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Finger Millet

Eleusine coracana (L.) Gaertn.

Distribution in Egypt

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Nile and Mediterranean regions.

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Global Distribution

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Cultivated in the Old World tropics and subtropics; probably arose in the uplands of east Africa as a derivative of Eleusine africana (q.v.)

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Habitat

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Cultivated for forage (African or Finger Millet) and occasionally escaping.

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Life Expectancy

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Annual.

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Comments

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In Taiwan, it is especially grown by the Tribal peoples.
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Gramineae (Poaceae) in Flora of Taiwan Vol. 0 in eFloras.org, Missouri Botanical Garden. Accessed Nov 12, 2008.
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Comments

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This species is used for cereal, forage, papermaking, and soil-retention.
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Flora of China Vol. 22: 482 in eFloras.org, Missouri Botanical Garden. Accessed Nov 12, 2008.
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Description

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Culm tufted. Blade linear; sheath overlapping; ligule 1-2 mm long, a fringe of hairs. Inflorescence of digitate one-sided spikes. Spikelets 2-4-flowered, about 5 mm long; glumes chartaceous, folded, conspicuously keeled on back, acute; the lower 2/3 as long as the upper; lemma deltoid-ovate, acute, keeled on back, about 3.5 mm long, 5-nerved, lateral nerves close to the midrib; palea narrowly ovate, 2-keeled, siliceous along keels, as long as the lemma. Seed about 1 mm long, black and wrinkled; embryo 1/2-3/4 the length of the seed. Fruit an utricle.
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Gramineae (Poaceae) in Flora of Taiwan Vol. 0 in eFloras.org, Missouri Botanical Garden. Accessed Nov 12, 2008.
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Description

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(African or Finger Millet) is sometimes cultivated in the plains and lower hills (usually below 300m) and used to make a kind of porridge or alcoholic beverage. The species may occasionally escape and can be recognised by the broad spikes of closely packed, non-shattering spikelets and the almost globular grains.
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Flora of Pakistan Vol. 0: 102 in eFloras.org, Missouri Botanical Garden. Accessed Nov 12, 2008.
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Description

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Annual. Culms tufted, robust, erect or ascending, usually branched, 50–120 cm tall. Leaf sheaths glabrous; leaf blades flat, 30–60 × 0.6–1.2 cm, pilose or glabrous; ligule 1–2 mm. Inflorescence subdigitate, racemes 5–20, stout, often incurved at maturity, 5–10 × 0.8–1.5 cm, hairy at base. Spikelets very closely imbricate, ovate, 5–9 mm, florets 6–9, not disarticulating at maturity; glumes lanceolate-oblong, scabrid along the winged keel; lower glume 3-veined, 1.5–3 mm; upper glume with additional veins in keel, 1.8–5 mm; lemmas triangular-ovate, 2.2–4.7 mm, keel 3-veined, scabrid and narrowly winged, subacute; palea narrowly ovate, keels scabrid, winged. Grain yellowish brown, globose, finely striate-punctate. Fl. and fr. May–Sep. 2n = 36.
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Flora of China Vol. 22: 482 in eFloras.org, Missouri Botanical Garden. Accessed Nov 12, 2008.
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Distribution

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Cultivated in tropics of Old World, introduced into the New World.
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Annotated Checklist of the Flowering Plants of Nepal Vol. 0 in eFloras.org, Missouri Botanical Garden. Accessed Nov 12, 2008.
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Annotated Checklist of the Flowering Plants of Nepal @ eFloras.org
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Distribution

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This species is widely cultivated in the tropics of the Old World.
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Gramineae (Poaceae) in Flora of Taiwan Vol. 0 in eFloras.org, Missouri Botanical Garden. Accessed Nov 12, 2008.
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Elevation Range

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1100-2000 m
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Annotated Checklist of the Flowering Plants of Nepal Vol. 0 in eFloras.org, Missouri Botanical Garden. Accessed Nov 12, 2008.
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Annotated Checklist of the Flowering Plants of Nepal @ eFloras.org
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Habitat & Distribution

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Cultivated cereal crop. Anhui, Fujian, Guangdong, Guizhou, Hainan, Henan, Hubei, Jiangxi, Ningxia, Shandong, Sichuan, Taiwan, Yunnan, Zhejiang [widely cultivated in tropical and subtropical regions of the Old World].
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Missouri Botanical Garden, 4344 Shaw Boulevard, St. Louis, MO, 63110 USA
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Flora of China Vol. 22: 482 in eFloras.org, Missouri Botanical Garden. Accessed Nov 12, 2008.
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Flora of China @ eFloras.org
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Wu Zhengyi, Peter H. Raven & Hong Deyuan
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Synonym

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Cynosurus coracanus L., Syst. Nat. ed. 10. 2: 875. 1759.
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Gramineae (Poaceae) in Flora of Taiwan Vol. 0 in eFloras.org, Missouri Botanical Garden. Accessed Nov 12, 2008.
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Synonym

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Cynosurus coracanus Linnaeus, Syst. Nat., ed. 10, 2: 875. 1759 ["coracan"].
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Flora of China Vol. 22: 482 in eFloras.org, Missouri Botanical Garden. Accessed Nov 12, 2008.
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Flora of China @ eFloras.org
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Wu Zhengyi, Peter H. Raven & Hong Deyuan
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Physical Description

provided by USDA PLANTS text
Annuals, Terrestrial, not aquatic, Stems nodes swollen or brittle, Stems erect or ascending, Stems caespitose, tufted, or clustered, Stems terete, round in cross section, or polygonal, Stems branching above base or distally at nodes, Stem internodes hollow, Stems with inflorescence less than 1 m tall, Stems with inflorescence 1-2 m tall, Stems, culms, or scapes exceeding basal leaves, Leaves mostly basal, below middle of stem, Leaves conspicuously 2-ranked, distichous, Leaves sheathing at base, Leaf sheath mostly open, or loose, Leaf sheath smooth, glabrous, Leaf sheath hairy, hispid or prickly, Leaf sheath or blade keeled, Leaf sheath and blade differentiated, Leaf blades linear, Leaf blades 2-10 mm wide, Leaf blades 1-2 cm wide, Leaf blade margins folded, involute, or conduplicate, Leaf blades mostly glabrous, Leaf blades more or less hairy, Leaf blades scabrous, roughened, or wrinkled, Ligule present, Ligule a fringed, ciliate, or lobed membrane, Inflorescence terminal, Inflorescence solitary, with 1 spike, fascicle, glomerule, head, or cluster per stem or culm, Inflorescence a panicle with digitately arranged spicate branches, Inflorescence with 2-10 branches, Inflorescence branches 1-sided, Inflorescence branches paired or digitate at a single node, Rachis dilated, flat, central axis to which spikelets are attached, Flowers bisexual, Spikelets sessile or subsessile, Spikelets laterally compressed, Spikelet less than 3 mm wide, Spikelets with 3-7 florets, Spikelets with 8-40 florets, Spikelets solitary at rachis nodes, Spikelets all alike and fertille, Spikelets bisexual, Spikelets disarticulating above the glumes, glumes persistent, Spikelets disarticulating beneath or between the florets, Spikelets secund, in rows on one side of rachis, Rachilla or pedicel glabrous, Glumes present, empty bracts, Glumes 2 clearly present, Glumes distinctly unequal, Glumes shorter than adjacent lemma, Glumes keeled or winged, Glumes 3 nerved, Lemmas thin, chartaceous, hyaline, cartilaginous, or membranous, Lemma 3 nerved, Lemma glabrous, Lemma apex acute or acuminate, Lemma awnless, Lemma margins thin, lying flat, Lemma straight, Palea present, well developed, Palea membranous, hyaline, Palea about equal to lemma, Palea 2 nerved or 2 keeled, Stamens 3, Styles 2-fid, deeply 2-branched, Stigmas 2, Fruit - caryopsis, Caryopsis isodiametric, trigonous or globose, broadest at base or beaked, Caryopsis minutely rugose.
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USDA PLANTS text

Eleusine coracana

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Eleusine coracana, or finger millet, also known as ragi in India, kodo in Nepal, and kurakkan in Sri Lanka, is an annual herbaceous plant widely grown as a cereal crop in the arid and semiarid areas in Africa and Asia. It is a tetraploid and self-pollinating species probably evolved from its wild relative Eleusine africana.[2]

Finger millet is native to the Ethiopian and Ugandan highlands.[3] Interesting crop characteristics of finger millet are the ability to withstand cultivation at altitudes over 2000 m above sea level, its high drought tolerance, and the long storage time of the grains.[2]

History

Finger millet originated in East Africa (Ethiopian and Ugandan highlands). It was claimed to have been found in an Indian archaeological site dated to 1800 BCE (Late Bronze Age);[4] however, this was subsequently demonstrated to be incorrectly identified cleaned grains of hulled millets.[5][6] The oldest record of finger millet comes from an archaeological site in Africa dating to the 8th century AD.[7]

By 1996, cultivation of finger millet in Africa was declining rapidly because of the large amount of labor it required, with farmers preferring to grow nutritionally-inferior but less labor-intensive crops such as maize, sorghum, and cassava.[2]: 39–40  Such a decline was not seen in Asia, however.[2]: 42 

Taxonomy and botanical description of finger millet

There are ten species under the genus Eleusine Gaertn, seven diploid (2n=16, 18 and 20) and three tetraploid taxa (2n=36 or 38). Eleusine africana (Kenn.-O'Bryne), Eleusine coracana (L.) Gaertn, Eleusine floccifolia (Spreng), Eleusine indica (L.) Gaertn, Eleusine intermedia (Chiov.) (S.M.Phillips), Eleusine jaegeri (Pilg.), Eleusine kigeziensis (S.M.Phillips), Eleusine multiflora (Hochst. ex A.Rich), Eleusine semisterilis (S.M.Phillips) and Eleusine tristachya (Lam.) Lam. Different studies confirmed that Eleusine coracana was originated from E. indica and E. floccifolia genomes and selected for cultivation from its wild type E. Africana. [8][9]

Growing regions

Main cultivation areas are parts of eastern and southern Africa – particularly Uganda, Kenya, the Democratic Republic of the Congo, Zimbabwe, Zambia, Malawi, and Tanzania – and parts of India and Nepal.[2]: 42, 52  It is also grown in southern Sudan[2]: 39  and "as far south" in Africa as Mozambique.[2]: 56 

Climate requirements

Finger millet is a short-day plant with a growing optimum 12 hours of daylight for most varieties. Its main growing area ranges from 20°N to 20°S, meaning mainly the semiarid to arid tropics. Nevertheless, finger millet is found to be grown at 30°N in the Himalaya region (India and Nepal). It is generally considered as a drought-tolerant crop, but compared with other millets, such as pearl millet and sorghum, it prefers moderate rainfall (500 millimetres (20 in) annually). The majority of worldwide finger millet farmers grow it rainfed, although yields often can be significantly improved when irrigation is applied. In India, finger millet is a typical rabi (dry-winter season) crop. Heat tolerance of finger millet is high. For Ugandan finger millet varieties, for instance, the optimal average growth temperature ranges at about 27 °C, while the minimal temperatures should not be lower than 18 °C. Relative to other species (pearl millet and sorghum), finger millet has a higher tolerance to cool temperatures. It is grown from about 500 to about 2400 m above sea level (e.g. in Himalaya region). Hence, it can be cultivated on higher elevations than most tropical crops. Finger millet can grow on various soils, including highly weathered tropical lateritic soils. It thrives in free-draining soils with steady moisture levels. Furthermore, it can tolerate soil salinity up to a certain extent. Its ability to bear waterlogging is limited, so good drainage of the soils and moderate water-holding capacity are optimal.[2] Finger millet can tolerate moderately acidic soils (pH 5), but also moderately alkaline soils (pH 8.2).[10]

Cropping systems

Fields of finger millet in the Annapurna region of Nepal

Finger millet monocrops grown under rainfed conditions are most common in drier areas of Eastern Africa. In addition, intercropping with legumes, such as cowpea or pigeon pea, are also quite common in East Africa. Tropical Central Africa supports scattered regions of finger millet intercropping mostly with legumes, but also with cassava, plantain, and vegetables.[2]

Most common finger millet intercropping systems in South India are as follows:

Weeds

Weeds are the major biotic stresses for finger millet cultivation. Its seeds are very small, which leads to a relatively slow development in early growing stages. This makes finger millet a weak competitor for light, water, and nutrients compared with weeds.[11] In East and Southern Africa, the closely related species Eleusine indica (common name Indian goose grass) is a severe weed competitor of finger millet. Especially in early growing stages of the crop and the weed and when broadcast seeding instead of row seeding is applied (as often the case in East Africa), the two species are very difficult to distinguish.[2] Besides Eleusine indica, the species Xanthium strumarium, which is animal dispersed and the stolon-owning species Cyperus rotondus and Cynodon dactylon are important finger millet weeds.[11] Measures to control weeds include cultural, physical, and chemical methods. Cultural methods could be sowing in rows instead of broadcast sowing to make distinction between finger millet seedlings and E. indica easier when hand weeding.[2] ICRISAT promotes cover crops and crop rotations to disrupt the growing cycle of the weeds. Physical weed control in financial resource-limited communities growing finger millet are mainly hand weeding or weeding with a hand hoe.[11]

Diseases and pests

Finger millet is generally seen as not very prone to diseases and pests. Nonetheless, finger millet blast, caused by the fungal pathogen Magnaporthe grisea (anamorph Pyricularia grisea), can locally cause severe damages, especially when untreated.[2] In Uganda, yield losses up to 80% were reported in bad years. The pathogen leads to drying out of leaves, neck rots, and ear rots.[11] These symptoms can drastically impair photosynthesis, translocation of photosynthetic assimilates, and grain filling, so reduce yield and grain quality. Finger millet blast can also infest finger millet weeds such as the closely related E. indica, E. africana, Digitaria spp., Setaria spp., and Doctylocterium spp.[11][12] Finger millet blast can be controlled with cultural measures, chemical treatments, and the use of resistant varieties. Researchers in Kenya have screened wild relatives of finger millet and landraces for resistance to blast.[13] Cultural measures to control finger millet blast suggested by ICRISAT for Eastern Africa include crop rotations with nonhost crops such as legumes, deep ploughing under of finger millet straw on infected fields, washing of field tools after use to prevent dissemination of the pathogen to uninfected fields, weed control to reduce infections by weed hosts, and avoiding of high plant densities to impede the pathogen dispersal from plant to plant.[11] Chemical measures can be direct spraying of systemic fungicides, such as the active ingredients pyroquilon or tricyclazone or seed dressings with fungicides such as trycyclozole.[11][14]

Striga, a parasitic weed which occurs naturally in parts of Africa, Asia, and Australia, can severely affect the crop and yield losses in finger millet and other cereals by 20 to 80%.[15] Striga can be controlled with limited success by hand weeding, herbicide application, crop rotations, improved soil fertility, intercropping and biological control.[16] The most economically feasible and environmentally friendly control measure would be to develop and use Striga-resistant cultivars.[17] Striga resistant genes have not been identified yet in cultivated finger millet but could be found in crop wild relatives of finger millet.[18]

Another pathogen of relevance in the finger millet cultivation is the fungus Helminthosporium nodulosum, causing leaf blight.[10]

Finger millet pests are bird predators, such as quelea in East Africa.[2]

Insects

The pink stem borer (Sesamia inferens) and the finger millet shoot fly (Atherigona miliaceae)[19] are considered as the most relevant insect pests in finger millet cultivation.[10] Measures to control Sesamia inferens are uprooting of infected plants, destroying of stubbles, having a crop rotation, chemical control with insecticides, biological measures such as pheromone traps, or biological pest control with the use of antagonistic organisms (e.g. Sturmiopsis inferens).[20]

Other insect pests include:[21]

Root feeders
Shoot and stem feeders
Leaf feeders
Sucking pests

Propagation and sowing

Ragi Plant

Propagation in finger millet farming is done mainly by seeds. In rainfed cropping, four sowing methods are used:[22]

  • Broadcasting: Seeds are directly sown in the field. This is the common method because it is the easiest way and no special machinery is required. The organic weed management with this method is a problem, because it is difficult to distinguish between weed and crop.
  • Line Sowing: Improved sowing compared to broadcasting. Facilitates organic weed management due to better distinction of weed and crop. In this method, spacing of 22 cm to 30 cm between lines and 8 cm to 10 cm within lines should be maintained. The seeds should be sown about 3 cm deep in the soil.
  • Drilling in rows: Seeds are sown directly in the untreated soil by using a direct-seed drill. This method is used in conservation agriculture.
  • Transplanting the seedlings: Raising the seedlings in nursery beds and transplant to the main field. Leveling and watering of beds is required during transplanting. Seedlings with 4 weeks age should be transplanted in the field. For early Rabi and Kharif season, seedlings should be transplanted at 25 cm x 10 cm and for late Kharif season at 30 cm x 10 cm. Planting should be done 3 cm depth in the soil

Harvest

Finger millet sprays in Uganda

Crop does not mature uniformly and hence the harvest is to be taken up in two stages. When the earhead on the main shoot and 50% of the earheads on the crop turn brown, the crop is ready for the first harvest. At the first harvest, all earheads that have turned brown should be cut. After this drying, threshing and cleaning the grains by winnowing. The second harvest is around seven days after the first. All earheads, including the green ones, should be cut. The grains should then be cured to obtain maturity by heaping the harvested earheads in shade for one day without drying, so that the humidity and temperature increase and the grains get cured. After this drying, threshing and cleaning as after the first harvesting.[2]

Storage

Once harvested, the seeds keep extremely well and are seldom attacked by insects or moulds. Finger millet can be kept for up to 10 years when it is unthreshed. Some sources report a storage duration up to 50 years under good storage conditions.[2] The long storage capacity makes finger millet an important crop in risk-avoidance strategies as a famine crop for farming communities.[2]

Processing

Milling

As a first step of processing finger millet can be milled to produce flour. However, finger millet is difficult to mill due to the small size of the seeds and because the bran is bound very tightly to the endosperm. Furthermore, the delicate seed can get crushed during the milling. The development of commercial mechanical milling systems for finger millet is challenging. Therefore, the main product of finger millet is whole grain flour. This has disadvantages, such as reduced storage time of the flour due to the high oil content. Furthermore, the industrial use of whole grain finger millet flour is limited. Moistening the millet seeds prior to grinding helps to remove the bran mechanically without causing damage to the rest of the seed. The mini millet mill can also be used to process other grains such as wheat and sorghum.

Malting

Another method to process the finger millet grain is germinating the seed. This process is also called malting and is very common in the production of brewed beverages such as beer. When finger millet is germinated, enzymes are activated, which transfer starches into other carbohydrates such as sugars. Finger millet has a good malting activity. The malted finger millet can be used as a substrate to produce for example gluten-free beer or easily digestible food for infants.[2]

Finger millet in its commonly consumed form as a porridge

Uses

Finger millet can be ground into a flour and cooked into cakes, puddings or porridge. The flour is made into a fermented drink (or beer) in Nepal and in many parts of Africa. The straw from finger millet is used as animal fodder.

Nutrition

Finger millet is 11% water, 7% protein, 54% carbohydrates, and 2% fat (table). In a 100 gram (3.5 oz) reference amount, finger millet supplies 305 calories, and is a rich source (20% or more of the Daily Value, DV) of dietary fiber and several dietary minerals, especially iron at 87% DV (table).

Growing finger millet to improve nutrition

The International Crops Research Institute for the Semi-Arid Tropics (ICRISAT), a member of the CGIAR consortium, partners with farmers, governments, researchers and NGOs to help farmers grow nutritious crops, including finger millet. This helps their communities have more balanced diets and become more resilient to pests and drought. For example, the Harnessing Opportunities for Productivity Enhancement of Sorghum and Millets in Sub-Saharan Africa and South Asia (HOPE) project is increasing yields of finger millet in Tanzania by encouraging farmers to grow improved varieties.[23]

Culinary Use

In India

The finger millet or ragi is malted and its grain is ground into flour. The flour is consumed with milk, boiled water, or yogurt. The flour is made into flatbreads, including thin, leavened dosa and thicker, unleavened roti.

There are various food recipes of finger millet, including dosa, idli, and laddu. In southern India, on pediatrician's recommendation, finger millet is used in preparing baby food, because of millet's high nutritional content, especially iron and calcium. Satva, pole (dosa), bhakri, ambil (a sour porridge), and pappad are common dishes made using finger millet. In Karnataka, finger millet is generally consumed in the form of a porridge called ragi mudde in Kannada. It is the staple diet of many residents of South Karnataka. Mudde is prepared by cooking the ragi flour with water to achieve a dough-like consistency. This is then rolled into balls of desired size and consumed with sambar (huli), saaru (ಸಾರು), or curries. Ragi is also used to make roti, idli, dosa and conjee. In the Malnad region of Karnataka, the whole ragi grain is soaked and the milk is extracted to make a dessert known as keelsa. A type of flat bread is prepared using finger millet flour (called ragi rotti in Kannada) in Northern districts of Karnataka.

In Tamil Nadu, ragi is called kezhvaragu (கேழ்வரகு) and also has other names like keppai, ragi, and ariyam.[24] Ragi is dried, powdered, and boiled to form a thick mass that is allowed to cool. This is the famed kali or keppai kali. This is made into large balls to quantify the intake. It is taken with sambar or kuzhambu. For children, ragi is also fed with milk and sugar (malt). It is also made in the form of pancakes with chopped onions and tomatoes. Kezhvaragu is used to make puttu with jaggery or sugar. Ragi is called koozh – a staple diet in farming communities, eaten along with raw onions and green chillies. In Andhra Pradesh, ragi sankati or ragi muddha – ragi balls – are eaten in the morning with chilli, onions, and sambar. In Kerala, puttu, a traditional breakfast dish, can be made with ragi flour and grated coconut, which is then steamed in a cylindrical steamer. In the tribal and western hilly regions of Odisha, ragi or mandiaa is a staple food. In the Garhwal and Kumaon regions of Uttarakhand, koda or maduwa is made into thick rotis (served with ghee), and also made into badi, which is similar to halwa but without sugar. In the Kumaon region, ragi is traditionally fed to women after child birth. In some parts of Kumaon region the ragi flour is used to make various snacks like namkeen sev, mathri and chips.

In South and Far East Asia

In Nepal, a thick dough (ḍhĩḍo) made of millet flour (kōdō) is cooked and eaten by hand. The dough, on other hand, can be made into thick bread (rotee) spread over flat utensil and heating it. Fermented millet is used to make a beer chhaang and the mash is distilled to make a liquor (rakśiशी). Whole grain millet is fermented to make tongba. Its use in holy Hindu practices is barred especially by upper castes. In Nepal, the National Plant Genetic Resource Centre at Khumaltar maintains 877 accessions (samples) of Nepalese finger millet (kodo).[25][26]

In Sri Lanka, finger millet is called kurakkan and is made into kurakkan roti – an earthy brown thick roti with coconut and thallapa – a thick dough made of ragi by boiling it with water and some salt until like a dough ball. It is then eaten with a spicy meat curry and is usually swallowed in small balls, rather than chewing. It is also eaten as a porridge (kurrakan kenda) and as a sweet called 'Halape'. In northwest Vietnam, finger millet is used as a medicine for women at childbirth. A minority use finger millet flour to make alcohol.

As beverage

Ragi malt porridge is made from finger millet which is soaked and shadow dried, then roasted and ground. This preparation is boiled in water and used as a substitute for milk powder-based beverages.

Gallery

References

  1. ^ "The Plant List: A Working List of All Plant Species". Retrieved 8 January 2015.
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  3. ^ A.C. D'Andrea, D.E. Lyons, Mitiku Haile, E.A. Butler, "Ethnoarchaeological Approaches to the Study of Prehistoric Agriculture in the Ethiopian Highlands" in Van der Veen, ed., The Exploitation of Plant Resources in Ancient Africa. Kluwer Academic: Plenum Publishers, New York, 1999.
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Eleusine coracana: Brief Summary

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Eleusine coracana, or finger millet, also known as ragi in India, kodo in Nepal, and kurakkan in Sri Lanka, is an annual herbaceous plant widely grown as a cereal crop in the arid and semiarid areas in Africa and Asia. It is a tetraploid and self-pollinating species probably evolved from its wild relative Eleusine africana.

Finger millet is native to the Ethiopian and Ugandan highlands. Interesting crop characteristics of finger millet are the ability to withstand cultivation at altitudes over 2000 m above sea level, its high drought tolerance, and the long storage time of the grains.

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