Wheat germ
Rating : 7
Evaluation | N. Experts | Evaluation | N. Experts |
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1 | 6 | ||
2 | 7 | ||
3 | 8 | ||
4 | 9 | ||
5 | 10 |
Cons:
Contains gluten (1)0 pts from Nat45
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![]() | "Descrizione" about Wheat germ by Nat45 (5730 pt) | 2025-Jun-14 08:54 | ![]() |
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Wheat Germ: composition, nutritional value, extraction, applications, and sustainability
Definition
Wheat germ is the embryonic part of the wheat kernel (Triticum spp.), from which a new plant develops. Although it represents only 2–3% of the total grain weight, it contains a high concentration of essential nutrients and bioactive compounds, making it one of the most nutrient-dense parts of the grain.
During industrial milling, it is typically separated to extend flour shelf life, but it can be recovered and used as a functional food ingredient or nutraceutical.
1. Average composition (per 100 g)
Energy: 350–370 kcal
Protein: 25–30 g
Fat: 8–13 g
includes linoleic acid (omega-6), oleic acid (omega-9), α-linolenic acid (omega-3)
Carbohydrates: 25–30 g
Fiber: 12–15 g
Vitamin E (α-tocopherol): 15–20 mg
B Vitamins: B1 (thiamine), B2, B3, B6, folate
Minerals: iron, zinc, magnesium, potassium, phosphorus, selenium
Phytosterols, polyphenols, alkylresorcinols
2. Biological role in the wheat kernel
Located at the base of the grain, adjacent to the aleurone layer
Contains enzymes, proteins, and lipids essential for germination
It is the living part of the seed that gives rise to roots and the embryonic shoot
3. Extraction and stabilization process
Separated during roller milling of wheat
Available in various forms:
raw (fresh wheat germ)
stabilized (heat-treated to prevent rancidity)
cold-pressed to obtain wheat germ oil
For food use, it is often dried and micronized
4. Nutritional benefits and functional properties
Rich source of complete plant proteins with a balanced amino acid profile
High in unsaturated fatty acids that support heart health
Excellent natural source of vitamin E, a powerful antioxidant
Contains folic acid, important during pregnancy
Supplies magnesium and zinc, key for energy metabolism and immune function
Phytosterols contribute to lowering LDL cholesterol
The fiber content improves digestive regularity and glycemic control
5. Applications
Food
Added to breakfast cereals, granola, bread, cookies
Incorporated in protein bars, smoothies, yogurts
Used as a natural nutrient booster in health foods and supplements
Cosmetics
Wheat germ oil is used for its vitamin E and emollient properties in:
anti-aging creams
body oils
hair masks
moisturizers for dry and sensitive skin
Pharmaceuticals/Nutraceuticals
Used in capsules or powders as antioxidant and energy-support supplements
Natural source of tocopherols and sterols
6. Safety and tolerability
Generally well tolerated
Contains gluten, not suitable for people with celiac disease
Raw wheat germ is prone to oxidation → must be stored cool or used in stabilized form
Wheat germ oil may trigger allergic reactions in sensitive individuals
7. Environmental and sustainability aspects
A valuable byproduct of wheat milling: recovering it reduces food waste
Using wheat germ supports a low-impact grain processing chain
In organic agriculture, it comes from rotational wheat crops, improving soil fertility
Cold-pressed wheat germ oil has a lower energy footprint compared to refined seed oils
8. Conclusion
Wheat germ is a highly nutritious and functional ingredient that concentrates the most vital components of the wheat kernel. Its high content of protein, healthy fats, vitamin E, B vitamins, and fiber makes it an excellent addition to a balanced diet.
Thanks to its versatility, it is used in health foods, cosmetics, and supplements, while contributing to sustainable food systems by making use of a part of the grain that would otherwise be discarded.
References_____________________________________________________________________
(1) Ann J Slade, Cate McGuire, Dayna Loeffler, Jessica Mullenberg, Wayne Skinner, Gia Fazio, Aaron Holm, Kali M Brandt, Michael N Steine, John F Goodstal, Vic C Knauf Development of high amylose wheat through TILLING BMC Plant Biol. 2012; 12: 69. Published online 2012 May 14. doi: 10.1186/1471-2229-12-69
Abstract Background: Wheat (Triticum spp.) is an important source of food worldwide and the focus of considerable efforts to identify new combinations of genetic diversity for crop improvement. In particular, wheat starch composition is a major target for changes that could benefit human health. Starches with increased levels of amylose are of interest because of the correlation between higher amylose content and elevated levels of resistant starch, which has been shown to have beneficial effects on health for combating obesity and diabetes. TILLING (Targeting Induced Local Lesions in Genomes) is a means to identify novel genetic variation without the need for direct selection of phenotypes. Results: Using TILLING to identify novel genetic variation in each of the A and B genomes in tetraploid durum wheat and the A, B and D genomes in hexaploid bread wheat, we have identified mutations in the form of single nucleotide polymorphisms (SNPs) in starch branching enzyme IIa genes (SBEIIa). Combining these new alleles of SBEIIa through breeding resulted in the development of high amylose durum and bread wheat varieties containing 47-55% amylose and having elevated resistant starch levels compared to wild-type wheat. High amylose lines also had reduced expression of SBEIIa RNA, changes in starch granule morphology and altered starch granule protein profiles as evaluated by mass spectrometry. Conclusions: We report the use of TILLING to develop new traits in crops with complex genomes without the use of transgenic modifications. Combined mutations in SBEIIa in durum and bread wheat varieties resulted in lines with significantly increased amylose and resistant starch contents.
(2) Englyst HN, Macfarlane GT. Breakdown of resistant and readily digestible starch by human gut bacteria. J Sci Food Agric. 1986;37:699–706.
Abstract. Cooking and processing of starch-containing foodstuffs results in a portion of the starch becoming resistant to hydrolytic enzymes secreted in the small intestine of man. In order to determine whether this resistant starch (RS) was degraded in the colon, samples of RS and readily digestible starch (RDS) for comparisons were incubated with (a) cell-free supernatants from faecal suspensions and (b) washed faecal bacterial cell suspensions. The data obtained showed that, whereas pancreatic amylase and faecal supernatants hydrolysed RDS, with the production of oligosaccharides, RS totally resisted breakdown. In contrast, both RS and RDS were completely degraded by the washed bacterial cells with the generation of volatile fatty acids (VFA) and organic acids. Hydrolysis and fermentation of RDS was extremely rapid and, as a consequence, oligosaccharides and lactate initially accumulated in the culture medium. RS was broken down more slowly, howevér, and oligosaccharides and lactate never accumulated. The rate of polysaccharide hydrolysis had a significant effect on the quantities of VFA produced, in that 54% of carbohydrate was fermented to VFA in cultures incubated with RDS as sole carbon source as compared to only 30% in cultures incubated with RS. However no qualitative difference was observed in the VFA produced by fermentation of RDS or RS.
(3) Robertson MD, Currie JM, Morgan LM, Jewell DP, Frayn KN. Prior short-term consumption of resistant starch enhances postprandial insulin sensitivity in healthy subjects. Diabetologia. 2003;46:659–665.
Abstract. Aims/hypothesis: Diets rich in insoluble-fibre are linked to a reduced risk of both diabetes and cardiovascular disease; however, the mechanism of action remains unclear. The aim of this study was to assess whether acute changes in the insoluble-fibre (resistant starch) content of the diet would have effects on postprandial carbohydrate and lipid handling. Methods: Ten healthy subjects consumed two identical, low-residue diets on separate occasions for 24 h (33% fat; <2 g dietary fibre). Of the diets one was supplemented with 60 g resistant starch (Novelose 260). On the following morning a fibre-free meal tolerance test (MTT) was carried out (59 g carbohydrate; 21 g fat; 2.1 kJ) and postprandial insulin sensitivity (SI(ORAL)) assessed using a minimal model approach. Results: Prior resistant starch consumption led to lower postprandial plasma glucose (p=0.037) and insulin (p=0.038) with a higher insulin sensitivity(44+/-7.5 vs 26+/-3.5 x 10(-4) dl kg(-1) min(-1) per micro Uml(-1); p=0.028) and C-peptide-to-insulin molar ratio (18.7+/-6.5 vs 9.7+/-0.69; p=0.017). There was no effect of resistant starch consumption on plasma triacylglycerol although non-esterified fatty acid and 3-hydroxybutyrate levels were suppressed 5 h after the meal tolerance test. Conclusion: Prior acute consumption of a high-dose of resistant starch enhanced carbohydrate handling in the postprandial period the following day potentially due to the increased rate of colonic fermentation.
Robertson MD, Bickerton AS, Dennis AL, Vidal H, Frayn KN. Insulin-sensitizing effects of dietary resistant starch and effects on skeletal muscle and adipose tissue metabolism. Am J Clin Nutr. 2005;82:559–567
Abstract. Background: Resistant starch may modulate insulin sensitivity, although the precise mechanism of this action is unknown. Objective: We studied the effects of resistant starch on insulin sensitivity and tissue metabolism. Design: We used a 4-wk supplementation period with 30 g resistant starch/d, compared with placebo, in 10 healthy subjects and assessed the results by using arteriovenous difference methods. Results: When assessed by euglycemic-hyperinsulinemic clamp, insulin sensitivity was higher after resistant starch supplementation than after placebo treatment (9.7 and 8.5 x 10(-2) mg glucose x kg(-1) x min(-1) x (mU insulin/L)(-1), respectively; P = 0.03); insulin sensitivity during the meal tolerance test (MTT) was 33% higher (P = 0.05). Forearm muscle glucose clearance during the MTT was also higher after resistant starch supplementation (P = 0.03) despite lower insulin concentrations (P = 0.02); glucose clearance adjusted for insulin was 44% higher. Subcutaneous abdominal adipose tissue nonesterified fatty acid (NEFA; P = 0.02) and glycerol (P = 0.05) release were lower with resistant starch supplementation, although systemic NEFA concentrations were not significantly altered. Short-chain fatty acid concentrations (acetate and propionate) were higher during the MTT (P = 0.05 and 0.01, respectively), as was acetate uptake by adipose tissue (P = 0.03). Fasting plasma ghrelin concentrations were higher with resistant starch supplementation (2769 compared with 2062 pg/mL; P = 0.03), although postprandial suppression (40-44%) did not differ significantly. Measurements of gene expression in adipose tissue and muscle were uninformative, which suggests effects at a metabolic level. The resistant starch supplement was well tolerated. Conclusion: These results suggest that dietary supplementation with resistant starch has the potential to improve insulin sensitivity. Further studies in insulin-resistant persons are needed.
(4) Topping DL, Clifton PM. Short-chain fatty acids and human colonic function: roles of resistant starch and nonstarch polysaccharides. Physiol Rev. 2001;81:1031–1064.
Abstract. Resistant starch (RS) is starch and products of its small intestinal digestion that enter the large bowel. It occurs for various reasons including chemical structure, cooking of food, chemical modification, and food mastication. Human colonic bacteria ferment RS and nonstarch polysaccharides (NSP; major components of dietary fiber) to short-chain fatty acids (SCFA), mainly acetate, propionate, and butyrate. SCFA stimulate colonic blood flow and fluid and electrolyte uptake. Butyrate is a preferred substrate for colonocytes and appears to promote a normal phenotype in these cells. Fermentation of some RS types favors butyrate production. Measurement of colonic fermentation in humans is difficult, and indirect measures (e.g., fecal samples) or animal models have been used. Of the latter, rodents appear to be of limited value, and pigs or dogs are preferable. RS is less effective than NSP in stool bulking, but epidemiological data suggest that it is more protective against colorectal cancer, possibly via butyrate. RS is a prebiotic, but knowledge of its other interactions with the microflora is limited. The contribution of RS to fermentation and colonic physiology seems to be greater than that of NSP. However, the lack of a generally accepted analytical procedure that accommodates the major influences on RS means this is yet to be established.
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