JP2008289397A - Method for producing processed starch, food items, and feed - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide processed starch giving no harmful effect to palate feeling and taste when utilizing the starch for food items, to provide a method for producing the processed starch, and to provide food items and feed that contain the processed starch. <P>SOLUTION: This method for producing the processed starch comprises a process of soaking raw material starch at 30°C or higher for 6 h or longer in water of less than gelation starting temperature of the raw material starch, and a treating process of the raw material starch which is warm water treated. The processed starch which is produced by the method, and the food and feed which contain the processed starch are each provided. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a method for producing processed starch, and a food and feed containing processed starch obtained by the method.

Various processing methods are known as methods for improving and modifying starch. Specific examples include etherification, esterification, cross-linking, pregelatinization, oxidation, enzyme treatment, wet heat treatment, addition of an emulsifier, processing of fats and oils, and combinations thereof. Such processed starch is widely used in the food industry.
Most food starch processing is carried out in the form of an aqueous slurry that retains the starch particle structure. The merit of processing in a state where the starch granules are retained is economical because the obtained processed starch can be purified by washing with water.
Although the viscosity, swelling degree, and the like of starch can be greatly modified by the processing methods exemplified above, workability may be reduced due to swelling and gelatinization of starch when processing is performed. In particular, in the etherification and esterification reactions, if an attempt is made to introduce a certain amount or more of ether groups and ester groups into the raw material starch, the starch granules swell and gelatinize. Therefore, even if an attempt is made to produce a processed starch having a more pronounced degree of substitution in etherification and esterification while retaining the starch granules, the starch granules are likely to swell and may become difficult to wash and dehydrate after processing. there were.

As an application example of processed starch to food, an example in which crosslinked starch is applied to food is disclosed. For example, Patent Documents 1 to 3 can be cited. However, when a cross-linked starch having a high degree of cross-linking is applied to food, the final product has a disadvantage that it has a powdery texture and inferior in flavor. In addition, when starch having a low degree of crosslinking is applied to foods, the amount used is limited because the powdery texture becomes stronger and the quality of the final product is reduced as the amount used increases.
On the other hand, hot water treatment is known as a method for improving and modifying starch. The hot water treatment in the starch industry is a treatment in which starch is made into a slurry state and heated at a temperature lower than the gelatinization start temperature. It has been reported that the gelatinization start temperature of starch is increased by hot water treatment (Non-patent Document 1), and the effect that the noodles become lumpy by using the hot-water-treated starch for hull shark (Non-patent Document 2). Yes. Starch products obtained by subjecting raw starch to hot water treatment are already on the market and are used in foods and the like. For example, the trade name Hokuren HR is commercially available from the Hokuren Agricultural Cooperative Federation.
However, since the warm water treatment of the raw starch is a mild reaction, the viscosity and swelling degree of the starch cannot be greatly modified, and only a slight improvement and a modification effect according to the raw starch can be obtained. .

Japanese Patent No. 3723860 Japanese Patent No. 3322225 US Pat. No. 5,855,946 Starch Science Vol.28, No.3 (1981) p206-214 Bulletin of Faculty of Home Economics, Kyoritsu Women's University No. 39 (1993) p103-108

The first object of the present invention is to provide a modified starch that does not adversely affect the texture and taste when used in foods, and a method for producing the same.
The second object of the present invention is to provide a method for producing processed starch having a high degree of substitution.
The third object of the present invention is to provide foods and feeds containing the modified starch.

As a result of intensive studies to solve the above problems in the starch processing method, the present inventors have found that the above problems can be solved by treating the raw starch with hot water, and have reached the present invention. This invention provides the manufacturing method of the modified starch shown below, the modified starch manufactured by this method, the foodstuff containing this modified starch, or feed.
1. A method for producing processed starch, comprising: a raw water starch warm water treatment step; and a warm water treated raw starch processing step.
2. 2. The method for producing processed starch according to 1 above, wherein the hot water treatment step is a step of immersing the raw material starch in water at 30 ° C. or higher and lower than the gelatinization start temperature of the raw material starch for 6 hours or more.
3. 3. The method for producing processed starch according to 1 or 2 above, wherein the hot water treatment step is performed under acidic conditions or alkaline conditions such that the starch is not hydrolyzed.
4). The method for producing a modified starch according to any one of 1 to 3 above, wherein the warm water treatment step is carried out at pH 3.0 to 5.5, or 8.0 to 12.0.
5. The manufacturing method of the processed starch of any one of said 1-4 whose warm water treatment process is a process which raises the endothermic amount of 1-3 J / g to a raw material starch.
6). 6. The method for producing a modified starch according to any one of 1 to 5 above, wherein the processing step is selected from the group consisting of etherification, esterification, crosslinking, and a combination of two or more thereof.
7). Processed starch manufactured by the method of any one of said 1-6.
8). A food containing the modified starch according to 7 above.
9. 9. The food according to 8 above, wherein the food is bread, confectionery, cereals, bars, cooked rice, or noodles.
10. 8. A feed containing the modified starch according to 7.
11. The feed according to 10 above, which is a pet food.

Processed starch obtained by warm water treatment of raw material starch and then various processing treatments shows unique starch characteristics compared to conventional processed starch that has not been subjected to warm water treatment, and uses this in the food sector Thus, a food with excellent taste and texture can be obtained. In particular, a cross-linked starch obtained using a raw starch treated with warm water exhibits starch characteristics different from those of conventional ones, and has high utility value for bakery foods and the like.
Moreover, since the swelling and gelatinization of starch granules can be suppressed by the effect of the hot water treatment, the workability at the time of producing processed starch can be improved.
Furthermore, it is possible to increase the efficiency of introducing substituents such as etherification and esterification. By using the processed starch obtained as a result for food, a more characteristic texture can be obtained.

  The raw starch used in the present invention can be derived from any natural source. The natural starch used in the present invention is found in nature. Also included in the present invention are starches derived from plants obtained by standard breeding techniques, including any other genetic engineering or chromosome engineering methods, including crossbreeding, translocation, inversion, transformation, or variations thereof. Suitable for the raw material starch used. Furthermore, starch derived from a plant grown by artificial mutation and a variation of the above-mentioned genus composition that can be produced by a known standard mutation breeding method is also used as the raw material starch used in the present invention. Is suitable. Furthermore, these starches can be selected by wet, dry, sieving, etc. and used as raw starch. As the raw material starch used in the present invention, one or more of these can be used.

  Typical sources for starch are cereals, tubers, roots, legumes and fruits. Specific examples of natural sources include corn, pea, potato, sweet potato, banana, barley, wheat, rice, sago, amaranth, tapioca, kuzukon, kanna, sorghum and their waxy or high amylose varieties. As used herein, the term “waxy” is meant to include starch containing at least about 95% by weight amylopectin, and the term “high amylose” is starch containing at least about 40% by weight amylose. Is included.

The hot water treatment in the present invention is preferably a raw material starch of 30 ° C. or higher and a gelatinization start temperature (defined by the peak start temperature at DSC (differential scanning calorimetry), and the temperature varies depending on the type of starch). The temperature is not reached, more preferably 3 to 15 ° C. lower than the gelatinization start temperature, and most preferably 5 to 10 ° C. lower than the gelatinization start temperature. For example, in the case of wheat starch, it is preferably immersed in water at 35 to 47 ° C., most preferably 40 to 45 ° C.
In the state where the starch is immersed, it may be allowed to stand, or may be stirred, shaken or the like. The immersion time is preferably 6 hours or more, more preferably 10 hours or more. The upper limit of the immersion time is not particularly limited, but is preferably 120 hours or less, more preferably 72 hours or less. When performing the hot water treatment, additives (for example, sodium dehydroacetate and ethanol) that are usually used in foods can be used for the purpose of bacteriostatic and antifungal.

In addition, the immersion solution for the hot water treatment can freely adjust the pH within a range where the starch granules do not collapse by acid hydrolysis and alkali hydrolysis, and the treatment time can be reduced by performing the hot water treatment under acidic conditions and alkaline conditions. It can be shortened significantly. Preferred pH is 2.7 to 5.5 on the acidic side and 8.0 to 12.0 on the alkaline side, more preferably 3.0 to 4.0 on the acidic side and 10.0 to 11.0 on the alkaline side. is there.
Moreover, the physical property change brought about by the hot water treatment in the present invention is confirmed by, for example, that the raw starch treated with the hot water brings about an increase in the endothermic amount of 1 to 3 J / g in the differential scanning calorimetry curve by DSC. Can do. An increase in the endothermic amount means an improvement in the strength of the crystal structure of starch, that is, an improvement in resistance to gelatinization, and there are advantages such as improvement in suitability for secondary processing and suitability for addition to foods.

Processing of the starch of the present invention includes etherification, esterification, phosphoric acid cross-linking, adipic acid cross-linking, oxidation, pregelatinization, enzyme treatment, wet heat treatment, addition of emulsifier, oil processing, and combinations of two or more thereof. A process selected from the group consisting of: Examples of processing particularly recommended in the present invention include etherification, etherified phosphoric acid crosslinking, phosphoric acid monoesterified phosphoric acid crosslinking, phosphoric acid crosslinking, and combinations of two or more thereof.
These processing methods are not limited at all, and conventional processing methods can be used. For example, for etherification, hydroxypropyl starch can be obtained by using propylene oxide as an etherifying agent and reacting with starch. For example, acetic anhydride or vinyl acetate monomer is used as an esterifying agent for esterification, and starch acetate can be obtained by reacting with starch.

  The hot water treatment of the raw material starch exhibits various effects in the production of these processed starches or in the production of foods containing the processed starch. For example, when a phosphate cross-linked starch, phosphate monoesterified phosphate cross-linked starch, or etherified phosphate cross-linked starch obtained by processing wheat starch after hot water treatment is used in the manufacture of bakery foods, the reason is clear. Although not, the quality can be significantly improved compared to the use of the conventional corresponding modified starch. Specifically, for example, when processing is applied to wheat starch that has been subjected to hot water treatment, and applied to bakery food, compared to wheat starch that has not been subjected to hot water treatment, the improvement effect of the mechanical suitability by improving the physical properties of the dough, Improve bakery aptitude by improving product quality due to significant improvement in gluten network formation. Furthermore, excellent food texture such as soft feeling can be imparted to the resulting product. On the other hand, by subjecting the raw material starch to hot water treatment, there is an effect that it becomes possible to introduce a high content of ether groups into the starch, which was not possible without treatment.

  The preferred use of the modified starch produced by the method of the present invention is breadmaking. It can also be used for confectionery, noodles, pasta, snacks, cereals, cereal bars, cooked rice, water-kneaded products, yogurt, flower paste, ice confectionery, ham / sausage, soup, seasonings and the like.

The following examples are presented to further illustrate and explain the present invention and should not be taken as limiting in any regard.
The warm water treatment described in the present example refers to a process for preparing a starch emulsion, adjusting the pH as necessary, and immersing it in warm water at 30 ° C. or higher and lower than the gelatinization start temperature to obtain a treated emulsion. The warm water treated sample refers to a sample obtained by drying the obtained treated emulsion by a conventional method (for example, in a dry oven at 30 to 50 ° C. for 10 to 24 hours).
As for the bread making test results shown in Tables 3, 8, 11, 12, 13, 16, 17, and 18, Table 1-1 shows the evaluation criteria for bread making aptitude and product quality, and Table 1-2 shows the bread volume. Table 1-3 shows the evaluation items and evaluation contents.

Table 1-1 Baking aptitude and product quality evaluation criteria

Table 1-2 Evaluation criteria for bread volume

Table 1-3 Evaluation items and evaluation contents

Example 1
About the commercially available wheat starch, after performing warm water processing, trial manufacture of etherified phosphoric acid bridge | crosslinking starch was used for the bread-making test. The procedure is shown below.
To 100 parts by weight of wheat starch, 130 parts by weight of water and 0.1 part by weight of sodium dehydroacetate (bactericidal agent) were added to prepare an emulsion (pH unadjusted), followed by warm water treatment at 45 ° C. for 72 hours with stirring. went. Next, a phosphoric acid crosslinking reaction and an etherification reaction were successively performed by a conventional method. That is, in the presence of mirabilite as a stabilizer, the pH of the emulsion was adjusted to 11-12 with caustic soda, and 0.1 parts by mass of phosphorus oxychloride as a cross-linking agent was added to 100 parts by mass of wheat starch. Then, a phosphoric acid crosslinking reaction was carried out at a reaction temperature of 40 ° C. for 1 hour, followed by an etherification reaction by a conventional method. That is, 10 parts by mass of propylene oxide was added to 100 parts by mass of wheat starch in the emulsion, and an etherification reaction was performed at a reaction temperature of 40 ° C. for 20 hours. The obtained emulsion was neutralized, washed and dried to obtain a sample No. 1 etherified phosphoric acid crosslinked starch. Further, in sample No. 1, the same reaction was performed except that the hot water treatment was not performed, and the etherified phosphoric acid crosslinked starch of sample No. 2 was obtained.
Sample No. 1 and Sample No. 2 were used as test materials, and a mountain-shaped bread was prepared according to a conventional method with the composition shown in Table 2, and the effects on bread making quality and quality were examined.

Table 2. Bread recipe
Table 3 shows the results of the bread making test.

Table 3. Bread-making test results of wheat etherified phosphate cross-linked starch

  From Table 3, the remarkable remarkable improvement effect by hot water processing was confirmed in bread making aptitude and product quality. As a specific warm water treatment effect, bread-making suitability has the effect of suppressing the water absorption of etherified phosphate cross-linked starch, thereby suppressing the drying of the dough, improving extensibility, and significantly improving the machine suitability. confirmed. In product quality, as compared with sample No. 2, an extremely remarkable increase effect in bread volume was confirmed, and a bread volume close to that when using 100% strong flour was shown. Moreover, in the texture, the crispness peculiar to etherified phosphoric acid cross-linked starch was improved, and it was soft and well melted, resulting in a natural texture.

Example 2
About commercially available wheat starch, after performing warm water processing, etherified starch was made as an experiment and manufacturing aptitude evaluation was performed. The procedure is shown below.
Using wheat starch, hot water treatment was carried out in the same manner as in Example 1, followed by etherification reaction by a conventional method. In the etherification reaction, sodium sulfate is added to the emulsion, the pH is adjusted to 11 to 12 with caustic soda, 10 parts by mass of propylene oxide is added to 100 parts by mass of wheat starch, and the reaction temperature is 40 ° C. for 20 hours. Reaction was performed. The obtained emulsion was neutralized with sulfuric acid to pH 5.5 to 6.0, washed and dried to obtain etherified starch of sample No. 3. In sample No. 3, the reaction was performed in the same manner except that the raw material starch was changed to any of waxy corn starch, tapioca starch or potato starch, and the amount of propylene oxide was changed to 10 to 18 parts by mass in the etherification reaction. The etherified starch of sample No. 4-6 was obtained. Furthermore, in sample No. 3-6, the same reaction was performed except not performing a warm water process, and the etherified starch of sample No. 7-10 was obtained.
Table 4 shows the etherified starch reaction conditions of sample Nos. 3 to 10.

Table 4. Etherified starch reaction conditions
*: Amount added to 100 parts by mass of raw starch

  About sample No. 3-10, the manufacture aptitude evaluation of etherified starch was performed by the presence or absence of gelatinization. As a criterion for gelatinization, after each sample is dried by a conventional method, the presence or absence of a place where the starch has changed from its original white color to transparent due to gelatinization is used as an index. As a result, it was evaluated that production suitability was impossible. Table 5 shows the results.

Table 5. Etherified starch production suitability evaluation results
DS: represents the number of substituents per glucose residue of starch.
From Table 5, in the etherification reaction, the production suitability improvement effect by the hot water treatment was confirmed.

Example 3
A commercially available wheat starch, waxy corn starch, tapioca starch, and potato starch were subjected to hot water treatment, and then an etherified starch was prepared and subjected to DSC analysis and bread making test. The procedure is shown below.
Using various raw material starches, a hot water treatment and an etherification reaction were conducted in the same manner as in Example 2 except that propylene oxide was changed to 8 to 15 parts by mass. 11-14 etherified starches were obtained. Moreover, in sample No. 11-14, the same reaction was performed except not performing a warm water process, and the etherified starch of sample No. 15-18 was obtained. Sample No. About 11-18, the presence or absence of gelatinization was confirmed similarly to Example 2, and it was confirmed that gelatinization did not arise in all the samples.
Moreover, about the sample Nos. 11-14, the warm water treatment sample used as a raw material of the warm water treatment sample obtained by drying a part of warm water treatment emulsion before etherification reaction by a conventional method, and sample Nos. 15-18 DSC analysis was performed using various raw material starches not subjected to the test as test materials. The DSC measurement was performed using an ultrasensitive differential scanning calorimeter 8240 manufactured by Rigaku Corporation. 300 parts by weight of water is added to 100 parts by weight of starch (anhydride) to prepare a measurement sample of about 10 mg, measured at a rate of temperature rise of 2 ° C./minute, and peak rise and return points from the obtained chart The endothermic amount was obtained from the integral value when the tie was established.
Table 6 shows the etherification reaction conditions and endothermic measurement results of Sample Nos. 11-18.

Table 6. Etherification reaction conditions and endothermic measurement results
*: Addition amount with respect to 100 parts by mass of raw material starch **: Endothermic amount of various starches before etherification reaction From Table 6, the endothermic amount of 1 to 3 J / g increases in various starches before etherification reaction by hot water treatment. Was confirmed.
Sample No. 11 and Sample No. 15 were used as test materials, and a mountain-shaped bread was prepared according to a conventional method with the composition shown in Table 7, and the influence on bread making quality and quality was examined. The results are shown in Table 8.

Table 7. Bread recipe

Table 8. Bread-making test results with a blend containing wheat etherified starch
From Table 8, the remarkable improvement effect by hot water treatment was confirmed in bread making aptitude and product quality.
As a specific hot water treatment effect, bread-making suitability improves the excessive water absorption of etherified starch, which suppresses the drying of the dough, improves the extensibility of the dough, and significantly improves the mechanical suitability. Was confirmed. In product quality, a significant increase effect was confirmed in bread volume as compared with Sample No. 15, and a bread volume close to that at the time of using 100% strong flour was shown. Moreover, in the texture, the stickiness peculiar to etherified starch was suppressed, it was soft and melted in the mouth, and it became a natural texture.
The same tendency was recognized also about sample Nos. 12-14 and sample Nos. 16-18 made experimentally with other raw material starches.
Moreover, from these bread-making test results and the results in Table 6, a correlation was confirmed between changes in physical properties due to hot water treatment indicated by an increase in the endothermic amount of 1 to 3 J / g and improvements in bread-making suitability.

Example 4
With respect to the commercially available wheat starch, a warm water-treated sample was produced under acidic conditions, subjected to DSC analysis, and the effect of pH was verified on the warm water treatment. The procedure is shown below.
Using wheat starch, adjust the pH to 2.5, 3.0, 3.5, 4.0, 4.5, 5.0, 5.5, 6.0 and change the treatment time to 24 hours A hot water treatment was performed in the same manner as in Example 1 except that.
DSC analysis was performed in the same manner as in Example 3 using the obtained warm water treated sample and wheat starch that had not been treated with warm water as a control sample, and the endothermic amount was measured. Table 9 shows the measurement results.

Table 9. Effect of pH in hot water treatment on endothermic quantity
From the results in Table 9, it was confirmed that the endothermic amount increased by 1 J / g or more in the pH 2.5 to 5.5 treated sample. In the pH 2.5 treated sample, a decrease in viscosity due to starch hydrolysis was confirmed.

Example 5
With respect to the commercially available wheat starch, a hot water-treated sample was produced under alkaline conditions, subjected to DSC analysis, and the effect of pH on the hot water treatment was verified. The procedure is shown below.
Using wheat starch, pH was adjusted to 6.0, 7.0, 8.0, 9.0, 10.0, 11.0, 12.0, and the treatment time was changed to 6 hours. The hot water treatment was performed in the same manner as in Example 1.
DSC analysis was performed in the same manner as in Example 3 using the obtained warm water treated sample and wheat starch that had not been treated with warm water as a control sample, and the endothermic amount was measured. Table 10 shows the measurement results.

Table 10. Effect of pH in hot water treatment on endothermic quantity

From the results in Table 10, it was confirmed that the endothermic amount increased by 1 J / g or more in the pH 8.0 to 12.0 treated sample. It should be noted that the endothermic amount increased in the untreated section and the pH 6.0 treated section as compared with Table 9, which is due to the difference in the degree of damage of the crystal structure of the raw material lot.

Example 6
About commercially available wheat starch, after performing warm water processing, etherified phosphoric acid bridge construction starch was made as an experiment, and it used for the bread making test, and investigated the influence of processing time about warm water processing. The procedure is shown below.
The wheat starch was used in the same manner as in Example 1 except that the pH was adjusted to 3.5 and the hot water treatment time was changed to 6, 10, and 24 hours, and the hot water treatment and the phosphoric acid crosslinking reaction and etherification reaction were performed. Etherified phosphoric acid crosslinked starches of No. 20 (warm water treatment 6 hours), No. 21 (warm water treatment 10 hours) and No. 22 (warm water treatment 24 hours) were obtained. Moreover, the same reaction was performed except not performing a warm water process, and the etherified phosphoric acid crosslinked starch of sample No. 23 was obtained.
For sample Nos. 20 to 23, a mountain-shaped bread was made according to a conventional method with the composition shown in Table 2, and the influence on bread making quality and quality was examined. Table 11 shows the results of the bread making test.

Table 11. Effect of hot water treatment time of raw starch on bread making
From Table 11, in sample No. 20-22, the improvement effect by a warm water process was confirmed. From the above results, it was confirmed that the treatment time for the hot water treatment is suitably 6 hours or more.

Example 7
After warm water treatment was performed using commercially available wheat starch, an etherified phosphate cross-linked starch was prototyped and subjected to a bread making test to examine the influence of the warm water treatment temperature. The procedure is shown below.
The hot water treatment, phosphoric acid crosslinking reaction and etherification reaction were carried out in the same manner as in Example 6 except that the treatment temperature was changed to 25 ° C, 30 ° C, 40 ° C, 47 ° C, 50 ° C and 55 ° C, and the treatment time was changed to 24 hours. Sample No. 24 (treatment temperature 25 ° C.), sample No. 25 (treatment temperature 30 ° C.), sample No. 26 (treatment temperature 40 ° C.), sample No. 27 (treatment temperature 47 ° C.), sample No. 28 An etherified phosphoric acid crosslinked starch having a treatment temperature of 50 ° C. was obtained. The gelatinization start temperature of wheat starch was 50 ° C. from the rise of the DSC peak, and gelatinization occurred during the hot water treatment in the 55 ° C. treatment section. In Sample No. 28, no clear defects such as gelatinization were confirmed during the etherification reaction, but deterioration in cleaning efficiency was confirmed in comparison with Samples No. 24-27 during cleaning. From this, it was shown that the hot water treatment at the gelatinization start temperature is inappropriate. Moreover, the same reaction was performed except not performing a warm water process, and the etherified phosphoric acid crosslinked starch of sample No. 29 was obtained.
About sample No. 24-27 and sample No. 29, the mountain-shaped bread was manufactured according to the conventional method with the mixing | blending of Table 2, and the influence on bread-making aptitude and quality was investigated. Table 12 shows the results of the bread making test.

Table 12. Influence of hot water treatment temperature
From Table 12, in sample No. 25-27, the improvement effect by a warm water process was confirmed.
From the above results, it is understood that 30 ° C. or more and less than the gelatinization start temperature are appropriate as the treatment temperature conditions for the hot water treatment.

Example 8
About commercially available wheat starch, after performing warm water processing, etherified phosphoric acid crosslinked starch was made as an experiment, and it used for the bread-making test, and verified the reaction efficiency of warm water processing on acidic conditions. The procedure is shown below.
Using wheat starch, prepare an emulsion in the same manner as in Example 1, and prepare treatment zones for pH 3.5 / 24 hour treatment, pH unadjusted / 24 hour treatment, pH unadjusted / 72 hour treatment, Warm water treatment (45 ° C. reaction with stirring) was performed. After completion of the hot water treatment, a phosphoric acid crosslinking reaction is carried out in the same manner as in Example 1, and the obtained emulsion is neutralized, washed and dried, sample No. 30 (pH 3.5 / 24 hour treatment), sample No. 31 (pH unadjusted / 24 hours treatment) and sample No. 32 (pH unadjusted / 72 hours treatment) were obtained as etherified phosphoric acid crosslinked starch.
Samples No. 30 to No. 32 were used as test materials, and a mountain-shaped bread was prepared according to a conventional method with the composition shown in Table 2, and the influence on bread making quality and quality was examined. Table 13 shows the results of the bread making test.

Table 13 Effect of hot water treatment time in acidity
From Table 13, it was shown that the effect of the hot water treatment can be obtained in a shorter time by making the pH acidic during the hot water treatment.

Example 9
Commercially available wheat starch and corn starch were treated with warm water, and then etherified phosphoric acid cross-linked starch and esterified phosphoric acid cross-linked starch were produced and subjected to DSC analysis. The procedure is shown below.
The wheat starch and corn starch were treated with warm water in the same manner as in Example 6 except that the treatment time was changed to 24 hours, and then phosphoric acid crosslinking reaction was carried out in the same manner as in Example 1. After completion of the phosphoric acid crosslinking reaction, an etherification reaction was performed on wheat starch and corn starch, or an esterification reaction was performed on wheat starch in the usual manner.
The etherification reaction was performed in the same manner as in Example 1 to obtain etherified phosphoric acid crosslinked starches of Sample Nos. 33 to 34. Moreover, the same reaction was performed except not performing a warm water process, and the etherification phosphoric acid crosslinked starch of sample No. 35-36 was obtained.
In the esterification reaction, 10 parts by mass of acetic anhydride was added dropwise to an emulsion derived from wheat starch over 100 parts by mass of wheat starch over 1 hour. During this time, the temperature was maintained at 30 ° C. and the pH was maintained at 8.0 to 8.5. After completion of dropping, the mixture was further stirred for 1 hour under the same conditions. The obtained emulsion was neutralized, washed and dried to obtain an esterified phosphoric acid crosslinked starch of sample No. 37. Moreover, the same reaction was performed except not performing a warm water process, and the esterified phosphoric acid crosslinked starch of sample No. 38 was obtained. Table 14 shows the reaction conditions for sample Nos. 33-38.

Table 14. Reaction conditions
Using sample Nos. 33 to 38 as test materials, DSC analysis was performed in the same manner as in Example 3, and the endothermic amount and peak temperature were measured. 1 to 3 show DSC charts, and Table 15 shows endothermic amounts and peak temperatures at that time.

Table 15. Change of DSC by hot water treatment
*: Difference from untreated

1-3, the remarkable change of the DSC chart by a warm water process was confirmed. From Table 15, it was shown that the endothermic amount is remarkably increased and the peak temperature is remarkably increased by performing the hot water treatment.
1-3 and Table 15 showed that even if secondary processing, such as etherification and esterification reaction, was performed, the change of the physical characteristic by a warm water process can be confirmed.

Example 10
About commercially available tapioca starch, after performing warm water processing, trial manufacture of etherified phosphoric acid crosslinked starch was used for the bread-making test. The reaction procedure is shown below.
The tapioca starch was subjected to hot water treatment, phosphoric acid crosslinking reaction, and etherification reaction in the same manner as in Example 1 except that the hot water treatment conditions were changed to pH 3.5 and treatment for 24 hours. A phosphoric acid crosslinked starch was obtained. Moreover, the same reaction was performed except not performing a warm water process, and the etherification phosphoric acid crosslinked starch of sample No. 40 was obtained.
Sample No. 39 and Sample No. 40 were used as test materials, and a mountain-shaped bread was prepared according to a conventional method with the composition shown in Table 2, and the effect on bread making quality and quality was examined. Table 16 shows the results of the bread making test.

Table 16. Breadmaking test results with a formulation containing tapioca etherified phosphate cross-linked starch

  From Table 16, the remarkable improvement effect by hot water processing was confirmed about bread-making aptitude and product quality. As a specific hot water treatment effect, bread making suitability has been confirmed by suppressing the water absorption of etherified phosphate cross-linked starch, thereby suppressing the drying of the dough, improving extensibility, and improving the machine suitability. It was. In product quality, an increase effect in the bread volume was confirmed as compared with Sample No. 40. Moreover, in the texture, the crispness peculiar to etherified phosphoric acid cross-linked starch was improved, and it was soft and well melted, resulting in a natural texture.

Example 11
About the commercially available wheat starch, after performing warm water processing, the phosphate crosslinked starch was made as an experiment and it used for the bread-making test. The procedure is shown below.
The wheat starch was treated with warm water in the same manner as in Example 10, and then subjected to a phosphoric acid crosslinking reaction by a conventional method. Phosphoric acid cross-linking reaction is performed by adding mirabilite to the emulsion, adding 7 parts by mass of sodium trimetaphosphate as a cross-linking agent to 100 parts by mass of wheat starch, adjusting the pH to 11-12 with caustic soda, Time reaction was performed. The pH was adjusted again to pH 11-12 with caustic soda 2 hours after the start of the reaction. The obtained emulsion was neutralized, washed and dried to obtain a phosphate crosslinked starch of Sample No. 41. Moreover, the same reaction was performed except not performing a warm water process, and the phosphoric acid crosslinked starch of sample No. 42 was obtained.
Sample No. 41 and Sample No. 42 were used as test materials, and a mountain-shaped bread was prepared according to a conventional method with the composition shown in Table 2, and the effect on bread making quality and quality was examined. Table 17 shows the results of the bread making test.

Table 17. Bread-making test results with a blend containing wheat phosphate cross-linked starch

  From Table 17, the improvement effect by warm water processing was confirmed about bread-making aptitude and product quality. As a specific effect of the hot water treatment, in the bread making aptitude, the flexibility of the dough was improved by the effect of the hot water treatment, and the improvement effect of the mechanical suitability was confirmed. In addition, in terms of product quality, the texture of the cross-linked starch was suppressed and the texture was soft.

Example 12
About the commercially available wheat starch, after performing a warm water process, the phosphate monoesterified phosphoric acid crosslinked starch was made as an experiment, and it used for the bread-making test. The procedure is shown below.
The wheat starch was treated with warm water in the same manner as in Example 10, and then phosphoric acid monoesterified phosphoric acid crosslinking reaction was performed. Phosphoric acid monoesterified phosphoric acid cross-linking reaction is carried out by adding mirabilite to the emulsion, adding 6.8 parts by mass of sodium trimetaphosphate and 0.2 parts by mass of sodium tripolyphosphate to 100 parts by mass of wheat starch, and then using caustic soda. The pH was adjusted to 11-12 and the reaction was carried out at 45 ° C. for 17 hours. The pH was adjusted again to pH 11-12 with caustic soda 2 hours after the start of the reaction. The obtained emulsion was neutralized, washed and dried to obtain a phosphoric acid monoesterified phosphoric acid crosslinked starch of Sample No. 43. Moreover, the same reaction was performed except not performing a warm water process, and the phosphoric acid monoesterified phosphoric acid crosslinked starch of sample No. 44 was obtained.
Sample No. 43 and Sample No. 44 were used as test materials, and a mountain-shaped bread was prepared according to a conventional method with the composition shown in Table 2, and the influence on bread making quality and quality was examined. Table 18 shows the results of the bread making test.

Table 18. Breadmaking test results of wheat phosphate monoesterified phosphate cross-linked starch
From Table 18, the improvement effect by warm water processing was confirmed about bread-making aptitude and product quality. As a specific effect of the hot water treatment, in the bread making aptitude, the flexibility of the dough was improved by the effect of the hot water treatment, and the improvement effect of the mechanical suitability was confirmed. In addition, in terms of product quality, the texture of the cross-linked starch was suppressed and the texture was soft.

Example 13
About commercially available tapioca starch, after performing a warm water process, etherified starch was made as an experiment and it used for the bread-making test. The procedure is shown below. Tapioca starch was subjected to a hot water treatment and an etherification reaction in the same manner as in Sample No. 5, and an etherified starch of Sample No. 45 was obtained. The degree of substitution (DS) of the obtained etherified starch was 0.18. Further, in sample No. 5, the same reaction except that the hot water treatment was not performed and propylene oxide was changed to 7 parts by mass (when 10 parts by mass of propylene oxide was used, gelatinization was performed as described in Table 5). The etherified starch of sample No. 46 was obtained. The obtained etherified starch had a DS of 0.09.
For sample No. 45 and sample No. 46, a chevron raisins bread was manufactured according to a conventional method with the composition shown in Table 19. Further, a control example was made in the same manner except that no starch was added.

Table 19. Raisin bread prescription

About the sample raisin bread, the toast and the range-up process were performed about the sample which passed 1 day and 4 days after baking, respectively, and the quality maintenance effect was evaluated about food texture. The toast was 1000 W · 1 minute, and the range was increased by 4 pieces of bread (about 200 g) at 500 W · 30 seconds. Table 20-1 shows the evaluation results of the quality maintenance effect, Table 20-2 shows the evaluation criteria, and Table 20-3 shows the evaluation items and evaluation contents.

Table 20-1 Evaluation results of quality retention effects

Table 20-2 Evaluation criteria

Table 20-3 Evaluation items and evaluation contents

  In the sample one day after the trial production, no difference was confirmed. In the sample 4 days after the trial production, as shown in Table 20, it was shown that Sample No. 45 has a higher quality retention effect than Sample No. 46. From this, it is possible to produce a product in which the processing characteristics of the processed starch are remarkably improved due to the effect of improving the introduction efficiency of the substituent by performing the hot water treatment as a pretreatment for the processing reaction of the starch. Indicated.

Example 14
For sample No. 45 and sample No. 46 prototyped in Example 13, starch crackers were prototyped by the following method.
100 parts by mass of water was added to 200 parts by mass of each sample and mixed well to prepare a dough, and this dough was baked at 185 ° C. for 1 minute 30 seconds in a rice cracker hand-baked machine manufactured by Chubu Kyoritsu Kogyo Co., Ltd.
Physical properties of the prototype starch crackers were evaluated. FIG. 4 shows a comparative photograph of the degree of expansion of starch crackers, Table 21-1 shows physical property evaluation results, Table 21-2 shows evaluation criteria, and Table 21-3 shows evaluation items and evaluation contents.

Table 21-1 Physical property evaluation results of starch crackers

Table 21-2 Evaluation criteria

Table 21-3 Evaluation items and evaluation contents

  From Table 21, it was found that Sample No. 45 has higher swelling property than Sample No. 46, and is softer in texture and mouthfeel of the product. From this, it is possible to produce a product in which the processing characteristics of the processed starch are remarkably improved due to the effect of improving the introduction efficiency of the substituent by performing the hot water treatment as a pretreatment for the processing reaction of the starch. Indicated.

Example 15
Sample No. 4 was used as a test material, and a soybean bar was manufactured by the all-in-mix method with the composition shown in Table 22.
Table 22. Soy bar formula

Example 16
About sample No. 45 and sample No. 46 which were made as an experiment in Example 13, the rice bran-like red rice was made using the rice bran by the following method.
Wash the red beans, add 2 times the amount of red beans and boil. After boiling, discard the broth, add 7 times the amount of red beans and simmer for about 20 minutes, then divide into boiled red beans and broth. It was. 100 parts by weight of polished rice were washed, immersed in water for 60 minutes, and three samples were drained. These samples were steamed in Seiro for 15 minutes to form incompletely steamed rice. These incompletely steamed rice was immersed in 100 parts by mass of the broth for about 20 minutes to completely absorb the broth. Samples No. 45 and No. 46 were added to these incompletely steamed rice that had absorbed the broth, and 15 parts by weight and 20% by weight of red beans (20 parts by weight of red beans) were added and dispersed. Then, steamed for 40 minutes to prepare red rice. In the control example, red rice was made in the same manner except that starch was not added.
A sensory test was performed on the obtained sample. Table 23-1 shows sensory test results, Table 23-2 shows evaluation criteria, and Table 23-3 shows evaluation items and evaluation contents.

Table 23-1 Sensory test results of glutinous rice-like red rice using glutinous rice

Table 23-2 Evaluation criteria

Table 23-3 Evaluation items and evaluation contents

  From Table 23, it was shown that the sample No. 45 has a remarkable quality improvement effect than the sample No. 46. From this, it is possible to produce a product in which the processing characteristics of the processed starch are remarkably improved due to the effect of improving the introduction efficiency of the substituent by performing the hot water treatment as a pretreatment for the processing reaction of the starch. Indicated.

Example 17
About the sample No. 45 made as an experiment in Example 13, the red rice was made as an experiment by the following method using the sticky rice. 100 parts by weight of polished rice were washed, immersed in water for 30 minutes, and two samples were drained. These samples were steamed in Seiro for 15 minutes to form incompletely steamed rice. These imperfect steamed rice was immersed for about 20 minutes in 100 parts by mass of red bean broth prepared in the same manner as in Example 16 to completely absorb the broth. To these incompletely steamed rice that has absorbed the broth, add 5 parts by weight of sample No. 45 and boiled red beans (20 parts by weight of red beans), disperse and mix, then return to Sero and steam for 20 minutes. Red rice was prepared. In the control example, red rice was made in the same manner except that starch was not added.
The sensory test was performed about the texture (hardness) of the obtained sample. Table 24-1 shows the results of the sensory test, and Table 24-2 shows the evaluation criteria.

Table 24-1 Sensory test results of red rice using glutinous rice

Table 24-2 Evaluation criteria

  From Table 24, it was shown that the effect of shortening the steaming time can be obtained by adding Sample No. 45.

Example 18
For Sample No. 45 and Sample No. 46 prototyped in Example 13, noodles were prototyped according to the conventional method with the formulation in Table 25.

Table 25. Noodle prescription

Example 19
Sample No. 41 prototyped in Example 11 was mixed with 180 parts by weight and 20 parts by weight of wheat flour, melted well with 100 parts by weight of hot water, 10 parts by weight of mutton and 40 parts by weight of banana were added and further mixed. 4 parts by mass of carbonic acid and 4 parts by mass of baking powder were added to the dough, and a waffle for pets was molded with a baked food production machine capable of making baked potatoes and the like.

In Example 9 (wheat etherified phosphate cross-linked starch), sample No. 33 (with hot water treatment) (lower side) and It is a chart when DSC analysis is performed using 35 (no hot water treatment) (upper side). Horizontal axis: temperature / ° C., vertical axis: heat flow / milliwatt. In Example 9 (corn starch etherified phosphoric acid crosslinked starch), sample No. 34 (with hot water treatment) (lower side) and It is a chart when DSC analysis is performed using 36 (no hot water treatment) (upper side). Horizontal axis: temperature / ° C., vertical axis: heat flow / milliwatt. In Example 9 (wheat esterified phosphate cross-linked starch), sample No. 37 (with hot water treatment) (lower side) and It is a chart when performing DSC analysis using 38 (no hot water treatment) (upper side). Horizontal axis: temperature / ° C., vertical axis: heat flow / milliwatt. It is the photograph which compared the swelling property of the starch cracker made as an experiment using sample No. 45 (with warm water treatment) (outside) and sample No. 46 (without warm water treatment) (inside) in Example 14.

Claims (11)

  A method for producing processed starch, comprising: a raw water starch warm water treatment step; and a warm water treated raw starch processing step.   The method for producing processed starch according to claim 1, wherein the warm water treatment step is a step of immersing the raw material starch in water at 30 ° C or higher and lower than the gelatinization start temperature of the raw material starch for 6 hours or more.   The method for producing processed starch according to claim 1 or 2, wherein the hot water treatment step is performed under acidic conditions or alkaline conditions such that the starch is not hydrolyzed.   The method for producing a modified starch according to any one of claims 1 to 3, wherein the warm water treatment step is performed at a pH of 3.0 to 5.5, or 8.0 to 12.0.   The manufacturing method of the processed starch of any one of Claims 1-4 whose warm water treatment process is a process which raises the endothermic amount of 1-3 J / g to a raw material starch.   The method for producing a modified starch according to any one of claims 1 to 5, wherein the processing step is selected from the group consisting of etherification, esterification, crosslinking and a combination of two or more thereof.   Processed starch manufactured with the method of any one of Claims 1-6.   A food containing the modified starch according to claim 7.   The food according to claim 8, wherein the food is bread, confectionery, cereals, bars, cooked rice, or noodles.   A feed containing the modified starch according to claim 7.   The feed according to claim 10, which is a pet food.