Studies (including secondary data) reporting origins of BTM, yield, physiochemical, sensory, functional and nutritional properties of BTM and its health benefits were considered and included while reviewing scientific literature.

Review articles, research articles and reports.

Reference books and electronic search engines like Google scholar, research gate, Pubmed and CERA J-gate which provided published research/ review articles in indexed journals about the BTM—origin, uses in different regions of India, physiochemical, sensory, functional and nutritional properties, health benefits of BTM, as well as websites of relevant organizations were referred for this study.

A thorough review of scientific literature was done using the keywords “millet”, “browntop millet”, “brachiaria ramosa”, “urochloa ramosa”, “panicum ramosum”, “health benefits”, “nutrition”, “physical properties”, “nutritional value”, “browntop millet origin”, “production”, etc. The policy documents and scientific literature available on websites of Government of India (GoI), Indian Institute of Millets Research (IIMR), Indian Agriculture Research Institute (IARI), Ministry of Agriculture & Farmers Welfare (MoAFW), International Crops Research Institute for the Semi-Arid Tropics (ICRISAT), etc., were reviewed thoroughly. The search was limited to literature published from 1984 to 2022.

As per the inclusion and exclusion criteria (Figure 1), all titles and abstracts were screened to determine eligibility and full articles were independently assessed. For inclusion, scientific literature had to cover research or data on the above mentioned at least two keywords.

Out of all the scientific literature (n = 208) that followed the search results; reviews, opinions, letters to the editor and articles not in English, were excluded. Out of the remaining studies, literature which correlated with the agriculture and disease on the BTM plant or providing repetitive information and other studies that were only related to other major and minor millets produced in India were excluded. Salient programmes and their reports were identified in which data on scientific information on BTM—history, yield, nutrition specific and/or nutritive value, physiochemical/sensory properties and uses were given. Finally, a total of 71 scientific papers/literature/ websites were selected for this paper (Figure 1).

The paper concludes with discussion on scope of work and unrealized potential of BTM and research recommendations.

Historical evidence (archaeo-botanical researches from the Neolithic south Indian sites) indicates that the early occurrence or first domestication of BTM was during the pre-historical period. It grew on the Deccan of southern parts of India from where it traveled to other parts of the country (Kingwell-Banham and Fuller, 2014). This millet was present in the staple-crop fields as a weed alongside other crops in southern India from beginning of the third millennium BCE (Fuller, 2006). During the second millennium BCE it reached to Gujarat and Tamil Nadu (Cooke et al., 2005). The grains of browntop millet have been observed in scattered sites in Odisha and the Gangetic plains. However, literature does not provide any authenticate information about commercial farming of this millet (Harvey, 2006). Up to the seventh century, existence of browntop millet was recognized at certain areas in Maharashtra (Paithan). However, with the passage of time cultivation of this crop got substituted by more productive millets, including pearl millet, sorghum, finger millet as well as foxtail millet. According to Sheahan (2014) browntop millet got originated in south-east Asia and presently it is grown in Africa, western Asia, Arabia, Australia and China (Clayton et al., 2006). It is grown in some parts of the USA as a fodder crop, largely to provide food for game birds, and was introduced by India at around 1915 (Oelke et al., 1990). In India, its existence is noted in the fields of little millet (Sakamoto, 1987).

Being domestic in India, it grows well in the dryland tracts of Karnataka-Andhra Pradesh border areas, Tamil Nadu and Maharashtra (Bhat et al., 2018), covering regions of Tumkur, Chitradurga, Mandya and Chikkaballapura districts in Karnataka and Ananthpur district in Andhra Pradesh and the crop is additionally grown and consumed in limited quantities in Bundelkhand region (north central India) (Reddy and Prasad, 2017). It is named differently in Indian languages as “korale” and “kadu-baragu” in Kannada, “andakorra” and “pedda-sama” in Telugu (Fuller et al., 2004; Fuller, 2006). It is also known as signal grass and is considered as one of the rare millet (Maitra, 2020).

Millets, often referred as smart food or smart crops, are the staple foods of people living in arid and semi-arid regions of the world. Especially in Asian and African countries. Minor millets are also referred as “coarse grains” or “poor man's crops” or “small millets” which include proso millet, finger millet, little millet, kodo millet, browntop millet, barnyard millet, and foxtail millet. They are not even traded in local markets in many countries (Ashoka and Sunitha, 2020). According to Chandel et al. (2014) and Perumal (2018), India has been the leading producer of millets followed by Nigeria and China. The production of millets has increased from 10.28 million tons in 2016 to 12.49 million tons in 2020. While in 2016 India contributed 37.34%, in 2020 the contribution was nearly 41% to the world's production of millets. Contribution to the pool of millets production in Asia by India has been most significant i.e., 80.46% in 2016 and 79.36% in 2020 (FAOSTAT, 2022). Refer Tables 1, 2 for more details.

As reported by Niharika V. et al. (2020) the average grain yield of BTM is 12.13 g per plant; the highest grain yield being of IC 617961 variety i.e., 20.38 g per plant. A study was conducted on growth and yield attributes of browntop millet (Brachiaria ramosa) in red sandy soils of Dharwad in Karnataka by Ashoka and Rajkumar (2020). They reported that the grain yield of browntop millet without any fertilizer was only 3.95 q/ha. However, by using the combination of organic manure and inorganic fertilizer the grain yield of BTM increased to 7.38 q/ha.

Moisture content: Moisture content of grains is one of the important factors which influence its physical properties (Goswami et al., 2015). It indicates as whether the grains can be stored for a long or short period of time (Ramashia et al., 2018). It influences the shelf life of grains, physical, sensory as well as functional properties. According to Food Safety and Standards Authority of India (FSSAI) (2011), the moisture content of grains/millets should not be more than 16.0 per cent by weight. According to a study carried out by Nagaraju et al. (2020) the moisture content of the BTM was found to be 11.2 ± 0.16% on wet basis. Hemamilini et al. (2021) found 7.32% moisture present in BTM and 3.08–5.99% of moisture content was recorded in a study by Saini and Sasmal (2022).

A study was conducted on analyzing the chemical properties of different types of browntop millet (brachiaria ramosa) flour obtained by various processing methods i.e., soaking, germination, fermentation, dryheating, hydrothermal treatment and extrusion cooking were assessed by Sirisha et al. (2022). The lowest moisture content was found in dry heated dehulled browntop millet flour i.e., 1.92 ± 0.05% whereas whole browntop millet flour had highest i.e., 8.99 ± 0.06% moisture (Figure 2). The moisture content ranged between 1.92 ± 0.05% and 8.99 ± 0.06% while no significant have been given by FSSAI for millet flour. If we compare it with the values recommended by Food Safety and Standards Authority of India (FSSAI) (2011), for whole wheat flour which should not be more than 14% then all types of BTM flour had moisture content well below the recommended level.

Seed mass: Seed mass is related to the size of the seeds. Larger seeds have higher tendency to germinate. It is also closely related to nutrient content. According to Saini and Sasmal (2022) the mass of 1,000 BTM grains was 3.66 ± 0.00 g. One thousand grains were counted, and afterwards, the weight of grains were recorded in grams to the closest one decimal point. Other studies conducted by Nagaraju et al. (2020) and Titkare et al. (2021) found the mean weight of 1,000 BTM seeds to be 3.42 ± 0.14 g and 2.49 g,respectively.

Seed volume: Seed volume is inversely proportional to the seed density means higher the density lowers the volume, vice-versa. Seed volume of BTM has been reported to be 3.00 ± 0.00 ml by Mohsenin (1986). To calculate the seed volume of BTM one thousand BTM grains were counted and transferred to a 50 ml measuring cylinder and 25 ml of demineralized water was added to it.

Bulk density: The bulk density is the ratio of the mass of seed samples to its total volume. It is a function of the closeness of packaging (Khatoniar and Das, 2020). To find bulk density ten grams of the BTM grain are placed in a 25 ml graduated cylinder and packed by gentle tapping of the cylinder on a bench top, ten times, from a height of 5–8cm. The final volume of the grain is expressed as bulk density (Ramashia et al., 2018). Bulk density of BTM was found to be 0.67 ± 0.00 g/ml by Sravani et al. (2020). Nagaraju et al. (2020) and Titkare et al. (2021) have reported the bulk density of BTM grains to be 601.17 ± 4.08 kg/m3 and 545 kg/m3, respectively.

Porosity: It is defined as the ratio of empty space of seeds to its total volume and it is important in storage process. The porosity of BTM was reported to be 87.78 ± 1.11% by Sravani et al. (2020). Similar studies found the porosity as 58.34% (Titkare et al., 2021) and 53.74 ± 3.23% (Nagaraju et al., 2020).

Ash content: Ash content represents the total mineral content and hence the nutritive value of a food. The ash content of BTM has been reported to range from 1.58 to 1.99 g/100 g by Saini and Sasmal (2022). The ash content reported in similar studies has been 8.62% (Hemamalini et al., 2021), 2.13 ± 0.21 g/100 g (Kishore et al., 2021) and 1.99 ± 0.01 g/100 g Saini and Sasmal (2022). The ash content of BTM is thus greater than rice (0.56 ± 0.08 g/100 g), wheat (1.42 ± 0.19 g/100 g), sorghum (1.39 ± 0.34 g/100 g), pearl millet (1.37 ± 0.17 g/100 g), foxtail millet (1.72 ± 0.27 g/100 g), finger millet (2.04 ± 0.34 g/100 g) and little millet (1.34 ± 0.16 g/100 g).

Dimensional properties: Dimensions include length, width and thickness of a seed. Seed length is the largest linear dimension of a seed, seed width is the largest linear dimension of the same seed perpendicular to the length-axis at its mid-point and seed thickness is the largest linear dimension of the same seed perpendicular to both the length-axis and the width-axis at their mid-points (Ganhao and Dias, 2019). The mean values of length, width and thickness of the BTM were found to be 3.00 ± 0.21, 1.79 ± 0.10 and 1.15 ± 0.09 mm. The average results of the geometric mean diameter and arithmetic mean diameter were found to be 1.82 ± 0.09 and 1.99 ± 0.1 mm at moisture content of 11.2 ± 0.16% (Nagaraju et al., 2020). Dayakar et al. (2019) has also reported the similar results for geometric and arithmetic mean diameter.

Color and Shape: Color and shape of millet distinguishes it from the other millets. It also influences sensory appeal. BTM is small greenish oval grain (Figure 3). The tristimulous color values for the BTM as determined by Minolta chromameter were found to be L^* = 60.45 ± 0.44, a^* = 3.78 ± 0.06 and b^* = 14.71 ± 0.33. The L^*, a^* and b^* values help to find out the color of the millet. The shape of the BTM was oval having sphericity of 59.82 ± 2.60% (Nagaraju et al., 2020). The shape of the kodo millet (Gomez and Gupta, 2003) is very similar to browntop millet. Its shape was determined by comparing the images (shapes) of BTMs with the standard shapes presented in the chart by Mohsenin (1986). The lengths of whole and dehulled BTM were found to be in the range of 1.79 ± 0.00 mm−3.19 ± 0.11 mm and 1.46 ± 0.00 mm−1.93±0.03 mm, respectively (Sravani et al., 2020).

Millets have unique nutrient composition which is good for physical and mental health. They have high fiber and vitamin content, low simple carbohydrates (ICAR-IIMR, 2016-17). Browntop millet is high in nutrition and has high energy content; 100 grams of BTM contains 338 Kcal of energy, 71.32 g of carbohydrate, 8.98 g of protein, and 1.89 g of fat (Roopa, 2015). It is a rich source of natural fiber i.e., 8.5% (Kishore et al., 2021). Consumption of dietary fiber has long been associated with health benefits like bowel movement, and maintenance of normal blood cholesterol and glucose levels. Further, it is a rich source of micro nutrients such as iron, calcium, potassium, magnesium, zinc, phosphorus, and B group Vitamins (Sarita and Singh, 2016). Therefore, BTM may serve as budding grain for therapeutic diets (Hithamani and Srinivasan, 2014).

According to Kishore et al. (2021), BTM is a good source of several minerals. It contains the 28 mg of calcium, 7.72 mg of iron, 276 mg of phosphorus, 60 mg of potassium, 94.5 mg of magnesium, 1.99 mg of manganese, 7.60 mg of sodium, 2.5 mg of zinc, 1.23 mg of copper per 100 gram of grain. Therefore, BTM can be considered as a dietary component which may support the prevention and management of certain non-communicable diseases (Kishore et al., 2021). The residual stalk including stem and leaves after harvesting the BTM (Panicum ramosum L.) is used as livestock feed because it contains 56.7 g/kg of crude protein and 594.2 g/kg of total digestible nutrient (Kering and Broderick, 2018) along with higher level of minerals like magnesium (5.9 g/kg), phosphorus (1.5 g/kg), and calcium (9.0 g/kg). High fiber content and presence of some anti-nutritional factors like phytates and tannins in millets affect bioavailability of minerals but these compounds are limited to millet seed coat which can be removed during processing (Ramashia et al., 2019). According to the Tables 3, 4 which shows comparison of macronutrients and micronutrients of different millets and staple cereals with the browntop millet (in percent), BTM contains 8.98 gm/100 gm of protein which is higher than protein of rice, wheat, sorghum, proso millet, finger millet, little millet, barnyard millet and kodo millet. Fat content of BTM is 1.89 gm/100 gm which is much higher than fat content of rice, wheat and sorghum. 71.32 gm/100 gm is the carbohydrate content of BTM that is higher than wheat, sorghum, pearl millet, proso millet, finger millet, little millet, barnyard millet and foxtail millet. Crude fiber value of BTM is 8.06 gm/100gm which is higher than rice, proso millet, little millet, foxtail millet and kodo millet. The energy value of BTM is 1414 kj/100 gm which is greater than energy value of wheat, sorghum, proso millet, finger millet, barnyard millet and foxtail millet. Calcium content of BTM is 28 mg/100 gm which is higher than calcium content of rice, pearl millet, proso millet, little millet and barnyard millet. Iron content of BTM is 8.86 mg/100 gm which is higher than iron content of all the millets and staple cereal grains i.e., rice and wheat. According to ICMR (2010), the bioavailability of iron is higher in case of rice based Indian diets (4–5%), followed by wheat Indian based diets (1.7–1.9%) and millet based Indian diet (0.8–0.7%). Keeping this assumption in mind, if BTM is substituted by rice in 1:1 ratio in typical Indian diets, the total iron absorption would be 5.02% higher. Similarly, if BTM is included in 1:1 ratio with wheat, the total iron absorption would be 172.6% higher. Phosphorus content of BTM is 276 mg/100 gm which is higher than phosphorus content of rice, sorghum, proso millet, finger millet and little millet while zinc in BTM is 2.5 mg/100 gm which is higher than zinc content of rice, sorghum, proso millet, little millet, foxtail millet and kodo millet.

According to Niharika B. et al. (2020), millets are rich in phytochemicals, also known as secondary metabolites such as flavonoids, quinones, phenols, tannins, alkaloids, besides carbohydrates and proteins. Her study found that flavonoids, tannins, resins and quinones were found to be present in BTM whereas in pearl millet, finger millet, sorghum and foxtail millet flavonoids and quinones they were not detected. Amount of phytochemicals present in BTM are unknown therefore, emphasis need to be given to find out the exact amount of therapeutic compounds present in BTM. Millets exhibit variable antimicrobial activities. The antimicrobial activity of various millets was studied by Niharika B. et al. (2020) and antimicrobial activity of BTM against Bacillus subtilis was in the lowest zone of inhibition i.e., 20 mm and highest zone of inhibition (30 mm) was shown by foxtail millet.

Millets are safe when consumed in a moderate amount. They have been consumed as staple food by millions of peoples in the past thousands of years. However, excessive consumption of millet might cause adverse effects. For example, millets contain phytic acids; it is a chelating agent which binds with cations of potassium, calcium, iron, zinc, magnesium and other cations and reduces their bioavailability in the body (Boncompagni et al., 2018). Besides phytic acid, goitrogens are also present. Goitrogens interfere with the production of thyroid hormones and inhibits iodine uptake and utilization by the thyroid gland (Gaitan et al., 1989). Deficiency of iodine leads to an array of Iodine Deficiency Disorders. In the Sudan region of Africa where millet is consumed as the primary source of energy, the occurrence of goiter has been found to be much greater than anywhere else in the world (Eltom et al., 1984). Hence, people with thyroid problems need to restrict consumption of millets. Other anti-nutritional factors present in millets/BTM include phenols, tannins, and enzyme inhibitors, and also a high amount of protease and amylase inhibitors that affect the digestibility of millets grains (Vetriventhan et al., 2020).

Thus, the advantage of having higher content of micronutrients may to some extent be nullified by lower bioavailability. More studies using state of art techniques and different methods of cooking are needed to examine the bioavailability of micronutrients including minerals and B-vitamins to ascertain the nutritional advantage in vivo especially for BTM. Processing can improve the bioavailability of nutrients as well as functionality of BTM grains. Limited studies show that bioavailability as well as functionality differs with the type of processing and preparation.

Processing of BTM has been studied by some researchers. Processing techniques like soaking and fermentation reduce the interaction between nutrients and anti-nutritional factors. They have been found to enhance the antioxidant activity and total phenolic compounds of BTM. Fermentation using curd has been found to increase nutritional value at a low cost for browntop millet Saini and Sasmal (2022). Millet grains, before consumption are usually processed by commonly used traditional techniques such as decortication, malting, fermentation, roasting, flaking, and grinding to improve their edible, nutritional, and sensory properties (Ahmed et al., 2006; Vinoth and Ravindhran, 2017). This could improve bioavailability of nutrients. However, the extent to which bioavailability may improve, need to be ascertained by systematized research.

Sirisha et al. (2022) analyzed the nutritive value of different types of browntop millet (brachiaria ramosa) flour obtained through various processing methods i.e., soaking, germination, fermentation, dry heating, hydrothermal treatment and extrusion cooking. According to the study, germinated whole browntop millet flour had lowest amount of energy i.e., 365.2 ± 2.4 kcal/100 g and highest energy value was recorded in hydrothermally treated dehulled browntop millet flour i.e., 396.5 ± 0.8 kcal/100 g. Lowest amount of carbohydrate was found in whole browntop millet flour i.e., 58.00 ± 1.06% and highest (79.68 ± 0.75%) in dry heated whole browntop millet flour. Hydrothermally treated dehulled browntop millet flour had lowest crude fiber i.e., 2.42 ± 0.16% while highest amount of crude fiber was present in fermented whole browntop millet flour i.e., 19.44 ± 0.29%. Lowest percent of fat was recorded in dry heated whole browntop millet flour i.e., 4.16 ± 0.08%, while fermented dehulled browntop millet flour had the highest amount of (7.08 ± 0.03%) fat. Fermented whole browntop millet flour had the lowest amount (6.10 ± 0.06%) of protein and dehulled browntop millet flour had highest amount (17.31 ± 0.25%). Refer Table 5 for details. Low ash content was recorded in soaked dehulled browntop millet flour i.e., 1.79 ± 0.17% and 5.80 ± 0.15% was the highest recorded in germinated whole browntop millet flour (Figure 4). Almost all the BTM flour had ash content higher than wheat—the staple cereal used in India. No, specifications have been given by Food Safety and Standards Authority of India (FSSAI) (2011), for millet flours. Such data can be used to develop specifications by regulatory agencies. Thus, to prepare value-added macronutrient rich products dry heated whole browntop millet flour and fermented dehulled browntop millet flour can preferably be used because it has highest energy value percentage of carbohydrates and fat i.e., 85.06% and 16.65%, germinated whole browntop millet flour had highest energy value of crude fiber i.e., 12.15%. Highest energy value of protein is 18.61% recorded in dehulled browntop millet flour.

Niharika V. et al. (2020) studied nutritional traits and grain yield of 30 indigenous collections of BTM (Brachiaria ramosa (L.) Stapf.). It was found that the protein content varied from 8.93% to 19.33% with a mean of 10.72%, crude fiber content varied from 6.5% to 9.87% with a mean of 8.06%, iron content was between 3.70 mg/100 g and 15.32 mg/100 g with a mean of 8.86 mg/100 g, zinc content from 1.36 mg/100 g to 2.8 mg/100 g with a mean of 2.11 mg/100 g, calcium content was from 8.00 mg/100 g to 33.00 mg/100 g with a mean of 13.97 mg/100 g, and grain yield per plant ranged from 4.74 g to 20.38 g with a mean of 12.13 g. The genotype IC 613556 had highest protein content, IC 613554 had highest crude fiber content, IC 617957 had highest iron content, IC 606693 and the “28 bijapur collection” had highest zinc content, IC 617952 had highest calcium content, and IC 617961 had high grain yield per plant (Figures 5, 6).

A study was conducted by Saini and Sasmal (2022) in which the effect of fermentation on the total phenolic compound content of BTM (brachiaria ramosa) samples was studied. It was found that the batch of BTM which was fermented for 18 h possessed the highest total phenolic content i.e., 73.50%w/w whereas unfermented BTM had low phenolic content i.e., 27.16%. BTM fermentation for 12 h and 48 h had 68 μmol (highest) and 52.54 μmol (lowest) iron (Fe(II)/ml) content.

Browntop millet is a crop of versatile use as it is grown as food for human consumption, forage and food for birds and as raw material for industries (Sheahan, 2014). In countries like India and Africa, small millets are consumed as whole or in form of flour. They are mainly used as food and for allied purposes, whereas in Japan they are mainly used as birds feed (Asharani et al., 2010). Studies report that under drought and cold stressed conditions the nitrate level reaches to toxic or lethal level and the forage obtained should not be fed to animals. In Southern part of India the grains of browntop millet from non-shattering varieties are consumed as boiled whole grain (like rice), porridge, kheer or unleavened bread and dosa (Nesbitt, 2005).

According to Reddy and Prasad (2017), BTM can be used to prepare a variety of dishes. Its grains are used in preparing at least nine traditional foods in southern India such as anna, dosai, kheer, nuchina mudda, roti, nippattu, chakkulli, haralu, kodubale and kadabuappe. Browntop millet is usually ground into flour and used to make flat breads like roti or dosa or polished and boiled to make gruel (kheer). Some of these foods are used in religious rituals, which may partly account for its persistence in cultivation (Kimata et al., 2000).

For human consumption, there is enough scope for value addition in the form of idli mix or making of biscuit by proportionately mixing browntop millet with other flours of major cereals, namely, rice and wheat (Roopa, 2015). BTM is an effective crop, much like oats (Bhat et al., 2018). Various ready-to-eat (RTE) and ready-to-cook (RTC) value-added products have been developed by University of Agricultural Science, Dharwad like laddu, cookies and dosa mix by using BTM as a core ingredient. BTM has been mixed with other ingredients like coconut, chocolate, drumstick etc (Table 6).

Millets fall under the category of C4 cereals. C4 cereals take more carbon dioxide (CO₂) from the atmosphere and convert it to oxygen (O₂), require low input, have high efficiency of water use, and hence, are more environment friendly. Thus, millets can help to phase out climatic uncertainties, reducing carbon dioxide from atmosphere, and can contribute in mitigating the climate change (Kumar et al., 2018). BTM is drought-tolerant, early maturing and harvested in about 75–80 days earlier than other millets. This millet is well suited for dry land, grown under a variety of soils and climates (Kishore et al., 2020, 2021).

Millets have been recognized as smart foods in view of their health benefits by International Crops Research Institute for the Semi-Arid Tropics. BTM is also rich in fiber i.e., 12.5 gm per 100 gram (Indian Institute of Millets Research (IIMR), 2022) and fiber helps to detoxify the body by removing the waste from the intestine. Fiber gets fermented in the colon and act as a prebiotic in the colon (Lei et al., 2006). Due to its high fiber content, if consumed regularly, BTM can help in the prevention and management of several non-communicable or lifestyle related diseases such as constipation, diverticulosis, dyslipidemia, metabolic syndrome to name a few (Dayakar et al., 2017; Ashoka and Sunitha, 2020). Millets have low glycemic index (GI). Because of the low GI, millets help in gradual increase in the post-prandial blood glucose levels. This is particularly helpful for patients suffering from impaired glucose tolerance as well as diabetes.

BTM contains good amount of minerals. It has significant levels of magnesium which is 94.5 mg/100 gm (Kishore et al., 2021). Magnesium is a vital mineral which aid in increasing the efficiency of insulin and glucose receptors by supporting many carbohydrate digesting enzymes, which manages insulin action (Hemamalini et al., 2021) and it also helps to reduce the pressure on blood vessels (Ashoka and Sunitha, 2020) which make it capable of reducing the effects of myocardium infarction and migraine (Sarita and Singh, 2016). BTM is gluten free and an excellent choice for people suffering from celiac disease (Saleh et al., 2013). BTM contain 276 mg per 100 gm phosphorous (Kishore et al., 2021). Phosphorous is involved in the structure of every cell in the body, forming the mineral matrix of bone and essential component in molecule i.e., adenosine triphosphate (ATP) also known as energy currency of the body (Hemamalini et al., 2021).

Besides fiber and minerals, millets are also rich in health-promoting phytochemicals like polyphenols, lignans, phytosterols, phyto-oestrogens, phytocyanins, phenolic compounds, tannis and flavonoids like, anthocyanins, carotenoids, and tocopherols. They are natural antioxidant that protect the phospholipid membrane around heart, nerves, muscles, and red blood cells from the attack of free radicals and thus prevent carcinogenesis, and aging (Theriault et al., 1999; Chandrasekara and Shahidi, 2010; Dayakar et al., 2018). Carotenoids are reported to prevent cardiovascular diseases like atherosclerosis, (Dwyer et al., 2001), maintain normal functioning of immune system, and retina of eyes (Beatty et al., 1999; Hegde et al., 2002; Chandrasekara and Shahidi, 2010; Sarita and Singh, 2016; Niharika B. et al., 2020). These also function as, immune modulators and detoxifying agents. BTM being rich in secondary metabolites (phytochemicals) can help to reduce the risk for gastric ulcers and colon cancer.

This study indicates that while scanty literature and isolated studies are available on BTM:- systematized evidence based literature and research is lacking. So far BTM is not listed in the “generally regarded as safe” (GRAS) list and no specific regulations have been outlined for this millet by the Food Safety and Standards Authority of India. There is an emergent need to carry systematized research in various salient areas pertaining to BTM such as nutritional and non-nutritional components in various varieties of BTM, especially those grown in various parts of India, in-vitro and in-vivo studies related to consumption of BTM, toxicological studies for various varieties and different parts of the plant (on both human and animal), bioavailability of nutrients from BTM in typical Indian diet, scope of value-added products prepared by using BTM, sensory and analytical studies on BTM and products/dishes made from BTM, scope of establishment of market linkages for BTM grains as well as innovative products made from BTM, scope of bio-fuels from BTM plant post-harvest, development, standardization and safety/efficacy studies on designer food products using BTM for specific diseases, development of regulations related to the production, processing, sale of BTM in India as well as for export, assessing the optimal use of water, manure, fertilizers for BTM, assessing the quality of BTM currently available in the market, animals studies on the safety aspects of using BTM as feed, promoting non-food uses of BTM plants such as in textiles, handicrafts, etc., e-database or e-repository on cultivation, availability, composition and research work done in above areas.