This invention relates to gluten-free bakery products containing heat-moisture treated flour.
Flours are an important and major component of the diet, which are used to provide a multitude of functional aspects to a variety of food products. However, some individuals cannot consume certain flours because they are allergic or cannot easily digest gluten.
Gluten is a protein found in grains including wheat, oats, barley, and rye. In baked products, gluten forms the backbone of the viscoelastic matrix of the dough, which becomes a firm yet flexible structure upon baking. This matrix has desirable and typical qualities such as absence of crumbliness and cohesiveness in the mouth.
Wheat flour, which can be high in gluten, can be substituted with other gluten-free flours for baking, such as rice flour. Other commercially available gluten-free baked goods substitute wheat flour with starches, such as cornstarch. However, these gluten-free baked goods lack the structure and texture typical of gluten-containing baked goods. There are also difficulties in using gluten-free flours or starches related to their processing characteristics; to form a gluten-free dough, frequently an increase in the amount of water is needed, resulting in stickiness. Also, the resulting dough has less flexibility as it is more sensitive to holding times within the production process than its gluten-containing counterpart.
It is known to use guar gum, xanthan gum and/or modified starch in gluten-free baked products as dough binder alternatives in those products. Further, modified starches are used as expansion and structuring aids in gluten-free products such as bread. However, these gums and modified starches often do not provide the structure, texture, and expansion demanded to be similar to gluten-containing foods, and furthermore, require a sacrifice of taste, texture and/or appearance of the final product as compared to those gluten-containing foods.
Despite the numerous ingredients and combinations of ingredients used as flour and/or starch replacers in preparing gluten-free bakery products, there remains a need for a product which functions in a way that enables manufactured gluten-free baked goods to more closely resemble the conventional, wheat flour containing bakery products in texture. The ability to use gluten-free ingredients in conventional baking processes without the need for modified or specialized processes is also important.
It has now been discovered that a heat moisture treated flour can be used in bakery products to provide a product which more closely mimics the conventional, wheat flour containing products than other gluten-free products.
As used herein, the term bakery product is intended to mean those products typically found in a bakery, whether baked, fried, steamed or otherwise cooked, and include without limitation breads and bread products, cakes, cookies, donuts, and the like.
As used herein, the term gluten-free product is intended to mean those products containing less than 20 ppm gluten (w/w basis).
As used herein, the term high amylopectin is intended to mean containing at least about 90% amylopectin by weight of the starch or starch portion of the flour.
As used herein, the term high amylose is intended to mean containing at least about 27% amylose for wheat or rice and at least about 50% amylose for other sources, by weight of the starch or starch portion of the flour. The percent amylose (and therefore amylopectin) is determined by using the potentiometric method.
As used herein, dough is intended to mean a mixture of the flour/starch component and other ingredients firm enough to knead, roll or form. In addition, it also refers to the cohesive product that results from the mixture of the flour/starch component and water along with possibly fats and other usual ingredients normally entering the composition of a usual dough such as salt, yeast or chemical leavening agents, egg products, milk products and sugar.
As used herein, fat is intended to include both fat and oil.
As used herein, granular is intended to mean that the starches have the intact structure of a native starch granule, but their Maltese cross (under polarized light) is less defined or even absent due to compromised crystallinity.
As used herein, clean labeled is intended to mean that the ingredients do not include modified food starch, as currently defined by the U.S. Food and Drug Administration.
As used herein, the flour/starch component is intended to mean all the flour and/or starch ingredients in the product.
This invention pertains to a gluten-free bakery product which comprises a flour/starch component comprising a heat moisture treated flour. Such bakery products more closely mimic the conventional, wheat flour containing products than other gluten-free products.
The flours and starches used in preparing the present invention may be derived from native sources. Native, as used herein, is one as it is found in nature. Also suitable are flours and starches derived from a plant obtained by standard breeding techniques including crossbreeding, translocation, inversion, transformation or any other method of gene or chromosome engineering to include variations thereof. In addition, flours and starches derived from a plant grown from induced mutations and variations of the above generic composition which may be produced by known standard methods of mutation breeding are also suitable herein,
Typical sources for the flours and starches of this invention are cereals, tubers, roots, legumes and fruits. The native source can include corn (maize), pea, potato, sweet potato, garbanzo beans, banana, barley, wheat, rice (including brown rice), sago, oat, amaranth, tapioca, arrowroot, canna, quinoa, or sorghum, as well as high amylopectin or high amylose varieties thereof. However, if a gluten-containing source is used, the gluten must be removed to an extent sufficient to obtain the gluten-free compositions of the invention. In one embodiment, the native source is selected from the group consisting of rice, tapioca, corn, potato, oat, amaranth, and sorghum.
Flours and starches suitable in the present invention may be derived from the plant material by any method used in the art of manufacturing flours and starches. In one embodiment, the flours are derived by dry milling. However, other methods, including combinations of wet and dry milling techniques may be used.
In one embodiment, the flour will contain 8-25% moisture, 1-50% protein, 0.1-8% fat (lipids), 1-50% fiber, 20-90% starch, 0-3% ash and optionally, other components such as nutrients (e.g. vitamins and minerals). The particle size may be varied as may the percents of the components using methods known in the art. For example, fine grinding and air classification may be used to alter the protein content. Flour is intended to include, without limitation, white flour, wholemeal flour, and wholegrain flour.
Heat moisture treated flour is known in the art and is, for example, commercially available from National Starch LLC (Bridgewater, N.J., USA). The heat moisture treated flour may be prepared by any process known in the art to produce such flours. One such process follows.
In one suitable process, it is necessary that the starting flour have a specified amount of water or moisture content and is heated to a defined temperature in order to accomplish the goal of enhanced process tolerance and solution stability. The total moisture or water content of the starch to be heat treated will be in the range of from 10 to 50%, and in one embodiment will be in the range of 15 to 30%, by weight of the dry flour (dry solids basis, dsb). In another suitable embodiment, the level of moisture is substantially maintained during the heating step, such that it does not change by more than 5% (±5%). This may be accomplished, for example, by heat treating the flour in a sealed vessel to avoid water evaporation and/or by pre-conditioning the air circulating through the heating vessel. In another embodiment, the heat treatment has a drying effect and reduces the moisture content of the flour during processing, but not outside the above-stated moisture range.
The flour with specified moisture content is heated to a target temperature of from 100 to 180° C., and in one aspect from 100 to 120° C. It is important that the starch of the flour remain in the granular state. Other changes may occur, including denaturation of the protein. The time of heating can vary depending on the composition of the flour, including the starch and protein content, the particle size distribution, the amylase content of the starch component, and the level of enhancement desired as well as the amount of moisture and the heating temperature. In one embodiment, the heating time at target temperature will be from about 1 to 150 minutes, and in another embodiment from about 30 to 120 minutes.
The heat moisture treatment may be conducted using any equipment known in the art which provides sufficient capabilities for such treatment, particularly those which are enabled for powder processing, moisture addition and/or moisture control, mixing, heating and drying. The heat treatment may be done as a batch or a continuous process. In one embodiment, the equipment is a batch ploughshare mixer. In another embodiment, the equipment is a continuous solid-liquid mixer followed by a continuous heated conveyer screw. In yet another embodiment, the continuous process uses a tubular thin film dryer by itself or in combination with a continuous screw to extend and control the residence time. Any system used may be pressurized to control the moisture content at target temperatures at or above 100° C.
The conditions for treating the flour must be such that the granular structure of the starch within the flour is not destroyed. In one embodiment, the granules are still birefringent and there is evidence of a Maltese cross when the granular structure of the starch is viewed under polarized light. Under some conditions, such as at high moisture and high temperature, the starch granule may be partially swollen but the crystallinity is not completely destroyed. Accordingly, the term ‘granular starch’ as used herein, means a starch which predominantly retains its granular structure (native granules) and has some crystallinity, and the granules may be birefringent and the Maltese cross may be evident under polar light. Further, the denaturing effect of the heat-moisture treatment on the protein component may have an impact on the observed functionality of the flour. The resulting product which has been heat treated will still have at least some granular structure and in one embodiment will be birefringent when viewed under the microscope and have a Maltese cross when viewed under polarized light.
After the heat moisture treatment, the flour may be allowed to air dry to reach equilibrium moisture conditions or may be dried using a flash dryer or other drying means, such as spray drying, freeze-drying, or drum drying. In one embodiment, the flour is air dried or flash dried. The pH of the flour may also be adjusted and is typically adjusted to between 6.0 and 7.5.
The heat moisture treated flour of the present invention may be used in an amount effective to produce an organoleptically acceptable gluten-free bakery product. In one embodiment, the flour or flour mixture (hereinafter “flour”) is used in the range of 2-95% (w/w) based on the gluten-free bakery product.
In one particularly suitable embodiment, the heat moisture treated flour is derived from a gluten-free grain and in another embodiment is rice flour.
In another embodiment, the gluten-free bakery product further contains either heat moisture treated or native tapioca flour and/or starch, which are known in the art and are, for example, commercially available from National Starch LLC (Bridgewater, N.J., USA). Hereinafter, tapioca starch or tapioca flour will be referred to as tapioca flour.
The ratio of heat moisture treated flour to tapioca flour (native or heat-moisture treated) is from 98:2 to 2:98 (w/w), in another embodiment is from 95:5 to 5:95 (w/w), in yet another embodiment is from 90:10 to 10:90 (w/w), and in still yet another embodiment is from 85:15 to 15:85 (w/w).
The flour/starch component may contain other flours and/or starches to provide further desired organoleptic qualities, such as thermally inhibited starches and flours, inhibited potato starches, inhibited corn starches, inhibited tapioca starches, cold water swellable starches, and/or octenylsuccinic anhydride substituted starch.
The thermally inhibited starch of the present invention may be used in an amount effective to produce an organoleptically acceptable gluten-free bakery product, and in one aspect of the invention is used in an amount of from 5 to 100% (w/w) based upon the amount of the heat moisture treated flour. The thermally inhibited starch typically is used to modify organoleptic properties, and in one instance is used as a dough conditioner and/or viscosity modifier. Such viscosity modifiers are commonly used in the trade to help thicken the dough or batter, enabling its further processing into finished products such as cookies, muffins, pancakes, cakes, and other baked goods. It is also used to modify chewiness, gumminess, moistness, crispness, and other organoleptic qualities of the food product.
Such thermally inhibited starches and flours may prepared by any process known in the art. Thermally inhibited starches and flours (hereinafter “starches”) are known in the art: see for example WO 95/04082, WO 96/40794, U.S. Pat. Nos. 5,932,017 and 6,261,376, and U.S. Ser. No. 12/423,213. One such thermal inhibition process follows.
The starch may be adjusted before, after, and/or during the dehydration step, if necessary, to a pH level effective to maintain the pH at neutral (range of pH values around 7, from about pH of 6 to 8) or basic pH (alkali) during the subsequent thermal inhibition step. Such adjustment is known in the art, including methods of pH adjustment, types of buffers and alkalis used, and pH levels suitable.
The starch is dehydrated to anhydrous or substantially anhydrous conditions. As used herein, the term “substantially anhydrous” is intended to mean less than 5%, in one embodiment less than 2% and in yet another embodiment less than 1% (w/w) water. The dehydration step to remove moisture and obtain a substantially anhydrous starch may be accomplished by any means known in the art and includes thermal methods, and non-thermal methods. Non-thermal methods would include using a hydrophilic solvent such as an alcohol (e.g. ethanol), freeze drying, or using a desiccant. Non-thermal dehydration may contribute to improvement of the taste of the thermally-inhibited polysaccharides.
Thermal methods of dehydration are also known in the art and are accomplished using a heating device for a time and elevated temperature sufficient to reduce the moisture content to that desired. In one embodiment, the temperature used is 125° C. or less. In another embodiment, the temperature will range from 100 to 140° C. While the dehydration temperature can be lower than 100° C., a temperature of at least 100° C. will be more effective in removing moisture when using a thermal method. The dehydration step may be conducted using any process or combination of processes and is typically conducted in an apparatus fitted with a means for moisture removal (e.g. a blower to sweep gas from the head-space of the apparatus, fluidizing gas) to substantially prevent moisture from accumulating and/or precipitating onto the starch. The time and temperature combination for the dehydration will depend upon the equipment used and may also be affected by the type of starch being treated, the pH and moisture content, and other factors identified and selected by the practitioner.
The thermal inhibition step is performed by heating the substantially anhydrous starch at a temperature of 100° C. or greater for a time sufficient to inhibit the starch. In one aspect of the invention, the starch is substantially anhydrous before reaching heat treatment temperatures, and in another aspect of the invention the starch is substantially anhydrous throughout at least ninety percent of the heat treatment.
The heat treatment may be conducted over a range of temperatures of at least 100° C. In one embodiment, the temperature will range from 100 to 200° C., in another embodiment from 120 to 180° C. and in yet another embodiment from 150 to 170° C. The time for thermal inhibition in one embodiment is from 0 to 12 hours, in another embodiment is from 0.25 to 6 hours and in yet another embodiment is from 0.5 to 2 hours. The time for thermal inhibition is measured from the time the temperature stabilizes (the target temperature is reached) and therefore the thermal inhibition time may be zero if thermal inhibition occurs while such temperature is being reached. For example, if conducting the process in an apparatus which has a comparatively slow temperature ramp-up, once the starch has reached substantially anhydrous conditions, thermal inhibition will begin if the temperature is sufficiently high and may be complete before the apparatus reaches final temperature.
The dehydrating and/or heat treatment steps may be performed at normal pressures, under vacuum or under pressure, and may be accomplished using any means known in the art. In one method, the gas used is pre-dried to remove any moisture. In another embodiment, at least one of these steps is carried out under increased pressure and/or under increased effective oxygen concentration.
The time and temperature combination for the dehydration and thermal inhibition steps will depend upon the equipment used and may also be affected by the type of starch being treated, the pH and moisture content, and other factors identified and selected by the practitioner.
In one aspect of this invention, the thermally inhibited starch is selected from the group consisting of rice starch, tapioca starch, corn starch, and potato starch.
In one aspect of the invention, inhibited potato starches are added in an amount of from 10-100% (w/w) of the heat moisture treated flour. Such inhibited potato starches are produced from native potato starches. Inhibition may be by any method including without limitation chemical crosslinking and thermal inhibition. Chemical crosslinking is well known in the art as described for example in Modified Starches: Properties and Uses, Ed. Wurzburg, CRC Press, Inc., Florida (1986). In one embodiment, the starch is crosslinked using at least one reagent selected from sodium trimetaphosphate (STMP), sodium tripolyphosphate (STPP), phosphorous oxychloride, epihydrochlorohydrin, and adipic-acetic anhydride (1:4) using methods known in the art. In another embodiment of the invention in which the flour/starch component is clean labeled, and in a further embodiment in which the bakery product is clean labeled, inhibition of the potato starch is by thermal inhibition.
In another aspect of the invention, inhibited tapioca starches are added in an amount of from 5-100% (w/w) of the heat moisture treated flour. Such inhibited tapioca starches are produced from native tapioca starches. Inhibition may be by any method including without limitation chemical crosslinking and thermal inhibition.
In another aspect of the invention, the inhibited starch is an octenylsuccinic anhydride (OSA) substituted starch which may be used to produce an organoleptically acceptable gluten-free bakery product. In one aspect of the invention, the OSA starch is used in an amount of from 1 to 50% (w/w) based upon the amount of the heat moisture treated flour. Such OSA starches are produced from waxy maize, dent corn, or tapioca starches. Suitable levels of OSA modification are by addition of the OSA reagent in the amount of from 0.5 to 3% (w/w), and in one embodiment in an amount of 2 to 3% (w/w), based on the starch. The starch is modified with octenyl succinic anhydride using methods known in the art. Exemplary processes for preparing OSA starches known in the art and are disclosed, for example in U.S. Patent Application 2005/0008761 and Wurzburg (ibid). Other alkenyl succinic anhydrides, such as dodecenyl succinic anhydrides, may also be used.
In another aspect of the invention, cold water swellable starch is added in an amount of from 2 to 100% (w/w) and in yet another aspect in an amount of from 5 to 100% (w/w), based upon the heat moisture treated flour. Such cold water swellable cornstarch is known in the art and is otherwise known as pregelatinized starch. The cold water swellable starches of the present invention may be either granular or non-granular.
Granular pregelatinized starches have retained their granular structure but lost their Maltese crosses under polarized light. They are pregelatinized in such a way that a majority of the starch granules are swollen, but remain intact. Exemplary processes for preparing pregelatinized granular starches known in the art and are disclosed for examples in U.S. Pat. Nos. 4,280,851; 4,465,702; 5,037,929; and 5,149,799.
Pregelatinized non-granular starches and flours have also lost their Maltese crosses under polarized light and have become so swollen that the starches have lost their granular structure and broken into fragments. They can be prepared according to any of the known physical, chemical or thermal pregelatinization processes that destroy starch granules which include without limitation drum drying, extrusion, and jet-cooking.
In one treatment for making the starch cold water swellable, the starch may be pregelatinized by simultaneous cooking and spray drying such as disclosed in U.S. Pat. No. 5,149,799. Conventional procedures for pregelatinizing starch are known to those skilled in the art are also described for example in Chapter XXII—“Production and Use of Pregelatinized Starch”, Starch: Chemistry and Technology, Vol. III—Industrial Aspects, R. L. Whistler and E. F. Paschall, Editors, Academic Press, New York 1967.
In one aspect of the invention, an optional bulking agent is used in the flour/starch component. This bulking agent can be any starch or flour added at a level that it does not significantly alter the texture imparted to the product by the heat moisture treated flour. In one embodiment of the invention, the optional bulking agent is native rice flour. In another embodiment of the invention, the bulking agent is used at a level of 20% (w/w) or less and in a further embodiment at a level of 15% (w/w) or less of the heat moisture treated flour in the formulation. In yet another embodiment of the invention, the bulking agent is used at a level of less than 10% (w/w) and in still yet another embodiment at a level of less than 5% (w/w) of the bakery product.
In one embodiment of the invention, the flour/starch component of the bakery product consists essentially of the heat moisture treated flour and the native tapioca flour and in another consists essentially of the heat moisture treated rice flour and the native tapioca flour. In yet another embodiment, the flour/starch component of the bakery product does not contain any starch or flour other than the heat moisture treated rice flour and the native tapioca flour.
The bakery product of this invention contains from 1% to 99% (w/w) of the flour/starch component and in another embodiment from 5% to 95% (w/w) of the flour/starch component.
The bakery products of this invention also contain at least one other conventional bakery product ingredient, such as eggs, milk, water, sugar, fats (shortening), chocolate, leavening agents, yeast, salt, emulsifier, and flavorings. Such conventional ingredients are well known in the art modify taste, texture, smell, appearance, keeping properties, workability, cooking properties, nutritional balance and the like. In one embodiment, the bakery products of this invention are clean label; that is, they do not contain any chemically modified ingredients or ingredients produced using genetically modified organisms. The bakery products do not contain any starch or flour other than the flour/starch component.
In one embodiment, the bakery product contains less than 3% gum, in another embodiment less than 1.0% gum, in yet another embodiment less than 0.5% gum all on a weight/weight basis and in still another embodiment no gum.
In one embodiment of the invention, the flour/starch component, in combination with the other optional ingredient(s), is capable of forming a dough, such as a bread dough, cake dough, cookie dough or biscuit dough. Such dough is capable of containing air cells produced by any leavening agent, and may be processed using conventional methods available to wheat products, for instance, mixed, fermented, scaled, molded, proofed and cooked (eg baked, fried, steamed etc.) like conventional gluten containing products. In one embodiment of the invention, the bakery product is a baked product.
The bakery products of this invention are gluten free, containing less than 20 ppm gluten (weight/weight basis).
The bakery products of this invention have improved organoleptic properties compared to other gluten-free bakery products and in one aspect of the invention are substantially the same as gluten containing bakery products. In particular, the bakery products of this invention have improved textural and structural attributes. In one embodiment of the invention, the graininess of the bakery product is less than 8.5 and in one embodiment is less than 7 as measured using the test set forth in the Examples section. In another embodiment of the invention, the cohesiveness of the bakery product is at least 5, in one embodiment is greater than 6, in another embodiment is greater than 7, and in yet another embodiment is greater than 8.5 as measured using the test set forth in the Examples section.
The bakery product of the present invention include without limitation breads, rolls, buns, bagels, toasts, crackers, pizza crust, brownies, croissants, pastries, croutons, wafers, rolls, biscuits, cookies, cakes, pie crusts, muffins, donuts, tortillas, waffles, pancakes, pretzels, sheeted baked snacks, pound cakes, and wraps. The bakery product is also intended to include mixes useful to prepare bakery products, and shelf-stable, or refrigerated, and frozen bakery products.
The following examples are presented to further illustrate and explain the present invention and should not be taken as limiting in any regard. All parts and percentages are given by weight and all temperatures in degrees Celsius (° C.) unless otherwise noted.
The following ingredients were used throughout the examples.
Viscosity modifier—NOVATION® 4600 starch, a thermally inhibited starch commercially available from National Starch LLC (Bridgewater, N.J., USA) Tapioca flour, commercially available from National Starch LLC (Bridgewater, N.J., USA)
Heat-moisture treated rice flour, prepared according to Example 1, and commercially available from National Starch LLC (Bridgewater, N.J., USA)
Hi-Maize® 260 starch, a high amylose starch commercially available from National Starch LLC (Bridgewater, N.J., USA)
Thermally inhibited tapioca starch, commercially available from National Starch LLC (Bridgewater, N.J., USA)
Thermally inhibited potato starch, commercially available from National Starch LLC (Bridgewater, N.J., USA)
Thermally inhibited waxy corn starch, commercially available from National Starch LLC (Bridgewater, N.J., USA)
Instant PURE-FLO® F starch, a cold water swellable starch commercially available from National Starch LLC (Bridgewater, N.J., USA)
Pregelatinized waxy corn starch, commercially available from National Starch LLC (Bridgewater, N.J., USA).
N-CREAMER™ 46 starch, an octenylsuccinic anhydride (OSA) substituted starch, commercially available from National Starch LLC (Bridgewater, N.J., USA).
Wheat flour, commercially available from a number of commercial sources.
Rice flour, commercially available from a number of commercial sources.
The following test procedures were used throughout the examples.
The cohesiveness of gluten free products is defined as the oral sensory perception of the degree to which the chewed product forms a ball or holds together into a bolus during the chewing process. It is measured by oral sensory analysis by trained experts who chew the food product being tested with the molar teeth and rate it on a 15-point scale in comparison to calibration samples. A higher number indicates more cohesiveness. The calibration samples consist of shoestring licorice candy with a score of 0, raw carrot with a score of 2, raw mushrooms with a score of 4, frankfurter with a score of 7.5, American cheese with a score of 9 and Fig Newtons with a score of 14.
The graininess of gluten free products is defined as the oral sensory perception caused by the amount of roughness on the surface of the mass or bolus during the chewing process. It is measured by oral sensory analysis by trained experts who chew the food product 8-10 times and then feel the surface of the mass or bolus in their mouth, and rate it on a 15-point scale in comparison to calibration samples. A higher number indicates more graininess. The calibration samples consist of American cheese with a score of 3, Graham crackers with a score of 5, Melba toast with a score of 7.5, hard pretzel rod with a score of 10, raw carrot with a score of 12, and granola bar with a score of 15.
0.5 g of a starch (1.0 g of a ground grain) sample was heated in 10 mls of concentrated calcium chloride (about 30% by weight) to 95° C. for 30 minutes. The sample was cooled to room temperature, diluted with 5 mls of a 2.5% uranyl acetate solution, mixed well, and centrifuged for 5 minutes at 2000 rpm. The sample was then filtered to give a clear solution.
The starch concentration was determined polarimetrically using a 1 cm polarimetric cell. An aliquot of the sample (normally 5 mls) was then directly titrated with a standardized 0.01 N iodine solution while recording the potential using a platinum electrode with a KCl reference electrode. The amount of iodine needed to reach the inflection point was measured directly as bound iodine. The amount of amylose was calculated by assuming 1.0 gram of amylose will bind with 200 milligrams of iodine.
Combine dry ingredients except sugars. Cream butter and sugars in mixer with paddle. Add eggs and vanilla and mix until well blended. Add dry ingredients in two equal additions, mixing well after each. Mix in chocolate chips. Spoon approximately 30 g portions on parchment-lined cookie sheet. Flatten each portion slightly. Bake for approximately 12 minutes at 190° C. (pre-heated).
Combine dry ingredients except sugar and blueberries. Cream sugar and shortening on speed 2 of a Hobart mixer for 5 minutes. Add eggs and vanilla slowly while mixing on speed 1. Add combined dry ingredients in alternating additions with water on speed 1 over a period of 2 minutes. Add blueberries and mix in by hand. Scale at approximately 61 grams and bake in muffin tins for 20-21 minutes at 190° C.
This example shows a method for heat moisture treatment of flours.
A. A fine mist of water was sprayed on 1500 g of low amylose rice flour (LARF, amylose content—12%; RM100AR—lot #7519) while mixing it in a Kitchen Aid mixer at number 2-3 speed. The moisture of the flour was checked intermittently during the spraying by the Cenco moisture balance. The flour powder was adjusted to four different final moisture contents of 15, 20, 25, and 30%. It was further mixed for 1 hour to ensure moisture uniformity, About 200 grams of moist flour was then sealed in aluminum cans with less than 1 inch head space. The sealed aluminum cans were placed in ovens already at the desired temperatures of 100° C., and 120° C. for the heat moisture treatment. There was a 30 minute ramp up time to allow the sample temperature inside the cans to equilibrate with the outside oven temperature. The sample was further held at that temperature for 2 hours. After the heat-moisture treatment, the cans were opened and the heat moisture treated (HMT) flours were air-dried at room temperature. The dry samples were ground to fine powder using a coffee grinder and sieved using a US mesh 20 screen (0.841 mm sieve opening). Samples were subsequently characterized for thermal and rheological properties.
B. Example 1A was repeated for waxy rice flour except that the moisture was adjusted to 25% and was then heat treated at 100° C.
C. Example 1A was repeated for regular rice flour except that the moisture was adjusted to 20% and was then heat treated at 100° C.
Cookies were prepared from the following formulation.
These cookies had a cohesiveness of 7 and a graininess score of 8.
Cookies were prepared from the following formulation.
These cookies had a cohesiveness of 8 and a graininess score of 7.8.
Cookies were prepared from the following formulation.
These cookies had a cohesiveness of mass score or 7.7 and a graininess score of 11.5 due to the high amount of native rice flour.
Cookies were prepared from the following formulation.
Cookies had a cohesiveness of mass score or 6.8 and a graininess score of 8.7.
Bulking agent (rice flour) has a negative effect on the texture of the cookie.
Cookies were prepared from the following formulation.
Cookies had a cohesiveness of mass score or 5 and a graininess score of 10 due to the high amount of native rice flour included and the lack of heat moisture treated flour.
Cookies were prepared from the following formulation.
These cookies had a cohesiveness of 8.5 and a graininess score of 7.
Muffins were prepared from the following formulation.
Muffins had a cohesiveness of 9 and a graininess score of 8.
Muffins were prepared from the following formulation.
Muffins had a cohesiveness of 7 and a graininess score of 7.
Muffins were prepared from the following formulation.
Muffins had a cohesiveness of mass score or 7 and a graininess score of 5.
Muffins were prepared from the following formulation.
Muffins had a cohesiveness of 7 and a graininess score of 5.
Muffins were prepared from the following formulation.
Muffins had a cohesiveness of 9 and a graininess score of 6.5.
Muffins were prepared from the following formulation.
Muffins had a cohesiveness of 4 and a graininess score of 10.
Muffins were prepared from the following formulation.
These muffins had a cohesiveness of 8 and a graininess score of 5.
This set of examples shows the utility of the invention in producing a variety of gluten-free products.
The following test procedure was used to make bread.
Bread was prepared using the following formulation.
The following test procedure was used to make pizza dough.
Disperse yeast in warm water. Sift flour and salt into mixing bowl and while mixing on low add the olive oil and yeast/water mixture. Mix 1 minute on low speed in Hobart mixer, 3-4 min. on med-high speed or until dough is smooth and elastic. Place in well-oiled bowl and bulk ferment until double in size. Fold and form into individual balls to size. Form into a circular base of 1 cm thickness and spread layer of tomato sauce and cheese on base. Pre-heat oven to 175 degrees C. Bake pizza at 175 degrees C. for 30 min. Remove from oven.
Pizza dough was prepared from the following formulation.
The following test procedure was used to make pancakes.
Whisk to combine all dry ingredients. Whisk to combine all wet ingredients in a separate bowl.
Pour wets into dries, mix just until combined. Lightly oil a griddle. Heat griddle to 149° C. Pour batter onto griddle surface. Turn when bubbles begin to form on surface of pancake, about 3 minutes. Turn and cook about 2 minutes more. Remove from griddle.
Pancakes were prepared from the following formulation.
Pancakes were prepared from the following formulation.
The following test procedure was used to make brownies.
Grease and flour a 9×9 inch pan. Melt butter in microwave or in saucepan on stovetop. Transfer to mixer using the paddle to mix the cocoa with the butter until smooth. Mix in the sugar, eggs, coffee, and vanilla. Scrape down the sides and bottom of the bowl and mix again until smooth. Combine all of the dry ingredients. Add the dry ingredients to the wet ingredients and mix until fully blended. Transfer batter to pan. A 9×9 inch pan should hold about 1000 grams of batter. Bake for 20-25 minutes at 175° C., or until a toothpick comes out clean. Cool on wire rack and tip over to release from pan.
Brownies were prepared from the following formulation.
Brownies were prepared from the following formulation.
The following test procedure was used to make a hi-ratio cake.
Sift together dry ingredients in part A. Mix A for 5 minutes at medium speed with paddle.
Add part B and mix 3 minutes at medium speed. Add part C in 2 stages blending well after each addition. Weigh 400 g batter into 2 greased & floured 8 inch round cake pans.
Bake at 177° C. for 18-22 minutes. Cool 15-20 minutes and remove from pan.
A hi-ratio cake was prepared from the following formulation.
A hi-ratio cake was prepared from the following formulation.
The following test procedure was used to make a pie crust.
Blend flours and salt. Add chilled shortening and cut in with 2 knives until like coarse meal. Add chilled water, a small amount at a time, and mix with fork until dough comes together.
Form ball and wrap in saran. Chill ball until 14-16° C. For 4½ inch tart pans, scale top and bottom crusts at approx 120 g. With rolling pin, roll dough to 114 inch thick circle, or press dough by hand unto a ¼ thick circle. Place bottom crust in pan and trim. Fill with approx. 240 g pie filling. Top with crust, trim, and seal. Bake at 218° C. for 30 minutes.
A pie crust was prepared from the following formulation.
The following test procedure was used to make a snack cracker.
Blend part A with paddle in a Hobart Mixer for 5 minutes at low speed. Make part B by dispersing sugar, dextrose, salt, and sodium bicarbonate in water with mixing for 3 minutes. Add B slowly to the dry blend; continue mixing for 3 minutes or until it forms a dough. By hand, make a dough sheet of approximately ½ inch thickness. Reduce the dough sheet to get final thickness of 0.7-0.8 mm in three steps. First step: roller setting 1 mm. Second step: roller setting 0.7 mm. Third, final step: roller setting 0.3 mm. Cut with cracker die cutter and place pieces on a perforated baking pan. Bake in deck oven for 5-10 min at 177° C.
Snack crackers were prepared from the following formulation.
Cookies were prepared from the following formulation.
Muffins were prepared from the following formulation.
Muffins were prepared from the following formulation.
Muffins were prepared from the following formulation.
Rolls were prepared from the following formulation.
This application claims priority to provisional patent application Ser. No. 61/184,445 filed 5 Jun. 2009.
Number | Date | Country | |
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61184445 | Jun 2009 | US |
Number | Date | Country | |
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Parent | 12776580 | May 2010 | US |
Child | 16167021 | US |