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millet

What is millet

Millet is not just one grain, but the name given to a group of several different small-seeded grains from several different genera of the grass family Poaceae. Millets are commonly referred as “small seeded grasses” which include pearl millet [Pennisetum glaucum (L.) R. Br.], finger millet [Eleusine coracana (L.) Gaertn], foxtail millet [Setaria italica (L.) Beauv], proso millet (Panicum miliaceum L.), barnyard millet (Echinochloa spp.), kodo millet (Paspalum scrobiculatum), and little millet (Panicum sumatrense) 1. Moreover, millets are drought tolerant crops 2, resistant to pests and diseases offering good insurance against crop failure in developing countries 3.

Millets are highly nutritious being rich source of proteins, vitamins, and minerals 4. About 80% of millet grains are used for food, while the rest is used as animal fodder and in brewing industry for alcoholic products 5. Millet grains are ground into flour and consumed as cakes or porridges. In Asian countries, street food vendors serve less expensive, ready-to-eat millet-based foods for poor consumers.

Millets are naturally gluten free 6 that’s high in antioxidant activity and also especially high in magnesium, a mineral that helps maintain normal muscle and nerve function. For many years, little research was done on the health benefits of millets, but recently they have been “rediscovered” by researchers, who have found millets helpful in controlling diabetes and inflammation.

Four different millets are mostly commonly cultivated worldwide, listed here starting with the most widely produced:

  1. Pearl millet [Pennisetum glaucum]
  2. Foxtail millet [Setaria italica]
  3. Proso millet, also called hog, common or broom corn millet [Panicum miliaceum]
  4. Finger millet, also called ragi in India [Eleusine coracana]
  5. Fonio [Digitaria exilis]

AACC International recognizes seven genera of millets: Brachiaria spp.; Pennisetum spp.; Panicum spp.; Setaria spp.; Paspalum spp.; Eleusine spp.; Echinochloa spp. Teff [Eragrostis tef], Fonio [Digitaria exilis] and Job’s Tears [Coix lacrima-jobi] are also sometimes classifed as millets, including by the USDA 7.

Among the millets, pearl millet occupies 95% of the production 8, 9. Foxtail millet [S. italica (L.) P. Beauv] is the second largest crop among the millets, cultivated for food in semi-arid tropics of Asia and as forage in Europe, North America, Australia, and North Africa 10. Finger millet is the sixth largest crop under cultivation serving as the primary food for rural populations of East and Central Africa and southern India 11. Proso millet is a short-season crop cultivated in drier regions of Asia, Africa, Europe, Australia, and North America 12. Barnyard millet is the fastest growing among the millets with a harvesting period of 6 weeks 13. It is predominantly cultivated in India, China, Japan, and Korea for food as well as fodder. Kodo millet is native to the tropical and sub-tropical regions of South America and domesticated in India 3,000 years ago 14. Little millet was domesticated in the Eastern Ghats of India occupying a major portion of diet amongst the tribal people and spread to Sri Lanka, Nepal, and Myanmar 15.

Millets are nutritionally superior to rice and wheat as they contain a high amount of proteins, dietary fibers, iron, zinc, calcium, phosphorus, potassium, vitamin B, and essential amino acids 16. But the presence of antinutrients like phytates, polyphenols, and tannins reduce the mineral bioavailability by chelating multivalent cations like Fe2+, Zn2+, Ca2+, Mg2+, and K+ 17. In addition, high amounts of protease and amylase inhibitors affect the digestibility of millet grains 18. The predominance of the antinutritional factors has thus rendered the orphan status to millets in terms of global economic importance.

Today, millet is the world’s sixth most important grain. India is the world’s largest producer of millet, with eight African countries and China making up the rest of the top ten producers. Depending on variety, millets can grow anywhere from one to 15 feet tall, and usually have a an undigestible hull (ranging from papery-thin to hard) that must be removed before the grain can be eaten. Most millets do best in dry, warm climates.

Millets exhibit vast genetic variability for key mineral elements like, iron, zinc, and calcium when compared to other cereal crops 19. In spite of the superior quality of millets, only pearl millet has been prioritized as crop of choice for iron biofortification in India.

In India, ragi (finger millet) is used to make roti, a staple flat bread. And in much of Africa, millet is commonly eaten as a porridge, and is also used for brewing millet beer. In the United States, millet is probably most familiar as the primary component of birdseed.

Figure 1. Millet grain

millet

is millet gluten free

millet bread

 

millet flour

 

 

Millet nutrition facts

In a 100 gram serving, raw millet provides 378 calories and is a rich source (20% or more of the Daily Value, DV) of protein, dietary fiber, several B vitamins and numerous dietary minerals, especially manganese at 76% DV. Raw millet is 9% water, 73% carbohydrates, 4% fat and 11% protein (Table 1).

Table 1. Millet (raw) nutrition facts

NutrientUnitValue per 100 g
Approximates
Waterg8.67
Energykcal378
EnergykJ1582
Proteing11.02
Total lipid (fat)g4.22
Ashg3.25
Carbohydrate, by differenceg72.85
Fiber, total dietaryg8.5
Minerals
Calcium, Camg8
Iron, Femg3.01
Magnesium, Mgmg114
Phosphorus, Pmg285
Potassium, Kmg195
Sodium, Namg5
Zinc, Znmg1.68
Copper, Cumg0.75
Manganese, Mnmg1.632
Selenium, Seµg2.7
Vitamins
Vitamin C, total ascorbic acidmg0
Thiaminmg0.421
Riboflavinmg0.29
Niacinmg4.72
Pantothenic acidmg0.848
Vitamin B-6mg0.384
Folate, totalµg85
Folic acidµg0
Folate, foodµg85
Folate, DFEµg85
Vitamin B-12µg0
Vitamin A, RAEµg0
Retinolµg0
Vitamin A, IUIU0
Vitamin E (alpha-tocopherol)mg0.05
Vitamin D (D2 + D3)µg0
Vitamin DIU0
Vitamin K (phylloquinone)µg0.9
Lipids
Fatty acids, total saturatedg0.723
12:00:00g0.003
16:00:00g0.528
18:00:00g0.154
Fatty acids, total monounsaturatedg0.773
16:1 undifferentiatedg0.014
18:1 undifferentiatedg0.739
20:01:00g0.02
Fatty acids, total polyunsaturatedg2.134
18:2 undifferentiatedg2.015
18:3 undifferentiatedg0.118
Cholesterolmg0
Amino Acids
Tryptophang0.119
Threonineg0.353
Isoleucineg0.465
Leucineg1.4
Lysineg0.212
Methionineg0.221
Cystineg0.212
Phenylalanineg0.58
Tyrosineg0.34
Valineg0.578
Arginineg0.382
Histidineg0.236
Alanineg0.986
Aspartic acidg0.726
Glutamic acidg2.396
Glycineg0.287
Prolineg0.877
Serineg0.644
Proanthocyanidin
Proanthocyanidin dimersmg0
Proanthocyanidin trimersmg0
Proanthocyanidin 4-6mersmg0
Proanthocyanidin 7-10mersmg0
Proanthocyanidin polymers (>10mers)mg0
[Source 20]

Table 2. Millet (cooked) nutrition facts

NutrientUnitValue per 100 g
Approximates
Waterg71.41
Energykcal119
Proteing3.51
Total lipid (fat)g1
Carbohydrate, by differenceg23.67
Fiber, total dietaryg1.3
Sugars, totalg0.13
Minerals
Calcium, Camg3
Iron, Femg0.63
Magnesium, Mgmg44
Phosphorus, Pmg100
Potassium, Kmg62
Sodium, Namg2
Zinc, Znmg0.91
Vitamins
Vitamin C, total ascorbic acidmg0
Thiaminmg0.106
Riboflavinmg0.082
Niacinmg1.33
Vitamin B-6mg0.108
Folate, DFEµg19
Vitamin B-12µg0
Vitamin A, RAEµg0
Vitamin A, IUIU3
Vitamin E (alpha-tocopherol)mg0.02
Vitamin D (D2 + D3)µg0
Vitamin DIU0
Vitamin K (phylloquinone)µg0.3
Lipids
Fatty acids, total saturatedg0.172
Fatty acids, total monounsaturatedg0.184
Fatty acids, total polyunsaturatedg0.508
Cholesterolmg0
Other
Caffeinemg0
[Source 20]

Table 3. Millet flour nutrition facts

NutrientUnitValue per 100 g
Approximates
Waterg8.67
Energykcal382
Proteing10.75
Total lipid (fat)g4.25
Carbohydrate, by differenceg75.12
Fiber, total dietaryg3.5
Sugars, totalg1.66
Minerals
Calcium, Camg14
Iron, Femg3.94
Magnesium, Mgmg119
Phosphorus, Pmg285
Potassium, Kmg224
Sodium, Namg4
Zinc, Znmg2.63
Vitamins
Vitamin C, total ascorbic acidmg0
Thiaminmg0.413
Riboflavinmg0.073
Niacinmg6.02
Vitamin B-6mg0.372
Folate, DFEµg42
Vitamin E (alpha-tocopherol)mg0.11
Vitamin K (phylloquinone)µg0.8
Lipids
Fatty acids, total saturatedg0.536
Fatty acids, total monounsaturatedg0.924
Fatty acids, total polyunsaturatedg2.618
Fatty acids, total transg0.002
[Source 20]

Table 4. Millet puffed nutrition facts

NutrientUnitValue per 100 g
Approximates
Waterg2.5
Energykcal354
Proteing13
Total lipid (fat)g3.4
Carbohydrate, by differenceg80
Fiber, total dietaryg2.7
Sugars, totalg0.55
Minerals
Calcium, Camg8
Iron, Femg2.81
Magnesium, Mgmg106
Phosphorus, Pmg266
Potassium, Kmg40
Sodium, Namg5
Zinc, Znmg1.58
Vitamins
Vitamin C, total ascorbic acidmg0
Thiaminmg0.39
Riboflavinmg0.27
Niacinmg4.42
Vitamin B-6mg0.36
Folate, DFEµg79
Vitamin B-12µg0
Vitamin A, RAEµg0
Vitamin A, IUIU0
Vitamin E (alpha-tocopherol)mg0.66
Vitamin D (D2 + D3)µg0
Vitamin DIU0
Vitamin K (phylloquinone)µg1.4
Lipids
Fatty acids, total saturatedg0.67
Fatty acids, total monounsaturatedg0.717
Fatty acids, total polyunsaturatedg1.98
Cholesterolmg0
Other
Caffeinemg0
[Source 20]

Millet comparison with other major cereal grains

Nutritional potential of millets in terms of protein, carbohydrate and energy values are comparable to the popular cereals like rice, wheat, barley or bajra (Tables 5 and 6). Finger millet contains about 5–8% protein, 1–2% ether extractives, 65–75% carbohydrates, 15–20% dietary fiber and 2.5–3.5% minerals 21. Finger Millet has the highest calcium content among all cereals (344 mg/100 g) (see Table 6). However, the millet also contains phytates (0.48%), polyphenols, tannins (0.61%), trypsin inhibitory factors, and dietary fiber, which were once considered as “anti nutrients” due to their metal chelating and enzyme inhibition activities 22 but nowadays they are termed as neutraceuticals. The seed coat of the millet is an edible component of the kernel and is a rich source of phytochemicals, such as dietary fiber and polyphenols (0.2–3.0%) 23. It is now established that phytates, polyphenols and tannins can contribute to antioxidant activity of the millet foods, which is an important factor in health, aging and metabolic diseases 24.

Table 5. Nutrient composition of cereal grains

CerealsProtein (%)Fat (%)Crude fiber (%)Ash (%)Starch (%)Total dietary fiber (%)Total phenol (mg/100 g)
Wheat14.42.32.91.964.012.120.5
Rice7.52.410.24.777.23.72.51
Maize12.14.62.31.862.312.82.91
Sorghum113.22.71.873.811.843.1
Barley11.52.25.62.958.515.416.4
Oats17.16.411.33.252.812.51.2
Rye13.41.82.12.068.316.113.2
Finger millet7.31.33.63.059.019.1102
Pearl millet14.55.12.02.060.57.051.4
Proso millet113.59.03.656.18.5
Foxtail millet11.73.97.03.059.119.11106
Kodo millet8.31.49.03.672.037.8368
[Source 25]

Table 6. Mineral and vitamin composition of cereal grains

CerealsCa (%)P (%)K (%)Na (%)Mg (%)Fe (%)Mn (%)Zn (%)Thiamin (mg/100gm)Riboflavin (mg/100gm)Nicotinic acid (mg/100gm)
Wheat0.040.350.360.040.1440.140.030.90.570.127.40
Rice0.020.120.100.000.0319.012.010.00.070.031.60
Maize0.030.290.370.030.1430.05.020.00.380.142.80
Sorghum0.040.350.380.050.1950.016.315.40.460.154.84
Barley0.040.560.500.020.1436.718.923.60.440.157.20
Oats0.110.380.470.020.1362.045.037.00.770.140.97
Rye0.050.360.470.010.1138.058.432.20.690.261.52
Finger millet0.330.240.430.020.1146.07.515.00.480.120.30
Pearl millet0.010.350.440.010.1374.918.029.50.380.222.70
Proso millet0.010.150.210.010.1233.118.118.10.630.221.32
Foxtail millet0.010.310.270.010.1332.621.921.90.480.123.70
Kodo millet0.010.320.170.010.137.00.320.050.70
[Source 25]

Millet health benefits

Millets are recommended for well-being of infants, lactating mothers, elderly, and convalescents. The grains release sugar slowly into the blood stream and thus considered “gluten-free” 6. With high fiber and protein content, millets are preferred as dietary foods for people with diabetes and cardiovascular diseases 26. In addition, they contain health promoting phenolic acids and flavonoids, that play a vital role in combating free-radical mediated oxidative stress and in lowering blood glucose levels 27. Pearl millet is rich in Fe (iron), Zn (zinc), and lysine (17–65 mg/g of protein) compared to other millets 28. Foxtail millet contains a high amount of protein (11%) and fat (4%). The protein fractions are represented by albumins and globulins (13%), prolamins (39.4%), and glutelins (9.9%). It is thus recommended as an ideal food for diabetics. It also contains significant amounts of potential antioxidants like phenols, phenolic acids, and carotenoids 29. Finger millet grains contain higher levels of minerals like Ca (calcium), Mg (magnesium), and K (potassium) 30. Positive calcium content maintains healthy bones 31, while potassium prevents the onset of diabetes, renal and cardiovascular diseases 32. It also has high levels of amino acids like methionine, lysine and tryptophan 33, and polyphenols 34. Proso millet contains the highest amount of proteins (12.5%) while barnyard millet is the richest source of crude fiber (13.6%) and Fe (186 mg/kg dry matter) 16. Barnyard millet grains possess other functional constituents’ viz. γ-amino butyric acid (GABA) and β-glucan, used as antioxidants and in reducing blood lipid levels 35. With lowest carbohydrate content among the millets, barnyard millet is recommended as an ideal food for type II diabetics 36. Kodo millet is bestowed with high magnesium content (1.1 g/kg dry matter). Millets are therefore consumed as multi-grains to reap the collective health benefits of nutrients.

The dietary fiber and polyphenols in finger millet are known to offer several health benefits such as antidiabetic, antioxidant, hypocholesterolaemic, antimicrobial effects and protection from diet related chronic diseases. The millet polyphenols is a complex mixture of benzoic acid and cinnamic acid derivatives and exhibit enzyme inhibitory and anti-cataractogenic activities also. The non starchy polysaccharides of the millet form bulk of its dietary fiber constituents and offer several health benefits including delayed nutrient absorption, increased faecal bulk and lowering of blood lipids. Regular consumption of finger millet as a food or even as snacks helps in managing diabetes and its complications by regulation of glucose homeostasis and prevention of dyslipideamia.

Potential contribution of dietary fiber to the health effects of finger millets

Finger millet like any other cereal is a source of dietary carbohydrates but the proportion of dietary fiber in finger millet is relatively higher than many other cereals. Finger millet carbohydrates (72%) comprises of starch as the main constituent and the non starchy polysaccharides which amounts to 15–20% of the seed matter as an unavailable carbohydrate. Dietary fiber, principally the non starchy polysaccharides and lignin of the plant origin, is not digested by endogenous enzymes within the human intestinal tract, but is an important component of our diet 37. Dietary fiber can be divided into two categories according to their water solubility. Each category provides different therapeutic effects. Water-soluble fiber consists of non starchy polysaccharides, mainly β-glucan and arabinoxylan. Water-insoluble fiber contains lignin, cellulose, hemicelluloses 38, and non starchy polysaccharides such as water-unextractable arabinoxylan. In millets, non starchy polysaccharides form the quantitatively most important source of both soluble and insoluble dietary fibers 39. In cereal botanical components, the majority of dietary fibres generally occur in decreasing amounts from the outer pericarp to the endosperm, except arabinoxylan, which is also a major component of endosperm cell wall materials.

The health benefits associated with high fiber foods are delayed nutrient absorption, increased fecal bulk, lowering of blood lipids, prevention of colon cancer, barrier to digestion, mobility of intestinal contents, increased faecal transit time and fermentability characteristics 40. Water-soluble fiber fractions are important in foods because they trap fatty substances in the gastro-intestinal tract and therefore, reduce cholesterol level in the blood and lower the risk of heart disease. Water-soluble fiber in general has a wide range of functionality due to its ability to absorb water and form gel like structure, and is almost fully fermented in the large intestine microflora, bringing about many desired metabolic effects of fiber 41. The ability of water-soluble fiber to retard absorption of glucose in the small intestine is also a desirable characteristic in the development of foods for diabetic individuals 42. The increase in the soluble fibre content of the product has special nutritional significance because of its physiological advantages in terms of hypoglycemic and hypocholesterolemic characteristics 43. Soluble fibre also decreases serum cholesterol, postprandial blood glucose, and insulin contents in the human body. Insoluble fiber has a major impact on gastrointestinal transit times, binds water, speeds up intestinal transit, faecal bulk and binds some carcinogens. It reduces contact time for faecal mutagens to interact with the intestinal epithelium and also modifies the activity of digestive microflora and leads to modification or reduction in the production of mutagens. Some fibers can adsorb mutagenic agents and are eliminated in the faeces 44.

Formation of the resistant starch also contributes towards dietary fibre content and complements the health benefits of the millet 43. This residual starch can be quantified in the soluble dietary fiber residue and is highly susceptible to fermentation in the large intestine. Resistant starch, a functional fiber fraction is also present in ragi, which escapes the enzymatic digestion imparts beneficial effects by preventing several intestinal disorders 45. Similar to oligosaccharides, especially fructooligosaccharides, it escapes digestion and provides fermentable carbohydrates for colonic bacteria. It has also been shown to provide benefits such as the production of desirable metabolites, including short-chain fatty acids in the colon, especially butyrate, which seems to stabilize colonic cell proliferation as a preventive mechanism for colon cancer 46. In addition to its therapeutic effects, resistant starch provides better appearance, texture, and mouth feel than conventional fibres 47.

Dietary fiber has gained importance during the last two decades due to its role in decreasing the risk diseases such as diabetes, cardiovascular diseases, colon cancer, constipation and diverticulosis. Physical attributes of the fiber causes change in morphology of the intestine and these changes could be associated with functional changes in the gastrointestinal tract through different mechanisms. Consumption of dietary fiber that are viscous lowers blood glucose levels and helps to maintain it and also helps to treat cardiovascular and type II diabetes. Fibers are incompletely or slowly fermented by microflora in the colon promotes normal laxation which prevents constipation, diverticulosis and diverticulitis. Daily intake of fiber is 20–35 g/day for healthy individuals and age plus 5 g/day for children is recommended.

Dietary fiber has major effects on the rate of gastrointestinal absorption; sterol metabolism; ceacal fermentation and stool weight. Rate of intestinal absorption in the upper gastrointestinal tract dietary fiber prolongs gastric emptying time and retards the absorption of nutrients. Both processes are dependent on the physical form of the fiber, and particularly on viscosity. The physiological effects of dietary fiber in relation to functions of intestines are given in Table 7. An important function of insoluble fibers is to increase luminal viscosity in the intestine. The inclusion of viscous polysaccharides in carbohydrate meals reduces the postprandial blood glucose level concentrations in humans. The direct effect of fiber on sterol metabolism may be through one of several mechanisms: altered lipid absorption; altered bile acid metabolism in the cecum; reduced bile acid absorption in the cecum; indirectly via short chain fatty acids, especially propionic acid, resulting from fiber fermentation. Fermentation in colon involves nutrient salvage so that dietary fiber, resistant starch, fat, and protein are utilized by bacteria and the end products are absorbed and used by the body. The functions of dietary fiber in the colon are susceptible to bacterial fermentation, ability to increase bacterial mass and saccharolytic enzyme activity and water holding capacity of the fiber residue after fermentation. The most important mechanism whereby dietary fiber increases stool weight is through the water-holding capacity of unfermented fiber 48. Potential negative effects of dietary fiber are reduced absorption of vitamins, minerals and proteins. Fermentation of dietary fiber by anaerobic bacteria in the large intestine produces gas such as hydrogen, methane and carbon dioxide, which causes flatulence problems.

Table 7. Physiological effects of dietary fiber in relation to intestinal functions

CharacteristicsEffectsPhysiological implications
Dietary fiber and small intestinal functions
Dispersibility in waterIncreases volume, dilution of metabolites formedSlower digestion, promotes nutrient absorption with reduction of plasma cholesterol
BulkIncreases bulk, alters mixing of contentsAlters transit time
ViscositySlows gastric emptyingAlters mixing and diffusion
Adsorption-bindingIncreases bile acid excretionReduction in plasma cholesterol
Dietary fiber and large intestinal functions
Dispersibility in waterProvides an aqueous phase for penetration of microbesIncreased polysaccharide break down by microflora
BulkIncreases bulk/volumeAids laxation
Adsorption-bindingIncreases bile acid concentrationBile acid excretion increased
FermentabilityGrowth of microflora, microbial adaptation to polysaccharide structuresIncreased microbial mass and products of metabolism
[Source 49]

Foxtail Millet May Help Control Blood Sugar and Cholesterol

Foxtail millet (Setaria italica) is a common food in parts of India. Scientists at Sri Venkateswara University 50 studied its health benefits in diabetic rats, and concluded that the millet produced a “significant fall (70%) in blood glucose” while having no such effect in normal rats. Diabetic rats fed millet also showed significantly lower levels of triglycerides, and total/LDL/VLDLcholesterol, while exhibiting an increase in HDL cholesterol.

Sprouting (Malting) Millet Makes Some Minerals More Bioavailable

In India and some other countries, sprouted (malted) grains are commonly used as weaning foods for infants and as easily-digested foods for the elderly and infirm. A study at the Central Food Technological Research Institute in Mysore, India 51, measured the changes caused by malting finger millet, wheat and barley. They found that malting millet increased the bioaccessibility of iron (> 300%) and manganese (17%), and calcium (“marginally”), while reducing bioaccessibility of zinc and making no difference in copper. The effects of malting on different minerals varied widely by grain.

All Millet Varieties Show High Antioxidant Activity

At the Memorial University of Newfoundland in Canada 52, a team of biochemists analyzed the antioxidant activity and phenolic content of several varieties of millet: kodo, finger, foxtail, proso, pearl, and little millets. Kodo millet showed the highest phenolic content, and proso millet the least. All varieties showed high antioxidant activity, in both soluble and bound fractions.

Naturally Gluten-Free Grains May Be Cross-Contaminated

A Polish team from the Instytut Zywnosci in Warsaw 53 analyzed 22 gluten-free products and 19 naturally gluten-free grains and flours, for gluten content. Gluten content in the products ranged from 5.19 to 57.16 mg/kg. In the inherently gluten-free grains and flours, no gluten was detected in rice and buckwheat samples, but was detected in rice flakes (7.05 mg/kg) in pearl millet (27.51 mg/kg) and in oats (>100 mg/kg).

Meanwhile, in the U.S., Tricia Thompson 54, a nutrition consultant specializing in gluten-free diets, arranged for gluten-testing of 22 retail samples of inherently gluten-free grains, seeds, and flours. She found contamination of 20 to 2925 ppm in seven of 22 samples, putting them over the proposed FDA limit of 20 ppm, with lower levels in some others. Both articles point to the importance of gluten-free certification even on foods that are naturally gluten-free, such as millet.

Millet consumption decreases triglycerides and C-reactive protein

Scientists in Seoul, South Korea 55, fed a high-fat diet to rats for 8 weeks to induce hyperlipidemia, then randomly divided into four diet groups: white rice, sorghum, foxtail millet and proso millet for the next 4 weeks. At the end of the study, triglycerides were significantly lower in the two groups consuming foxtail or proso millet, and levels of C-reactive protein were lowest in the foxtail millet group. The researchers concluded that millet may be useful in preventing cardiovascular disease.

Indian Diabetics Turn to Ragi (Finger Millet) and other Millets

Diabetes is rising rapidly in India, as it is in many nations. Researchers at Sri Devaraj Urs Medical College in Tamaka, Kola, India 56 decided to study the prevalence and awareness of diabetes in rural areas, in order to inform health policy. While there was widespread lack of awareness of the longterm effects of diabetes and diabetic care, common perception favored consumption of ragi, millet and whole wheat chapatis instead of rice, sweets and fruit.

Finger Millet (Ragi) Tops in Antioxidant Activity Among Common Indian Foods

The National Institute of Nutrition in Hyderabad, India 57, carried out a study of the total phenolic content and antioxidant activity of various pulses, legumes and cereals, including millets. Finger millet and Rajmah (a type of bean) were highest in antioxidant activity, while finger millet and black gram dhal (a type of lentil) had the highest total phenolic content.

Millets Macronutrients

Starch

Millets are the primary source of carbohydrates in tropics and semi-arid tropics of India and sub-Saharan Africa 5. Grain starch typically comprises of two polymers, amylose (15–30%) and amylopectin (70–85%). Based on the amylose content, millet are classified into two major phenotypes, waxy and non-waxy. Waxy grains containing 0% amylose and nearly 100% amylopectin are glutinous in nature, easily digestible and therefore recommended as food for infants under 6 years of age 58. Waxy mutants in staple crops have evolved during the domestication of landraces by human selection. They have been identified in cereals and millets including rice (Oryza sativa), barley (Hordeum vulgare), sorghum (Sorghum bicolor), maize (Zea mays), foxtail millet (S. italica), proso millet (P. miliaceum), and barnyard millet (Echinochloa sp.) 59. Amylose synthesis in millets is controlled by a single dominant waxy allele (Wx), while the recessive loss-of-function allele (wx) leads to the waxy phenotype with near 0% amylose content. In polyploid crops, mutations in different alleles of Wx loci produce low amylose, non-waxy and waxy phenotypes. Low amylose lines contain <3% amylose content due to the residual activity of non-mutant alleles. Precise identification of mutations in low amylose and waxy mutants have led to the development of waxy starch foods. Traditional breeding in millets for waxy trait is a labor intensive and time consuming process. It took nearly 15 years to transform waxy trait into non-waxy elite foxtail millet cultivar Yugu1 through cross breeding 60. With recent advancements in genome editing, application of programmable site-specific nucleases is a straightforward approach to induce genetic mutations in non-waxy elite cultivars for transforming them into waxy phenotypes. Thus genomics approaches will speed up the genetic improvement in millets in a cost effective manner to produce biofortified varieties.

Proteins and Amino Acids

High quality proteins are essential for physical and mental well-being of humans, especially children 61. Cereal proteins deficient in essential amino acids like methionine, lysine, and tryptophan lead to malnutrition in developing countries 62. Cereal proteins contain 1.5–2% lysine and 0.25–0.5% tryptophan while estimated average requirement is 5% and 1.1% for lysine and tryptophan 63). Finger millet on the other hand is high in essential amino acids than cereals 64.

References
  1. Vinoth A, Ravindhran R. Biofortification in Millets: A Sustainable Approach for Nutritional Security. Frontiers in Plant Science. 2017;8:29. doi:10.3389/fpls.2017.00029. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5253353
  2. O’Kennedy M. M., Crampton B. G., Ozias-Akins P. (2009). “Pearl millet,” in Compendium of Transgenic Crop Plants: Transgenic Cereals and Forage Grasses Vol. 1 eds Kole C., Hall T. C., editors. (Chichester: John Wiley & Sons; ) 177–190.
  3. Reddy I. N. B. L., Reddy D. S., Narasu M. L., Sivaramakrishnan S. (2011). Characterization of disease resistance gene homologues isolated from finger millet (Eleusine coracana L. Gaertn). Mol. Breed. 27 315–328. 10.1007/s11032-010-9433-1
  4. Vinoth A, Ravindhran R. Biofortification in Millets: A Sustainable Approach for Nutritional Security. Frontiers in Plant Science. 2017;8:29. doi:10.3389/fpls.2017.00029. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5253353/
  5. Shivran A. C. (2016). “Biofortification for nutrient-rich millets,” in Biofortification of Food Crops eds Singh U., Praharaj C. S., Singh S. S., Singh N. P., editors. (New Delhi: Springer; ) 409–420. 10.1007/978-81-322-2716-8_30
  6. Taylor J. R. N., Emmambux M. N. (2008). “Gluten-free foods and beverages from millets,” in Gluten-Free Cereal Products and Beverages (Food Science and Technology) eds Arendt E. K., Dal Bello F., editors. (Cambridge, MA: Academic Press; ) 119–148.
  7. Millet and Teff – November Grains of the Month. https://wholegrainscouncil.org/whole-grains-101/grain-month-calendar/millet-and-teff-%E2%80%93-november-grains-month
  8. Nedumaran S., Bantilan M. C. S., Gupta S. K., Irshad A., Davis J. S. (2014). Potential Welfare Benefit of Millets Improvement Research at ICRISAT: Multi Country-Economic Surplus Model Approach, Socioeconomics Discussion Paper Series Number 15. Hyderabad: ICRISAT.
  9. Agricultural Statistics, Government of India (2014). “Pearl Millet,” in Agricultural Statistics at a Glance–2014 Government of India (New Delhi: Oxford University Press; ) 85–86.
  10. Austin D. (2006). Fox-tail millets (Setaria: Poaceae): abandoned food in two hemispheres. Econ. Bot. 60 143–158. 10.1663/0013-0001200660[143:FMSPFI]2.0.CO;2
  11. Vijayakumari J., Mushtari Begum J., Begum S., Gokavi S. (2003). “Sensory attributes of ethnic foods from finger millet (Eleusine coracana),” in Proceeding of the National Seminar on Processing and Utilization of Millet for Nutrition Security: Recent Trends in Millet Processing and Utilization (Hisar: CCSHAV; ) 7–12.
  12. Kimata M., Negishi M. (2002). Geographical distribution of proso millet, Panicum miliaceum L. on iodostarch and phenol reactions; with special references to a northern propagation route into Japanese Islands. Environ. Edu. Stud. Tokyo Gakugei University 12 15–22.
  13. Sood S., Khulbe R. K., Gupta A. K., Agrawal P. K., Upadhyaya H. D., Bhatt J. C. (2015). Barnyard millet – a potential food and feed crop of future. Plant Breed. 134 135–147. 10.1111/pbr.12243
  14. de Wet J. M. J., Rao K. E. P., Mengesha M. H., Brink D. E. (1983b). Diversity in kodo millet, Paspalum scrobiculatum. Econ. Bot. 37 159–163. 10.1007/BF02858779
  15. de Wet J. M. J., Rao K. E. P., Brink D. E. (1983a). Systematics and domestication of Panicum sumatrense (Gramineae). J. Agric. Trad. Bot. Appl. 30 159–168. 10.3406/jatba.1983.3898
  16. Saleh A. S. M., Zhang Q., Chen J., Shen Q. (2013). Millet grains: nutritional quality, processing, and potential health benefits. Compr. Rev. Food Sci. Food Saf. 12 281–295. 10.1111/1541-4337.12012
  17. AbdelRahman S. M., Babiker E. E., El Tinay A. H. (2005). Effect of fermentation on antinutritional factors and HCl extractability of minerals of pearl millet cultivars. J. Food Tech. 3 516–522.
  18. Pearl millet cysteine protease inhibitor. Evidence for the presence of two distinct sites responsible for anti-fungal and anti-feedent activities. Joshi BN, Sainani MN, Bastawade KB, Deshpande VV, Gupta VS, Ranjekar PK. Eur J Biochem. 1999 Oct; 265(2):556-63.
  19. Advances in Setaria genomics for genetic improvement of cereals and bioenergy grasses. Muthamilarasan M, Prasad M. Theor Appl Genet. 2015 Jan; 128(1):1-14. https://www.ncbi.nlm.nih.gov/pubmed/25239219/
  20. United States Department of Agriculture Agricultural Research Service. National Nutrient Database for Standard Reference Release 28. https://ndb.nal.usda.gov/ndb/search/list
  21. Chethan S, Malleshi NG. Finger millet polyphenols: optimization of extraction and the effect of pH on their stability. Food Chem. 2007;105:862–870.
  22. Thompson LU. Potential health benefits and problems associated with antinutrients in foods. Food Res Int. 1993;26:131–149.
  23. Hadimani NA, Malleshi NG. Studies on milling, physicochemical properties, nutrient composition and dietary fiber content of millets. J Food Sci Technol. 1993;30:17–20.
  24. Polyphenols: chemistry, dietary sources, metabolism, and nutritional significance. Bravo L. Nutr Rev. 1998 Nov; 56(11):317-33. https://www.ncbi.nlm.nih.gov/pubmed/9838798/
  25. Saldivar S (2003) Cereals: dietary importance. In: Caballero B, Trugo L, Finglas P (ed) Encyclopedia of Food Sciences and Nutrition, Reino Unido: Academic Press, Agosto, London, pp 1027–1033
  26. Exploration of millet models for developing nutrient rich graminaceous crops. Muthamilarasan M, Dhaka A, Yadav R, Prasad M. Plant Sci. 2016 Jan; 242():89-97. https://www.ncbi.nlm.nih.gov/pubmed/26566827/
  27. Kunyanga C. N., Imungi J. K., Okoh M. W., Biesalski H. K. (2012). Total phenolic content, antioxidant and antidiabetic properties of methanolic extract of raw and traditionally processed Kenyan indigenous food ingredients. LWT Food Sci. Technol. 45 269–276. 10.1016/j.lwt.2011.08.006
  28. Hadimani N. A., Muralikrishna G., Tharanathan R. N., Malleshi N. G. (2001). Nature of carbohydrates and proteins in three pearl millet varieties varying in processing characteristics and kernel texture. J. Cereal Sci. 33 17–25. 10.1006/jcrs.2000.0342
  29. Phenolic and carotenoid profiles and antiproliferative activity of foxtail millet. Zhang LZ, Liu RH. Food Chem. 2015 May 1; 174():495-501. https://www.ncbi.nlm.nih.gov/pubmed/25529711/
  30. Health benefits of finger millet (Eleusine coracana L.) polyphenols and dietary fiber: a review. Devi PB, Vijayabharathi R, Sathyabama S, Malleshi NG, Priyadarisini VB. J Food Sci Technol. 2014 Jun; 51(6):1021-40. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4033754/
  31. Nutritional rickets: deficiency of vitamin D, calcium, or both? Pettifor JM. Am J Clin Nutr. 2004 Dec; 80(6 Suppl):1725S-9S. http://ajcn.nutrition.org/content/80/6/1725S.long
  32. Beneficial effects of potassium on human health. He FJ, MacGregor GA. Physiol Plant. 2008 Aug; 133(4):725-35. https://www.ncbi.nlm.nih.gov/pubmed/18724413/
  33. Responses to drought induced oxidative stress in five finger millet varieties differing in their geographical distribution. Bhatt D, Negi M, Sharma P, Saxena SC, Dobriyal AK, Arora S. Physiol Mol Biol Plants. 2011 Oct; 17(4):347-53. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3550588/
  34. Inhibitory activities of soluble and bound millet seed phenolics on free radicals and reactive oxygen species. Chandrasekara A, Shahidi F. J Agric Food Chem. 2011 Jan 12; 59(1):428-36. https://www.ncbi.nlm.nih.gov/pubmed/21133411/
  35. Isolation of Functional Components β-Glucan and γ-Amino Butyric Acid from Raw and Germinated Barnyard Millet (Echinochloa frumentaceae) and their Characterization. Sharma S, Saxena DC, Riar CS. Plant Foods Hum Nutr. 2016 Sep; 71(3):231-8. https://www.ncbi.nlm.nih.gov/pubmed/27245684/
  36. Glycemic index and significance of barnyard millet (Echinochloa frumentacae) in type II diabetics. Ugare R, Chimmad B, Naik R, Bharati P, Itagi S. J Food Sci Technol. 2014 Feb; 51(2):392-5. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3907638/
  37. DeVries JW, Prosky L, Li B, Cho S. A historic perspective on defining dietary fiber. Cereal Foods World. 1999;44:367–369.
  38. Marlett JA. Analysis of dietary fiber in human foods. In: Kritchevsky D, Bonfield C, Anderson JW, editors. Dietary fibre: Chemistry, physiology and health effects. New York: Plenum; 1990. pp. 31–48.
  39. Bunzel M, Ralph J, Marita JM, Hatfield RD, Steinhart H. Diferulates as structural components in soluble and insoluble cereal dietary fiber. J Sci Food Agric. 2001;81:653–660.
  40. Tharanathan RN, Mahadevamma S. Grain legumes—a boon to human nutrition. Trends Food Sci Technol. 2003;14:507–518.
  41. Effects of soluble corn bran arabinoxylans on cecal digestion, lipid metabolism, and mineral balance (Ca, Mg) in rats. Lopez HW, Levrat MA, Guy C, Messager A, Demigné C, Rémésy C. J Nutr Biochem. 1999 Sep; 10(9):500-9.
  42. Onyango C, Noetzold H, Bley T, Henle T. Proximate composition and digestibility of fermented and extruded uji from maize-finger millet blend. LWT Food Sci Technol. 2004;37:827–832.
  43. Shobana S, Malleshi NG. Preparation and functional properties of decorticated finger millet (Eleusine coracana) J Food Eng. 2007;79:529–538.
  44. Thebaudin JY, Lefebvre AC, Harrington M, Bourgeois CM. Dietary fibre: nutritional and technological interest. Trends Food Sci Technol. 1997;8:41–48.
  45. Nutritional role of resistant starch: chemical structure vs physiological function. Annison G, Topping DL. Annu Rev Nutr. 1994; 14():297-320. https://www.ncbi.nlm.nih.gov/pubmed/7946522/
  46. Classification and measurement of nutritionally important starch fractions. Englyst HN, Kingman SM, Cummings JH. Eur J Clin Nutr. 1992 Oct; 46 Suppl 2():S33-50. https://www.ncbi.nlm.nih.gov/pubmed/1330528/
  47. Martinez-Flores HE, Chang YK, Bustos FM, Sinencio FS (1999) Extrusion-cooking of cassava starch with different fiber sources: effect of fibers on expansion and physicochemical properties. Adv Extrusions 271–278
  48. Eastwood MA. The physiological effect of dietary fiber. Annu Rev Nutr. 1992;12:19–35. https://www.ncbi.nlm.nih.gov/pubmed/1323981
  49. Barbara OS. Fiber, inulin and oligofructose: similarities and differences. J of Nutr. 1999;129:1424S–1430S. http://jn.nutrition.org/content/129/7/1424.long
  50. Antihyperglycemic and hypolipidemic activities of Setaria italica seeds in STZ diabetic rats. Pathophysiology. 2011 Apr;18(2):159-64. doi: 10.1016/j.pathophys.2010.08.003. Epub 2010 Sep 24. https://www.ncbi.nlm.nih.gov/pubmed/20869855
  51. Bioaccessible mineral content of malted finger millet (Eleusine coracana), wheat (Triticum aestivum), and barley (Hordeum vulgare). J Agric Food Chem. 2010 Jul 14;58(13):8100-3. doi: 10.1021/jf100846e. https://www.ncbi.nlm.nih.gov/pubmed/20560601
  52. Content of insoluble bound phenolics in millets and their contribution to antioxidant capacity. J Agric Food Chem. 2010 Jun 9;58(11):6706-14. doi: 10.1021/jf100868b. https://www.ncbi.nlm.nih.gov/pubmed/20465288
  53. [Gluten content in special dietary use gluten-free products and other food products]. Rocz Panstw Zakl Hig. 2010;61(1):51-5. https://www.ncbi.nlm.nih.gov/pubmed/20803900
  54. Gluten contamination of grains, seeds, and flours in the United States: a pilot study. J Am Diet Assoc. 2010 Jun;110(6):937-40. doi: 10.1016/j.jada.2010.03.014. http://jandonline.org/article/S0002-8223(10)00234-8/fulltext
  55. Millet consumption decreased serum concentration of triglyceride and C-reactive protein but not oxidative status in hyperlipidemic rats. Nutr Res. 2010 Apr;30(4):290-6. doi: 10.1016/j.nutres.2010.04.007. https://www.ncbi.nlm.nih.gov/pubmed/20534332
  56. Muninarayana C, Balachandra G, Hiremath SG, Iyengar K, Anil NS. Prevalence and awareness regarding diabetes mellitus in rural Tamaka, Kolar. International Journal of Diabetes in Developing Countries. 2010;30(1):18-21. doi:10.4103/0973-3930.60005. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2859279/
  57. Antioxidant activity of commonly consumed cereals, millets, pulses and legumes in India. Indian J Biochem Biophys. 2009 Feb;46(1):112-5. https://www.ncbi.nlm.nih.gov/pubmed/19374263
  58. Classification and measurement of nutritionally important starch fractions. Englyst HN, Kingman SM, Cummings JH. Eur J Clin Nutr. 1992 Oct; 46 Suppl 2():S33-50.
  59. Kim S. K., Sohn E. Y., Lee I. J. (2009). Starch properties of native foxtail millet, Setaria italica Beauv. J. Crop Sci. Biotech. 12 59–62. 10.1007/s12892-009-0073-0
  60. Quan J., Dong L., Ma J., Li Z., Zheng Z. (2010). Breeding of leaf rust resistance and waxy millet new variety Jichuang 1. J. Hebei. Agric. Sci. 14 127–128.
  61. Lysine requirement through the human life cycle. Tomé D, Bos C. J Nutr. 2007 Jun; 137(6 Suppl 2):1642S-1645S.
  62. Development and molecular characterization of genic molecular markers for grain protein and calcium content in finger millet (Eleusine coracana (L.) Gaertn.). Nirgude M, Babu BK, Shambhavi Y, Singh UM, Upadhyaya HD, Kumar A. Mol Biol Rep. 2014 Mar; 41(3):1189-200. https://www.ncbi.nlm.nih.gov/pubmed/24477581/
  63. Young V. R., Scrimshaw N. S., Pellet P. (1998). “Significance of dietary protein source in human nutrition: animal and/or plant proteins?,” in Feeding a World Population of More than Eight Billion People eds Waterlow J. C., Armstrong D. G., Fowden L., Riley R., editors. (New York, NY: Oxford University Press;
  64. Mbithi-Mwikya S., Camp J. V., Yiru Y., Huyghebaert A. (2000). Nutrient and antinutrient changes in finger millet (Eleusine coracana) during sprouting. LWT Food Sci. Technol. 33 9–14. 10.1006/fstl.1999.0605
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