A method includes: acquiring chewing/swallowing information from a sensing device with which a user is equipped, wherein the chewing/swallowing information is related to chewing of the user when the user eats a first printed food; determining based on the chewing/swallowing information, a number of chews made within a swallow cycle duration of the user, and determining based on a first hardness and the number of chews, a second hardness for a second printed food to be created by a food printer; and transmitting print control information to the food printer via a network, wherein the print control information is used for causing the food printer to create the second printed food having the determined second hardness.

A method includes: acquiring chewing/swallowing information from a sensing device with which a user is equipped, wherein the chewing/swallowing information is related to chewing of the user when the user eats a first printed food; determining based on the chewing/swallowing information, a number of chews made within a swallow cycle duration of the user, and determining based on a first hardness and the number of chews, a second hardness for a second printed food to be created by a food printer; and transmitting print control information to the food printer via a network, wherein the print control information is used for causing the food printer to create the second printed food having the determined second hardness.

A control method includes: acquiring chewing/swallowing information via a network from a sensing device with which a user is equipped, wherein the chewing/swallowing information is related to chewing of the user when the user eats a first printed food; determining based on the chewing/swallowing information, a swallow cycle duration of the user, and determining based on a first hardness and the swallow cycle duration, a second hardness for a second printed food to be created by a food printer; and transmitting print control information to the food printer via the network, wherein the print control information being used for causing the food printer to create the second printed food having the determined second hardness.

A control method includes: acquiring chewing/swallowing information via a network from a sensing device with which a user is equipped, wherein the chewing/swallowing information is related to chewing of the user when the user eats a first printed food; determining based on the chewing/swallowing information, a swallow cycle duration of the user, and determining based on a first hardness and the swallow cycle duration, a second hardness for a second printed food to be created by a food printer; and transmitting print control information to the food printer via the network, wherein the print control information being used for causing the food printer to create the second printed food having the determined second hardness.

Method for preparing potato chips, comprising the following steps in a central kitchen: - subjecting the potato to a thermal treatment of cooking by single-layer immersion, vacuum cooking or steam cooking,- subjecting the potato to a scan to record its shape and size,- determining the position of cuts on the potato model,- determining the position of a hole with a single inlet in each portion,- performing the mechanical emptying of the holes, recovering a cap for each hole,- injecting a filling into each hole and covering each hole with the caps,- performing the mechanical cutting of the potato into the predetermined portions,- performing a pre-frying of the portions,- cooling and deep-freezing the filled and pre-fried portions, and- packaging the already frozen portions; comprising a step of preparation at the place of consumption, comprising heating the portions.

A solid object feeder according to the present invention includes a rotary disk including a plurality of storing holes of storing solid objects, a supporting member disposed below the rotary disk, and a guide member disposed above a peripheral portion of the rotary disk. The supporting member includes a step region continuing from an upstream side to a downstream side with respect to the guide member, and another region located upstream of the step region. A gap between the supporting member and a lower surface of the rotary disk in the step region is defined so that the solid object can move a space below the guide member from the upstream side to the downstream side. The gap is larger than a gap between the supporting member and the lower surface of the rotary disk in the other region.

A solid object feeder according to the present invention includes a rotary disk including a plurality of storing holes of storing solid objects, a supporting member disposed below the rotary disk, and a guide member disposed above a peripheral portion of the rotary disk. The supporting member includes a step region continuing from an upstream side to a downstream side with respect to the guide member, and another region located upstream of the step region. A gap between the supporting member and a lower surface of the rotary disk in the step region is defined so that the solid object can move a space below the guide member from the upstream side to the downstream side. The gap is larger than a gap between the supporting member and the lower surface of the rotary disk in the other region.

The disclosure relates to print heads for use in the bioprinting of biostructures having predetermined two (2D)- and/or three dimensional (3D) pattern of cells. Specifically, the disclosure relates to print heads operable in a bioprinting systems for the fabrication of edible biostructures using drop-on-demand.

A fruit snack with probiotics that is stable at room temperature is manufactured by combining various ingredients including fruit juices/purees to produce a slurry and cooking the slurry to produce a center that contains a high moisture content. The fruit snack center is covered with a barrier layer which in turn is covered by an outer layer that contains heat sensitive ingredients, such as probiotic cultures. The barrier layer substantially prevents migration of moisture from the center to the outer layer, and the fruit snack is cooled prior to applying the outer layer to minimize damage/harm to the heat sensitive ingredients. In addition to including probiotic cultures and being stable at room temperature, the fruit snack has other desirable characteristics including a chewy soft texture and fruit-flavorings, and may be manufactured using traditional processes.

A fruit snack with probiotics that is stable at room temperature is manufactured by combining various ingredients including fruit juices/purees to produce a slurry and cooking the slurry to produce a center that contains a high moisture content. The fruit snack center is covered with a barrier layer which in turn is covered by an outer layer that contains heat sensitive ingredients, such as probiotic cultures. The barrier layer substantially prevents migration of moisture from the center to the outer layer, and the fruit snack is cooled prior to applying the outer layer to minimize damage/harm to the heat sensitive ingredients. In addition to including probiotic cultures and being stable at room temperature, the fruit snack has other desirable characteristics including a chewy soft texture and fruit-flavorings, and may be manufactured using traditional processes.