A pressurization processing system that performs pressurization processing on a target by immersing the target in the sea or a lake, includes a housing body that is configured to house the target, a buoyancy body that is configured to float the housing body, a weight body that has a specific gravity greater than that of seawater or lake water, and a separation mechanism that separably connects the housing body and the weight body. In the system, the buoyancy body includes a housing bag having water permeability, and the housing bag houses a plurality of hollow glass spheres, and is immersed in the seawater or the lake water so that a space between the plurality of hollow glass spheres housed in the housing bag is filled with the seawater or the lake water.

A method of drying high sugar content food products such as honey and molasses in a vacuum microwave chamber. The method comprises loading the food product into the vacuum chamber, and exposing the food product to a vacuum pressure in the range of 45 to 250 Torr (60 to 333 mbar) in the vacuum chamber while irradiating the food product with microwave radiation. This dries the food product and forms a porous structure. The method minimizes or prevents foaming and dries the product at a temperature that prevents burning, while reducing the moisture content to a very low level.

The present invention is direct to an edible composition in which fruit, vegetables and/or nuts, in conjunction with a hydrocolloid, are treated with pressure and/or heat to form an edible composition that is dimensionally stable, ambient stable for at least 12 months, has a moisture content greater than 50 wt. %, has a pH less than 4.5, has a water activity greater than 0.5, is commercially sterile, is free of artificial flavors, has a solids content greater than 10 wt. %, and does not exhibit syneresis. Also provided is a method for preparation of the edible composition.

A device for indicating exposure to a pressure. The device may include a base layer, a plurality of microcapsules, and a coating, with the microcapsules being disposed between the base layer and the coating. The microcapsules contain a indicator material that can be released once the microcapsules burst. The microcapsules then have a compressive bursting strength that is chosen or designed to be less than a selected pressure (e.g., the pressure being that to which a particular article may be exposed during high pressure processing). Thus, when the device is subjected to a pressure greater than the compressive bursting strength, at least some microcapsules burst, the indicator material is released from the microcapsules, and the release of the indicator material can be detected by observation of the device. The device may be a label that is associated (such as by being affixed) to the article being subjected to pressure (or multiple labels being associated (such as by being affixed) to multiple articles. Alternatively, the device may be associated with an article or articles without being affixed thereto.

The present invention relates to high pressure processing (HPP) methods of and containers for preparation of food products such as solid or semi-solid foods, beverages and food supplements containing high-pressure sensitive probiotics and other high-pressure sensitive substances, which maintain their viability, biological activity and other beneficial properties in the prepared food product. The present invention also relates to pasteurized food products containing biologically active high-pressure sensitive probiotics, other high-pressure sensitive substances, or their combinations.

A freeze drying method including vacuuming freezing food, confirming operational status of at least one of a pressure sensor, a temperature sensor, a heating system, a cooling system, and/or a vacuum pump, and/or performing at least one of pre-frozen or not frozen status check, a chamber pre-freezing process, a vacuum leak check, a drying process, a final dry process, including any of such processes described in the specification.

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 process for the production of fat-encapsulated follistatin. The process includes metering fat having a melting point of at least 40° C. into an extruder, heating the fat in the extruder during rotation of the at least one screw, metering the follistatin into the extruder barrel to produce a flowable mixture, cooling the flowable mixture in a downstream adjacent section of the extruder barrel, subsequently discharging the mixture through an extruder die, and comminuting the mixture after it discharges from the extruder die.

When a food processing vessel under vacuum is repressurized, the tendency of product in the vessel to be forced into feed lines is relieved or overcome by establishing an effectively high pressure in the feed lines.

Embodiments herein include processing systems for food products and related methods. In an embodiment, a food processing system is included with a continuous processing channel divided into a come-up chamber, a main electromagnetic wave (such as microwave) heating chamber, and a cool-down chamber. The continuous processing channel can define at least two separate portions oriented for vertical product movement. In various embodiments, the come-up chamber, the main electromagnetic wave heating chamber, and the cool-down chamber are at least partially filled with liquid. The system can further include a product conveyor mechanism to convey food products to be processed continuously along a conveyance path passing from the come-up chamber through the main electromagnetic wave heating chamber and to the cool-down chamber. The system can further include an electromagnetic wave energy emitting apparatus configured to emit electromagnetic wave energy into the main heating chamber. Other embodiments are also included herein.