dart from teat to teat and recommence suckling with slow movements, or nosing the udder. Piglets massage and suckle the sow’s teats after milk flow ceases as a way of letting the sow know their nutritional status. This helps her to regulate the amount of milk released from that teat in future sucklings. The more intense the post-feed massaging of a teat, the greater the future milk release from that teat will be.
In pigs, dominance hierarchies can be formed at a very early age. Domestic piglets are highly precocious and within minutes of being born, or sometimes seconds, will attempt to suckle. The piglets are born with sharp teeth and fight to develop a teat order as the anterior teats produce a greater quantity of milk. Once established, this teat order remains stable with each piglet tending to feed from a particular teat or group of teats. Stimulation of the anterior teats appears to be important in causing milk letdown, so it might be advantageous to the entire litter to have these teats occupied by healthy piglets. Using an artificial sow to rear groups of piglets, recognition of a teat in a particular area of the udder depended initially on visual orientation by means of reference points on the udder to find the area, and then the olfactory sense for the more accurate search within that area.
Pigs have panoramic vision of approximately 310° and binocular vision of 35° to 50°. It is thought they have no eye accommodation. Other animals that have no accommodation, e.g. sheep, lift their heads to see distant objects. The extent to which pigs have colour vision is still a source of some debate; however, the presence of cone cells in the retina with two distinct wavelength sensitivities (blue and green) suggests that at least some colour vision is present.
Pigs have a well-developed sense of smell, and use is made of this in Europe where they are trained to locate underground truffles. Olfactory rather than visual stimuli are used in the identification of other pigs. Hearing is also well developed, and localisation of sounds is made by moving the head. Pigs use auditory stimuli extensively as a means of communication in all social activities. Alarm or aversive stimuli are transmitted to other pigs not only by auditory cues but also by pheromones. Similarly, recognition between the sow and her piglets is by olfactory and vocal cues.
Many breeds of domestic pig exist; in many colors, shapes, and sizes. According to The Livestock Conservancy, as of 2016, three breeds of domestic pig are critically rare (having a global population of fewer than 2000). They are the Choctaw hog, the Mulefoot, and the Ossabaw Island pig. The known smallest domestic pig breed in the world is the Göttingen minipig, typically weighing about 26 kilograms (57 lb) as a healthy, full-grown adult.
|Global pig stocks|
|People's Republic of China||474.1|
Food & Agriculture Organization
When in use as livestock, the domestic pig is mostly farmed for its meat, pork. Other food products made from pigs include pork sausage (which includes casings that are made from the intestines), bacon, gammon, ham and pork rinds. The head of a pig can be used to make a preserved jelly called head cheese, which is sometimes known as brawn. Liver, chitterlings, blood (for black pudding), and other offal from pigs are also widely used for food. In some religions, such as Judaism and Islam, pork is a taboo food.
The use of pig milk for human consumption does take place, but as there are certain difficulties in obtaining it, there is little commercial production.
Livestock pigs are exhibited at agricultural shows, judged either as stud stock compared to the standard features of each pig breed, or in commercial classes where the animals are judged primarily on their suitability for slaughter to provide premium meat.
In some developing and developed nations, the domestic pig is usually raised outdoors in yards or fields. In some areas, pigs are allowed to forage in woods where they may be taken care of by swineherds. In industrialized nations such as the United States, domestic pig farming has switched from the traditional pig farm to large-scale intensive pig farms. This has resulted in lower production costs, but can cause significant cruelty problems. As consumers have become concerned with humane treatment of livestock, demand for pasture-raised pork in these nations has increased.
Vietnamese pot-bellied pigs, a miniature breed of domestic pig, have made popular pets in the United States, beginning in the latter half of the 20th century. These pot-bellied pigs were soon crossbred with a variety of other small breeds, such as the Göttingen minipig, with separate locations breeding different lineages. These crossbred miniature pigs soon gained attention, even more so than the original Vietnamese pot-bellied. As a result of this, many pet pigs are now of unknown genetic descent.
Domestic pigs are highly intelligent, social creatures. They are considered hypoallergenic, and are known to do quite well with people who have usual animal allergies. Since these animals are known to have a life expectancy of 15 to 20 years, they require a long-term commitment.
Male and female swine that have not been de-sexed may express unwanted aggressive behavior, and are prone to developing serious health issues. Regular trimming of the hooves is necessary; hooves left untreated cause major pain in the pig, can create malformations in bone structure, and may cause it to be more susceptible to fungal growth between crevices of the hoof, or between the cracks in a split hoof. Male pigs, especially when left unaltered, can grow large, sharp tusks which may continue growing for years. Domestic owners may wish to keep their pigs' tusks trimmed back, or have them removed entirely.
As prey animals, pigs' natural instinctive behavior causes them to have a strong fear of being picked up, but they will usually calm down once placed back onto the ground. This instinctual fear may be lessened if the pig has been frequently held since infancy. When holding a pig, supporting it under the legs makes being held not as stressful for the animal. Pigs need enrichment activities to keep their intelligent minds occupied; if pigs get bored, they often become destructive. As rooting is found to be comforting, pigs kept in the house may root household objects, furniture or surfaces. While some owners are known to pierce their pigs' noses to discourage rooting behaviour, the efficacy and humaneness of this practice is questionable. As such, indoor pigs should be provided with a box with rocks, soil, straw, and/or other material for them to root in instead.
In human medical applications
The domestic pig, both as a live animal and source of post-mortem tissues, is one of the most valuable animal models used in biomedical research today, because of its biological, physiological and anatomical similarities to human beings. For instance, human skin is very similar to pig skin, therefore pig skin has been used in many preclinical studies. Porcine are used in finding treatments, cures for diseases, xenotransplantation, and for general education. They are also used in the development of medical instruments and devices, surgical techniques and instrumentation, and FDA-approved research. As part of animal conservation (The Three Rs (animals)), these animals contribute to the reduction methods for animal research, as they supply more information from fewer animals used, for a lower cost.
Pigs are currently thought to be the best non-human candidates for organ donation to humans. The risk of cross-species disease transmission is decreased because of their increased phylogenetic distance from humans. They are readily available, their organs are anatomically comparable in size, and new infectious agents are less likely since they have been in close contact with humans through domestication for many generations.
To date, no xenotransplantation trials have been entirely successful due to obstacles arising from the response of the recipient’s immune system—generally more extreme than in allotransplantations, ultimately results in rejection of the xenograft, and in some cases result in the death of the recipient—including hyperacute rejection, acute vascular rejection, cellular rejection and chronic rejection. An early major breakthrough was the 1,3 galactosyl transferase gene knockout.
Examples of viruses carried by pigs include porcine herpesvirus, rotavirus, parvovirus, and circovirus. Of particular concern are PERVs (porcine endogenous retroviruses), vertically transmitted microbes that embed in swine genomes. The risks with xenosis are twofold, as not only could the individual become infected, but a novel infection could initiate an epidemic in the human population. Because of this risk, the FDA has suggested any recipients of xenotransplants shall be closely monitored for the remainder of their life, and quarantined if they show signs of xenosis.
Glossary of terms
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- barrow - a castrated male swine
- boar - a mature male swine; often a wild or feral swine
- boneen - a very young pig (Ireland)
- farrow (verb) - to give birth to piglets
- farrow (noun) - a litter of piglets
- gilt - a female pig that has never been pregnant or is pregnant for the first time
- hog - a domestic swine, especially a fully-grown specimen
- parcel - collective noun
- pig - strictly, an immature swine; more generally, any swine, especially of the domestic variety
- piglet - a very young pig
- queen - a female pig that has never been mated
- savaging - the act of a sow attacking her own piglets, sometimes killing and cannibalising them
- shoat - a young pig, especially one that has been weaned
- sounder - collective noun
- sow - a mature female swine
- swine (singular and plural) - a hog; hogs collectively or generally
- swineherd - one who tends to swine raised as livestock; a pig farmer
- Colin P. Groves (1995). "On the nomenclature of domestic animals" (PDF). Bulletin of Zoological Nomenclature. 52 (2): 137–141. doi:10.5962/bhl.part.6749. Archived from the original (PDF) on 8 April 2011. Biodiversity Heritage Library
- "Sus scrofa (wild boar)". Animal Diversity Web.
- Lockhart, Kim. "American Wild Game / Feral Pigs / Hogs / Pigs / Wild Boar". gunnersden.com. Archived from the original on 23 August 2018. Retrieved 15 August 2012.
- "Royal visit delights at the Three Counties Show". Malvern Gazette.
- Sumena, K.B.; Lucy, K.M.; Chungath, J.J.; Ashok, N.; Harshan, K.R. (2010). "Regional histology of the subcutaneous tissue and the sweat glands of large white Yorkshire pigs" (PDF). Tamilnadu Journal of Veterinary and Animal Sciences. 6 (3): 128–135.[permanent dead link]
- Folk, G.E.; Semken, H.A. (1991). "The evolution of sweat glands". International Journal of Biometeorology. 35 (3): 180–186. Bibcode:1991IJBm...35..180F. doi:10.1007/bf01049065.
- "Sweat like a pig?". abc.net.au. 22 April 2008.
- Bracke, M.B.M. (2011). "Review of wallowing in pigs: Description of the behaviour and its motivational basis". Applied Animal Behaviour Science. 132 (1): 1–13. doi:10.1016/j.applanim.2011.01.002.
- Drabeck, D.H.; Dean, A.M.; Jansa, S.A. (1 June 2015). "Why the honey badger don't care: Convergent evolution of venom-targeted nicotinic acetylcholine receptors in mammals that survive venomous snake bites". Toxicon. 99: 68–72. doi:10.1016/j.toxicon.2015.03.007. PMID 25796346.
- "Pros and Cons of Potbellied Pigs". Archived from the original on 17 March 2014. Retrieved 25 November 2017.
- "Taxonomy Browser". ncbi.nlm.nih.gov.
- Anthea Gentry; Juliet Clutton-Brock; Colin P. Groves (2004). "The naming of wild animal species and their domestic derivatives" (PDF). Journal of Archaeological Science. 31 (5): 645–651. doi:10.1016/j.jas.2003.10.006. Archived from the original (PDF) on 8 April 2011.
- Corbet and Hill (1992), referred to in Wilson, D.E.; Reeder, D.M., eds. (2005). Mammal Species of the World: A Taxonomic and Geographic Reference (3rd ed.). Johns Hopkins University Press. ISBN 978-0-8018-8221-0. OCLC 62265494.
- Anthea Gentry; Juliet Clutton-Brock; Colin P. Groves (1996). "Proposed conservation of usage of 15 mammal specific names based on wild species which are antedated by or contemporary with those based on domestic animals" (PDF). Bulletin of Zoological Nomenclature. 53: 28–37. doi:10.5962/bhl.part.14102. Archived from the original (PDF) on 14 October 2014.
- Nelson, Sarah M. (1998). Ancestors for the Pigs. Pigs in prehistory. University of Pennsylvania Museum of Archaeology and Anthropolog. ISBN 9781931707091.
Ottoni, C; Flink, LG; Evin, A; Geörg, C; De Cupere, B; Van Neer, W; Bartosiewicz, L; Linderholm, A; Barnett, R; Peters, J; Decorte, R; Waelkens, M; Vanderheyden, N; Ricaut, FX; Cakirlar, C; Cevik, O; Hoelzel, AR; Mashkour, M; Karimlu, AF; Seno, SS; Daujat, J; Brock, F; Pinhasi, R; Hongo, H; Perez-Enciso, M; Rasmussen, M; Frantz, L; Megens, HJ; Crooijmans, R; Groenen, M; Arbuckle, B; Benecke, N; Vidarsdottir, US; Burger, J; Cucchi, T; Dobney, K; Larson, G (2013). "our data suggest a narrative that begins with the domestication of pigs in Southwest Asia, at Upper Tigris sites including Çayönü Tepesi (Ervynck et al. 2001) and possibly Upper Euphrates sites including Cafer Höyük (Helmer 2008) and Nevali Çori (Peters et al. 2005);
from google (Çayönü pig ancestor) result 2; 'Çayönü Tepesi' in wiki (Cattle)". Mol Biol Evol. 30 (4): 824–32. doi:10.1093/molbev/mss261. PMC 3603306. PMID 23180578.
- Rosenberg M, Nesbitt R, Redding RW, Peasnall BL (1998). Hallan Çemi, pig husbandry, and post-Pleistocene adaptations along the Taurus-Zagros Arc (Turkey). Paleorient, 24(1):25–41.
- Vigne, JD; Zazzo, A; Saliège, JF; Poplin, F; Guilaine, J; Simmons, A (2009). "Pre-Neolithic wild boar management and introduction to Cyprus more than 11,400 years ago". Proceedings of the National Academy of Sciences of the United States of America. 106 (38): 16135–8. Bibcode:2009PNAS..10616135V. doi:10.1073/pnas.0905015106. PMC 2752532. PMID 19706455.
- Giuffra, E; Kijas, JM; Amarger, V; Carlborg, O; Jeon, JT; Andersson, L (2000). "The origin of the domestic pig: independent domestication and subsequent introgression". Genetics. 154 (4): 1785–91. PMC 1461048. PMID 10747069.
- Jean-Denis Vigne; Anne Tresset; Jean-Pierre Digard (3 July 2012). History of domestication (PDF) (Speech).
- BBC News, "Pig DNA reveals farming history" 4 September 2007. The report concerns an article in the journal PNAS
- Larson, G; Albarella, U; Dobney, K; Rowley-Conwy, P; Schibler, J; Tresset, A; Vigne, JD; Edwards, CJ; et al. (2007). "Ancient DNA, pig domestication, and the spread of the Neolithic into Europe" (PDF). Proceedings of the National Academy of Sciences of the United States of America. 104 (39): 15276–81. Bibcode:2007PNAS..10415276L. doi:10.1073/pnas.0703411104. PMC 1976408. PMID 17855556.
- Frantz, L (2015). "Evidence of long-term gene flow and selection during domestication from analyses of Eurasian wild and domestic pig genomes". Nat. Genet. 47 (10): 1141–8. doi:10.1038/ng.3394. PMID 26323058.
- Pennisi, E (2015). "The taming of the pig took some wild turns". Science. doi:10.1126/science.aad1692.
- Oral Care. Archived 16 September 2007 at the Wayback Machine
- Torrejón, Fernando; Cisternas, Marco; Araneda, Alberto (2004). "Efectos ambientales de la colonización española desde el río Maullín al archipiélago de Chiloé, sur de Chile" [Environmental effects of the spanish colonization from de Maullín river to the Chiloé archipelago, southern Chile]. Revista Chilena de Historia Natural (in Spanish). 77 (4): 661–677. doi:10.4067/s0716-078x2004000400009.
- II.G.13. – Hogs. Archived 20 December 2007 at the Wayback Machine
- "Feral Hogs in Missouri | Missouri Department of Conservation". mdc.mo.gov. Retrieved 7 March 2017.
- "AGFC | Feral Hog Hunting Regulations". agfc.com. Archived from the original on 22 February 2017. Retrieved 7 March 2017.
- "Feral Hog Management | Georgia DNR - Wildlife Resources Division". georgiawildlife.com. Archived from the original on 8 March 2017. Retrieved 8 March 2017.
- Yoon, Carol Kaesuk (29 December 1992). "Alien Species Threaten Hawaii's Environment". The New York Times.
- "Introduced Birds and Mammals in New Zealand and Their Effect on the Environment - NZETC". nzetc.org.
- "World's 100 most destructive species named". The Independent. 21 November 2004. Retrieved 7 March 2017.
- Authorization for the slaughter of the 'javaporco' reassures farmers in Assis, SP ‹See Tfd›(in Portuguese)
- IBAMA authorizes capture and slaughter of 'javaporcos' – Folha do Sul Gaúcho ‹See Tfd›(in Portuguese)
- 'Javaporco' gives damage and scares farmers in Maracaí, SP – O Grito do Bicho ‹See Tfd›(in Portuguese)
- MS Rural – farmers are authorized to make populational control of exotic species, such as the European boar ‹See Tfd›(in Portuguese)
- "Status and Distribution of wild boar in Rio Grande do Sul, Southern Brazil". 2009.
- "PSD Online". fas.usda.gov.
- Swine Summary Selected Countries Archived 29 March 2012 at the Wayback Machine, United States Department of Agriculture, Foreign Agricultural Service, (total number is Production (Pig Crop) plus Total Beginning Stocks
- Hughes, Paul (1980). Reproduction in the Pig. Massachusetts: The Butterworth Group. ISBN 0408709464.
- "Feral Hog Reproductive Biology". 16 May 2012.
- "G2312 Artificial Insemination in Swine: Breeding the Female | University of Missouri Extension". extension.missouri.edu. Retrieved 7 March 2017.
- "The Female - Swine Reproduction". livestocktrail.illinois.edu. Retrieved 7 March 2017.
- Bazer, F. W.; Vallet, J. L.; Roberts, R. M.; Sharp, D. D.; Thatcher, W. W. (1986). "Role of conceptus secretory products in establishment of pregnancy". J. Reprod. Fertil. 76 (2): 841–850. doi:10.1530/jrf.0.0760841.
- Bazer, Fuller W.; Song, Gwonhwa; Kim, Jinyoung; Dunlap, Kathrin A.; Satterfield, Michael Carey; Johnson, Gregory A.; Burghardt, Robert C.; Wu, Guoyao (1 January 2012). "Uterine biology in pigs and sheep". Journal of Animal Science and Biotechnology. 3 (1): 23. doi:10.1186/2049-1891-3-23. ISSN 2049-1891. PMC 3436697. PMID 22958877.
- Ziecik, A. J., et al. (2018). "Regulation of the porcine corpus luteum during pregnancy." Reproduction 156(3): R57-R67
- Waclawik, A., et al. (2017). "Embryo‐maternal dialogue during pregnancy establishment and implantation in the pig." Molecular reproduction and development 84(9): 842-855
- Farmer, Chantal (2015). The gestating and lactating sow. The Netherlands: Wageningen Academic Publishers. ISBN 9789086868032. OCLC 899008362.
- Clutton-Brock, J., (1987). A Natural History of Domesticated Mammals. Cambridge University Press, Cambridge pp.73-74
- Algers, Bo; Uvnäs-Moberg, Kerstin (1 June 2007). "Maternal behavior in pigs". Hormones and Behavior. Reproductive Behavior in Farm and Laboratory Animals11th Annual Meeting of the Society for Behavioral Neuroendocrinology. 52 (1): 78–85. doi:10.1016/j.yhbeh.2007.03.022. PMID 17482189.
- Bracke, M.B.M (2011). "Review of wallowing in pigs: description of the behaviour and its motivational basis". Applied Animal Behaviour Science. 132 (1–2): 1–13. doi:10.1016/j.applanim.2011.01.002.
- "Blowing Coat - Mini Pig Shedding FAQ". americanminipigassociation.com. 28 April 2016.
- Kongsted, A. G.; Horsted, K.; Hermansen, J. E. (2013). "Free-range pigs foraging on Jerusalem artichokes ( Helianthus tuberosus L.) – Effect of feeding strategy on growth, feed conversion and animal behaviour". Acta Agriculturae Scandinavica, Section A. 63 (2): 76–83. doi:10.1080/09064702.2013.787116.
- "10 of the smartest animals on Earth". MNN - Mother Nature Network. Retrieved 8 March 2017.
- "Signs of Intelligent Life | Natural History Magazine". naturalhistorymag.com. Retrieved 3 June 2019.
- David Disalvo 2014/11/26 how-smart-was-that-turkey-and-ham-before-it-became-dinner at forbes.com Accessed 27 January 2017
- "In a Pig's Eye" - by Eston Martz Penn State Agricultural Magazine, Fall/ Winter 1997 Penn State College of Agricultural Sciences[permanent dead link] Accessed 27 January 2017
- Catherine Becker: 'Pork' at u.osu.edu[permanent dead link] Accessed 27 January 2017
- 'Croney to head Purdue Center for Animal Welfare Science' Accessed 27 January 2017
- Angier, Natalie (9 November 2009). "Pigs Prove to Be Smart, if Not Vain". The New York Times. New York, New York, US: The New York Times Company. Retrieved 28 July 2010.
- "Rooting & Nudging Behaviors in Mini Pigs". americanminipigassociation.com. 8 June 2016.
- "Kunekune pigs are just right for farm life". tractorsupply.com.
- Algers, Bo; Uvnäs-Moberg, Kerstin (1 June 2007). "Maternal behavior in pigs". Hormones and Behavior. 52 (1): 78–85. doi:10.1016/j.yhbeh.2007.03.022. ISSN 0018-506X. PMID 17482189.
- Wischner D., Kemper N., and Krieter J. 2009. "Nest-building behaviour in sows and consequences for pig husbandry". Livestock Science. 124(1): 1-8.
- Fraser, D (1980). "A review of the behavioural mechanisms of milk ejection of the domestic pig". Applied Animal Ethology. 6 (3): 247–256. doi:10.1016/0304-3762(80)90026-7.
- Rohde Parfet, K.A.; Gonyou, H.W. (1991). "Attraction of newborn piglets to auditory, visual, olfactory and tactile stimuli". Journal of Animal Science. 69: 125–133. doi:10.2527/1991.691125x.
- Algers, B (1993). "Nursing in pigs: communicating needs and distributing resources". Journal of Animal Science. 71 (10): 2826–2831. doi:10.2527/1993.71102826x.
- Castren, H.; Algers, B.; Jensen, P.; Saloniemi, H. (1989). "Suckling behaviour and milk consumption in newborn piglets as a response to sow grunting". Applied Animal Behaviour Science. 24 (3): 227–238. doi:10.1016/0168-1591(89)90069-5.
- Jensen, P.; Gustafsson, G.; Augustsson, H. (1998). "Massaging after milk ejection in domestic pigs - an example of honest begging?". Animal Behaviour. 55 (4): 779–786. doi:10.1006/anbe.1997.0651. PMID 9632466.
- Fraser, D., (1973). The nursing and suckling behaviour in pigs. I. The importance of stimulation of the anterior teats. British Veterinary Journal, 129: 324-336
- Jeppesen, L.E. (1982). "Teat-order in groups of piglets reared on an artificial sow. II. Maintenance of teatorder with some evidence for the use of odour cues". Applied Animal Ethology. 8 (4): 347–355. doi:10.1016/0304-3762(82)90067-0.
- "Animalbehaviour.net (Pigs)". Archived from the original on 17 March 2012. Retrieved 9 December 2012.
- "Animalbehaviour.net (Sheep)". Archived from the original on 26 December 2012. Retrieved 9 December 2012.
- Lomas, C.A.; Piggins, D.; Phillips, C.J.C. (1998). "Visual awareness". Applied Animal Behaviour Science. 57 (3–4): 247–257. doi:10.1016/s0168-1591(98)00100-2.
- Houpt, K.A., (1998). Domestic Animal Behavior for Veterinarians and Animal Scientists. 3rd edition. Iowa State University Press, Ames.
- Gonyou, H.W., (2001). The social behaviour of pigs. In "Social Behaviour in Farm Animals", eds. Keeling, L.J. and Gonyou, H.W. CABI, Oxford.
- Vieuille-Thomas, C.; Signoret, J.P. (1992). "Pheromonal transmission of an aversive experience in domestic pigs". Journal of Chemical Ecology. 18 (9): 1551–1557. doi:10.1007/bf00993228. PMID 24254286.
- Jensen, P.; Redbo, I. (1987). "Behaviour during nest leaving in free ranging domestic pigs". Applied Animal Behaviour Science. 18 (3–4): 355–362. doi:10.1016/0168-1591(87)90229-2.
- "The Livestock Conservancy". livestockconservancy.org. Retrieved 7 March 2017.
- "Taking good care of Ellegaard Göttingen Minipigs®" (PDF). Ellegaard Göttingen Minipigs. Retrieved 2 July 2018.
- Strom, Stephanie (20 January 2014). "Demand Grows for Hogs That Are Raised Humanely Outdoors". The New York Times. Retrieved 15 April 2015.
- "Spay and Neuter - American Mini Pig Association". americanminipigassociation.com.
- "Hoof Trimming - American Mini Pig Association". americanminipigassociation.com.
- "Tusk Trimming in Mini Pigs Using Gigli Wire Saw -". 26 September 2016. Retrieved 7 May 2019.
- "Mini Pig Training: How to Hold a Mini Pig - Life with a Mini Pig". 21 June 2015.
- "Enrichment Activities For A Bored Pig - American mini Pig Association". Retrieved 7 May 2019.
- "Aggressive Mini Pigs- How To Correct Aggression Issues". Mini Pig Info.
- "Nose Rings in Mini Pigs, Cruel and Ineffective, Nose Ring Alternatives -". 19 September 2016. Retrieved 7 May 2019.
- Herron, Alan J. (5 December 2009). "Pigs as Dermatologic Models of Human Skin Disease" (PDF). ivis.org. DVM Center for Comparative Medicine and Department of Pathology Baylor College of Medicine Houston, Texas. Retrieved 27 January 2018.
pig skin has been shown to be the most similar to human skin. Pig skin is structurally similar to human epidermal thickness and dermal-epidermal thickness ratios. Pigs and humans have similar hair follicle and blood vessel patterns in the skin. Biochemically, pigs contain dermal collagen and elastic content that is more similar to humans than other laboratory animals. Finally, pigs have similar physical and molecular responses to various growth factors.
- Liu, J., Kim, D., Brown, L., Madsen, T., Bouchard, G. F. "Comparison of Human, Porcine and Rodent Wound Healing With New Miniature Swine Study Data" (PDF). sinclairresearch.com. Sinclair Research Centre, Auxvasse, MO, USA; Veterinary Medical Diagnostic Laboratory, Columbia, MO, USA. Retrieved 27 January 2018.
Pig skin is anatomically, physiologically, biochemically and immunologically similar to human skinCS1 maint: Multiple names: authors list (link)
- "Xenotransplantation: How Pig Organs Could Be Transplanted into Humans". https://www.animalbiotech.com. Animal Biotech Industries. Retrieved 5 November 2018. External link in
- Dooldeniya, M. D.; Warrens, A. N. (2003). "Xenotransplantation: Where are we today?". Journal of the Royal Society of Medicine. 96 (3): 111–117. doi:10.1177/014107680309600303. PMC 539416. PMID 12612110.
- Taylor, L. (2007) Xenotransplantation. Emedicine.com
- Latemple, D. C.; Galili, U. (1998). "Adult and neonatal anti-Gal response in knock-out mice for alpha1,3galactosyltransferase". Xenotransplantation. 5 (3): 191–196. doi:10.1111/j.1399-3089.1998.tb00027.x. PMID 9741457.
- FDA. (2006) Xenotransplantation Action Plan: FDA Approach to the Regulation of Xenotransplantation. Center for Biologics Evaluation and Research.
- Carl Zimmerman (15 October 2015). "Editing of Pig DNA May Lead to More Organs for People". NY Times.
- Pigs & Peccaries Specialist Group (1996). "Sus scrofa". IUCN Red List of Threatened Species. Version 2006. International Union for Conservation of Nature. Retrieved 12 May 2006.
- Animal Welfare AVMA Policy on Pregnant Sow Housing
- CAST Scientific Assessment of the Welfare of Dry Sows kept in Individual Accommodations- March 2009
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