Edible mushroom

Edible mushrooms are the fleshy and edible fruit bodies of several species of fungi. Mushrooms belong to the macrofungi, because their fruiting structures are large enough to be seen with the naked eye. They can appear either below ground (hypogeous) or above ground (epigeous) where they may be picked by hand.[1] Edibility may be defined by criteria that include absence of poisonous effects on humans and desirable taste and aroma.[2][3] Of the estimated 1.5 million species of fungi, only about 150 are considered toxic.[4]

Edible mushrooms are consumed by humans for their nutritional and occasionally medicinal value as comestibles. Mushrooms consumed for health reasons are known as medicinal mushrooms. While hallucinogenic mushrooms (e.g. Psilocybin mushrooms) are occasionally consumed for recreational or religious purposes, they can produce severe nausea and disorientation, and are therefore not commonly considered edible mushrooms.[5]

Edible mushrooms include many fungal species that are either harvested wild or cultivated. Easily cultivatable and common wild mushrooms are often available in markets, and those that are more difficult to obtain (such as the prized truffle and matsutake) may be collected on a smaller scale by private gatherers. Some preparations may render certain poisonous mushrooms fit for consumption.

Before assuming that any wild mushroom is edible, it should be identified. Proper identification of a species is the only safe way to ensure edibility. Some mushrooms that are edible for most people can cause allergic reactions in some individuals, and old or improperly stored specimens can cause food poisoning. Deadly poisonous mushrooms that are frequently confused with edible mushrooms and responsible for many fatal poisonings include several species of the Amanita genus, in particular, Amanita phalloides, the death cap.

Contents

History of mushroom use

Mycophagy ( /mˈkɒfəi/), the act of consuming mushrooms, dates to ancient times. Edible mushroom species have been found in association with 13,000 year old ruins in Chile, but the first reliable evidence of mushroom consumption dates to several hundred years BC in China. The Chinese value mushrooms for medicinal properties as well as for food. Ancient Romans and Greeks ate mushrooms, particularly the upper class.[5] The Roman Caesars would have a food taster taste the mushrooms before the Caesar to make sure they were safe.[6]

Mushrooms are also easily preserved, and historically have provided additional nutrition over winter.

Many cultures around the world have either used or continue to use psilocybin mushrooms for spiritual purposes as well as medicinal mushrooms in folk medicine.

Current culinary use

A fraction of the many fungi consumed by humans are currently cultivated and sold commercially. Commercial cultivation is important ecologically, as there have been concerns of depletion of larger fungi such as chanterelles in Europe, possibly because the group has grown so popular yet remains a challenge to cultivate.

Commercially cultivated

Mushroom cultivation has a long history, with over twenty species commercially cultivated. Mushrooms are cultivated in at least 60 countries[7] with China, the United States, Netherlands, France and Poland being the top five producers in 2000.

Commercially harvested wild edibles

Some species are difficult to cultivate; others (particularly mycorrhizal species) have not yet been successfully cultivated. Some of these species are harvested from the wild, and can be found in markets. When in season they can be purchased fresh, and many species are sold dried as well. The following species are commonly harvested from the wild:

Other edible wild species

Many wild species are consumed around the world. The species which can be identified "in the field" (without use of special chemistry or a microscope) and therefore safely eaten vary widely from country to country, even from region to region. This list is a sampling of lesser-known species that are reportedly edible.

Conditionally edible species

There are a number of fungi that are considered choice by some and toxic by others. In some cases, proper preparation can remove some or all of the toxins.

Medicinal use

Medicinal mushrooms are mushrooms or extracts from mushrooms that are used or studied as possible treatments for diseases. Research has shown some medicinal mushroom isolates that have promising cardiovascular, anticancer, antiviral, antibacterial, antiparasitic, anti-inflammatory, and antidiabetic properties. Currently, several extracts (polysaccharide-K,[12] polysaccharide peptide,[13] lentinan[1]) have widespread use in Japan, Korea and China, as adjuvants to radiation treatments and chemotherapy.[14][15]

The concept of a medicinal mushroom has a history spanning millennia in parts of Asia.[16] Only a few mushroom extracts have been extensively tested for efficacy. The available results for most other extracts, are on isolated cell lines, animal research with rodents, or small clinical human trials.[15]

Preparing wild edibles

Some wild species are toxic, or at least indigestible, when raw. As a rule all wild mushroom species should be cooked thoroughly before eating. Many species can be dried and re-hydrated by pouring boiling water over the dried mushrooms and letting them steep for approximately 30 minutes. The soaking liquid can be used for cooking as well, provided that any dirt at the bottom of the container is discarded.

One recipe for Auricularia auricula-judae is to collect it while still soft, wash it thoroughly and cut it into thin slices. The prepared slices should be stewed in stock or milk for around three-quarters of an hour, and then served with plenty of pepper. The result is crispy and not unlike seaweed.[17]

The difficult task of identifying mushrooms in the wild, for culinary or recreational purposes, can produce severe poisoning.[18]

Production

Top ten mushroom and truffle producing countries in 2008
Country Output in tons Percentage of total world output
China 1,608,219 45.89
United States 363,560 10.40
Netherlands 240,000 6.86
Poland 180,000 5.15
France 150,450 4.30
Spain 131,974 3.77
Italy 100,000 2.86
Canada 86,946 2.49
Ireland 75,000 2.14
Japan 67,000 1.92
WORLD 3,497,290 100.00

Source: FAOSTAT

Vitamin D

Name Chemical composition Structure
Vitamin D2 ergocalciferol (made from ergosterol)
Vitamin D3 cholecalciferol (made from 7-dehydrocholesterol in the skin).

Mushrooms that have been exposed to ultraviolet (UV) light contain large amounts of vitamin D2.[19][20][21] Mushrooms, when exposed to UV light, convert ergosterol, a chemical found in large concentrations in many mushrooms, to vitamin D2. This is similar to the reaction in humans, where Vitamin D3 is synthesized after exposure to UV light.

Testing conducted by the Pennsylvania State University showed an hour of UV light exposure made a serving of mushrooms contain twice the U.S. Food and Drug Administration's daily recommendation of vitamin D. Testing by the Monterey Mushrooms Company demonstrated 5 minutes of UV light exposure made a serving of mushrooms contain four times the FDA's daily recommendation of vitamin D.[19] High performance liquid chromatography analysis has also demonstrated the effect sunlight has on mushroom vitamin D2 content.[22]

The ergocalciferol, vitamin D2, in UV-irradiated mushrooms is not the same form of vitamin D as is produced by UV-irradiation of human skin or animal skin, fur, or feathers (cholecalciferol, vitamin D3). Although vitamin D2 clearly has vitamin D activity in humans and formerly was widely used in milk fortification and in nutritional supplements, vitamin D3 is often used in dairy products.[23][24] However, any difference in vitamin D bioavailability from the two forms has been adequately disproved to allow reasonable assumption that D2 and D3 are equal for maintaining 25-hydroxyvitamin D status.[25]

Mushroom Sunlight exposure Vitamin D2 content (IU/100g)
Shiitake None 10 — 100
Shiitake Gills down 11,000
Shiitake Gills up 46,000
Reishi None 66
Reishi Pores up 2,760
Maitake None 460
Maitake Pores up 31,900

See also

Fungi portal
Food portal

References

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  2. ^ Arora D (1986). Mushrooms demystified. Ten Speed Press. p. 23. ISBN 0-89815-169-4. 
  3. ^ Mattila P, Suonpää K, Piironen V. (2000). "Functional properties of edible mushrooms". Nutrition 16 (7–8): 694–6. doi:10.1016/S0899-9007(00)00341-5. PMID 10906601. 
  4. ^ http://www.einstein.yu.edu/uploadedfiles/casadevall/2005/4.pdf
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  7. ^ John Fereira. "U.S. Mushroom Industry". Usda.mannlib.cornell.edu. http://usda.mannlib.cornell.edu/MannUsda/viewDocumentInfo.do?documentID=1395. Retrieved 2010-05-30. 
  8. ^ T. mesenterium was first reported in Great Britain after the wet August 2008 ((BBC News) " New fungi species unearthed in UK", 9 October 2008: accessed 9 October 2008.
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  10. ^ Arora, David. Mushrooms Demystified, 2nd ed. Ten Speed Press, 1986
  11. ^ FDA IMPORT ALERT IA2502
  12. ^ "Coriolus Versicolor". About Herbs, Botanicals & Other Products. Memorial Sloan-Kettering Cancer Center. http://www.mskcc.org/mskcc/html/69194.cfm. 
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  16. ^ Hobbs CJ. (1995). Medicinal Mushrooms: An Exploration of Tradition, Healing & Culture. Portland, Oregon: Culinary Arts Ltd. p. 20. ISBN 1-884360-01-7. 
  17. ^ Mabey, Richard (1984), Food for Free., Pub. Fontana / Collins. ISBN 0-00-633470-9. P. 54.
  18. ^ Barbee G, Berry-Cabán C, Barry J, Borys D, Ward J, Salyer S (2009). ECC1ED5314DF17993B4B357234FB1F8D?issue=20090502 "Analysis of mushroom exposures in Texas requiring hospitalization, 2005-2006". Journal of Medical Toxicology 5 (2): 59–62. doi:10.1007/BF03161087. PMID 19415588. http://jmt.pennpress.org/strands/jmt/toc.htm;jsessionid= ECC1ED5314DF17993B4B357234FB1F8D?issue=20090502. 
  19. ^ a b Bowerman S (March 31, 2008). "If mushrooms see the light". Los Angeles Times. http://articles.latimes.com/2008/mar/31/health/he-eat31. 
  20. ^ Koyyalamudi SR, Jeong SC, Song CH, Cho KY, Pang G (April 2009). "Vitamin D2 formation and bioavailability from Agaricus bisporus button mushrooms treated with ultraviolet irradiation". J Agric Food Chem 57 (8): 3351–5. doi:10.1021/jf803908q. PMID 19281276. 
  21. ^ Lee GS, Byun HS, Yoon KH, Lee JS, Choi KC, Jeung EB (March 2009). "Dietary calcium and vitamin D2 supplementation with enhanced Lentinula edodes improves osteoporosis-like symptoms and induces duodenal and renal active calcium transport gene expression in mice". Eur J Nutr 48 (2): 75–83. doi:10.1007/s00394-008-0763-2. PMID 19093162. 
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