Quality of Bread Supplemented with Antrodiasalmonea-Fermented Grains.

Fermented grains of buckwheat, oat, embryo rice and wheat, which were prepared by solid-state fermentation with Antrodia salmonea, and the mycelium was used to substitute 7% of wheat flour to make bread. No difference in proximate composition, texture profile and contents of non-volatile taste components was observed among bread samples. White bread and bread supplemented with mycelium and fermented grains looked different. Bread supplemented with fermented grains had similar thermal properties, which differed from those of white bread and bread supplemented with mycelium. Bread supplemented with fermented grains contained substantial mass fractions (on dry mass basis) of adenosine (0.92-1.96 µg/g), ergosterol (24.53-30.12 µg/g), ergothioneine (2.16-3.18 µg/g) and γ-aminobutyric acid (2.20-2.45 µg/g). In addition, bread supplemented with mycelium contained lovastatin (0.43 µg/g). White bread and bread supplemented with fermented grains had similar sensory results. Overall, fermented grains could be incorporated into bread to provide beneficial effects.

Antioxidant and Anti-Inflammatory Properties of Solid-State Fermented Products from a Medicinal Mushroom, Taiwanofungus salmoneus (Higher Basidiomycetes) from Taiwan.

Cooked grains of buckwheat (TSFB), oats (TSFO), embryo rice (TSFR), or wheat (TSFW) were inoculated with the medicinal fungus Taiwanofungus salmoneus (=Antrodia salmonea), and the metabolites formed were evaluated for antioxidant activity using the conjugated diene method, reducing power, scavenging ability, and chelating ability. Overall, the effectiveness was generally in the descending order of TSFB ≥ TSFO > TSFR ≥ TSFW. The correlation between effective concentration (EC50) of antioxidant property and antioxidant component content measured was established. However, flavonoid contents correlated well with antioxidant properties assayed (r = 0.707-0.933). Fermented products contained substantial amounts of adenosine (34.7-73.8 µg/g), ergosterol (1070-1212 µg/g), ergothioneine (81.0-119.8 µg/g), γ-aminobutyric acid (100.9-170.2 µg/g), and lovastatin (3.06-5.60 µg/g). In addition, with the addition of the extracts from fermented products, lipopolysaccharide-induced nitric oxide, tumor necrosis factor-α, interleukin-1ß, and interleukin-6 production in RAW 264.7 murine macrophage cells could be effectively suppressed. Accordingly, four types of T. salmoneus fermented products could be beneficially used as food-flavoring materials and food ingredients or as nutritional supplements.

Quality of bread supplemented with mushroom mycelia.

Mushroom mycelia of Antrodia camphorata, Agaricus blazei, Hericium erinaceus and Phellinus linteus were used to substitute 5% of wheat flour to make bread. Bread quality, including specific volume, colour property, equivalent umami concentration (EUC), texture profile analysis, sensory evaluation and functional components, was analysed. Mycelium-supplemented bread was smaller in loaf volume and coloured, and had lower lightness and white index values. White bread contained the lowest amounts of free umami amino acids and umami 5'-nucleotides and showed the lowest EUC value. Incorporating 5% mushroom mycelia into the bread formula did not adversely affect the texture profile of the bread. However, incorporating 5% mushroom mycelia into the bread formula did lower bread's acceptability. After baking, mycelium-supplemented bread still contained substantial amounts of γ-aminobutyric acid and ergothioneine (0.23-0.86 and 0.79-2.10 mg/g dry matter, respectively). Overall, mushroom mycelium could be incorporated into bread to provide its beneficial health effects.

Comparative study of contents of several bioactive components in fruiting bodies and mycelia of culinary-medicinal mushrooms.

Mushrooms have been consumed for thousands of years, and several bioactive components were found therein, including lovastatin, γ-aminobutyric acid (GABA) and ergothioneine. The study reported herein was to analyze these three bioactive components in 15 fruiting bodies and 9 mycelia of 19 species of mushrooms from genera Agaricus, Agrocybe, Auricularia, Boletus, Ganoderma, Hypsizygus, Inonotus, Lentinus, Morchella, Pleurotus, Tremella, Termitomyces, and Volvariella. The results show that Hypsizygus marmoreus contained the highest amount of lovastatin (628.05 mg/kg) in fruiting bodies and Morchella esculenta contained the highest amount (1438.42 mg/ kg) in mycelia. Agaricus brasiliensis contained the highest amount of GABA (1844.85 mg/kg) in fruiting bodies, and mycelia of Boletus edulis, Pleurotus citrinopileatus, and Termitomyces albuminosus contained extraordinarily higher amounts (1274.03, 1631.67, and 2560.00 mg/kg, respectively). Volvariella volvacea contained the highest amount of ergothioneine (537.27 mg/kg) in fruiting bodies and mycelia; Boletus edulis, Pleurotus ferulae, and P. salmoneostramineus contained relatively higher amount of ergothioneine too (258.03, 250.23, and 222.08 mg/kg, respectively). However, none of these components was detected in fruiting bodies of Inonotus obliquus. In conclusion, these three bioactive components were commonly found in most mushrooms, and these results might be related to their beneficial effects.

Nutrient compositions of culinary-medicinal mushroom fruiting bodies and mycelia.

Mushrooms (including fruiting bodies and mycelia) are a food with high nutritional value. This article summarizes the results of proximate composition studies of 38 fruiting bodies and 19 mycelia of 32 species of culinary-medicinal mushrooms from genera Agaricus, Agrocybe, Antrodia, Auricularia, Boletus, Clitocybe, Coprinus, Cordyceps, Trametes, Dictyophora, Flammulina, Ganoderma, Grifola, Hericium, Hypsizygus, Inonotus, Lentinus, Morchella, Pleurotus, Sparassis, Termitomyces, Tremella, and Tricholoma. Based on the proximate composition, most fruiting bodies and mycelia are low in fat and rich in protein and dietary fiber (DF); however, some are rich in soluble polysaccharides and others are rich in crude fiber. Due to the high amount of DF present, the energy provided by 100 g of dry fruiting bodies and mycelia is 46.96-292.37 kcal and 195.84-373.22 kcal, respectively. The energy (100 g) is classified into four levels: first level of >300 kcal, second level of 200-300 kcal, third level of 100-200 kcal, and fourth level of <100 kcal. Most fruiting bodies are listed in the third level; nine mycelia are listed in the first level and ten in the second level. Overall, the information about the proximate composition and energy are of great interest for fruiting bodies and mycelia to be used as foods or food-flavoring materials or in the formulation of health foods.