A method of processing is disclosed that provides improved water retention and enhanced coloring and flavor, while preserving the meat and preventing bacterial contamination. In an exemplary embodiment, the method includes: (a) providing a body of meat at a first temperature; (b) contacting the body of meat of step (a), in at least one treating vessel, with a brine solution at a second temperature, wherein the second temperature is greater than the first temperature, and wherein the brine solution comprises a vinegar-derived food additive and/or a reddening agent, wherein the reddening agent comprises nitrite; (c) agitating the body of meat at the second temperature for a time sufficient to distribute the solution throughout the body of meat; (d) cooling the body of meat in at least one cooling vessel to a third temperature, wherein the third temperature is less than the second temperature; (e) agitating the body of meat at the third temperature; (f) contacting the body of meat of step (e) with the brine solution at the third temperature and agitating the body of meat at the third temperature until the brine solution is substantially absorbed by the body of meat; and (g) recovering the body of meat in a dry state at the third temperature. In one embodiment, the aforementioned brine solution comprises a vinegar-variety food additive, such as a vinegar-derived acetate composition. In another embodiment, the reddening agent comprises nitrate derived from plant material comprising nitrate.

A method of processing is disclosed that provides improved water retention and enhanced coloring and flavor, while preserving the meat and preventing bacterial contamination. In an exemplary embodiment, the method includes: (a) providing a body of meat at a first temperature; (b) contacting the body of meat of step (a), in at least one treating vessel, with a brine solution at a second temperature, wherein the second temperature is greater than the first temperature, and wherein the brine solution comprises a vinegar-derived food additive and/or a reddening agent, wherein the reddening agent comprises nitrite; (c) agitating the body of meat at the second temperature for a time sufficient to distribute the solution throughout the body of meat; (d) cooling the body of meat in at least one cooling vessel to a third temperature, wherein the third temperature is less than the second temperature; (e) agitating the body of meat at the third temperature; (f) contacting the body of meat of step (e) with the brine solution at the third temperature and agitating the body of meat at the third temperature until the brine solution is substantially absorbed by the body of meat; and (g) recovering the body of meat in a dry state at the third temperature. In one embodiment, the aforementioned brine solution comprises a vinegar-variety food additive, such as a vinegar-derived acetate composition. In another embodiment, the reddening agent comprises nitrate derived from plant material comprising nitrate.

The present invention discloses an antifreeze solution for food preservation, which comprises edible alcohol, propylene glycol, glycerin, calcium chloride, sodium chloride, amino acid, Antarctic krill protein hydrolysate with an average molecular weight of 50-100 KDa, surfactant and water, wherein the surfactant is one or more of phospholipid, Tween-20, Tween-60, and Tween-80; each component is food grade, and the mass percentage is expressed as follows: alcohol 15-30%, propylene glycol 10-30%, glycerol 2-15%, calcium chloride 1-10%, sodium chloride 3-10%, amino acid 0.1-0.15%, Antarctic krill protein hydrolysate 0.01-0.3%, surfactant 0.005-0.5%, and the balance is water. The antifreeze solution provided by the present invention can lower the freezing point, improve the heat transfer efficiency, inhibit the crystallization of antifreeze solution during the low temperature stirring process and improve the stability of the antifreeze solution.

The present invention discloses an antifreeze solution for food preservation, which comprises edible alcohol, propylene glycol, glycerin, calcium chloride, sodium chloride, amino acid, Antarctic krill protein hydrolysate with an average molecular weight of 50-100 KDa, surfactant and water, wherein the surfactant is one or more of phospholipid, Tween-20, Tween-60, and Tween-80; each component is food grade, and the mass percentage is expressed as follows: alcohol 15-30%, propylene glycol 10-30%, glycerol 2-15%, calcium chloride 1-10%, sodium chloride 3-10%, amino acid 0.1-0.15%, Antarctic krill protein hydrolysate 0.01-0.3%, surfactant 0.005-0.5%, and the balance is water. The antifreeze solution provided by the present invention can lower the freezing point, improve the heat transfer efficiency, inhibit the crystallization of antifreeze solution during the low temperature stirring process and improve the stability of the antifreeze solution.

Compositions are disclosed herein that comprise a mixture of at least one Albizia extract and a Magnolia extract. In some embodiments, the composition comprises a mixture of at least one Albizia extract enriched for one or more macrocyclic alkaloids and at least one Magnolia extract enrich for one or more lignans.

The present invention is a composition that can form an edible film or an edible liquid coating that can be applied to the surface of fresh fish (fillets or cuts) or fresh seafood. The present invention acts as a physical barrier preventing oxygen, water and microorganisms from entering the food product, and also acts as a bacteriostatic and antioxidant agent.

The present invention is a composition that can form an edible film or an edible liquid coating that can be applied to the surface of fresh fish (fillets or cuts) or fresh seafood. The present invention acts as a physical barrier preventing oxygen, water and microorganisms from entering the food product, and also acts as a bacteriostatic and antioxidant agent.

The disclosure discloses a method for killing A. Flavus spores by infrared radiation in coordination with essential oil fumigation, and belongs to the technical field of sterilization. The method is to treat A. Flavus spores by medium and short wave infrared radiation in combination with essential oil fumigation. The disclosure provides a method for killing A. Flavus spores by medium and short wave infrared radiation in coordination with essential oil fumigation. On the one hand, air residual heat and energy of medium and short wave infrared radiation are fully used to make a material heated up rapidly, and on the other hand, essential oil on the surface of the material penetrates the cell membrane of A. Flavus spores, and further damages protein on the membrane and internal organelles in combination with the heat effect. The process is easy in operation, low in energy consumption, pollution-free and high in sterilization efficiency, and can be used for purifying bulk grains.

The present invention relates to a new curing aid that is nitrite replacement. The composition comprises natural ingredients, including but not limited to a blend of buffered dry vinegar and red radish, and optionally rosemary extract and green tea extract, in various ratios, which working together are able to mimic the desirable functions of nitrite in cured or processed meat including controlling the growth of Clostridium botulinum and Listeria monocytogenes.

A process for producing a nanoemulsion formulation comprising the following main stages: (a) extraction of natural antioxidants from peels or seeds of fruits, vegetables or cereals, wherein the extraction is carried out with pure water, with a concentration of the extracted natural antioxidants with a vacuum distillation method between 0.5-15 inHg at 20-60° C. for 10-95 minutes until the concentration of the extracted natural antioxidants is between 10-50 wt % and then a tangential nanofiltration of the concentrated natural antioxidants; (b) encapsulation of the natural antioxidants; (c) formation of a nanoemulsion; and (d) cryodrying of the formed nanoemulsion.