Embodiments herein include gluten-free baked products such as crackers, gluten-free flour formulations, and related methods. In an embodiment, a cracker flour substitute composition is included having a starch blend including a native starch with 20-30% amylose content, a cross-linked starch and a pre-gelatinized starch with 1-5% amylose content. The composition can include between 0 and 20 ppm gluten. In an embodiment, a shelf-stable baked cracker is included. The shelf-stable baked cracker can include a flour substitute composition including a starch blend having a native starch with 20-30% amylose content, a cross-linked starch, and a pre-gelatinized starch with 1-5% amylose content. The composition can include between 0 and 20 ppm gluten. Other embodiments are also included herein.

Embodiments herein include gluten-free baked products such as breads gluten-free flour formulations, and related methods. In an embodiment, a bread flour substitute composition is included having a starch blend and a hydrocolloid blend. The starch blend can include a native starch with 20-30% amylose content, a native waxy starch with 0-1% amylose content, and a cross-linked starch. The hydrocolloid blend can include hydroxypropyl methylcellulose (HPMC) and psyllium fiber. The composition can include between 0 and 20 ppm gluten. Other embodiments are also included herein.

Embodiments herein include gluten-free baked products such as breads gluten-free flour formulations, and related methods. In an embodiment, a bread flour substitute composition is included having a starch blend and a hydrocolloid blend. The starch blend can include a native starch with 20-30% amylose content, a native waxy starch with 0-1% amylose content, and a cross-linked starch. The hydrocolloid blend can include hydroxypropyl methylcellulose (HPMC) and psyllium fiber. The composition can include between 0 and 20 ppm gluten. Other embodiments are also included herein.

The present invention relates to a soft bakery product having a slowly-available-glucose (SAG) content of at least 15 wt % and a water activity of from 0.4 to 0.9, the product comprising a dough-based, baked portion and optionally a coating and/or a filling, the product comprising: cereals in an amount of at least 35 wt %; at least 5 wt % sugars, having a degree of polymerisation of 1 or 2, by weight of the soft bakery product; and from 0.1 to 15 wt % maltitol by weight of the soft bakery product.

The present invention relates to a soft bakery product having a slowly-available-glucose (SAG) content of at least 15 wt % and a water activity of from 0.4 to 0.9, the product comprising a dough-based, baked portion and optionally a coating and/or a filling, the product comprising: cereals in an amount of at least 35 wt %; at least 5 wt % sugars, having a degree of polymerisation of 1 or 2, by weight of the soft bakery product; and from 0.1 to 15 wt % maltitol by weight of the soft bakery product.

A food baking apparatus includes a compressible die and a mechanical stop for controlling a die spacing of the compressible die. The mechanical stop includes a supporting system and a mounting element mounted onto the supporting system. The mounting element includes at least one protrusion having a particular amount of protrusion from the mounting element, which amount of protrusion may be adjustable for any single protrusion. By translation or rotation of the supporting system and/or the mounting element during operation of the apparatus, a protrusion is selected. The protrusions mechanically stop further compression of the dies during an operation of the food baking apparatus. Thus, the selection determines the die spacing applicable for the baking process, based on the amount of protrusion of the selected protrusion.

A food baking apparatus includes a compressible die and a mechanical stop for controlling a die spacing of the compressible die. The mechanical stop includes a supporting system and a mounting element mounted onto the supporting system. The mounting element includes at least one protrusion having a particular amount of protrusion from the mounting element, which amount of protrusion may be adjustable for any single protrusion. By translation or rotation of the supporting system and/or the mounting element during operation of the apparatus, a protrusion is selected. The protrusions mechanically stop further compression of the dies during an operation of the food baking apparatus. Thus, the selection determines the die spacing applicable for the baking process, based on the amount of protrusion of the selected protrusion.

The disclosure provides a bread-derived scaffold biomaterial for supporting cells, the scaffold comprising a bread crumb and wherein the bread crumb comprises a three-dimensional porous structure to support the cells. Further provided is a use of the scaffold and a method of making same.

The disclosure provides a bread-derived scaffold biomaterial for supporting cells, the scaffold comprising a bread crumb and wherein the bread crumb comprises a three-dimensional porous structure to support the cells. Further provided is a use of the scaffold and a method of making same.

The present invention consists of an automatic apparatus for the production and cooking (50) of tortillas, which comprises a cartridge (1, 54, 71), which contains raw or partially cooked tortillas (21) pre-formed in a circle, a coupling system to easily attach and remove the cartridge (1, 54, 71) and an automatic cooking system (2) consisting of two parallel griddles or also called comales (11, 12), each griddle configured to cook each side of the tortilla and dispensing the tortilla to a container (10) after completing a cooking cycle by means of a specific movement of the griddles (11, 12) controlled by a microcomputer.