The present specification provides a method of preparing a mycelium complex, which includes inputting a β-glucan-containing mushroom raw material into a medium, inputting a physiologically active material-containing plant raw material into the medium, and culturing the β-glucan-containing mushroom raw material with the physiologically active material-containing plant raw material, a mycelium complex, and a method of preparing a β-glucan-containing product.

Generally described are methods of preparing flavor-infused coffee beans by preparing a flavor-infused spirit, steeping coffee beans in the flavor-infused spirit, and roasting the flavor-infused coffee beans. Some embodiments relate to flavor-infused coffee beverages prepared from flavor-infused coffee beans.

Generally described are methods of preparing flavor-infused coffee beans by preparing a flavor-infused spirit, steeping coffee beans in the flavor-infused spirit, and roasting the flavor-infused coffee beans. Some embodiments relate to flavor-infused coffee beverages prepared from flavor-infused coffee beans.

A primary processing technology for effectively improving the qualities of immature coffea Arabica fruits, in which the immature coffea Arabica fruits, particularly the coffee cherries picked at the last batch, are subjected to selecting, cleansing, drying, peeling, fermentation, the first sun-cure, stacking, kneading, the second sun-cure, to achieve the primary processing on the immature coffea Arabica fruits, thus obtaining coffee beans in the shell, which could effectively reduce the production of defects, increase the aroma of coffee beans, enhance the level of body, making the coffee beans with bright and lively sour taste and a lasting taste, thus enhancing the qualities of the immature coffea Arabica fruits. The SCAA cupping scores of the coffee beans in the shell obtained after being processed were not lower than 84, while the SCAA scores of the coffee beans in the shell obtained with the existing technology were not greater than 75.

A primary processing technology for effectively improving the qualities of immature coffea Arabica fruits, in which the immature coffea Arabica fruits, particularly the coffee cherries picked at the last batch, are subjected to selecting, cleansing, drying, peeling, fermentation, the first sun-cure, stacking, kneading, the second sun-cure, to achieve the primary processing on the immature coffea Arabica fruits, thus obtaining coffee beans in the shell, which could effectively reduce the production of defects, increase the aroma of coffee beans, enhance the level of body, making the coffee beans with bright and lively sour taste and a lasting taste, thus enhancing the qualities of the immature coffea Arabica fruits. The SCAA cupping scores of the coffee beans in the shell obtained after being processed were not lower than 84, while the SCAA scores of the coffee beans in the shell obtained with the existing technology were not greater than 75.

The invention relates to a plant-based glutamic acid rich protein composition and method of making the same. The composition provides a spectrum of amino acids, including an abundance of glutamic acid. The composition is free of the antibiotics and growth hormones associated with animal-sourced proteins and does not require amino acid supplementation to achieve high levels of glutamic acid. In some aspects, the composition is obtained from coffee beans, including defatted green coffee beans.

The invention relates to a plant-based glutamic acid rich protein composition and method of making the same. The composition provides a spectrum of amino acids, including an abundance of glutamic acid. The composition is free of the antibiotics and growth hormones associated with animal-sourced proteins and does not require amino acid supplementation to achieve high levels of glutamic acid. In some aspects, the composition is obtained from coffee beans, including defatted green coffee beans.

Described are methods and/or techniques for the production of coffee fruit extracts on the basis of coffee cherries, which enable improved extraction and yield of usable aromatic constituents and nutritionally beneficial components (incl. polyphenols, antioxidants, and/or sugars) of the coffee fruit. Specifically, the invention relates to a coffee cherry processing method, having the steps of: (1) adding water to coffee cherries or to any of pulp or green, unroasted coffee beans obtained from the coffee cherries to form a suspension; (2) wet grinding said suspension in multiple steps to an average particle size of 100μηη or less; and (3) subjecting said suspension to one or more separation and/or processing steps having at least the separation of the water phase to obtain at least one coffee cherry extract selected from coffee cherry aroma, coffee cherry oil, coffee cherry powder, coffee cherry juice, coffee pulp aroma, coffee pulp powder, coffee pulp juice, coffee aroma and green or roasted coffee powder.

Described are methods and/or techniques for the production of coffee fruit extracts on the basis of coffee cherries, which enable improved extraction and yield of usable aromatic constituents and nutritionally beneficial components (incl. polyphenols, antioxidants, and/or sugars) of the coffee fruit. Specifically, the invention relates to a coffee cherry processing method, having the steps of: (1) adding water to coffee cherries or to any of pulp or green, unroasted coffee beans obtained from the coffee cherries to form a suspension; (2) wet grinding said suspension in multiple steps to an average particle size of 100μηη or less; and (3) subjecting said suspension to one or more separation and/or processing steps having at least the separation of the water phase to obtain at least one coffee cherry extract selected from coffee cherry aroma, coffee cherry oil, coffee cherry powder, coffee cherry juice, coffee pulp aroma, coffee pulp powder, coffee pulp juice, coffee aroma and green or roasted coffee powder.

Disclosed are novel processing methods for green coffee beans that result in novel green coffee bean products, including products that incorporate whole green coffee beans which is combined with a whole hemp powder or CBD. Methods for processing green coffee beans include selecting whole coffee beans in their fresh green unroasted state with naturally-occurring levels of phytonutrients, sterilizing and drying them, applying iterative grinding processes and stabilization techniques, all while avoiding high temperatures. A similar method is used to prepare a whole hemp powder, which may then be combined with the whole green coffee bean powder.