The present application provides a system or kit for printing tempered chocolate. The system includes a first heated vessel for maintaining chocolate therein untempered, and a second heated vessel in fluid communication with the first heated vessel for maintaining chocolate therein within the range of about 84 degrees Fahrenheit and about 92 degrees Fahrenheit and tempered with about 0.5% to about 3% type V crystals. The system further includes a syringe pump configured to pump tempered chocolate and a nozzle. The system further includes a three-way valve for selectively coupling the syringe pump and the second vessel, or the nozzle and the syringe pump, in fluid communication to direct the tempered chocolate from the second vessel through the nozzle. The system further includes a control system for controlling the system such that the chocolate flowing from the nozzle includes greater than about 3% type V crystals.

A method for printing a three-dimensional crystalline structure such as a chocolate layer wherein, after printing, the material has a desired crystal structure. An embodiment can include printing a liquid first layer of material with a printer onto a second layer of material having a crystal structure. Subsequently, the printed liquid first layer is processed to solidify the first layer. During the processing of the printed liquid first layer, the second layer functions as a crystal seed layer through physical contact with the printed liquid first layer and the second layer crystallizes with the crystal structure.

The invention relates to small edible portions (i.e., bite-sized snacks) comprising a soft nut butter inner core coated with a crunchy grain-based outer coating. The bite-sized snacks have an equivalent spherical diameter of about 1 to 3 cm. Texture analysis of the bite-sized snacks determines that the bite-sized snacks have a soft texture with an average peak force in the range of about 800-5,000 g and an average positive area in the range of about 2,000-15,000 g*sec. The bite-sized snacks unexpected have both a soft and crunchy texture and are surprisingly shelf stable.

Content containers and vessels, one aspect including a deformable fluid-tight container shell defining an internal volume and separating the internal volume from an external environment; a room-temperature semi-solid content contained within the internal volume; and a valve operationally connected to and disposed at least partially without the deformable container shell; where the semi-solid content is a hydrophobic matrix with at least partially emulsified hydrophilic components; where the container shell is substantially fluid-tight; where the valve has open state(s) and a closed state; where the valve may be actuated between the open state(s) and the closed state; where the valve is self-cleaning; where during the open state(s), the internal volume is in fluidic communication with the external environment; where during the closed state, the internal volume content cannot fluidically communicate with the external environment; and where the content remains moisture-stable while the valve is in the closed state.

A method for printing a three-dimensional crystalline structure such as a chocolate layer wherein, after printing, the material has a desired crystal structure and a plurality of non-random cavities. An embodiment can include printing a liquid first layer of material with a printer onto a second layer of material having a crystal structure. Subsequently, the printed liquid first layer is processed to solidify the first layer. During the processing of the printed liquid first layer, the second layer functions as a crystal seed layer through physical contact with the printed liquid first layer and the second layer crystallizes with the crystal structure. In some embodiments, confections may be formed from high-quality chocolate, where the confection has a reduced caloric content with acceptable mouthfeel. In other embodiments, a confection may have a previously unrealized mouthfeel and taste.

Content containers and vessels, one aspect including a chocolate dispensing vessel, having a generally fluid-tight enclosure, chocolate substantially filling the fluid-tight enclosure, a fluidic conduit extending through the fluid-tight enclosure, and a fluidic valve operationally connected to the fluidic conduit and positioned outside of the fluid-tight enclosure. The chocolate is solid state at room temperature and the chocolate softens to a liquid state in the temperature range from 26 to 36 degrees Celsius.

Systems for dispensing chocolate, in one aspect including an exterior housing with first volume; a vertical support member; a base support member; a dispenser guiding member within the first volume; an extruder connection member extending through the housing and having a first end within the housing and a second end outside of the housing, defining a pivot axis; an extruder member connected to the first end; a lever connected to the second end; at least one extruder guide member within the first volume and connected to the extruder member; and at least one extruder guide rail connected to the housing within the first volume and capable of receiving the at least one extruder guide member; and where manual actuation of the lever pivots the extruder member in cooperation with the at least one extruder guide member.

Systems for dispensing chocolate, in one aspect including a generally fluid-tight exterior housing with first volume; a vertical support member; a base support member; a dispenser guiding member within the first volume; an extruder connection member extending through the housing and having a first end within the housing and a second end outside of the housing, defining a pivot axis; an extruder member connected to the first end; a lever connected to the second end; at least one extruder guide member within the first volume and connected to the extruder member; and at least one extruder guide rail connected to the housing within the first volume and capable of receiving the at least one extruder guide member; and where manual actuation of the lever pivots the extruder member in cooperation with the at least one extruder guide member.

Provided are: a composition having an excellent anti-norovirus effect; use of a theaflavin compound for the preparation of the composition; and a method for preventing infection with a norovirus using a theaflavin compound. A theaflavin compound is used as an active ingredient for preventing infection with a norovirus. The theaflavin compound is preferably used together with an alcohol. The theaflavin compound is preferably one or more members selected from the group consisting of theaflavin, theaflavin-3-O-gallate, theaflavin-3′-O-gallate and theaflavin-3,3′-O-digallate that are derived from tea components.

Apparatus and systems for melting and liquefying chocolate. In one aspect, a system includes a generally fluid-tight exterior housing defining a first volume; a bulkhead positioned within the housing and dividing the first volume into separate second and third volumes; at least one vertical support member operationally connected to the exterior housing; a base support member operationally connected to the vertical support member; a dispenser guiding member disposed within the first volume and operationally connected to the exterior housing; and a heating element in thermal communication with the first volume, wherein energization heats the first volume to 37 to 46 degrees Celsius. Other aspects include where the liquid chocolate contains less than 3% water; where the liquid chocolate is solid at room temperature; a multiple pivot hinge; and a noninterfering interdigitating hinge.