Enzyme-resistant starch for reduced-calorie flour replacer

Food or edible material: processes – compositions – and products – Products per se – or processes of preparing or treating... – Basic ingredient is starch based batter – dough product – etc.

Reexamination Certificate

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C426S028000, C426S578000, C426S391000, C426S496000, C127S038000, C127S071000

Reexamination Certificate

active

06352733

ABSTRACT:

FIELD OF THE INVENTION
This invention relates to the production of enzyme-resistant starch in high yield for a reduced-calorie flour replacer. Doughs and cookies containing the enzyme-resistant starch are also contemplated by the present invention. This invention also relates to reduced-calorie baked goods which contain the enzyme-resistant starch for substantial calorie reduction.
BACKGROUND OF THE INVENTION
Enzyme-resistant starch (RS) is a fraction of starch not digested in the small intestine of healthy individuals. Microflora may partially ferment certain types of resistant starch in the large bowel. According to a doctoral thesis by Relinde Eerlingen entitled “Formation, Structure and Properties of Enzyme Resistant Starch,” Katholieke Universiteit te Leuven (February 1994), enzyme-resistant starch may be defined as the sum of starch and products of starch degradation not absorbed in the small intestine, and it may be classified into four types. Physically inaccessible starch, which is locked in the plant cell, is classified as type I resistant starch. It is a fraction which can be found in foodstuffs with partially milled grains and seeds and legumes. Native granular starch found in uncooked ready-to-eat starch-containing foods, such as in bananas, is classified as type II resistant starch. Enzyme susceptibility of type II resistant starch is reduced by the high density and the partial crystallinity of the granular starch. The amount of type I and type II resistant starches is generally less than about 12% by weight, based upon the total amount of uncooked or raw starch contained in the starch source. However, the type I and type II resistant starches have low melting points, do not survive a baking process, and do not exhibit good baking functionality. For example, granular starches in the presence of excess water melt at a temperature of about 80° C. to about 100° C., which is generally below baking temperatures for cookies and crackers. Additionally, yields of resistant starch substantially greater than 12% by weight of the original starch component are desirable for the mass production of baked products having substantially reduced calorie content.
Starch may be treated to obtain an indigestible starch fraction. Depending upon the type of treatment, a type III resistant starch or a type IV resistant starch may be produced. An indigestible starch fraction which forms after certain heat-moisture treatments of the starch, which may be present in, for example, cooled, cooked potatoes and canned peas or beans, is type III enzyme-resistant starch.
In type IV resistant starch, the enzyme resistance is introduced by chemically modifying or thermally modifying the starch. The modification may be the formation of glycosidic bonds, other than alpha-(1-4) or alpha-(1-6) bonds, by heat treatment. Formation of these other glycosidic bonds may reduce the availability of starch for amylolitic enzymes. These types of bonds may be present, for example, in products of caramelization and products of Maillard reactions.
U.S. Pat. No. 5,330,779 to Watanabe discloses a food additive which is slowly absorbed and digested, comprising a mixture of starches comprising a starchy material having a high amylose content and a modifier which modifies the enzymatic reaction ratio with amylase, such that it is not more than 95% digested, as compared to an unmodified starch mixture. The modifier may be a saccharide or a fatty acid compound.
U.S. Pat. Nos. 5,364,652 and 5,472,732 and European patent application publication 443,788A1 published Aug. 28, 1991), each to Ohlkuma et al., disclose the production of indigestible dextrins or pyrodextrins by heat-treating potato starch in the presence of an acid and then refining the product. According to U.S. Pat. Nos. 5,364,652 and 5,472,732, attempts to increase the amount of pyrodextrin produced by increasing the reaction time and reaction temperature result in a colored substance, release a stimulative odor, and result in a product which is not practically useful. Each of the U.S. patents and the European patent publication disclose refining of the pyrodextrin by the use of hydrolysis with alpha-amylase, followed by separation of the dextrin fraction from the digestible components by continuous chromatography with use of an ion-exchange resin.
In addition, the digestibility of starch may be reduced by cross-linking or the presence of various substituents such as hydroxypropyl groups. However, the chemical or thermal modification of the starch, which results in a type IV resistant starch, often affects the baking characteristics of the starch. In addition, chemically or thermally modified starches may exhibit undesirable flavors or colors when used in substantial amounts in baked goods. Legal limitations by the U.S. Food and Drug Administration (FDA) have also been placed upon the use of various chemically modified starches in baked goods.
However, to produce enzyme-resistant starch type III, heat-moisture treatments of the starch create crystalline regions, without the formation of glycosidic bonds other than alpha-(1-4) or alpha-(1-6) bonds. The type III resistant starch is thermally very stable, which is highly advantageous for producing reduced-calorie baked goods. If the crystal structure which provides enzyme resistance is destroyed or melts during baking, and if the crystal recrystallizes into a lower-melting form which is not enzyme resistant, then calorie reduction will not be achieved in the baked product. According to the Eerlingen dissertation, when RS type III is heated in the presence of water, an endotherm is revealed at about 150° C., with enthalpy values ranging from 8 mJ/mg to 30 mJ/mg. Heating to 180° C., it is reported, leads to partial thermal degradation of the RS chains. During cooling, an exotherm with an enthalpy value of about −22 mJ/mg, starting at about 60° C., can be observed. The exotherm has been attributed to reassociation of the resistant-starch chains.
Reported chain lengths for resistant starch type III vary between an average degree of polymerization, DP
n
, of 22 and 65 glucose residues, with the chains being linear. Accordingly, RS type III is reported as consisting of short linear segments of alpha-glucans arranged in a crystalline structure.
To produce enzyme-resistant starch type III from native starch granules, the starch has to be gelatinized and then retrograded. Factors which affect the yield of enzyme-resistant starch type III include: amylose content of the starch, the number of autoclaving-cooling cycles used to form the RS type III, the water content of the starch, the autoclaving temperature, and the presence of complexing lipids. It has been reported that higher amylose-content starches result in increased resistant-starch yield. According to Eerlingen, high yields of more than 20% resistant starch can be obtained from autoclaved amylomaize starch containing 70% amylose. This yield, it is stated, can even be raised to levels of 40% by increasing the number of autoclaving-cooling cycles up to 20 cycles. A starch:water ratio of 1:3.5 is disclosed as providing an optimum in resistant-starch yield. The effect of autoclaving temperature upon resistant-starch yield has been reported to depend upon the starch type. According to Eerlingen, increasing the autoclaving temperature from 100° C. to 134° C. increased the RS yield for wheat starch, but did not significantly affect the yield for amylomaize starch. It is also disclosed that the formation of amylose-lipid complexes, due to the addition of an excess of complexing lipids, decreases resistant-starch yields.
Several methods are available for the in vitro determination of resistant starch. The resistant-starch levels and yields determined in vitro depend upon the method used. The methods differ in the enzymes used and the temperature-time conditions of incubation. Lower resistant-starch yields are obtained when more severe conditions are applied, such as higher incubation temperatures, longer incubation times, and higher enzyme levels. For example, in one p

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