A package for packaging a meat product. The package comprises a multilayer film with a food contact sealant layer and a food additive in an amount sufficient to capture oxygen bound to myoglobin on the surface of the meat product. The meat product may have a conversion rate of oxymyoglobin to deoxymyoglobin with less than 5% metmyoglobin remaining on the surface of the meat product within a time period of 36 hours or less. The present invention may also be used in a low oxygen environment package, such as vacuum skin packaging.

This method for producing a packaged food product portion includes the following steps: providing a cup defining an inner area for receiving the food product; cold pouring, at a temperature below 50° C., the food product into the receiving area of the cup; covering the food product using a thermally insulating lid arranged such that thermally conducting flaps of the cup extend toward the outside of the lid after the covering step; folding the flaps on an outer face of the lid opposite the receiving area; and heat-sealing the flaps on the outer face.

This method for producing a packaged food product portion includes the following steps: providing a cup defining an inner area for receiving the food product; cold pouring, at a temperature below 50° C., the food product into the receiving area of the cup; covering the food product using a thermally insulating lid arranged such that thermally conducting flaps of the cup extend toward the outside of the lid after the covering step; folding the flaps on an outer face of the lid opposite the receiving area; and heat-sealing the flaps on the outer face.

This invention relates to inner-plies for bulk-bags that surprisingly offer not only high thermal resistance, but also high flex-crack resistance. This invention also relates to such bulk-bags made for packaging of flowable materials, aseptic or otherwise, and the process for improving their flex-crack and thermal resistance. Preferably, the packaging is aseptic. More specifically, the inner-ply of the invention comprises a resin blend comprising the Exceed® XP resin; an LDPE resin or an ethylene—α-olefin copolymer (EAO copolymer); or a blend of said LDPE resin and said EAO copolymer, with flex-crack resistance improved in both machine direction and transverse direction, in conjunction with an improved thermal resistance. Thus, in addition to possessing good flex-crack resistance, the bulk-bags can withstand steam sterilization and/or aseptic packaging conditions.

This invention relates to inner-plies for bulk-bags that surprisingly offer not only high thermal resistance, but also high flex-crack resistance. This invention also relates to such bulk-bags made for packaging of flowable materials, aseptic or otherwise, and the process for improving their flex-crack and thermal resistance. Preferably, the packaging is aseptic. More specifically, the inner-ply of the invention comprises a resin blend comprising the Exceed® XP resin; an LDPE resin or an ethylene—α-olefin copolymer (EAO copolymer); or a blend of said LDPE resin and said EAO copolymer, with flex-crack resistance improved in both machine direction and transverse direction, in conjunction with an improved thermal resistance. Thus, in addition to possessing good flex-crack resistance, the bulk-bags can withstand steam sterilization and/or aseptic packaging conditions.

The disclosure provides oral pouched products in the form of a porous pouch defining a cavity containing a composition adapted for oral use, wherein the porous pouch is formed from a fleece material comprising two or more layers, wherein the two or more layers are in direct contact with one another. The disclosure also provides pouched products that include at least one layer of fleece material and at least one layer of a gel that is in direct contact with the fleece material. The disclosure also provides methods of forming such pouched products and for controlling/tailoring certain properties of pouched products using such multi-layered and/or gel-based approaches.

The present invention is directed to an unprinted electrophotographically printable fillable pouch made of an unprinted electrophotographically printable film including (a) a multilayer polymer film including a base layer (a1) and a sealing layer (a2) which is the inner layer of the pouch and (b) at least one toner-receiving layer as the outer layer deposited on the multilayer polymer film (a) from an aqueous coating composition including (b1) a polymeric binder, (b2) fine inorganic particles, and (b3) coarse inorganic and/or organic particles. Also provided is a method for producing the unprinted pouches on a pouch making machine as well as a method for printing the pouches in an electrophotographic printing process. The printed pouch is ideal to be filled with food, pet food, beverages, pharmaceuticals and/or personal care product.

The present invention is directed to an unprinted electrophotographically printable fillable pouch made of an unprinted electrophotographically printable film including (a) a multilayer polymer film including a base layer (a1) and a sealing layer (a2) which is the inner layer of the pouch and (b) at least one toner-receiving layer as the outer layer deposited on the multilayer polymer film (a) from an aqueous coating composition including (b1) a polymeric binder, (b2) fine inorganic particles, and (b3) coarse inorganic and/or organic particles. Also provided is a method for producing the unprinted pouches on a pouch making machine as well as a method for printing the pouches in an electrophotographic printing process. The printed pouch is ideal to be filled with food, pet food, beverages, pharmaceuticals and/or personal care product.

The present invention is directed to an unprinted inkjet-printable fillable pouch made of an unprinted inkjet-printable film including (a) a multilayer polymer film including a base layer (a1) and a sealing layer (a2) which is the inner layer of the pouch and (b) at least one ink-receiving layer as the outer layer deposited on the multilayer polymer film (a) from an aqueous coating composition including (b1) a polymeric binder, (b2) fine inorganic particles, and (b3) coarse inorganic and/or organic particles. Also provided is a method for producing the unprinted pouches on a pouch making machine as well as a method for printing the pouches, preferably in a single pass inkjet printing process. The printed pouch is ideal to be filled with food, pet food, beverages, pharmaceuticals and/or personal care products.

The present invention is directed to an unprinted inkjet-printable fillable pouch made of an unprinted inkjet-printable film including (a) a multilayer polymer film including a base layer (a1) and a sealing layer (a2) which is the inner layer of the pouch and (b) at least one ink-receiving layer as the outer layer deposited on the multilayer polymer film (a) from an aqueous coating composition including (b1) a polymeric binder, (b2) fine inorganic particles, and (b3) coarse inorganic and/or organic particles. Also provided is a method for producing the unprinted pouches on a pouch making machine as well as a method for printing the pouches, preferably in a single pass inkjet printing process. The printed pouch is ideal to be filled with food, pet food, beverages, pharmaceuticals and/or personal care products.