A method is provided for packaging live clams in a container. The method includes harvesting the live clams from sea water having a first temperature. The method further includes placing the live clams in a tank of sea water having a second temperature that is less than the first temperature. The method further includes drying, with a blowing device, an outside surface of the live clams after removing the live clams from the tank. The method further includes placing a number of the live clams in the container after the drying step. The method further includes applying a vacuum seal along a top of the container and over the live clams in the container.

Fluorine being present in the exoskeleton of crustaceans, and especially krill represents a problem for using hill as a source for food, feed, food additives and/or feed additives. There has been developed a process for removing such fluorine from krill material by subjecting the krill to disintegration and to an enzymatic hydrolysis process prior to or simultaneously with a removal of the exoskeleton particles producing a fluorine-reduced product. Inherent in the disclosed process is the ability to process krill material with a high polar lipid content for producing superior quality, low fluorine, products suitable for the food and feed as well as the pharmaceutical, neutraceutical and cosmetic industry.

Fluorine being present in the exoskeleton of crustaceans, and especially krill represents a problem for using hill as a source for food, feed, food additives and/or feed additives. There has been developed a process for removing such fluorine from krill material by subjecting the krill to disintegration and to an enzymatic hydrolysis process prior to or simultaneously with a removal of the exoskeleton particles producing a fluorine-reduced product. Inherent in the disclosed process is the ability to process krill material with a high polar lipid content for producing superior quality, low fluorine, products suitable for the food and feed as well as the pharmaceutical, neutraceutical and cosmetic industry.

A shrimp-like food has mannan-containing fibrous portions and a mannan-containing binding portion binding between the fibrous portions. The fibrous portions are preferably arranged in a random orientation in the food. The fibrous portions preferably have a thickness of 0.8 to 3.0 mm. The mannan contents in the fibrous and binding portions are both preferably 1 to 7 mass %.

A method of producing a protein phospholipid complex from a crustacean catch including protein is claimed where hydrolysis occurs without substantially denaturing the protein from the crustacean catch. A method of producing a stable protein phospholipid emulsion from a crustacean catch is also claimed. A method of producing crustacean oil is claimed where the oil is separated from the hydrolyzed crustacean catch. Other methods of producing a protein phospholipid complex are claimed which relate to not removing the shell, removing the shell, and removing then adding back the shell to form the protein phospholipid complex.

A method of producing a protein phospholipid complex from a crustacean catch including protein is claimed where hydrolysis occurs without substantially denaturing the protein from the crustacean catch. A method of producing a stable protein phospholipid emulsion from a crustacean catch is also claimed. A method of producing crustacean oil is claimed where the oil is separated from the hydrolyzed crustacean catch. Other methods of producing a protein phospholipid complex are claimed which relate to not removing the shell, removing the shell, and removing then adding back the shell to form the protein phospholipid complex.

An embodiment of the present invention makes it possible to sterilize a marine animal with use of sea water and atmospheric air, to the extent that the marine animal can be eaten as an unheated food product. A sterilization method in accordance with an embodiment of the present invention is a method for sterilizing a marine animal as an unheated food product, the method comprising the steps of: producing oxygen-enriched water by mixing electrolyzed atmospheric air into sea water; producing sterilizing water by electrolyzing the oxygen-enriched water; and bringing the marine animal into contact with the sterilizing water, the sterilizing water containing HOCl, OH.sup. and O.sup..

Provided is an aquacultured crustacean having improved umami, uses thereof, and a method for producing the same. The crustacean does not burrow in sand, contain glycine and alanine, and has 2400 mg or more of free amino acids per 100 g of abdominal muscle. The content of glycine is 550 mg or more per 100 g of abdominal muscle, and the content of alanine is 140 mg or more per 100 g of abdominal muscle.

Provided is an aquacultured crustacean having improved umami, uses thereof, and a method for producing the same. The crustacean does not burrow in sand, contain glycine and alanine, and has 2400 mg or more of free amino acids per 100 g of abdominal muscle. The content of glycine is 550 mg or more per 100 g of abdominal muscle, and the content of alanine is 140 mg or more per 100 g of abdominal muscle.

A method of producing a protein phospholipid complex from a crustacean catch including protein is claimed where hydrolysis occurs without substantially denaturing the protein from the crustacean catch. A method of producing a stable protein phospholipid emulsion from a crustacean catch is also claimed. A method of producing crustacean oil is claimed where the oil is separated from the hydrolyzed crustacean catch. Other methods of producing a protein phospholipid complex are claimed which relate to not removing the shell, removing the shell, and removing then adding back the shell to form the protein phospholipid complex.