Disclosed is a green tea beverage packed in a container which has a strong fire odor (savory odor), yet gives a refreshing aftertaste and can be drunk delectably even in a cold state. Specifically disclosed is a green tea beverage packed in a container characterized in that the saccharide concentration thereof, which is the sum of the monosaccharide concentration and the disaccharide concentration, is 100 to 300 ppm and the ratio of the disaccharide concentration to the monosaccharide concentration (disaccharides/monosaccharides) is 10 to 28. It is preferred that the ratio of catechins with electron localization to said saccharide concentration (catechins with electron localization/saccharides) is 1.0 to 2.5.

Low water liquid beverage concentrates and methods for making the concentrates are provided herein. The concentrates include a high coffee and/or tea solids content and total solids content. The amounts of water, total solids, and coffee and/or tea solids are effective to provide a low water beverage concentrate having a pH between about 3.0 to about 6.0. In some approaches, the pH of the low water beverage concentrate changes fewer than about 0.5 pH units after at least three months storage at 70 F in a closed container. The low water beverage concentrates provide a desired flavor profile with little or no flavor degradation after storage at 70 F in a closed container for at least about three months. Methods for making the low water beverage concentrates are also provided.

An object of the present invention is to provide a beverage packed in a sealed container, which can suppress occurrence of precipitation for a long period and retain high flavor. The above-described problem can be overcome by containing (1) theanine ranging from 100 mg to 1000 mg and (2) quinic acid ranging from 30 mg to 300 mg per 500 ml beverage.

A method for producing a cellulose composite containing cellulose and a polysaccharide, wherein a median size of colloidal cellulose composites contained in the cellulose composite as measured by a dynamic light scattering method is 0.85 m or more, the method including treating a mixture containing cellulose, a polysaccharide and an aqueous medium together in a wet process, wherein a solid content is controlled to be 35 mass % or more, and temperature is set at 80 C. or less.

An upward flow extraction method, apparatus, and extract are disclosed. The upward flow extraction method can comprise loading extraction material into an extraction cell having a bottom portion and a top portion; introducing a first aliquot of extraction medium through the bottom portion of the extraction cell; expelling gas from the extraction cell through the top portion of the extraction cell; closing the top portion of the extraction cell and increasing the pressure in the extraction cell as extraction medium flows into the bottom portion of the extraction cell; stopping the flow of extraction medium into the extraction cell; steeping the extraction material in the extraction medium under pressure to produce an extract; and introducing a second aliquot of extraction medium through the bottom portion of the extraction cell to push extract through top portion of the extraction cell.

A method of manufacturing a liquid food/beverage packed in a container obtained by diluting a raw material liquid with a diluting liquid having a lower viscosity than that of the raw material liquid includes: a diluting liquid heating step of heating the diluting liquid up to a higher temperature than that of the raw material liquid before being mixed with the raw material liquid; a primary heating/diluting step of swirling the diluting liquid in the raw material liquid to generate a swirl flow thereby to dilute the raw material liquid while heating the raw material liquid through heat convection of the swirl flow; and a secondary heating/sterilizing step of, after the primary heating/diluting step, heating and sterilizing a mixed liquid of the raw material liquid and the diluting liquid by conductive heat.

Methods for modulating the bitterness and astringency of green tea, and nutritional products having a green tea with reduced bitterness and astringency, are provided. In a general embodiment, the methods comprise performing microfiltration on green tea extract to form a microfiltration retentate and a microfiltration permeate; performing at least one of ultrafiltration or reduced temperature fractionation on the microfiltration permeate; and using the ultrafiltration permeate from the ultrafiltration or the supernatant from the reduced temperature fractionation to make a green tea product. The ultrafiltration permeate or the supernatant can be further concentrated, spray or freeze dried to form a powder, used as a concentrate, or diluted to form a ready-to-drink beverage. In an embodiment, the ultrafiltration is performed on the microfiltration permeate to form an ultrafiltration retentate and an ultrafiltration permeate and then the reduced temperature fractionation is performed on the ultrafiltration permeate to form a supernatant and a sediment.

The disclosure relates to compositions comprising low levels of caffeine (e.g., 25 wt % or less), wherein the composition contains a natural caffeine source in combination with antioxidants, vitamins, electrolytes, and/or amino acids. The disclosed composition, which is made up of natural ingredients, beneficially offers a holistic approach to physical and mental energy. This abstract is intended as a scanning tool for purposes of searching in the particular art and is not intended to be limiting of the present disclosure.

A method of manufacturing a Ready-to-Drink (RTD) infused beverage containing atmospheric-plasma-treated protein. A quantity of protein is atmospheric-plasma treated to produce a quantity of plasma-treated protein. An infusion base is also brewed using a quantity of brewing water and a quantity of infusion materials at a specific brewing temperature. Then, the quantity of plasma-treated protein is dispersed into the infusion base to make a beverage mixture. A quantity of sweeteners and a quantity of preservatives are mixed into the beverage mixture. Then, the beverage mixture pH is adjusted to match a specific mixture pH using a quantity of pH control agents. Afterwards, the beverage container is filled with the beverage mixture. Once the beverage container is filled, the beverage container is then nitrogen-dosed and then sealed. Finally, the beverage container is pasteurized after the beverage container is sealed.