The oat grain comprises the groat, which in turn is enclosed within the external hull layer [79, 85]. Although structural differences between assorted varieties of oats have been highlighted by various researchers, generally speaking, an oat grain has a shell (25%); the pericarp, testa, and aleurone (9%); the endosperm (63%), which is a starchy substance; and the embryo (3%) [86]. Hulls must be separated from the groats before the beginning of the processing [85, 87]. After being dehulled, these grains or groats constitute approximately 75% of the whole grain’s total; this figure fluctuates between 65% and 80% due to both diversity and environmental differences [86]. Oat is generally consumed whole as oat flakes [85]. The metabolizable energy content of whole oats is 2.5 to 2.6 kcal/g, and it is quite low [88]. The highly nutritious nature of oat species means that they are beneficial components of human and animal diets [78]. The typical protein value of whole oats is 10%–12% [86, 89] and this value is similar to that of wheat [86]. Meanwhile, oats have amino acid contents that are better than those found in other grain species due to the main protein being globulin [78, 90]. Compared to prolamins, which are grain storage proteins, globulins contain higher amounts of lysine and other essential amino acids [78, 91]. Oats also contain high levels of lipids [78, 84, 92, 93]. The lipid concentration of oat groats is 2 to 5 times higher than that present in wheat. Lipid contents can reach amounts of up to 10% of the total oat mass [93,94]. The major fatty acids in oatmeal can be listed as linoleic acid (38%), oleic acid (36%), and palmitic acid (19%), followed by linolenic acid (2%) and stearic acid (2%). The water content of oatmeal is 8.5% and the ash content is 1.8%. About 57.8% of oatmeal consists of carbohydrates, so it can be said to be a valuable source for obtaining dietary fiber [79]. Total sugar contents of oats are about 1%, while reducing sugar contents are less than 0.1% [86, 95]. Meanwhile, there are rising levels of interest in the consumption of oat-derived food items due to the requirement for soluble fibers in the human diet, and especially β-glucans, having valuable health-promoting effects [78, 96–98]. 1,3- and 1,4-β-Glucans are present as 2% to 6% of the total mass of groats and 7% of the starchy endosperm [86, 99, 100]. β-Glucans create viscous gums with water [86, 101] and contribute to water retention capacity, processing behavior, and viscosity [86, 102]. As the most highly abundant component of oats, starch accounts for 60% of whole oat grain’s dry matter. Oat starch’s iodine affinity is about 19.5%. This is reasonably close to the values of wheat, rye, and barley [86, 103]. Also, the α-tocopherol content of oat grain is 4.5–12.3 mg/kg and can be considered as high [104].
In the daily diet, the consumption of oats, which contain β-glucan polysaccharides, various dietary fiber components, and antioxidant compounds like tocopherol, wields a positive influence on consumer health and decreases the risks of various illnesses and malignancies [104]. In many studies, the valuable fiber components in oats were found to exert both therapeutic and protective activities against cardiovascular diseases, type-2 diabetes mellitus, and various types of cancer, like colon cancer [105–109]. The β-glucans found in oats are reported to have an association with oat’s ability to lower blood cholesterol levels [109]. New data also show that oats positively affect body weight and blood pressure [79].
3.2.4 Barley
Barley is known as one of the most ancient cereals to have been produced throughout the world. Archaeological proof demonstrates barley’s presence along Egypt’s Nile River about 17,000 years ago [110, 111]. Production of barley, scientifically known as Hordeum vulgare L., ranks 4th globally after respective maize, rice, and wheat production [112, 113]. Approximately 12% of the grain cultivated in the world is barley [111, 114]. Barley is utilized as one of the necessary raw materials for producing malt and beer, also being widely consumed in the production processes for animal feed [113, 115]. It has been generally used in the feeding of poultry, pigs, and adult ruminants and monogastrics [116, 117]. Of the barley being grown today, approximately 65% is utilized for animal feed, while 33% is used for malt products and 2% is reserved for human consumption [111, 118]. Barley can be farmed on diverse types of soil and in various climates, and it is used by many different cultures and nations [119, 120]. Compared to other types of cereals, it performs better under varied environmental pressures because it is drought-resistant, survives well in winter, and matures early; therefore, it is commonly more economically cultivated compared to other possible crops [111, 121]. The United States, China, India, Russia, and other countries from the former USSR are the major barley-producing countries [122].
Barley grains primarily comprise the husk, the embryo, and the endosperm, consisting of the aleurone and of endosperm cells, which are starchy [123]. The husk is the outer layer of the barley and forms 10%–13% of the grain weight [123, 124]. The embryo is made up of an acrospire, which is a nodal region located in between the shoot and root, as well as a primary root, which is enclosed by a root sheath known as the coleorhiza. Embryos are disconnected from the endosperm during germination by the modified cotyledon (the scutellum) [123, 125]. The endosperm comprises a starchy part and a layer of aleurone around it. The endosperm constitutes the major unit of a barley grain, representing 75% of a grain’s weight [123, 124]. The endosperm’s task is to function like a starchy storage center for nutrients that embryos can utilize in the process of germination [99, 123]. The cells in the aleurone layer include lipids, protein, minerals, and vitamins [123, 124, 126, 127]. Aleurone cells are isodiametric, which is different from the endosperm cells. Apart from the embryo, the sole unit of the grain that contains living cells is the aleurone layer [123, 125].
Barley genotypes are classified as hulled and hull-less. The hull-less variety has better nutritional value compared to the hulled one [120, 128]. Hull-less barley generally has higher amino acid, total protein, and digestible energy contents compared to hulled barley [129–131]. Barley can be described as a perfect source for obtaining β-glucans and complex carbohydrates, two critical constituents of dietary fiber [132]. Barley grain contains 60%–80% carbohydrates, 9%–13% protein contents, 1%–2% fat, and 10%–15% water [132, 133]. The most limiting essential amino acid of cereal species, namely lysine, is found in higher levels in some cultivars [129–131]. Starch is the carbohydrate to be found most plentifully in barley grain, its levels varying between 62% and 77% in terms of the dry grain weight [132, 134]. The dietary fiber content of barley is 14%–25%. Arabinoxylan content is 4%–11%, while the β-glucans, cellulose, and lignin contents are 3%–7% [135–138]. Barley is rich in vitamins, particularly B vitamins, and it also has valuable mineral contents, especially trace minerals [139, 140]. Apart from β-glucans, the compounds in barley such as tocotrienol, phytoestrogens, lignans, polyphenols and phytic acid have been associated with health benefits [140, 141].
Epidemiological studies show that regular barley consumption has the possible ability of lowering the risks of various chronic diseases including colon cancer [111, 142, 143], chronic heart disease [111, 118, 144, 145], gallstones [111, 146, 147], and high blood pressure [111, 148]. There are reports of the role of barley in the maintenance of colon health [111, 149], the induction of stimulation of the immune system [111, 150], and immuno-enhancement [111]. In addition, barley consumption provides a protective effect against toxins, diabetes mellitus, and neurological problems such as Alzheimer disease [111, 151, 152].
3.2.5 Flaxseed