Bean pods on a plant
Bean plant

A bean is the seed of several plants in the family Fabaceae, which are used as vegetables for human or animal food.[1] They can be cooked in many different ways,[2] including boiling, frying, and baking, and are used in many traditional dishes throughout the world.

Terminology

The word "bean" and its Germanic cognates (e.g. German Bohne) have existed in common use in West Germanic languages since before the 12th century,[3] referring to broad beans, chickpeas, and other pod-borne seeds. This was long before the New World genus Phaseolus was known in Europe. With the Columbian exchange of domestic plants between Europe and the Americas, use of the word was extended to pod-borne seeds of Phaseolus, such as the common bean and the runner bean, and the related genus Vigna. The term has long been applied generally to many other seeds of similar form,[3][4] such as Old World soybeans, peas, other vetches, and lupins, and even to those with slighter resemblances, such as coffee beans, vanilla beans, castor beans, and cocoa beans. Thus the term "bean" in general usage can refer to a host of different species.[5]

Seeds called "beans" are often included among the crops called "pulses" (legumes),[3] although the words are not always interchangeable (usage varies by plant variety and by region). Both terms, beans and pulses, are usually reserved for grain crops and thus exclude those legumes that have tiny seeds and are used exclusively for non-grain purposes (forage, hay, and silage), such as clover and alfalfa. The United Nations Food and Agriculture Organization defines "BEANS, DRY" (item code 176)[5] as applicable only to species of Phaseolus. This is one of various examples of how narrower word senses enforced in trade regulations or botany often coexist in natural language with broader senses in culinary use and general use; other common examples are the narrow sense of the word nut and the broader sense of the word nut, and the fact that tomatoes are fruit, botanically speaking, but are often treated as vegetables in culinary and general usage. Relatedly, another detail of usage is that several species of plants that are sometimes called beans, including Vigna angularis (azuki bean), mungo (black gram), radiata (green gram), and aconitifolia (moth bean), were once classified as Phaseolus but later reclassified—but the taxonomic revision does not entirely stop the use of well-established senses in general usage.

Cultivation

Vicia faba ready for harvest

Unlike the closely related pea, beans are a summer crop that needs warm temperatures to grow. Legumes are capable of nitrogen fixation and hence need less fertiliser than most plants. Maturity is typically 55–60 days from planting to harvest.[6] As the bean pods mature, they turn yellow and dry up, and the beans inside change from green to their mature colour. Many beans are vines, as such the plants need external support, which may take the form of special "bean cages" or poles. Native Americans customarily grew them along with corn and squash (the so-called Three Sisters),[7] with the tall cornstalks acting as support for the beans.

In more recent times, the so-called "bush bean" has been developed which does not require support and has all its pods develop simultaneously (as opposed to pole beans which develop gradually).[8] This makes the bush bean more practical for commercial production.

History

Acacia farnesiana Beans in a pod
Baked beans on toast (with egg)

Beans were an important source of protein throughout Old and New World history, and still are today.

Beans are one of the longest-cultivated plants in history. Broad beans, also called fava beans, are in their wild state the size of a small fingernail, and were first gathered in Afghanistan and the Himalayan foothills.[9] An early cultivated form were grown in Thailand from the early seventh millennium BCE, predating ceramics.[10] Beans were deposited with the dead in ancient Egypt. Not until the second millennium BCE did cultivated, large-seeded broad beans appear in the Aegean region, Iberia, and transalpine Europe.[11] In the Iliad (8th century BCE), there is a passing mention of beans and chickpeas cast on the threshing floor.[12]

The oldest-known domesticated beans in the Americas were found in Guitarrero Cave, an archaeological site in Peru, and dated to around the second millennium BCE.[13] However, genetic analyses of the common bean Phaseolus show that it originated in Mesoamerica, and subsequently spread southward, along with maize and squash, traditional companion crops.[14]

Most of the kinds of beans commonly eaten today are part of the genus Phaseolus, which originated in the Americas. The first European to encounter them was Christopher Columbus, while exploring what may have been the Bahamas, and saw them growing in fields. Five kinds of Phaseolus beans were domesticated[15] by pre-Columbian peoples: common beans (P. vulgaris) grown from Chile to the northern part of what is now the United States; and lima and sieva beans (P. lunatus); as well as the less widely distributed teparies (P. acutifolius), scarlet runner beans (P. coccineus), and polyanthus beans.[16]

One well-documented use of beans by pre-Columbian people as far north as the Atlantic seaboard is the "Three Sisters" method of companion plant cultivation: Many tribes would grow beans together with maize (corn), and squash. The corn would not be planted in rows as is done by European agriculture, but in a checkerboard/hex fashion across a field, in separate patches of one to six stalks each. Beans would be planted around the base of the developing stalks, and would vine their way up as the stalks grew. All American beans at that time were vine plants; "bush beans" were cultivated more recently. The cornstalks would work as a trellis for the bean plants, and the beans would provide much-needed nitrogen for the corn. Squash would be planted in the spaces between the patches of corn in the field. They would be provided slight shelter from the sun by the corn, would shade the soil and reduce evaporation, and would deter many animals from attacking the corn and beans because their coarse, hairy vines and broad, stiff leaves are difficult or uncomfortable for animals such as deer and raccoons to walk through, crows to land on, and are a deterrent to other animals as well.

Beans were cultivated across Chile in Pre-Hispanic times, likely as far south as Chiloé Archipelago.[17]

Dry beans come from both Old World varieties of broad beans (fava beans) and New World varieties (kidney, black, cranberry, pinto, navy/haricot).

Common genera and species

Types of beans in a market
Market

Most of the foods we call "beans", "legumes", "lentils" and "pulses" belong to the same family, Fabaceae ("leguminous" plants), but are from different genera and species, native to different homelands and distributed worldwide depending on their adaptability.[18] Many varieties are eaten both fresh (the whole pod, and the immature beans may or may not be inside) or shelled (immature seeds, mature and fresh seeds, or mature and dried seeds). Numerous legumes look similar, and have become naturalized in locations across the world, which often lead to similar names for different species.

Genus Species and Common Varieties Probable Homeland Distribution, Cultivation and Climate Notes
Phaseolus P. vulgaris: Kidney Bean, Pinto Bean, Navy Bean (Cannellini, Haricot Beans/French Beans/Pole Beans/Bush Beans), Black Beans, Borlotti Beans

P. lunatus: Lima Beans

P. coccineus: Runner Beans, Flat Beans

P. acutifolius: Tepary Bean

The Americas Tropical, Subtropical, Warm Temperate Certain varieties contain high levels of toxic phytohemagglutinin. Requires soaking and then cooking at or above 100C for a minimum of 30 minutes, and ideally much longer.[19][20][21]
Pisum P. sativum: Green Peas/Garden Peas, White Peas, Yellow Peas, Field Peas, Snow Peas, Snap Peas Mediterranean Subtropical, Temperate, Occasionally Cool Tropical
Vigna V. radiata: Mung Bean

V. mungo: Urad

V. unguiculata (Cowpeas): Yardlong bean, Black-eyed Peas

V. aconitifolia: Moth bean

V. angularis: Adzuki beans

Mostly South Asia Equatorial, Pantropical, Warm Subtropical, Hot Temperate
Cajanus C. cajan: Pigeon Pea Indian Subcontinent Pantropical, Equatorial
Lens L. culinaris (Lentils): Red Lentil, Green Lentil, Puy Lentil Near East/Levant Temperate, Subtropical, Cool Tropical
Cicer C. arietinum: Chickpeas (Garbanzo Beans) Turkey/Levant/Near East Temperate, Subtropical, Cool Tropical
Vicia V. faba: Fava Beans (Broad Beans)

V. ervilia: Bitter vetch

V. sativa: Common vetch

Near East Subtropical, Temperate Causes Favism in those susceptible.[22][23]
Arachis A. hypogaea: Peanut (Groundnut) South America Warm Subtropical, Cool Tropical
Glycine G. max: Soybean East Asia Hot Temperate, Subtropical, Cool Tropical
Macrotyloma M. uniflorum: Horsegram South Asia Tropical, Subtropical
Mucuna M. pruriens: Velvet Bean Tropical Asia and Africa Tropical, Warm Subtropical Contains L-DOPA,[24] and smaller amounts of other psychoactive compounds. Can also cause itching and rashes on contact.
Lupinus L. albus: White Lupin

L. mutabilis: Tarwi/Andean Lupin

The Mediterranean, Balkans, Levant (albinus), The Andes (mutabilis) Subtropical, Temperate Requires prolonged soaking in the correct way to reduce toxic compounds.[25]
Ceratonia C. siliqua: Carob bean Mediterranean, Middle East Subtropical, Arid Subtropical, Hot Temperate
Canavalia C. gladiata: Sword Bean

C. ensiformis: Jack Beans

South Asia or Africa (C. gladiata), Brazil and South America (C. Ensiformis) Tropical
Cyamopsis C. tetragonoloba: Guar Bean Africa or South Asia Tropical, Semi-Arid Source of Guar gum
Lablab L. purpureus: Hyacinth Bean/Lablab Bean South Asia, Indian Subcontinent or Africa Tropical
Psophocarpus P. tetranoglobulus: Winged Bean New Guinea Tropical, Equatorial
Clitoria C. ternatea: Butterfly Pea Equatorial and Tropical Asia Tropical, Subtropical Flowers used as a natural food colouring
Lathyrus L. sativus: Grass Pea

L. tuberosus: Tuberous Pea

Balkans, India or Asia Subtropical Can cause Lathyrism if used as staple.[26][27]
Trifolium T. repens: White Clover

T. pratense: Red Clover

Europe and Central Asia Subtropical, Temperate
Medicago M. sativa: Alfalfa Central Asia Subtropical, Temperate
Melilotus M. officinalis: Sweet Clover Europe and Central Asia Subtropical, Temperate Contains Coumarins, an important class of perfume ingredients. Coumarin is also a blood thinner.
Tamarindus T. indica: Tamarind Africa Tropical, Subtropical

Bean seed storage

As of 2023, the Norwegian Svalbard Global Seed Vault holds more than 40,000 accessions of Phaseolus bean species.[28]

Properties

Nutrition

Green beans, raw
Nutritional value per 100 g (3.5 oz)
Energy31 kcal (130 kJ)
6.97 g
Sugars3.26 g
Dietary fiber2.7 g
0.22 g
1.83 g
VitaminsQuantity
%DV
Thiamine (B1)
7%
0.082 mg
Riboflavin (B2)
9%
0.104 mg
Niacin (B3)
5%
0.734 mg
Vitamin B6
11%
0.141 mg
Folate (B9)
8%
33 μg
Vitamin C
15%
12.2 mg
MineralsQuantity
%DV
Calcium
4%
37 mg
Iron
8%
1.03 mg
Magnesium
7%
25 mg
Phosphorus
5%
38 mg
Potassium
4%
211 mg
Sodium
0%
6 mg
Zinc
3%
0.24 mg
Other constituentsQuantity
Water90.3 g

Percentages are roughly approximated using US recommendations for adults.

Raw green beans are 90% water, 7% carbohydrates, 2% protein, and contain negligible fat (table). In a 100 grams (3.5 oz) reference serving, raw green beans supply 31 calories of food energy, and are a moderate source (10-19% of the Daily Value, DV) of vitamin C (15% DV) and vitamin B6 (11% DV), with no other micronutrients in significant content (table).

Antinutrients

Many types of bean like kidney bean contain significant amounts of antinutrients that inhibit some enzyme processes in the body. Phytic acid and phytates, present in grains, nuts, seeds and beans, interfere with bone growth and interrupt vitamin D metabolism. Pioneering work on the effect of phytic acid was done by Edward Mellanby from 1939.[29][30]

Health concerns

Toxins

Some kinds of raw beans contain a harmful, tasteless toxin: the lectin phytohaemagglutinin, which must be removed by cooking. Red kidney beans are particularly toxic, but other types also pose risks of food poisoning. Many types of beans contain lectins, and kidney beans have the highest concentrations – especially red kidney beans. As few as 4 or 5 raw beans can cause severe stomachache, vomiting and diarrhoea.[31] A recommended method is to boil the beans for at least ten minutes; under-cooked beans may be more toxic than raw beans.[32]

Cooking beans, without bringing them to a boil, in a slow cooker at a temperature well below boiling may not destroy toxins.[32] A case of poisoning by butter beans used to make falafel was reported; the beans were used instead of traditional broad beans or chickpeas, soaked and ground without boiling, made into patties, and shallow fried.[33]

Bean poisoning is not well known in the medical community, and many cases may be misdiagnosed or never reported; figures appear not to be available. In the case of the UK National Poisons Information Service, available only to health professionals, the dangers of beans other than red beans were not flagged as of 2008.[33]

Fermentation is used in some parts of Africa to improve the nutritional value of beans by removing toxins. Inexpensive fermentation improves the nutritional impact of flour from dry beans and improves digestibility, according to research co-authored by Emire Shimelis, from the Food Engineering Program at Addis Ababa University.[34] Beans are a major source of dietary protein in Kenya, Malawi, Tanzania, Uganda and Zambia.[35]

Bacterial infection from bean sprouts

It is common to make beansprouts by letting some types of bean, often mung beans, germinate in moist and warm conditions; beansprouts may be used as ingredients in cooked dishes, or eaten raw or lightly cooked. There have been many outbreaks of disease from bacterial contamination, often by salmonella, listeria, and Escherichia coli, of beansprouts not thoroughly cooked,[36] some causing significant mortality.[37]

Flatulence

Many edible beans, including broad beans, navy beans, kidney beans and soybeans, contain oligosaccharides (particularly raffinose and stachyose), a type of sugar molecule also found in cabbage. An anti-oligosaccharide enzyme is necessary to properly digest these sugar molecules. As a normal human digestive tract does not contain any anti-oligosaccharide enzymes, consumed oligosaccharides are typically digested by bacteria in the large intestine. This digestion process produces gases, such as methane as a byproduct, which are then released as flatulence.[38][39][40][41]

Production

The production data for legumes are published by FAO in three categories:

  1. Pulses dry: all mature and dry seeds of leguminous plants except soybeans and groundnuts.
  2. Oil crops: soybeans and groundnuts.
  3. Fresh vegetable: immature green fresh fruits of leguminous plants.

The following is a summary of FAO data.[42]

Production of legumes (million metric tons)
Crops
[FAO code][43]
1961 1981 2001 2015 2016 Ratio
2016 /1961
Remarks
Total pulses (dry) [1726] 40.78 41.63 56.23 77.57 81.80 2.01 Per capita production had decreased.
(Population increase was 2.4×)
Oil crops (dry)
Soybeans [236] 26.88 88.53 177.02 323.20 334.89 12.46 Drastic increase driven by the demand for animal feeds and oil.
Groundnuts, with shell [242] 14.13 20.58 35.82 45.08 43.98 3.11
Fresh vegetables (80–90% water)
Beans, green [414] 2.63 4.09 10.92 23.12 23.60 8.96
Peas, green [417] 3.79 5.66 12.41 19.44 19.88 5.25

Main crops of "Pulses, Total (dry)" are "Beans, dry [176]" 26.83 million tons, "Peas, dry [187]" 14.36 million tons, "Chick peas [191]" 12.09 million tons, "Cow peas [195]" 6.99 million tons, "Lentils [201]" 6.32 million tons, "Pigeon peas [197]" 4.49 million tons, "Broad beans, horse beans [181]" 4.46 million tons. In general, the consumption of pulses per capita has been decreasing since 1961. Exceptions are lentils and cowpeas.

Top producers, pulses, total [1726][44]
(million metric tons)
Country 2016 Share Remarks
Total 81.80 100%
1 India 17.56 21.47%
2 Canada 8.20 10.03%
3 Myanmar 6.57 8.03%
4 China 4.23 5.17%
5 Nigeria 3.09 3.78%
6 Russia 2.94 3.60%
7 Ethiopia 2.73 3.34%
8 Brazil 2.62 3.21%
9 Australia 2.52 3.09%
10 USA 2.44 2.98%
11 Niger 2.06 2.51%
12 Tanzania 2.00 2.45%
Others 24.82 30.34%

The world leader in production of dry beans (Phaseolus spp),[45] is India, followed by Myanmar (Burma) and Brazil. In Africa, the most important producer is Tanzania.[46]

Top ten dry beans (Phaseolus spp) producers, 2020
Country Production
(tonnes)
Footnote
 India5,460,000F
 Myanmar3,053,012
 Brazil3,035,290A
 United States1,495,180*
 China1,281,586
 Tanzania1,267,648F
 Mexico1,056,071
 Kenya774,366F
 Argentina633,823*
 Uganda603,980
 World27,545,942A

No symbol = official figure, P = official figure, F = FAO estimate, * = unofficial/semi-official/mirror data, C = calculated figure A = aggregate (may include official, semi-official or estimates)

Source: UN Food and Agriculture Organization (FAO)[47]

See also

References

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  2. Clark, Mellisa. "How to Cook Beans". New York Times Cooking. Retrieved 3 January 2020.
  3. 1 2 3 Merriam-Webster, Merriam-Webster's Collegiate Dictionary, Merriam-Webster, archived from the original on 10 October 2020, retrieved 3 May 2016
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  5. 1 2 "Definition And Classification Of Commodities (See Chapter 4)". FAO, United Nations. 1994. Archived from the original on 12 October 2018. Retrieved 5 July 2012.
  6. Shurtleff, William; Aoyagi, Akiko (1 October 2013). Early Named Soybean Varieties in the United States and Canada: Extensively Annotated Bibliography and Sourcebook. Soyinfo Center. ISBN 9781928914600. Retrieved 18 November 2017 via Google Books.
  7. Schneider, Meg. New York Yesterday & Today. Voyageur Press. ISBN 9781616731267. Retrieved 18 November 2017 via Google Books.
  8. "The Germination Of a Bean" (PDF). Microscopy-uk.org.uk. Archived (PDF) from the original on 9 October 2022. Retrieved 18 November 2017.
  9. Kaplan, pp. 27 ff
  10. Gorman, CF (1969). "Hoabinhian: A pebble-tool complex with early plant associations in southeast Asia". Science. 163 (3868): 671–3. Bibcode:1969Sci...163..671G. doi:10.1126/science.163.3868.671. PMID 17742735. S2CID 34052655.
  11. Daniel Zohary and Maria Hopf Domestication of Plants in the Old World Oxford University Press, 2012, ISBN 0199549060, p. 114.
  12. "And as in some great threshing-floor go leaping From a broad pan the black-skinned beans or peas." (Iliad xiii, 589).
  13. Chazan, Michael (2008). World Prehistory and Archaeology: Pathways through Time. Pearson Education, Inc. ISBN 978-0-205-40621-0.
  14. Bitocchi, Elena; Nanni, Laura; Bellucci, Elisa; Rossi, Monica; Giardini, Alessandro; Zeuli, Pierluigi Spagnoletti; Logozzo, Giuseppina; Stougaard, Jens; McClean, Phillip; Attene, Giovanna; Papa, Roberto (3 April 2012). "Mesoamerican origin of the common bean (Phaseolus vulgaris L.) is revealed by sequence data". Proceedings of the National Academy of Sciences. 109 (14): E788–E796. doi:10.1073/pnas.1108973109. PMC 3325731. PMID 22393017.
  15. Kaplan, p. 30: Domestication, besides involving selection for larger seed size, also involved selection for pods that did not curl and open when ripe, scattering the beans they contained.
  16. Kaplan, p. 30
  17. Pardo B., Oriana; Pizarro, José Luis (2014). Chile: Plantas alimentarias Prehispánicas (in Spanish) (2015 ed.). Arica, Chile: Ediciones Parina. p. 162. ISBN 9789569120022.
  18. Boston, 677 Huntington Avenue; Ma 02115 +1495‑1000 (28 October 2019). "Legumes and Pulses". The Nutrition Source. Retrieved 7 April 2022.{{cite web}}: CS1 maint: numeric names: authors list (link)
  19. Nyombaire, G.; Siddiq, M.; Dolan, K. (2007). "Effect of soaking and cooking on the oligosaccharides and lectins of red kidney beans (Phaseolus vulgaris L.)". Annual Report. ISSN 0084-7747.
  20. Nciri, Nader; Cho, Namjun (15 December 2017). "New research highlights: Impact of chronic ingestion of white kidney beans (Phaseolus vulgaris L. var. Beldia) on small-intestinal disaccharidase activity in Wistar rats". Toxicology Reports. 5: 46–55. doi:10.1016/j.toxrep.2017.12.016. ISSN 2214-7500. PMC 5735304. PMID 29270365.
  21. Sun, Yufeng; Liu, Jiameng; Huang, Yatao; Li, Minmin; Lu, Jia; Jin, Nuo; He, Yan; Fan, Bei (1 January 2019). "Phytohemagglutinin content in fresh kidney bean in China". International Journal of Food Properties. 22 (1): 405–413. doi:10.1080/10942912.2019.1590399. ISSN 1094-2912.
  22. Belsey, Mark A. (1973). "The epidemiology of favism". Bulletin of the World Health Organization. 48 (1): 1–13. ISSN 0042-9686. PMC 2481045. PMID 4541143.
  23. Tarhani, Fariba; Nezami, Alireza; Heidari, Ghobad; Abdolkarimi, Babak (18 August 2020). "Clinical Manifestations and Therapeutic Findings of the Children with Glucose-6-Phosphate Dehydrogenase Deficiency Presenting Favism". Endocrine, Metabolic & Immune Disorders Drug Targets. 21 (6): 1125–1129. doi:10.2174/1871530320999200818182905. ISSN 2212-3873. PMID 32811422. S2CID 221182334.
  24. Raina, Archana P.; Khatri, Renu (2011). "Quantitative Determination of L-DOPA in Seeds of Mucuna Pruriens Germplasm by High Performance Thin Layer Chromatography". Indian Journal of Pharmaceutical Sciences. 73 (4): 459–462. doi:10.4103/0250-474X.95651 (inactive 11 November 2023). ISSN 0250-474X. PMC 3374567. PMID 22707835.{{cite journal}}: CS1 maint: DOI inactive as of November 2023 (link)
  25. Schrenk, Dieter; Bodin, Laurent; Chipman, James Kevin; del Mazo, Jesús; Grasl‐Kraupp, Bettina; Hogstrand, Christer; Hoogenboom, Laurentius (Ron); Leblanc, Jean‐Charles; Nebbia, Carlo Stefano; Nielsen, Elsa; Ntzani, Evangelia (5 November 2019). "Scientific opinion on the risks for animal and human health related to the presence of quinolizidine alkaloids in feed and food, in particular in lupins and lupin‐derived products". EFSA Journal. 17 (11): e05860. doi:10.2903/j.efsa.2019.5860. ISSN 1831-4732. PMC 7008800. PMID 32626161.
  26. Haque, A.; Hossain, M.; Wouters, G.; Lambein, F. (1996). "Epidemiological Study of Lathyrism in Northwestern Districts of Bangladesh". Neuroepidemiology. 15 (2): 83–91. doi:10.1159/000109893. ISSN 0251-5350. PMID 8684587.
  27. Jahan, K.; Ahmad, K. (February 1993). "Studies on neurolathyrism". Environmental Research. 60 (2): 259–266. Bibcode:1993ER.....60..259J. doi:10.1006/enrs.1993.1035. ISSN 0013-9351. PMID 8472656.
  28. "The seeds". Svalbard Global Seed Vault, Norwegian Ministry of Agriculture and Food. 2023. Retrieved 5 November 2023.
  29. Harrison, DC; Mellanby, E (October 1939). "Phytic acid and the rickets-producing action of cereals". Biochem. J. 33 (10): 1660–1680.1. doi:10.1042/bj0331660. PMC 1264631. PMID 16747083.
  30. Ramiel Nagel (26 March 2010). "Living With Phytic Acid - Weston A Price". The Weston A Price Foundation. Retrieved 23 January 2016.
  31. "Natural toxins in food". www.who.int. Retrieved 7 April 2022.
  32. 1 2 "Foodborne Pathogenic Microorganisms and Natural Toxins Handbook: Phytohaemagglutinin". Bad Bug Book. United States Food and Drug Administration. Archived from the original on 9 July 2009. Retrieved 11 July 2009.
  33. 1 2 Vicky Jones (15 September 2008). "Beware of the beans: How beans can be a surprising source of food poisoning". The Independent. Retrieved 23 January 2016.
  34. Shimelis, Emire Admassu; Rakshit, Sudip Kumar (2008). "Influence of natural and controlled fermentations on α-galactosides, antinutrients and protein digestibility of beans (Phaseolus vulgaris L.)". International Journal of Food Science & Technology. 43 (4): 658–665. doi:10.1111/j.1365-2621.2006.01506.x. ISSN 1365-2621.
  35. Summary: Fermentation 'improves nutritional value of beans' Archived 22 May 2013 at the Wayback Machine (Sub Saharan Africa page, Science and Development Network website). Paper: Influence of natural and controlled fermentations on α-galactosides, antinutrients and protein digestibility of beans (Phaseolus vulgaris L.)
  36. "Sprouts: What You Should Know". Foodsafety.gov. Retrieved 23 January 2016.
  37. "Shiga toxin-producing E. coli (STEC): Update on outbreak in the EU (27 July 2011, 11:00)". European Centre for Disease Prevention and Control. 27 July 2011. Archived from the original on 15 March 2017.
  38. "Health | Experts make flatulence-free bean". BBC News. 25 April 2006. Archived from the original on 31 March 2009. Retrieved 25 February 2009.
  39. "Flatulence – Overview – Introduction". Nhs.uk. Archived from the original on 21 February 2009. Retrieved 25 February 2009.
  40. Harold McGee (2003). Food and Cooking. Simon & Schuster. p. 486. ISBN 978-0684843285. Many legumes, especially soy, navy and lima beans, cause a sudden increase in bacterial activity and gas production a few hours after they're consumed. This is because they contain large amounts of carbohydrates that human digestive enzymes can't convert into absorbable sugars. These carbohydrates therefore leave the upper intestine unchanged and enter the lower reaches, where our resident bacterial population does the job we are unable to do.
  41. Peter Barham (2001). The Science of Cooking. Springer. p. 14. ISBN 978-3-540-67466-5. we do not possess any enzymes that are capable of breaking down larger sugars, such as raffinose etc. These 3, 4 and 5 ring sugars are made by plants especially as part of the energy storage system in seeds and beans. If these sugars are ingested, they can't be broken down in the intestines; rather, they travel into the colon, where various bacteria digest them – and in the process produce copious amounts of carbon dioxide gas
  42. FAO STAT Production/Crops.
  43. See Legume § Classification.
  44. All legumes dry.
  45. Dry beans does not include broad beans, dry peas, chickpea, lentil.
  46. FAO Pulses and Derived Products Archived 7 December 2015 at the Wayback Machine.
  47. "Major Food And Agricultural Commodities And Producers – Countries By Commodity". Fao.org. Archived from the original on 6 September 2015. Retrieved 2 February 2015.

Bibliography

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