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Bran

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Wheat bran structure (E: outer layer; I: intermediate layer; A: aleurone layer)

Bran, also known as miller's bran, is the component of a cereal grain consisting of the hard layers - the combined aleurone and pericarp - surrounding the endosperm. Corn (maize) bran also includes the pedicel (tip cap).[1] Along with the germ, it is an integral part of whole grains, and is often produced as a byproduct of milling in the production of refined grains. Bran is highly nutritious, but is difficult to digest due to its high fiber content; its high fat content also reduces its shelf life as the oils/fats are prone to becoming rancid. As such, it is typically removed from whole grain during the refining process - e.g. in processing wheat grain into white flour, or refining brown rice into white rice.

Bran is present in cereal grain, including rice, corn (maize), wheat, oats, barley, rye, and millet. Bran is not the same as chaff, which is a coarser, scaly material surrounding the grain, but does not form part of the grain itself, and which is indigestible by humans.[2]

Composition

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Bran is particularly rich in dietary fiber and essential fatty acids, and contains significant quantities of starch, protein, vitamins, and dietary minerals. It is also a source of phytic acid, an antinutrient that prevents nutrient absorption.

The high oil content of bran makes it subject to rancidification, one of the reasons that it is often separated from the grain before storage or further processing. Bran is often heat-treated to increase its shelf life.

Nutrients (%) Wheat Rye Oat Rice Barley
Carbohydrates (excluding starch) 45–50 50–70 16–34 18–23 70–80
Starch 13–18 12–15 18–45 18–30 8–11
Proteins 15–18 8–9 13–20 15–18 11–15
Fats 4–5 4–5 6–11 18–23 1–2

Rice bran

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Rice bran is a byproduct of the rice-milling process (the conversion of brown rice to white rice), and it contains various antioxidants. A major rice bran fraction contains 12%–13% oil and highly unsaponifiable components (4.3%).[citation needed] This fraction contains tocotrienols (a form of vitamin E), gamma-oryzanol, and beta-sitosterol; all these constituents may contribute to the lowering of the plasma levels of the various parameters of the lipid profile. Rice bran also contains a high level of dietary fiber (beta-glucan, pectin, and gum). It also contains ferulic acid, which is also a component of the structure of nonlignified cell walls. Some research suggests, though, inorganic arsenic is present at some level in rice bran. One study found the levels to be 20% higher than in contaminated drinking water.[3] In recent study it was found that rice bran helps improve the health and manages to control the diabetes at certain extent. Also, it was noted that the aflatoxin contamination and arsenic contamination was increasing and their proper mitigation strategies are required [4]. Rice bran, is increasingly recognised for its diverse applications and significant health benefits. Rich in dietary fiber, essential vitamins (B and E), minerals, and bioactive compounds like γ-oryzanol and tocopherols, rice bran offers antioxidant, anti-inflammatory, and cholesterol-lowering properties. Its health benefits include managing diabetes by improving glycemic control, promoting cardiovascular health by reducing cholesterol levels, and supporting cancer prevention through its antioxidant compounds. Rice bran's high fiber content aids in digestive health enhance gut microbiota and helps manage weight by promoting satiety. It is also used in skincare products for its antioxidant properties and as an animal feed ingredient to improve livestock nutrition. Industrial applications include its use in producing biofuels and biodegradable plastics, showcasing its sustainability. Despite challenges like contamination by aflatoxins and arsenic, advancements in processing and stabilisation techniques have expanded rice bran's use as a functional food ingredient, dietary supplement, and environmentally friendly resource [4].

Uses

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Rice bran
Wheat bran
Oat bran

Bran is often used to enrich breads (notably muffins) and breakfast cereals, especially for the benefit of those wishing to increase their intake of dietary fiber. Bran may also be used for pickling (nukazuke) as in the tsukemono of Japan. Rice bran in particular finds many uses in Japan, where it is known as nuka (; ぬか). Besides using it for pickling, Japanese people add it to the water when boiling bamboo shoots, and use it for dish washing. In Kitakyushu City, it is called jinda and used for stewing fish, such as sardines.

Rice bran is stuck to the surface of commercial ice blocks to prevent them from melting.[citation needed] Bran oil may be also extracted for use by itself for industrial purposes (such as in the paint industry), or as a cooking oil, such as rice bran oil.

Wheat bran is useful as feed for poultry and other livestock, as part of a balanced ration with other inputs. Wheatings, a milling byproduct comprising mostly bran with some pieces of endosperm also left over, are included in this category.

Bran was found to be the most successful slug deterrent by BBC's TV programme Gardeners' World. It is a common substrate and food source used for feeder insects, such as mealworms and waxworms. Wheat bran has also been used for tanning leather since at least the 16th century.[5]

Research

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As with cereal fibers and whole grain consumption, bran is under preliminary research for the potential to improve nutrition and affect chronic diseases.[6][7]

Stability

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Commonly, bran is heat-treated with the intention of slowing undesirable rancidification, but a 2003 study of heat-treatment of oat bran found a complex pattern whereby increasingly intense heat treatment reduced the development of hydrolytic rancidity and bitterness with time, but increased oxidative rancidity. The authors recommended that heat treatment should be sufficient to achieve selective lipase inactivation, but not so much as to render the polar lipids oxidizable upon prolonged storage.[8]

See also

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References

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  1. ^ Corn Chemistry and Technology Watson and Ramstad 1987 p. 69
  2. ^ Catsberg, C. M. E. (1990). Food Handbook. Dordrecht: Springer Netherlands. doi:10.1007/978-94-009-0445-3_15. ISBN 978-94-009-0445-3. "chaff, which is indigestible for humans"
  3. ^ Sun, Guo-Xin; Williams, Paul N.; Carey, Anne-Marie; Zhu, Yong-Guan; Deacon, Claire; Raab, Andrea; Feldmann, Joerg; Islam, Rafiqul M.; Meharg, Andrew A. (2008). "Inorganic Arsenic in Rice Bran and Its Products Are an Order of Magnitude Higher than in Bulk Grain". Environmental Science & Technology. 42 (19): 7542–7546. Bibcode:2008EnST...42.7542S. doi:10.1021/es801238p. PMID 18939599.
  4. ^ a b Kodape, Anup; Kodape, Atul; Desai, Ria (1 February 2025). "Rice bran: Nutritional value, health benefits, and global implications for aflatoxin mitigation, cancer, diabetes, and diarrhea prevention". Food Chemistry. 464: 141749. doi:10.1016/j.foodchem.2024.141749. ISSN 0308-8146.
  5. ^ Rossetti, Gioanventura (1969). the plictho. Massachusetts: The Massachusetts Institute of Technology. pp. 159–160. ISBN 978-0262180306.
  6. ^ Barrett EM, Batterham MJ, Ray S, Beck EJ. (2019). "Whole grain, bran and cereal fibre consumption and CVD: a systematic review". British Journal of Nutrition. 121 (8): 914–937. doi:10.1017/S000711451900031X. PMID 30761962. S2CID 73449809.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  7. ^ Jefferson, A., & Adolphus, K. (2020). "The Effects of Increasing Intake of Intact Wheat Fibre or Wheat Bran on Gut Microbiota Diversity: A Systematic Review". Proceedings of the Nutrition Society. 79 (OCE2): E531. doi:10.1017/S0029665120004802.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  8. ^ Lehtinen, Pekka; Kiiliäinen, Katja; Lehtomäki, Ilkka; Laakso, Simo (2003). "Effect of Heat Treatment on Lipid Stability in Processed Oats". Journal of Cereal Science. 37 (2): 215–221. doi:10.1006/jcrs.2002.0496. ISSN 0733-5210. See figure 1 in particular