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Millets stand out as a beacon of hope and promise in a time when concerns about public health, environmental sustainability, and food security are on the rise. These modest grains, which are sometimes overlooked in favour of more popular crops, have exceptional properties that make them essential to sustainable agriculture as well as a rich in nutrients staple. A possible threat to global food security has been raised as the declining diversity of crop species that supply the world's food supply. Just twelve crops account for 75% of the world's food supply, with rice, wheat, and maize accounting for 50% of the world's dietary needs. Although these crops are the main sources of carbohydrates, they are deficient in important minerals and amino acids that are necessary for a balanced diet. Millions of individuals worldwide are impacted by the poor nutritional quality of the human food, which causes hidden hunger due to inadequate intake of vitamins and micronutrients like zinc (Zn), magnesium (Mg), and iron (Fe). For example, developing nations are home to over half of the world's population that is malnourished. The primary cause of this is an excessive reliance on starchy foods like rice, wheat, and maize. One useful tactic for increasing dietary diversity and lowering latent hunger would be to supplement major grains with alternative crops with superior nutritional content and nutraceutical qualities.

Millets are a type of minor cereals found in the Poaceae family. Millets are often described as “Nutri-Cereals” since they contain more nutrients than commonly produced main cereals. They are an important part of human’s diet in the world. These are foods with a high nutritional content, gluten-free and have nutraceutical qualities. The adequate amount of protein (essential amino acid), micronutrients and phytochemicals are found in millets. The phytochemicals found in millet grains enhance human health by lowering cholesterol and phytates in the body. Millets are full of antioxidants, minerals including dietary fibre, iron, calcium and magnesium that are vital for battling a variety of diseases. These are beneficial to include in our daily diet because the grain is healthy and nutritious. They decrease blood pressure, prevent cancer and lessen the chance of tumour growth. The rich nutrient content in millet has many health advantages such as cancer, obesity, lower risk of cardiovascular disease, gastrointestinal issues, migraines and asthma. People utilise millet-based products to fight a variety of nutritional deficiencies and diseases.

Millets which are also known as “Shree Anna” are a type of grass with small seeds that belongs to the Poaceae family and are widely grown throughout the world. Millets have high levels of proteins, minerals, vitamins, and antioxidants that why they are known to be climate-change-resilient crops. Proteins are essential amino acids that the body cannot synthesize and are used as a nitrogen source during embryo development following germination. Millets are high in dietary fibre and are important staple crop in many parts of the world. They are versatile grains that can be used to make a variety of food products, including millet flour. Millets are good for cardiac health, weight management, antioxidant activity, and may have anti-cancerous properties. They are nutrient- dense, provide sustained energy, and contain antioxidants such as polyphenols and flavonoids. Millets are considered safe and have a variety of health benefits. Surprisingly, millets perform major non-millet cereals in terms of nutrition. They are particularly high in dietary fibres, minerals, antioxidants, phytochemicals, and polyphenols, all of which have broad-spectrum positive effects on human health.

Minor millets, that belong to members of the cereal grass family, are advantageous in areas where large crops like Bread wheat, Rice paddy, and maize are relatively ineffective because they have a wide range of genetic diversity and thrive in marginal environments. The varied soil types, temperatures, heat and light cycles, and rainfall patterns across India all support the cultivation of minor millets. Finger millet, barnyard millet, foxtail millet, proso millet, and many more types of minor millet are used in agriculture. The majority of those who depend on these millets for sustenance and income are small-scale indigenous farmers and dwellers of rainfed areas, mainly among impoverished tribal populations numbering in the millions. Coarse cereals,now a days known as Nutri cereals or nutraceutical flora and are no longer known as coarse cereals as a potential global answer to malnutrition and unrecognized hunger. Minor millets have long been an essential component of Indian tribal societies’ agricultural systems and practices. They have used little millets for both famine prevention and ethnomedicine since the beginning of time. This chapter focuses on how little millet could help people have access to food and nutrition security while reducing hunger and malnutrition.

Millions of people worldwide suffer from food insecurity and malnutrition, which are exacerbated by issues including pollution, overcrowding, climate change, and economic hardship. These problems highlight the necessity of changing food systems for better immunity and health since they lead to both undernutrition and overnutrition. Essential carbs, fiber, fats, and important micronutrients including iron, calcium, potassium, zinc, and magnesium are all found in nutrient-dense grains such as foxtail, kodo, proso, tiny, and pearl millets. These millets are widely accessible and have several health advantages. For example, pearl millet is high in amylose starch and contains essential minerals like phosphorus and magnesium, whereas proso millet is a good source of iron, calcium, potassium, and B-vitamins. B vitamins, iron, calcium, and zinc are all found in kodo millet, while finger millet is a great provider of calcium, iron and magnesium. The nutritional profile of millets is further improved by processing methods like milling, germination, extrusion, and fermentation. Prominent research organizations, including as ICRISAT, ICAR, and CGIAR, are actively working to conserve millet and create better types to combat chronic illnesses and malnutrition. Targeted improvements in disease resistance and nutrient content are now possible because to biotechnology advancements. For improved worldwide health outcomes, dietary patterns must nonetheless be changed and these nutrient rich grains incorporated into contemporary food systems, notwithstanding current advancements.

Millets are highly nutritious and play a significant role in many people’s diets around the world. They have traditionally been transformed into a range of products through fermentation and malting for centuries. In the era of sustainable development, we still lag in using millets as a primary source of nutrition even after knowing that they are rich in terms of nutrition and other essential elements as compared to cereals. Today we have lots of information regarding different millets; nutrition content, methods of preservation, fermentation, malting, its products etc. Foods made from millet are regarded as potential prebiotics because they can improve the availability or functionality of probiotics, which has major positive effects on health. Foods have been fermented in order to enhance their flavor, texture and palatability. Although fermentation can result in a variety of products, the most prevalent ones are ethanol, lactic acid, carbon dioxide and hydrogen gas (H2 ). Commercial applications for these materials include use in food, vitamins, medications and industrial chemicals. Additionally, fermentation increases the amount of protein present, improves the accessibility of carbohydrates and reduces antinutritional components like tannin and phytic acid. Even though it has some drawbacks, such as the potential for contamination with dangerous microbes, fermentation technology is proven to enhance the nutritional quality of food products. This chapter covers the millet fermentation technology’s effects on the nutritional composition of the millets, contemporary developments in fermented millet-based products and technological improvements examined in the millet fermentation technology.

Introduction Millets, which are small-seeded grasses belonging to the Poaceae family, have a rich historical and cultural significance as they have been cultivated for thousands of years (Goron and Raizada, 2015; Wen et al., 2014; Cheng, 2018). They remain an important crop in various regions worldwide, particularly in developing countries where they serve as a staple food for millions, especially in rural areas. Millets offer several advantages as they are gluten free and provide valuable protein, fiber, and minerals, making them highly nutritious for both human consumption and animal feed. The diverse range of millets includes pearl millet (Cenchrus americanus (L.) Morrone), foxtail millet (Setaria italica (L.) P.Beauv.), proso millet (Panicum dichotomiflorum Michx.; syn. Panicum miliaceum Walter), finger millet (Eleusine coracana (L.) Gaertn.), barnyard millet (Echinochloa frumentacea Link), kodo millet (Paspalum scrobiculatum L.), little millet (Panicum sumatrense Roth), and more (Ahmad et al., 2018; Bora et al., 2019). These grains have a significant historical presence globally, with evidence of cultivation in ancient China, Greece, and Rome (Li et al., 2020a; Huan et al., 2022). In India, millets have maintained their importance as a vital crop for thousands of years and continue to be an integral part of the diet in many regions of the country today (Padulosi et al., 2015; Li et al., 2020b).

Due to their remarkable health benefits, such as their low glycemic index, rich amino acid profiles, and abundance of B vitamins and antioxidants, little millets, formerly hailed as nutri-cereals, are once again becoming important dietary staples. These crops, which include a variety of species like finger millet, foxtail millet, and barnyard millet, have stimulated innovation in the food business by producing value-added goods like rice analogs, noodles, and biscuits. Additionally, their medicinal qualities could help advance research on nutraceuticals. Small millets are essential to climate-smart agriculture because of their renowned resilience, which allows them to flourish on marginal soils and in difficult climates. Breeding efforts seeking to create climate-resilient, high-yielding, and lucrative cultivars can benefit greatly from their extensive genetic diversity, which is conserved in traditional landraces and farmer-managed cultivars. Even with their potential, small millets’ genetic development projects are still in their early stages, requiring concentrated efforts to find trait-specific donors and enhance breeding techniques. In addition to preserving their ethnobotanical and cultural heritage, the conservation of their genetic resources supports international initiatives for environmental sustainability and food security. Small millets have the potential to become a vital component of sustainable and nutritionally enhanced agricultural systems by incorporating cutting edge agricultural techniques and speeding up breeding improvements.

Millets categorized as cereal crops are rich sources of nutrients, mostly cultivated across arid and semiarid areas of the world, specifically in southeast Asia and Africa. Millets are easy to cultivate, demands minimal field input and have appreciable market values. Despite of great value of millets, their production is limited mainly because of climate change which triggers multiple abiotic stresses like drought, high temperature, salinity, etc. Even though millets can withstand the majority of abiotic stresses, it necessitates their further improvement to develop more resilience against unprecedented effects of climate change by incorporating or enhancing stress tolerance characteristics. It is currently not attainable to create stress tolerant and high yielding varieties through conventional breeding techniques and thus modern approaches like genome editing become inevitable to achieve this goal. Also, available data for genome sequences of millets in these years promotes genome editing. The technique has drawn tremendous attention recently due to its potential in precise modification of alleles and is considerable to speed-up crop breeding by targeting important traits with precision. Additionally, many stress-resistant genes are identified in related monocots and are reported to be orthologs of millets which could assist genome editing for developing stress resilience and productivity in millets. Above all, the technique has also gained legal acceptance and has potential to revolutionary counter climatic challenges.

Millets are an essential food in the world’s semi-arid and arid regions. These are effective energy providers. They provide dietary fibre, polyphenols, fatty acids, minerals, vitamins and protein. The production of tropical crops is highly risky due to the pest outbreaks and increased abiotic pressures triggered by the climate change. Despite the fact that conventional breeding methods have greatly enhanced crop yield and output, new strategies are needed to further enhance crop productivity in order to fulfil the world’s expanding need for the food. The use of site-specific nucleases like zinc finger nuclease (ZFN), transcription activator-like effector nuclease (TALEN) and clustered regularly interspaced short palindromic repeat associated proteins 9 (CRISPR-Cas9) are the genome editing technologies developing very fast. The advancement of plant genome research and its use in plant breeding are significantly aided by such achievements. CRISPR/Cas9 and related genome editing methods are emerging as appropriate methods to reduce the negative consequences of climate change and assure the long-term food security of tropical countries’ growing populations.

Millets have potential as both food and fodders crops. Foods made from millet are abundant in micronutrients and necessary amino acids for regulatory functions. Since, millets were traditionally grown under adverse conditions, a great amount of polymorphism was preserved, making millet crops naturally resistant to abiotic and biotic stresses. Using data-driven technology to increase genetic gain in breeding operations can improve traditional breeding. Artificial intelligence can be used to create varieties that are adapted to certain soil and climatic conditions. In order to achieve breeding goals, machine learning (ML) is crucial in data mining and analysis, providing information for decision-making. We have been able to generate information on interesting genes using data mining and allele identification methods. For the exploitation of the natural variation and the identification of target genes, advances in high-throughput sequencing for the detection of genetic variations as well as the role of phenomics in genomics-assisted breeding can be employed. QTLs and marker-trait correlations can be identified via genome-wide association analyses. Multiple loci and genes that control agronomic traits have can be studied by comparative and functional genomics. Model selection is crucial for ML algorithms in smart breeding, which depends on knowledge in genotype, phenotype, and G×E interaction to be handled through computer science.

The demand of day by day increasing population there is lacking of nutritious food to peoples all around world. Underutilized crops like small or minor millets are having more nutrition and providing calories up to 2000 to 3000 calories per person per day than our staple crops i.e wheat, rice, and maize etc. Small Millets are the most underutilized crop in the world possessing high nutrient-cereal qualities and potential for the improvement of food security, nation income and generate the employment for the rural peoples. Millets are rich in nutrients such as proteins, fibers, carbohydrates, fats, vitamin-B, and minerals like calcium, phosphorus, magnesium, iron, potassium, and zinc etc.They are highly nutritive crop, non-acid forming, glutan free and help in reducing blood sugar level, blood pressure, diabetes and cardiovascular diseases. They also help in preventing asthma and migraines sufferings and fighting malnutrition in children s and adults.S mall millets are considered the forgotten crop species because of lower yield compared to other millets i.e. Sorghum and Pearl millet and cereals i.e. rice, wheat, maize etc. Being a highly nutritive cereal crop, easy to digest, high fibers and low glycine-max content, environment friendly and prevent the human hazards small millets still remained neglected and underutilized crop. Out of 200 underutilized crops identified 29 are small millets species (NAS USA, ICUC). Considering the food demand of common peoples, emerging health consciousness and nutrient demand for food security emerged small millets to limelight because of ecologically sound to climate. Still, the harvest of crop demands combination of computational technologies to full-fill food needs of population. Recognizing the potential of small millets in improving the national income UN-FAO announced the year 2023 as International Year of Millets. This chapter focused on application of climate smart agricultural methods such as artificial intelligence for the improvement of small millets to achieve future food security.

Agriculture is the support for the sustainable health and economic growth of the country. With the frequent changes in climatic conditions and increase of global population, it is important to come up with new varieties and nutrient rich crops. In this context, underutilized and neglected millets, considered as “nutri-cereals” or “smart foods” due to better adaptation in diverse environmental stresses and tolerance to insect pests and diseases, also a staple crop for hunger-stricken areas. Millet production is limited by the lack of intensive farming and deployment of genetic tools for trait and nutrition improvement. The recent advancement in machine learning (ML) and Artificial Intelligence (AI) technologies are key to depict plant response to environmental perturbation in huge data sets. Therefore, precision agriculture or smart farming is necessary to explore the genetic makeup of the neglected millets. AI has a substantial potential to handle numerous challenges in the formation of knowledge-based farming systems. The next agricultural revolution would emphasize more on farm machinery using AI integrated with the Internet of Things (IoT). In Smart agriculture, deep learning facilitates fast and interesting data analysis and provides support to researchers and farmers by the outcomes generated from the analysis. Here, we emphasize on the advancement of AI and its application to monitor the underutilized and neglected millets quality, yield and disease assessment. This chapter summarizes how AI can contribute to the improvement of sustainable productivity and quality of underutilized and neglected millet.

Millets are the staple food cropsacross the globe. The ability to thrive in harsh conditions established them as most suitable for current climate adversaries. The nutritional richness of millet reminded the need for adding them to our food basket.Despite possessing several desirable traits their cultivation is limited to a few pockets across the globe.Though significant progress has been achieved by conventional and transgenic breeding programs inmillets, there is a need for rapid improvement to meet the current needs.In order to accelerate the pace of breeding efforts, several molecular biology and biotechnology tools are being deployed by plant breeders. In the meantime, genome editing techniques like CRISPR, TALENS, ZFNs, Base and Prime editing have revolutionized the methods of genome engineering among which CRISPR has emerged as the most rapid, convenient and effective mechanism. The availability ofwhole genome sequence information, identified candidate genesfor various traits and successful transformation methods of millets promoted the application of CRISPR and resulted in the improvement of several traits. Initially, its application has been limited due to the restricted policies across the globe but the gradual change in the policies promoted genome editing across several parts of the globe. Thus, the application of genome editing for millet crop improvement can bring back those ancient grains to our food basket.

A Alcohol content: 21 Alcoholic beverages: 20, 64, 70, 75, 189 Alternative grains: 21 Anti-diabetic: 7, 57, 104, 105, 121 Antioxidants: 1, 2, 6, 7, 13, 16, 25, 72, 103, 107, 112, 120, 122, 124, 130, 176 B Barnyard millet: 2, 5, 8, 15, 16, 27, 31, 34, 38, 41, 53, 71, 82, 83, 86, 92, 93, 102, 104, 107, 110, 111, 113, 114, 118, 120, 131, 150, 154, 184, 186, 187, 188, 192, 199, 216, 217 Bioavailability: 26, 51, 60, 61, 63, 65, 74, 78, 79, 80, 82, 99, 135, 234 Bread: 2, 31, 32, 38, 62, 63, 64, 66, 67, 70, 75, 82, 96