|White and green varieties|
The garbanzo bean or just garbanzo (Cicer arietinum) is a legume of the family Fabaceae, subfamily Faboideae. It is also known as chickpea or chick pea, gram or Bengal gram, and is sometimes known as Egyptian pea, ceci, cece or chana, or Kabuli chana (particularly in northern India). Its seeds are high in protein. It is one of the earliest cultivated legumes: 7,500-year-old remains have been found in the Middle East.
- 1 Etymology
- 2 History
- 3 Description
- 4 Uses
- 5 Nutrition
- 6 Production
- 7 Pathogens
- 8 References
- 9 External links
The word garbanzo came first to American English as garvance in the 17th century, from an alteration of the Old Spanish word arvanço (presumably influenced by garroba), being gradually anglicized to calavance, though it came to refer to a variety of other beans (cf. calavance). The current form garbanzo comes directly from modern Spanish. This word is still used in Latin America and Spain to designate chickpeas. Some have suggested that the origin of the word arvanço is in the Greek erebinthos. Another possible origin is the word garbantzu, from Basque — a non-Indo-European tongue — in which it is a compound of garau, seed + antzu, dry.
The name chickpea traces back through the French chiche to cicer, Latin for 'chickpea' (from which the Roman cognomen Cicero was taken). The Oxford English Dictionary lists a 1548 citation that reads, "Cicer may be named in English Cich, or ciche pease, after the Frenche tongue." The dictionary cites "Chick-pea" in the mid-18th century; the original word in English taken directly from French was chich, found in print in English in 1388.
Domesticated garbanzo beans have been found in the aceramic levels of Jericho (PPNB) along with Çayönü in Turkey and in Neolithic pottery at Hacilar, Turkey. They were found in the late Neolithic (about 3500 BC) at Thessaly, Kastanas, Lerna and Dimini, Greece. In southern France, Mesolithic layers in a cave at L'Abeurador, Aude, have yielded wild garbanzo beans carbon dated to 6790±90 BC.
Garbanzo beans are mentioned in Charlemagne's Capitulare de villis (about AD 800) as cicer italicum, as grown in each imperial demesne. Albertus Magnus mentions red, white, and black varieties. Nicholas Culpeper noted "chick-pease or cicers" are less "windy" than peas and more nourishing. Ancient people also associated garbanzo beans with Venus because they were said to offer medical uses such as increasing sperm and milk, provoking menstruation and urine, and helping to treat kidney stones. "White cicers" were thought to be especially strong and helpful.
In 1793, ground-roast garbanzo beans were noted by a German writer as a substitute for coffee in Europe. In the First World War, they were grown for this use in some areas of Germany. They are still sometimes brewed instead of coffee.
Sequencing of the garbanzo bean genome has been completed for 90 garbanzo bean genotypes, including several wild species. A collaboration of 20 research organizations, led by the International Crops Research Institute for the Semi-Arid Tropics (ICRISAT) identified more than 28,000 genes and several million genetic markers. Scientists expect this work will lead to the development of superior cultivars, among which 77 have already been released to farmers around the world.
The new research will benefit the millions of developing country farmers who grow garbanzo beans as a source of much needed income, as well as for its ability to add nitrogen to the soil in which it grows. Production is growing rapidly across the developing world, especially in West Asia, where it has increased four-fold over the past 30 years. India is by far the world largest producer, but is also the largest importer.
The plant grows to 20–50 cm (8–20 in) high and has small, feathery leaves on either side of the stem. Garbanzo beans are a type of pulse, with one seedpod containing two or three peas. It has white flowers with blue, violet, or pink veins.
The three main kinds of garbanzo beans are:
'Desi' has small, darker seeds and a rough coat. It is grown mostly in India and other parts of the Indian subcontinent, as well as in Ethiopia, Mexico, and Iran. Desi means 'country' or 'local' in Hindustani; its other names include Bengal gram or kala chana ("black chickpea" in both Hindi and Urdu) or chhola boot. 'Desi' is probably the earliest variety because it closely resembles seeds found both on archaeological sites and the wild plant ancestor Cicer reticulatum of domesticated garbanzo beans, which only grows in southeast Turkey, where it is believed to have originated. 'Desi' chickpeas have a markedly higher fibre content than other varieties, hence a very low glycemic index, which may make them suitable for people with blood sugar problems. The 'Desi' type is used to make chana dal, which is a split garbanzo bean with the skin removed.
Bombay garbanzo beans ('Bambai') are also dark but slightly larger than 'Desi'. They, too, are popular in the Indian subcontinent.
'Kabuli' is lighter-coloured, larger, and with a smoother coat, and is mainly grown in the Mediterranean, Southern Europe, Northern Africa, South America, and the Indian subcontinent. The name means "from Kabul" in Hindi and Urdu, and this variety was thought to come from Kabul, Afghanistan when it was introduced to India in the 18th century. It is called Kabuli chana (काबुली चणा) in Marathi and safed chana in India.
An uncommon black garbanzo bean, ceci neri, is grown only in Apulia, in southeastern Italy. It is larger and darker than the 'Desi' variety.
Green garbanzo beans are common in the state of Maharashtra, India. In Marathi, they are called harbhara (हरभरा). Chana dal is also called harbara dal (हरभरा डाळ). Tender, immature harbara roasted on coal before the skin is removed is called hula (हुळा) in Marathi.
Chickpeas are usually rapidly boiled for 10 minutes and then simmered for a longer period. Dried chickpeas need a long cooking time (1–2 hours) but will easily fall apart when cooked longer. If soaked for 12–24 hours before use, cooking time can be shortened by around 30 minutes. Chickpeas can also be pressure cooked or sous vide cooked at 90 °C (194 °F). Chickpeas (Cicer arietinum) do not cause lathyrism. Similarly named "chickling peas" (Lathyrus sativus) and other plants of the genus Lathyrus contain the toxins associated with lathyrism.
Mature chickpeas can be cooked and eaten cold in salads, cooked in stews, ground into gram flour (also known as chickpea flour and besan and used frequently in Indian cuisine), ground and shaped in balls and fried as falafel, or stirred into a batter and baked to make farinata or panelle.
Chickpeas are popular in the Iberian Peninsula. In Portugal, they are one of the main ingredients in rancho, eaten with pasta and meat, including Portuguese sausages, or with rice. They are used in other hot dishes with bacalhau and in soup. In Spain, they are used cold in tapas and salads, as well as in cocido madrileño. In Italy, chickpeas are eaten with pasta or in soup. In the southern regions such as Sicily, grounded chickpeas flour is used to produce a famous local street food called panelle. In Egypt, they are used as a topping for kushari.
Hummus is the Arabic word for chickpeas, which are often cooked and ground into a paste and mixed with tahini (sesame seed paste), the blend called hummus bi tahini, or chickpeas are roasted, spiced, and eaten as a snack, such as leblebi. By the end of the 20th century, hummus had become commonplace in American cuisine. By 2010, 5% of Americans consumed hummus on a regular basis, and it was present in 17% of American households.
Some varieties of chickpeas can be popped and eaten like popcorn.
Chickpeas and Bengal grams are used to make curries and are one of the most popular vegetarian foods in the Indian subcontinent and in diaspora communities of many other countries. Popular dishes in Indian cuisine are made with chickpea flour, such as mirchi bajji and mirapakaya bajji Telugu. In India, as well as in the Levant, unripe chickpeas are often picked out of the pod and eaten as a raw snack and the leaves are eaten as a leaf vegetable in salads.
Chickpea flour is used to make "Burmese tofu" which was first known among the Shan people of Burma. In Punjabi cuisine the flour (besan) is used as a batter to coat vegetables before deep frying to make pakoras. The flour is also used as a batter to coat vegetables and meats before frying, such as with panelle, a chickpea fritter from Sicily. Chickpea flour is used to make the Mediterranean flatbread socca and a patty called panisse in Provence, southern France. It is made of cooked chickpea flour, poured into saucers, allowed to set, cut in strips, and fried in olive oil, often eaten during Lent.
In the Philippines, garbanzo beans preserved in syrup are eaten as sweets and in desserts such as halo-halo. Ashkenazi Jews traditionally serve whole chickpeas at a Shalom Zachar celebration for baby boys.
Guasanas are a Mexican chickpea recipe in which the beans are cooked in water and salt.
Chana masala, India
Raw chickpeas have a lower trypsin and chymotrypsin inhibitor content than peas, common beans, and soybeans. This leads to higher nutrition values and fewer digestive problems in nonruminants. Nonruminant diets can be completed with 200 g/kg of raw chickpeas to promote egg production and growth of birds and pigs. Higher amounts can be used when chickpeas are treated with heat.
Experiments have shown that ruminants grow equally well and produce an equal amount and quality of milk when soybean or cereal meals are replaced with chickpeas. Pigs show the same performance, but growing pigs experience a negative effect of raw chickpea feed; extruded chickpeas can increase performance even in growing pigs. In poultry diet experiments with untreated chickpeas, only young broilers (starting period) showed worse performance. Fish performed equally well when their soybean or cereal diet was replaced by extruded chickpeas.
Secondary components of legumes — such as lecithin, polyphenols, oligosaccharides, and amylase, protease, trypsin and chymotrypsin inhibitors — can lead to lower nutrient availability, thus to negative effects in growth and health of animals (especially in nonruminants). Ruminants have generally less problems to digest legumes with secondary components, since they can inactivate them in the rumen liquor. Their diets can be supplemented by 300 g/kg or more raw chickpea seeds. However, protein digestibility and energy availability can be improved through treatments, such as germination, dehulling, and heat. Extrusion is a very good heat technique to destroy secondary components in legumes, since the proteins are irreversibly denatured. Overprocessing may decrease the nutritional value; extrusion leads to losses in minerals and vitamins, while dry heating does not change the chemical composition.
|Nutritional value per 100 g (3.5 oz)|
|Energy||686 kJ (164 kcal)|
|Dietary fibre||7.6 g|
|Vitamin A equiv.||
|Pantothenic acid (B5)||
|Percentages are roughly approximated using US recommendations for adults.
Source: USDA Nutrient Database
Chickpeas are a nutrient-dense food, providing rich content (> 20% of the Daily Value, DV) of protein, dietary fibre, folate, and certain dietary minerals such as iron and phosphorus. Thiamin, vitamin B6, magnesium, and zinc contents are moderate, providing 10-16% of the DV. Chickpeas have a Protein Digestibility Corrected Amino Acid Score of about 0.76, which is higher than many other legumes and cereals.
Compared to reference levels established by the United Nations Food and Agricultural Organization and World Health Organization, proteins in cooked and germinated chickpeas are rich in essential amino acids such as lysine, isoleucine, tryptophan, and total aromatic amino acids.
A 100-g serving of cooked chickpeas provides 164 kilocalories (690 kJ). Carbohydrates make up 68% of calories, most of which (84%) is starch, followed by total sugars and dietary fibre. Lipid content is 3%, 75% of which is unsaturated fatty acids for which linoleic acid comprises 43% of total fat.
Effects of cooking
Cooking treatments do not lead to variance in total protein and carbohydrate content. Soaking and cooking of dry seeds possibly induces chemical modification of protein-fibre complexes, which leads to an increase in crude fibre content. Thus, cooking can increase protein quality by inactivating or destroying heat-labile antinutritional factors. Cooking also increases protein digestibility, essential amino acid index, and protein efficiency ratio. Although cooking lowers concentrations of amino acids such as tryptophan, lysine, total aromatic, and sulphur-containing amino acids, their contents are still higher than proposed by the FAO/WHO reference. Diffusion of reducing sugars, raffinose, sucrose and others into cooking water reduces or completely removes these components. Cooking also significantly reduces fat and mineral contents. The B vitamins riboflavin, thiamin, niacin, and pyridoxine dissolve into cooking water at differing rates.
Germination of chickpeas improves protein digestibility, although at a lower level than cooking. Germination degrades proteins to simple peptides, so improves crude protein, nonprotein nitrogen, and crude fiber content. Germination decreases lysine, tryptophan, sulphur and total aromatic amino acids, but most contents are still higher than proposed by the FAO/WHO reference pattern.
Oligosaccharides, such as stachyose and raffinose, are reduced in higher amounts during germination than during cooking. Minerals and B vitamins are retained more effectively during germination than with cooking. Phytic acids are reduced significantly, but trypsin inhibitor, tannin, and saponin reduction is less effective than cooking.
Autoclaving, microwave cooking, boiling
Protein digestibility is improved by all treatments of cooking. Essential amino acids are slightly increased by boiling and microwave cooking when compared to autoclaving and germination. Overall, microwave cooking leads to a significantly lower loss of nutrients compared to autoclaving and boiling.
Finally, all treatments lead to an improved protein digestibility, protein efficiency ratio, and essential amino acid index. Microwave cooking seems to be an effective method to prepare chickpeas because of its improvement of nutritional values and its lower cooking time.
Malnutrition and insufficient micronutrient supply have been reported in many regions where chickpeas are a major part of the diet. However, this nutritional lack is not due to the consumption of chickpeas but due to the overall inadequate food supply for people. In some parts of the world, young chickpea leaves are consumed as cooked green vegetables. Especially in malnourished populations, it can supplement important dietary nutrients  Chickpea leaves have a significantly higher mineral content than cabbage and spinach. In natural settings, environmental factors and nutrient availability could influence mineral concentrations. Nevertheless, consumption of chickpea leaves is recommended for areas where chickpeas are produced as food for humans.
India is the world leader in chickpea (Bengal gram) production, and produces some 15 times as much as the second-largest producer, Australia. Other key producers are Pakistan, Turkey, Burma, Ethiopia, and Iran.
|Source: FAO||Source: FAO|
Heat and micronutrient cultivation
Agricultural yield for Chickpea is often based on genetic and phenotypic variability which has recently been influenced by artificial selection. The uptake of micronutrients such as inorganic phosphorus or nitrogen is vital to the plant development of Cicer arietinum, commonly known as the perennial chickpea. Heat cultivation and micronutrient coupling are two relatively unknown methods that are used to increase the yield and size of the chickpea. Recent research has indicated that a combination of heat treatment along with the two vital micronutrients, phosphorus and nitrogen, are the most critical components to increasing the overall yield of Cicer arietinum.
Perennial chickpeas are a fundamental source of nutrition in animal feed as they are high sources of energy and protein for livestock. Unlike other food crops, the perennial chickpea shows a remarkable capacity to change its nutritional content in response to heat cultivation. Treating the chickpea with a constant heat source increases its protein content almost three-fold. Consequently, the impact of heat cultivation not only affects the protein content of the chickpea itself, but the ecosystem that it supports as well. Increasing the height and size of chickpea plants involves using micronutrient fertilization with varying doses of inorganic phosphorus and nitrogen.
The level of phosphorus that a chickpea seed is exposed to during its lifecycle has a positive correlation relative to the height of the plant at full maturity. Increasing the levels of inorganic phosphorus at all doses incrementally increases the height of the chickpea plant. Thus, the seasonal changes in phosphorus soil content as well as periods of drought that are known to be a native characteristic of the dry Middle-Eastern region where the chickpea is most commonly cultivated have a strong effect on the growth of the plant itself. Plant yield is also affected by a combination of phosphorus nutrition and water supply, resulting in a 12% increase in yield of the crop.
Nitrogen nutrition is another factor that affects the yield of Cicer arietinum, although the application itself differs from other perennial crops with regards to the levels administered on the plant. High doses of nitrogen inhibit the yield of the chickpea plant. Drought stress is a likely factor that also inhibits the uptake of nitrogen and subsequent fixation in the roots of Cicer arietinum. The growth of the perennial chickpea is dependent on the balance between nitrogen fixation and assimilation that is also characteristic of many other agricultural plant types. The influence of drought stress, sowing date, and mineral nitrogen supply all have an effect on the yield and size of the plant, with trials showing that Cicer arietinum differed from other plant species in its capacity to assimilate mineral nitrogen supply from soil during drought stress. Additional minerals and micronutrients make the absorption process of nitrogen and phosphorus more available. Inorganic phosphate ions are generally attracted towards charged minerals such as iron and aluminium oxides.
Additionally, growth and yield are also limited by zinc and boron deficiencies in the soil. Boron-rich soil resulted in an increase of chickpea yield and size, while soil fertilization with zinc seemed to have no apparent effect on the chickpea yield.
Pathogens in chickpeas are the main cause for yield loss (up to 90%). One example is the fungus Fusarium oxysporum f. sp. cicero, present in most of the major pulse crop-growing areas and causing regular yield damages between 10 and 15%. From 1978 until 1995, the worldwide number of pathogens increased from 49 to 172, of which 35 have been recorded in India. These pathogens originate from the groups of bacteria, fungi, viruses, mycoplasma and nematodes and show a high genotypic variation. The most widely distributed pathogens are Ascochyta rabiei (35 countries), Fusarium oxysporum f. sp. cicero (32 countries) Uromyces ciceris-arietini (25 countries), bean (pea) leaf roll virus (23 countries), and Macrophomina phaseolina (21 countries). Ascochyta disease emergence is favored by wet weather; spores are carried to new plants by wind and water splash.
The stagnation of yield improvement over the last decades is linked to the susceptibility to pathogens. Research for yield improvement, such as an attempt to increase yield from 0.8 to 2.0 tons per hectare by breeding cold-resistant varieties, is always linked with pathogen-resistance breeding as pathogens such as Ascochyta rabiei and F. o. f. sp. cicero flourish in conditions such as cold temperature. Research started selecting favourable genes for pathogen resistance and other traits through marker-assisted selection. The use of this method is a promising sign for the future to achieve significant yield improvements.
- "The Plant List: A Working List of All Plant Species". Retrieved 22 October 2014.
- "USDA GRIN Taxonomy". Retrieved 21 October 2014.
- " Baynes, T.S.; Smith, W.R., eds. (1880). "Gram". Encyclopædia Britannica 11 (9th ed.). pp. 36–37.
- S, Bell (March 31, 2014). "The small but mighty chickpea". Phys.org. Retrieved 8 October 2015.
- Garbanzo bean, Oxford Reference
- Zohary, Daniel and Hopf, Maria, Domestication of Plants in the Old World (third edition), Oxford University Press, 2000, p 110
- Culpeper, Nicholas. Chick-Pease, or Cicers. The Complete Herbal (1652, originally titled The English Physitian).
- "Introduction: Chickpeas". International Center for Agricultural Research in the Dry Areas. Archived from the original on 18 July 2012. Retrieved 28 August 2008.
- "Chickpea (Chana)". CRN India. Retrieved 8 June 2016.
- "Global research team decodes genome sequence of 90 chickpea lines". International Crops Research Institute for the Semi-Arid Tropics. 2013. Retrieved 9 October 2015.
- "Chickpea (Cicer arietinum L.)". International Crops Research Institute for the Semi-Arid Tropics. 2015. Retrieved 9 October 2015.
- Chickpea: An ancient crop for the modern world http://exploreit.icrisat.org/page/chickpea/685/60. ICRISAT. Downloaded 26 January 2014.
- Mansfeld's World Database of Agricultural and Horticultural Crops, Cicer arietinum subsp. arietinum, mansfeld.ipk-gatersleben.de, retrieved 31 January 2008
- Marks, Gil (2010), Encyclopedia of Jewish Food, John Wiley and Sons, pp. 269-271
- Ferretti, Elena (April 5, 2010). "There's Hummus Among Us". Fox News.
- Deppe, Carol. The Resilient Gardener. Chelsea Green, 2010, p. 241
- Bampidis, V.A.; Christodoulou, V. (2011). "Chickpeas (Cicer arietinum L.) in animal nutrition: A review". Animal Feed Science and Technology 168: 1–20. doi:10.1016/j.anifeedsci.2011.04.098.
- El-Adawy, T.A. (2002). "Nutritional composition and antinutritional factors of chickpeas (Cicer arietinum L.) undergoing different cooking methods and germination". Plant Foods for Human Nutrition 57 (1): 83–97. PMID 11855623.
- Jukanti AK, Gaur PM, Gowda CL, Chibbar RN (2012). "Nutritional quality and health benefits of chickpea (Cicer arietinum L.): a review". Br J Nutr 108 (Suppl 1): S11–26. doi:10.1017/S0007114512000797. PMID 22916806.
- Khatoon N, Prakash J (2004). "Nutritional quality of microwave-cooked and pressure-cooked legumes". Int J Food Sci Nutr 55 (6): 441–8. doi:10.1080/09637480400009102. PMID 15762308.
- Milán-Carrillo J, Valdéz-Alarcón C, Gutiérrez-Dorado R, Cárdenas-Valenzuela OG, Mora-Escobedo R, Garzón-Tiznado JA, Reyes-Moreno C (2007). "Nutritional properties of quality protein maize and chickpea extruded based weaning food". Plant Foods Hum Nutr 62 (1): 31–7. doi:10.1007/s11130-006-0039-z. PMID 17243010.
- "Nutrition facts for Chickpeas (garbanzo beans, bengal gram), mature seeds, cooked, boiled, without salt, 100 g, USDA Nutrient Database, version SR-21". Conde Nast. 2014. Retrieved 15 January 2015.
- Ibrikci, H.; Knewtson, S.J.B.; Grusak, M.A. (2003). "Chickpea leaves as a vegetable green for humans: evaluation of mineral composition". Journal of the Science of Food and Agriculture 83: 945–950. doi:10.1002/jsfa.1427.
- Pittaway, JK; Robertson, IK; Ball, MJ (2008). "Chickpeas may influence fatty acid and fiber intake in an ad libitum diet, leading to small improvements in serum lipid profile and glycemic control". Journal of the American Dietetic Association 108 (6): 1009–13. doi:10.1016/j.jada.2008.03.009. PMID 18502235.
- Mixed Bean Salad (information and recipe) from The Mayo Clinic Healthy Recipes. Accessed February 2010.
- "Production of Chickpea by countries". UN Food & Agriculture Organization. 2011. Retrieved 2013-08-28.
- "Production of Chickpea by countries". UN Food & Agriculture Organization. 2014. Retrieved 2014-11-13.
- Naghavi, M.R., & Jahansouz, M.R. (2005). Variation in the agronomic and morphological traits of Iranian chickpea accessions. Journal of Integrative Plant Biology. 47(3): 375-379 doi:10.1111/j.1744-7909.2005.00058.x
- Bampidis, V.A. & Christodoulou, V. (2011). Chickpeas (Cicer arietinum L.) in animal nutrition: A review. Animal Feed Science and Technology, 168: 1-20. doi:10.1016/j.anifeedsci.2011.04.098
- Mishra, U.S., Sirothia, P., & Bhadoria, U.S. (2009). Effects of phosphorus nutrition on growth and yield of chickpea (Cicer arietinum) under rain fed conditions. International Journal of Agricultural and Statistical Sciences, 5(1): 85-88.
- Wery, J., Deschamps, M., & Leger-Cresson, N. (1988). Influence of some agroclimatic factors and agronomic practices on nitrogen nutrition of chickpea (Cicer arietinum L.). Developments in Plants and Soil Sciences, 32: 287-301.
- Hinsinger, P. (2001). Bioavailability of soil inorganic P in the rhizosphere as affected by root-induced chemical changes: A review. Plant and Soil, 237(2): 173-195.
- Johnson, S.E., Lauren, J.G., Welch, R.M., & Duxbury, J.M. (2005). A comparison of the effects of micronutrient seed priming and soil fertilization on the mineral nutrition of chickpea (Cicer arietinum), lentil (Lens culinaris), rice (Oryza sativa) and wheat (Triticum acstiyum) in Nepal.
- Datta, J.; Lal, N (2012). "Application of molecular markers for genetic discrimination of fusarium wilt pathogen races affecting chickpea and pigeonpea in major regions of india". European Journal of Agronomy 58 (1): 55–65. doi:10.1170/T921.
- Sheila, J.; Sharma, N. (1996). "A World list of Chickpea and Pigeonpea Pathogens". International Crops Research Institue for Semi-Arid Tropics,ICRISAT (5).
- Pfaff, T; Kahl, G (2003). "Mapping of gene-specific markers on the genetic map of chickpea ("Cicer atietinum"L)". Molecular Genetic Genomics 269: 243–251. doi:10.1007/s00438-003-0828-0.
- Millan, Teresa; Heather, J.Clarke; Kadambot, H.M.Siddique; et.al (2006). "Chickpea molecular breeding:New tools and concepts". Euphytica 147: 81–103. doi:10.1007/s10681-006-4261-4.
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