The present invention relates to a material suitable for use in packages comprising nano-sized cellulose and an ethylene scavenging or ethylene absorbing agent. The invention also relates to methods for manufacturing such material, which may be paper, label, paperboard, plastic or film products.

An electrostatic device that includes: an air flow regulator system including a pressure regulator and an air flow regulator; a liquid flow regulating system including a set of restrictors; an electrostatic system including an electrostatic emission antenna and an insulating hood of the electrostatic emission antenna; an air-liquid nozzle that is separated from the electrostatic emission antenna; a tank; a positive displacement pump and a low-wetting electrostatic application method.

Examples provide a fruit ripening rack having a plurality of chambers for on-site produce ripening at a retail location. A controller component generates predicted demand for ripened fruit on a selected date at a selected location based on transaction history data and/or seasonal demand. The controller component calculates the quantity of fruit based on the predicted demand. The controller component determines conditions within each chamber to accelerate ripening of the calculated quantity of one or more types of fruit to one or more selected levels of ripeness on the selected date. The conditions include amount of ethylene gas in each chamber, length of exposure to the ethylene gas, temperature inside the chamber and/or humidity level inside the chamber. The fruit ripening rack controls internal conditions within each chamber to provide variable fruit ripening in accordance with per-chamber configurations to satisfy predicted daily demand at the selected location.

The present invention relates to a material suitable for use in packages comprising nano-sized cellulose and an ethylene scavenging or ethylene absorbing agent. The invention also relates to methods for manufacturing such material, which may be paper, label, paperboard, plastic or film products.

The present disclosure is directed to a method of treating delicate fruit with pressurized carbon dioxide to achieve an enhanced shelf life over fresh. A treated fruit produced by a provided method also has one or more of an improved flavor, improved, texture or improved color over a delicate fruit pasteurized using a thermal treatment.

To provide sugar preserved vegetable foods containing sugar alcohol characterized in displaying a quality similar to that of conventional candied foods while being sugar free or with low sugar (reduced sugar). Sugar preserved vegetable foods, immersion syrup used therefor and method for manufacturing said vegetable foods, wherein 50% or more of the saccharides contained in the sugar preserved vegetable foods consists of sugar alcohol, this sugar alcohol comprising 50% to less than 99.5% maltitol, 0.5% to less than 50% sorbitol, and 5% or less of sugar alcohol with a degree of polymerization of 3.

To provide sugar preserved vegetable foods containing sugar alcohol characterized in displaying a quality similar to that of conventional candied foods while being sugar free or with low sugar (reduced sugar). Sugar preserved vegetable foods, immersion syrup used therefor and method for manufacturing said vegetable foods, wherein 50% or more of the saccharides contained in the sugar preserved vegetable foods consists of sugar alcohol, this sugar alcohol comprising 50% to less than 99.5% maltitol, 0.5% to less than 50% sorbitol, and 5% or less of sugar alcohol with a degree of polymerization of 3.

Disclosed herein is a method for preparing a ready to use storage stable food composition. The method comprises comminuting an admixture of a fresh plant material and an oil at a substantially neutral pH and under conditions whereby browning enzymes in the plant material are substantially prevented from reacting; rapidly heating the admixture to a temperature at which the browning enzymes are substantially inactivated, and under conditions whereby the admixture loses substantially no weight during heating; and cooling the heated admixture to a temperature at which growth of spoilage organisms does not occur. Also disclosed herein are ready to use storage stable food compositions. When the compositions are combined with foods containing phenolic compounds, no browning of the food occurs.

Disclosed herein is a method for preparing a ready to use storage stable food composition. The method comprises comminuting an admixture of a fresh plant material and an oil at a substantially neutral pH and under conditions whereby browning enzymes in the plant material are substantially prevented from reacting; rapidly heating the admixture to a temperature at which the browning enzymes are substantially inactivated, and under conditions whereby the admixture loses substantially no weight during heating; and cooling the heated admixture to a temperature at which growth of spoilage organisms does not occur. Also disclosed herein are ready to use storage stable food compositions. When the compositions are combined with foods containing phenolic compounds, no browning of the food occurs.

A food preservation system is provided. The system includes a storage cabinet for storing foods, an electrolytic gas generator, a gas sensor and a control unit. The electrolytic gas generator is in fluid communication with the storage cabinet to output a first gas and a second gas to preserve the foods. The gas sensor is arranged in the storage cabinet to detect the concentration of the gases in the storage cabinet for obtaining gas concentration information which includes a first gas concentration and a second gas concentration. The control unit is electrically connected to the electrolytic gas generator and the gas sensor. According to the received gas concentration information, the control unit adjusts the applied voltage of the electrolytic gas generator to control the gas species generated by the electrolytic gas generator and the first and second gas concentrations in the storage cabinet.