Trichinella spiralis larva displayed in a typical coil shape.
|Classification and external resources|
Trichinosis or trichiniasis, is a parasitic disease caused by eating raw or undercooked pork or wild game infected with the larvae of a species of roundworm Trichinella spiralis, commonly called the trichina worm. There are eight Trichinella species; five are encapsulated and three are not. Only three Trichinella species are known to cause trichinosis: T. spiralis, T. nativa, and T. britovi.
Historically, pork products were thought to have the most risk of infecting humans with Trichinella spiralis. However, a Trichinellosis surveillance conducted between 1997-2001 showed a higher percentage of cases was caused by consumption of wild game. This is thought to be due to the Federal Swine Health Protection Act (Public Law 96-468) that was passed by congress in 1980. Before this act swine were fed garbage that could potentially be infected by Trichinella spiralis. This act was put in place to prevent contaminated food from being given to swine. Additionally, other regulations were put in place such as rodent control, limiting commercial swines contact with wildlife, maintaining good hygiene, and removing dead pigs from pens immediately. 
Between 2002 and 2007, 11 cases were reported to CDC each year on average in the United States; these were mostly the result of eating undercooked game, bear meat, or home-reared pigs. It is common in developing countries where meat fed to pigs is raw or undercooked, but many cases also come from developed countries in Europe and North America,[clarification needed] where raw or undercooked pork and wild game may be consumed as delicacies.
- 1 Agent and taxonomy
- 2 History of the discovery
- 3 Signs and symptoms
- 4 Life cycle
- 5 Diagnosis
- 6 Treatment and vaccines
- 7 Epidemiology
- 8 International Commission on Trichinellosis
- 9 Prevention
- 10 See also
- 11 References
- 12 External links
Agent and taxonomy
The causative agents of trichinosis in humans include the three aforementioned species, however, T. spiralis is the most clinically diagnosed cause of the disease due to its cosmopolitan distribution and high pathogenicity.
- Species and characteristics
- T. spiralis is most adapted to swine, most pathogenic in humans and is cosmopolitan in distribution.
- T. britovi is the second most common species to infect humans; it is distributed throughout Europe, Asia, and northern and western Africa usually in wild boar and domesticated pigs.
- T. nativa, which has a high resistance to freezing, is found in the Arctic and subarctic regions; reservoir hosts include polar bears, arctic foxes, walruses and other wild game.
- T. pseudospiralis infects birds and mammals, and has demonstrated infection in humans; it is a nonencapsulated species.
- T. papuae infects both mammals and reptiles, including crocodiles, humans, and pigs; this species, found in Papua New Guinea and Thailand, is also nonencapsulated.
- T. nelsoni, found in eastern Africa, has been documented to cause a few human cases.
- T. murrelli also infects humans, especially from black bear meat; it is distributed among wild carnivores in North America.
- T. zimbabwensis can infect mammals and possibly humans; this nonencapsulated species was detected in reptiles of Africa.
- Kingdom: Animalia
- Phylum: Nematoda
- Class: Adenophorea
- Order: Trichurida
- Family: Trichinellidae
- Genus: Trichinella
History of the discovery
Discovery of the parasite
The circumstances surrounding the first observation and identification of Trichinella spiralis are controversial due to a lack of medical records. In 1835, James Paget, a first-year medical student, first observed the larval form of T. spiralis while witnessing an autopsy at St. Bartholomew’s Hospital in London. Paget took special interest in the presentation of muscle with white flecks, described as a "sandy diaphragm".
Although Paget is most likely the first person to have noticed and recorded these findings, the parasite was named and published in a report by his professor, Richard Owen, who is now credited for the discovery of the T. spiralis larval form.
Discovery of the life cycle
A series of experiments conducted between 1850 and 1870 by the German researchers Rudolf Virchow, Rudolf Leuckart and Friedrich Albert von Zenker, which involved feeding infected meat to a dog and performing the subsequent necropsy, led to the discovery of the life cycle of Trichinella. Through these experiments, Virchow was able to describe the development and infectivity of T. spiralis.
Signs and symptoms
The great majority of trichinosis infections have either minor or no symptoms and no complications. There are two main phases for the infection: enteral (affecting the intestines) and parenteral (outside the intestines). The symptoms vary depending on the phase, species of Trichinella, amount of encysted larvae ingested, age, gender, and host immunity.
A large burden of adult worms in the intestines promote symptoms such as nausea, heartburn, dyspepsia, and diarrhea from two to seven days after infection, while small worm burdens generally are asymptomatic. Eosinophilia presents early and increases rapidly.
The severity of symptoms caused by larval migration from the intestines depends on the number of larvae produced. As the larvae migrate through tissue and vessels, the body's inflammatory response results in edema, muscle pain, fever, and weakness. A classic sign of trichinosis is periorbital edema, swelling around the eyes, which may be caused by vasculitis. Splinter hemorrhage in the nails is also a common symptom.
They may very rarely cause enough damage to produce serious neurological deficits (such as ataxia or respiratory paralysis) from worms entering the central nervous system. The CNS is compromised by trichinosis in 10–24% of reported cases of a very rare form of stroke, 3-4 cases per million annual incidence in adults. Trichinosis can be fatal depending on the severity of the infection; death can occur 4–6 weeks after the infection, and is usually caused by myocarditis, encephalitis, or pneumonia.
The typical life cycle for T. spiralis involves humans, pigs, and rodents. Pigs become infected when they eat infectious cysts in raw meat, often pork or rats (sylvatic cycle). Humans become infected when they eat raw or undercooked infected pork (domestic cycle). After humans ingest the cysts from infected undercooked meat, pepsin and hydrochloric acid help free the larvae in the cysts in the stomach. The larvae then migrate to the small intestine, where they molt four times before becoming adults.
Thirty to 34 hours after the cysts were originally ingested, the adults mate, and within five days produce larvae. The worms can only reproduce for a limited time because the immune system will eventually expel them from the small intestine. The larvae then use their piercing mouthpart, called the "stylet", to pass through the intestinal mucosa and enter the lymphatic vessels, and then enter the bloodstream.
The larvae travel by capillaries to various organs, such as the retina, myocardium, or lymph nodes; however, only larvae that migrate to skeletal muscle cells survive and encyst. The larval host cell becomes a nurse cell in which the larvae will be encapsulated. The development of a capillary network around the nurse cell completes encystation of the larvae.
Diagnosis of trichinosis is confirmed by a combination of exposure history, clinical diagnosis, and laboratory testing.
An epidemiological investigation can be done to determine a patient's exposure to raw infected meat. Often, an infection arises from home-preparation of contaminated meat, in which case microscopy can be used to determine the infection. However, exposure does not have to be directly from an infected animal. Other exposure includes the consumption of products from a laboratory-confirmed infected animal or by sharing a common exposure as a laboratory-confirmed infected human.
Clinical presentation of the common trichinosis symptoms may also suggest infection. These symptoms include circumorbital edema, splinter hemorrhage, nonspecific gastroenteritis, and muscle pain. The case definition for trichinosis at the European Center for Disease Control states "at least three of the following six: fever, muscle soreness and pain, gastrointestinal symptoms, facial edema, eosinophilia, and subconjuctival, subungual, and retinal hemorrhages." 
Blood tests and microscopy can be used to aid in the diagnosis of trichinosis. Blood tests include a complete blood count for eosinophilia, creatine phosphokinase activity, and various immunoassays such as ELISA for larval antigens.
Treatment and vaccines
As is desirable with most diseases, early treatment is better and decreases the risk of developing disease. If larvae do encyst in skeletal muscle cells, they can remain infectious for months to years.
Early administration of anthelmintics, such as mebendazole or albendazole, decreases the likelihood of larval encystation, particularly if given within three days of infection. However, most cases are diagnosed after this time.
Mebendazole (200–400 mg three times a day for three days) or albendazole (400 mg twice a day for 8–14 days) are given to treat trichinosis. These drugs prevent newly hatched larvae from developing, but should not be given to pregnant women or children under two years of age.
There are currently no vaccines for trichinosis, although experimental mice studies have suggested a possibility. In one study, microwaved Trichinella larvae were used to immunize mice, which were subsequently infected. Depending on dosage and the frequency of immunization, results ranged from a decreased larval count to complete protection from trichinosis.
Another study, Dea-Ayuela et al. (2006) used extracts and excretory-secretory products from first stage larvae to produce an oral vaccine. To prevent the gastric acids from dissolving the antigens before reaching the small intestine, scientists encapsulated the antigens in a microcapsule made of copolymers. This vaccine significantly increased CD4+ cells and increased antigen-specific serum IgGq and IgA, resulting in a statistically significant reduction in the average number of adult worms in the small intestine of mice. The significance of this approach is that if the white blood cells in the small intestine have been exposed to Trichinella antigens (through vaccination) then, when an individual gets infected, the immune system will respond to expel the worms from the small intestine fast enough to prevent the female worms from releasing their larvae. Yuan Gu et al. (2008) tested a DNA vaccine on mice which "induced a muscle larvae burden reduction in BALB/c mice by 29% in response to T. spiralis infection". Researchers trying to develop a vaccine for Trichinella have tried to using either "larval extracts, excretory-secretory antigen, DNA vaccine, or recombinant antigen protein." 
As early as 1835, trichinosis was known to have been caused by a parasite, but the mechanism of infection was unclear at the time. A decade later, American scientist Joseph Leidy pinpointed undercooked meat as the primary vector for the parasite, and it was not until two decades afterwards that this hypothesis was fully accepted by the scientific community.
About 11 million individuals are infected with Trichinella; Trichinella spiralis is the species responsible for most of these infections. Infection was once very common, but is now rare in the developed world. The incidence of trichinosis in the U.S. has decreased dramatically in the past century. From 1997 to 2001, an annual average of 12 cases per year were reported in the United States. The number of cases has decreased because of legislation prohibiting the feeding of raw meat garbage to hogs, increased commercial and home freezing of pork, and the public awareness of the danger of eating raw or undercooked pork products.
In the developing world, most infections are associated with undercooked pork. For example, in Thailand, between 200 and 600 cases are reported annually around the Thai New Year. This is mostly attributable to a particular delicacy, larb, which calls for undercooked pork as part of the recipe. In parts of Eastern Europe, the World Health Organization (WHO) reports some swine herds have trichinosis infection rates above 50%, and there are correspondingly large numbers of human infections. 
The disappearance of the pathogen from domestic pigs has led to a relaxation of legislation and control efforts by veterinary public health systems. It has since been thought of as a reemerging zoonosis supplemented by the increased distribution of meat products, political changes, a changing climate, and increasing sylvatic transmission.
It is also important to keep in mind major socio-political changes can produce conditions that favor the resurgence of Trichinella infections in swine and, consequently, humans. For instance, "the overthrow of the social and political structures in the 1990s" in Romania led to an increase in the incidence rate of trichinosis. There is also a high incidence of trichinosis among refugees from Southeast Asia. China reports approximately 10,000 cases every year, and is therefore the country with the highest numbers of cases. In China, between 1964 and 1998, over 20,000 people were infected with Trichinosis and more than 200 people died.
The kashrut and halal dietary laws of Judaism and Islam prohibit eating pork. In the 19th century, when the association between trichinosis and undercooked pork was first established, it was suggested that this association was the reason for the prohibition, reminiscent of the earlier opinion of the medieval Jewish philosopher Maimonides that food forbidden by Jewish law was "unwholesome". This theory was controversial and eventually fell out of favor.
International Commission on Trichinellosis
The International Commission on Trichinellosis (ICT) was created in 1958 in Budapest and is aiming to exchange information on the biology, the physiopathology, the epidemiology, the immunology, and the clinical aspects of trichinellosis in humans and animals. Prevention is a primary goal. Since the creation of the ICT, its members (more than 110 from 46 countries) have regularly gathered and worked together during meetings held every four years : the International Conference on Trichinellosis.
Laws and rules required of food producers may improve food safety for consumers, such as the rules established by the European Commission for inspections, rodent control, and improved hygiene. Similar protocol exists in the United States in the USDA guidelines for establishment responsibilities in inspecting pork.
Education and training
Public education about the dangers of consuming raw and undercooked meat, especially pork, may reduce infection rates. Hunters are also an at-risk population due to their contact and consumption of wild game, including bear. As such, many states, such as New York, require the completion of a course in such matters before a hunting license can be obtained.
Larvae may be killed by the heating or irradiation of raw meat. Freezing is only usually effective for T. spiralis, since other species, such as T. nativa, are freeze resistant and can survive long-term freezing.
- All meat (including pork) can be safely prepared by cooking to an internal temperature of 165°F (74°C) or more for 15 seconds or more.
- Wild game: Wild game meat must be cooked thoroughly (see meat preparation above) Freezing wild game does not kill all trichinosis larval worms. This is because the worm species that typically infests wild game can resist freezing.
- Pork: Freezing cuts of pork less than 6 inches thick for 20 days at 5 °F (−15 °C) or three days at −4 °F (−20 °C) kills T. spiralis larval worms; but this will not kill other trichinosis larval worm species, such as T. nativa, if they have infested the pork food supply (which is unlikely).
Pork can be safely cooked to a slightly lower temperature provided that the internal meat temperature is at least as hot for at least as long as listed in the USDA table below. Nonetheless, it is prudent to allow a margin of error for variation in internal temperature within a particular cut of pork, which may have bones that affect temperature uniformity. In addition, your thermometer has measurement error that must be considered. Cook pork for significantly longer and at a higher uniform internal temperature than listed here to be safe.
|Internal Temperature||Internal Temperature||Minimum Time|
Unsafe and unreliable methods of cooking meat include the use of microwave ovens, curing, drying, and smoking, as these methods are difficult to standardize and control.
Hygienic pig farming
- Keeping pigs in clean pens with floors that can be washed (such as concrete)
- Not allowing hogs to eat carcasses of other animals, including rats, which may be infected with Trichinella
- Cleaning meat grinders thoroughly when preparing ground meats
- Control and destruction of meat containing trichinae, e.g., removal and proper disposal of porcine diaphragms prior to public sale of meat
The Centers for Disease Control and Prevention makes the following recommendation: "Curing (salting), drying, smoking, or microwaving meat does not consistently kill infective worms." However, under controlled commercial food processing conditions, some of these methods are considered effective by the United States Department of Agriculture (USDA).
The USDA Animal and Plant Health Inspection Service (APHIS) is responsible for the regulations concerning the importation of swine from foreign countries. The Foreign Origin Meat and Meat Products, Swine section covers swine meat (cooked, cured and dried, and fresh). APHIS developed the National Trichinae Certification Program; this is a voluntary "preharvest" program for U.S. swine producers "that will provide documentation of swine management practices" to reduce the incidence of Trichinella in swine. The CDC reports 0.013% of U.S. swine is infected with Trichinella.
- Pozio, E., & Murrell, D. K. (2006). Systematics and Epidemiology of Trichinella. Advances in Parasitology, 63, 368–439.
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- Dea-Ayuela, M. A., Iniguz, S.R., Fernandez, F.B. (2006). Vaccination of mice against intestinal Trichinella spiralis infections by oral administration of antigens microencapsulated in methacrilic acid copolymers. Vaccine, 24, 2772–2780.
- Gu, Y., Li, J., Zhu, X., Yang, J., Li, Q., Liu, Z., Yu, S., Li, Y. (2008). Trichinella spiralis: Characterization of phage-displayed specific epitopes and their protective immunity in BALB/c mice. Experimental Parasitology, 118, 66–74.
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- pp. 67–70, chapter 4, Good to Eat: Riddles of Food and Culture, Marvin Harris, New York: Simon and Schuster, 1985, ISBN 0-671-50366-9.
- United States Department of Agriculture – Food Safety and Inspection Service. "NSS NRTE/RTE Establishment Responsibilities." (2006).
- New York State Department of Environmental Conservation – Hunting Licenses <www.dec.ny.gov/permits/6094.html>
- USDA Title 9 section 318.10 Table
- In addition, out of the reports of trichinosis in the United States, all have been a result of mass produce, particularly in large venues, such as cafeterias and mall food courts. Centers for Disease Control and Prevention, Division of Parasitic Diseases (2004-07-15). "Parasitic Disease Information – Trichinellosis". Retrieved 2007-01-28.
- United States Department of Agriculture. "Electronic Code of Federal Regulations; Title 9: Animals and Animal Products; PART 318—ENTRY INTO OFFICIAL ESTABLISHMENTS; REINSPECTION AND PREPARATION OF PRODUCTS; § 318.10 Prescribed treatment of pork and products containing pork to destroy trichinae". Retrieved 2007-01-28.
- APHIS. USDA Animal and Plant Health Inspection Service APHIS – Veterinary Services. Retrieved February 11, 2009, http://www.aphis.usda.gov/vs/trichinae/
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- USDA regulations – Title 9 – Chapter 3 – Part 318 – includes "Prescribed treatment of pork and products containing pork to destroy trichinae."
- International Commission on trichinellosis web pages
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- Farmed wild boars exposed to Toxoplasma gondii and Trichinella spp.