A sushi maker kit having a frame member with first, second, third, fourth side walls and a ledge capturing portion is provided. The first, second, third and fourth side walls define an open region. The ledge capturing portion extends upwardly from the first, second, and third side walls proximate to a first end of the frame member. The sushi maker kit further includes an insert member having a plate portion and a keel portion. The keel portion is coupled to and extends from the plate portion in a first direction. The plate portion has a ledge portion at a first end thereof. The ledge portion is removably received in the ledge capturing portion such that the keel portion extends into the open region of the frame member when the insert member is in a first operational position relative to the frame member.

A sushi maker kit having a frame member with first, second, third, fourth side walls and a ledge capturing portion is provided. The first, second, third and fourth side walls define an open region. The ledge capturing portion extends upwardly from the first, second, and third side walls proximate to a first end of the frame member. The sushi maker kit further includes an insert member having a plate portion and a keel portion. The keel portion is coupled to and extends from the plate portion in a first direction. The plate portion has a ledge portion at a first end thereof. The ledge portion is removably received in the ledge capturing portion such that the keel portion extends into the open region of the frame member when the insert member is in a first operational position relative to the frame member.

Methods for processing seaweed. The methods include cold washing seaweed to generate cold-washed seaweed, outgassing the cold-washed seaweed to generate outgassed seaweed, and dry heating the outgassed seaweed to generate dried seaweed. The cold washing may include contacting the seaweed with cold water at a temperature and/or pressure that retains at least a threshold salts fraction of naturally occurring mineral salts in the raw seaweed. The dry heating may include dry heating at a dry-heat temperature that is less than at least one of a char temperature and a burn temperature for the outgassed seaweed and/or that is greater than a pasteurization temperature for the outgassed seaweed. The methods may include compressing the outgassed seaweed to separate water from the outgassed seaweed and/or pulverizing the dried seaweed to generate pulverized seaweed. The methods also may include producing baked goods utilizing the processed and/or pulverized seaweed.

Methods for processing seaweed. The methods include cold washing seaweed to generate cold-washed seaweed, outgassing the cold-washed seaweed to generate outgassed seaweed, and dry heating the outgassed seaweed to generate dried seaweed. The cold washing may include contacting the seaweed with cold water at a temperature and/or pressure that retains at least a threshold salts fraction of naturally occurring mineral salts in the raw seaweed. The dry heating may include dry heating at a dry-heat temperature that is less than at least one of a char temperature and a burn temperature for the outgassed seaweed and/or that is greater than a pasteurization temperature for the outgassed seaweed. The methods may include compressing the outgassed seaweed to separate water from the outgassed seaweed and/or pulverizing the dried seaweed to generate pulverized seaweed. The methods also may include producing baked goods utilizing the processed and/or pulverized seaweed.

A method for preparing beverages by extraction, employing high-pressure processing (HPP), for the bulk production of enriched beverages, ready for consumption and with an extended useful life. The method uses high hydrostatic pressures to perform a solid-liquid extraction and/or infusion (e.g. cold infusion) with an improved extraction rate and/or yield, and simultaneously inactivating spoilage and pathogenic micro-organisms to increase its safety and useful life. The method includes placing a mix (8) of solids and liquids in a bag (3) located within a vessel (4) and pressurising same to a pre-set pressure (up to 800 MPa) and maintaining said pressure (10) for a pre-set period of time. The method includes the subsequent depressurisation of the vessel (11) and the removal of the mix from the bag (12), filtering the same under ultra-clean conditions (13), thus obtaining a safe, particle-free beverage, enriched with the extracted compounds of interest.

A method for preparing beverages by extraction, employing high-pressure processing (HPP), for the bulk production of enriched beverages, ready for consumption and with an extended useful life. The method uses high hydrostatic pressures to perform a solid-liquid extraction and/or infusion (e.g. cold infusion) with an improved extraction rate and/or yield, and simultaneously inactivating spoilage and pathogenic micro-organisms to increase its safety and useful life. The method includes placing a mix (8) of solids and liquids in a bag (3) located within a vessel (4) and pressurising same to a pre-set pressure (up to 800 MPa) and maintaining said pressure (10) for a pre-set period of time. The method includes the subsequent depressurisation of the vessel (11) and the removal of the mix from the bag (12), filtering the same under ultra-clean conditions (13), thus obtaining a safe, particle-free beverage, enriched with the extracted compounds of interest.

A novel alga mutant having improved pigment productivity is provided. The mutant can be used to produce carotenoid-based pigments, particularly, xanthophyll by using a small amount of energy, and thus can effectively produce pigment on an industrial level. In addition, the mutant can be used as a source for foods, health functional foods, and medications which contain a pigment. Further, when account is taken of the physiological characteristics of the euryhaline microalgae Dunaliella and the geological characteristics of Korean, the three sides of which are in contact with the sea, sea-water can be used as a culture medium, with the expectation of reducing the cost and leading to the development of related industries.

A laver snack includes laver on the lower side forming a bottom; the edible adhesive applied to the laver on the lower side; the additive including hemp seed powder adhered to the edible adhesive; the laver on the upper side covering the above additives, forming a top; and hemp oil applied to the laver on the upper side.

A laver snack includes laver on the lower side forming a bottom; the edible adhesive applied to the laver on the lower side; the additive including hemp seed powder adhered to the edible adhesive; the laver on the upper side covering the above additives, forming a top; and hemp oil applied to the laver on the upper side.

The present disclosure relates to the preservation and processing of polysaccharides having gelling properties from plants. More particularly, the present disclosure provides an antioxidant rich gelling fibre from plants such as seaweed and a method for preparation of the same. The gelling fibre of the present disclosure has improved gelling and/or thickening properties as compared to fibre obtained from fresh unprocessed plant sources such as seaweed and retains the natural antioxidants present in the fresh plant. In particular, seaweed in this disclosure refers to red seaweed. The said method of the present disclosure facilitates minimization of the amount of chemicals traditionally used in such processing methods and helps preserve the naturalness of the fresh plant source. The present disclosure further provides applications of the antioxidant rich gelling fibres of the present disclosure, specifically applications in the food industry.