The invention provides novel microalgal food compositions comprising microalgal biomass that have been processed into flakes, powders and flours. The microalgal biomass of the invention is low in saturated fats, high in monounsaturated triglyceride oil and can be a good source of fiber. The invention also comprises microalgal biomass that is suitable as a vegetarian protein source and also as a good source of fiber. Novel methods of formulating food compositions with the microalgal biomass of the invention are also disclosed herein including beverages, baked goods, egg products, reduced fat foods and gluten-free foods. The provision of food compositions incorporating the microalgal biomass of the invention to ahuman have the further benefit of providing healthful ingredients while achieving levels of satiety sufficient to reduce further caloric intake. The invention also provides novel strains of microalgae that have been subject to non-transgenic methods of mutation sufficient to reduce the coloration of the biomass produced by the strains. Oil from the microalgal biomass can be extracted and is an edible oil that is heart-healthy. The novel microalgal biomass and oil therefrom can be manufactured from edible and inedible heterotrophic fermentation feedstocks, including corn starch, sugar cane, glycerol, and depolymerized cellulose that are purpose-grown or byproducts of existing agricultural processes from an extremely broad diversity of geographic regions.

Flavored flatbread is made by a method comprising providing a cooked flatbread having first and second major surfaces and a thickness of from about 1.0 to about 10 mm and a density of from about 0.1 to about 0.5 g per cubic cm and docking the cooked flatbread to impart a plurality of holes into at least the first major surface of the cooked flatbread. An egg containing liquid mixture is applied to the docked cooked flatbread in an amount and time sufficient to take up from about 0.02 to about 0.09 g per square cm linear surface area of the docked cooked flatbread to provide a coated flatbread. The coated flatbread is cooked to provide a cooked flavored flatbread. Flavored flatbreads are also described.

Flavored flatbread is made by a method comprising providing a cooked flatbread having first and second major surfaces and a thickness of from about 1.0 to about 10 mm and a density of from about 0.1 to about 0.5 g per cubic cm and docking the cooked flatbread to impart a plurality of holes into at least the first major surface of the cooked flatbread. An egg containing liquid mixture is applied to the docked cooked flatbread in an amount and time sufficient to take up from about 0.02 to about 0.09 g per square cm linear surface area of the docked cooked flatbread to provide a coated flatbread. The coated flatbread is cooked to provide a cooked flavored flatbread. Flavored flatbreads are also described.

A shell form and a method of using the shell form requires a wire form and a wire clip, a tortilla placed therebetween during the time that the tortilla is cooked in hot oil forming a taco shell.

A shell form and a method of using the shell form requires a wire form and a wire clip, a tortilla placed therebetween during the time that the tortilla is cooked in hot oil forming a taco shell.

An essentially carbohydrate-free., protein-based flour substitute and methods for preparing the same are disclosed herein. The flour substitute may be used to make pizza crusts, chips, taco shells, tortillas, crackers, sandwich thins, and other food products that are traditionally flour-based. The organoleptic properties of the disclosed flour substitute preferably resemble the organoleptic properties of traditional baked goods and are substantially different from the organoleptic properties of traditional meat products. The disclosed flour substitute comprises a meat or nut flour, a flavor-masking spice, salt, and a vegetable, fruit, or plant-based oil or an oil-based spray. The disclosed flour substitute is used to make substitute food products that preferably resemble, in both appearance and taste, the traditional food products that the substitute food products are replacing. The flour substitute is preferably fiber-free and does not contain any other non-digestible carbohydrates. Methods of preparing the disclosed flour substitute are also disclosed herein.

The present invention offers a new composition for tortillas, and more specifically a composition comprising hydrolyzed lecithin and lecithin in an amount effective to confer superior properties to the tortillas, such as anti-stickiness, where the composition can be incorporated as an ingredient in the formulation of the tortillas. Other aspects of the present invention relate to methods of making and using the compositions of the present invention to prevent the peeling or tearing of tortillas when separated.

The present invention offers a new composition for tortillas, and more specifically a composition comprising hydrolyzed lecithin and lecithin in an amount effective to confer superior properties to the tortillas, such as anti-stickiness, where the composition can be incorporated as an ingredient in the formulation of the tortillas. Other aspects of the present invention relate to methods of making and using the compositions of the present invention to prevent the peeling or tearing of tortillas when separated.

The present invention “Production process of nixtamalized maize flour, nixtamalizing the maize fractions separately without producing nejayote”, considers the integration of the processes: Semi-humid milling of the maize (fractionated degerm), extruding of the maize fractions and milling-instant dehydration of the different nixtamalized and extruded maize fractions, has as novelty the way in which the nixtamalization process is carried out and the objective is to provide a nixtamalized maize flour production system that reduces the residues from the maize grain and completely eliminating nejayote production.

Tortillas are formed from a composition including a gluten-free flour mixture constituting from 40-70% of weight of the composition, with the gluten-free flour mixture consisting of a combination of three or four different flours. In either of the three or four flour versions, the first flour, which is also the highest percentage flour, is tapioca flour, the second flour is quinoa flour, and the third flour is either corn or rice flour. In the four flour version, amaranth flour is added to this overall combination. The composition also includes at least 30%, preferably 30-50%, water by weight of the composition, and an enzyme, such as in an amount of about 0.2-1%, for structural integrity purposes.