Method for producing GABA mochi barley containing GABA and product thereof

Abstract

A technique for highly efficient production of -amino butyric acid (GABA) using mochi barley of the group of mules barley, as a raw material. The technique converts glutamic acid into GABA due to the glutamate decarboxylase contained in the mochi barley so GABA-mochi barley grains and GABA-mochi barley bran and GABA-containing bran supernatant can be produced highly-efficiently by mixing mochi barley grains, which have been polished in a barley milling device to an extent of 2% or more and less than 20%, with a glutamic acid solution, which has a concentration of 0.1 to 3% and a pH value of 2 to 9, and soaking the barley in the solution at room temperature for 1 hour or more to overnight or, after soaking in the solution similarly for 1 hour or more to overnight, draining the barley grains, and keeping it overnight at room temperature.

Claims

1. A method for producing mochi barley containing -amino butyric acid (GABA) comprising polishing mochi barley to an extent of 3% or more and less than 20%, and soaking the mochi barley that was polished in a glutamic acid solution, wherein the mochi barley belong to the group of mules barley.

2. The method for producing mochi barley containing -amino butyric acid (GABA) according to claim 1, wherein the polishing is performed by a barley milling device that removes an outer layer of a surface of unpolished barley.

3. The method for producing mochi barley containing -amino butyric acid (GABA) according to claim 1, wherein sodium glutamate or glutamic acid is used in the glutamic acid solution for soaking the mochi barley.

4. The method for producing mochi barley containing -amino butyric acid (GABA) according to claim 3, wherein the glutamic acid solution is a solution having concentration of 0.1% to 3% and a pH of 3 to 9.

5. The method for producing mochi barley containing -amino butyric acid (GABA) according to claim 1, wherein the soaking occurs for at least one hour at room temperature with a ratio of 2 kgs of mochi barley per 6 liters of the glutamic acid solution.

6. The method for producing mochi barley containing -amino butyric acid (GABA) according to claim 5, wherein after the soaking occurs, the mochi barley is drained and kept at room temperature.

7. The method for producing mochi barley containing -amino butyric acid (GABA) according to claim 1, wherein the mochi barley is polished to an extent of 5% or more and less than 16%.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 illustrates a process flow chart for producing GABA mochi barley, in which a method of performing the process for producing a GABA mochi barley product from unpolished barley is presented (Example 1).

(2) FIG. 2 is a graph illustrating the content of GABA produced in 100 g of mochi barley, as for the cases where pyridoxine (PN vitamin B6) is contained in glutamic acid solution and for the cases where pyridoxine (PN vitamin B6) is not contained in glutamic acid solution (Example 1).

(3) FIG. 3 is a graph illustrating the content of GABA produced at various pH of glutamic acid solution in 100 g of unpolished or polished mochi barley (Example 1).

(4) FIG. 4 is a graph illustrating the content of GABA at various degree of polishing of mochi barley in the horizontal axis, i.e., from unpolished barley to polished barley with 30% degree of polishing (Example 1).

(5) FIG. 5 is a graph illustrating the content of GABA produced in 100 g of dried grains in the solution which contains various concentration of glutamic acid in the horizontal axis (Example 1).

(6) FIG. 6 is a graph illustrating the content of GABA produced in 100 g at various pH of prepared glutamic acid solution in the horizontal axis (Example 1).

(7) FIG. 7 is a graph illustrating the content of GABA produced in 100 g for various time for soaking mochi barley in glutamic acid solution in the horizontal axis (Example 1).

(8) FIG. 8 is a drawing which demonstrates that GABA at the content of 30% is produced in an experimentation for barley bran left by polishing mochi barley to an extent of 20 to 25%, in which the mochi barley bran and a glutamic acid solution are mixed with each other and kept overnight (Example 2).

DETAILED DESCRIPTION OF THE INVENTION

(9) According to the present invention, to produce mochi barley grains and mochi barley bran, each containing GABA at a high content, and GABA-containing bran supernatant, a method for conversion into GABA in barley grains and barley bran by adding L-glutamic acid as a raw material of GABA and by keeping them at room temperature of about 25 C. is employed. According to the method, a GABA-enriched mochi barley products, such as a GABA-enriched polished mochi barley grains, a GABA-enriched mochi barley bran product, and GABA-containing mochi barley bran supernatant are obtained.

Example 1

(10) FIG. 1 relates to one embodiment of a process for the method for highly-effective production of a GABA mochi barley grains and a GABA mochi barley product from unpolished barley according to the present invention.

(11) With reference to the given numerals, 50 g of grain crops like mules barley and mochi barley 1 were polished with a rice milling device to give polished barley 2, and at step #4 which was then soaked overnight in 100 ml of L-glutamic acid solution at pH of from 3 to 5 at room temperature, and at step #5 which was drained off, and at step #6 which was further kept overnight at the temperature in a state where it is still somewhat wet.

(12) At Step #7, the incubated barley grains which have been treated with glutamic acid were dried for 3 hours at 65 C.

(13) Sample 8 of the dried barley grains was ground with a bean mill.

(14) To the ground Sample 3, 30 ml of 2% (W/V) of sulfosalicylic acid was added and shaken vigorously for 10 minutes.

(15) After centrifugal separation (1000g, for 10 min), the supernatant was recovered as a sample for GABA analysis.

(16) The GABA amount in a sample for GABA analysis was quantified by an apparatus for amino acid analysis (HPLC method).

(17) Result of the GABA content obtained by measurement of the sample of the previous paragraph 0011 is illustrated in FIG. 2.

(18) According to the result of the previous paragraph 0017, GABA was produced in mochi barley at almost the same level for the case where pyridoxine (vitamin B6) is added and the case where no pyridoxine is added. Glutamic acid as a raw material was almost disappeared.

(19) The mochi barley related to the results of the previous paragraphs 0017 and 0018 was mochi barley kernels that were obtained by removing an outer layer of surface to a certain extent with a barley milling devise. Herein below, polished mochi barley is referred to as polished barley, and a remaining outer layer of surface of mochi barley is referred to as mochi barley bran, specifically.

(20) It was then determined whether the high production of GABA in mochi barley is caused by polishing. As a sample, unpolished or polished mochi barley grains were soaked in a glutamic acid solution adjusted to pH 4 or pH 5 in the presence or absence of pyridoxine (vitamin B6), and treated according to the descriptions of the previous paragraphs 0011 and 0012.

(21) Analysis results of the sample of the previous paragraph 0020 are illustrated in FIG. 3. Regardless of the presence or absence of pyridoxine, a high amount of GABA was produced in the polished mochi barley at pH 4. On the other hand, little GABA was produced in the unpolished mochi barley even after the same treatment, and the glutamic acid as a raw material was collected.

(22) As indicated in the previous paragraphs 0020 and 0021, it was found that the polishing treatment is essential for GABA production in mochi barley. Accordingly, the procedure of the previous paragraphs 0011 and 0012 was carried out for unpolished barley and barley samples that were polished to an extent of 2% to 30% of degree of polishing.

(23) Analysis results of the samples of the previous paragraph 0022 are illustrated in FIG. 4. Favorable GABA production was observed at the degree of polishing between 5% and 16%.

(24) Then, it was further determined which concentration (%) of a glutamic solution for soaking is effective to produce favorable GABA production for polishing-treated mochi barley. Polished mochi barley was soaked in a 0% to 3% sodium glutamate solution which has been adjusted to pH 4.

(25) Analysis results of the sample of the previous paragraph 0024 are illustrated in FIG. 5. Favorable GABA production was confirmed for the concentration of between 0.1% and 3%.

(26) As illustrated in the process for producing GABA mochi barley (i.e., FIG. 1), grains of polished mochi barley were initially subjected to a heating treatment at 65 C. to 70 C. for about three hours or so for the experiments described above. The results of the treatment are then examined.

(27) GABA production amount was measured for the sample with and without the heating treatment. As a result, almost no difference is recognized between them. Meanwhile, it is expected that sterilization is achieved by drying polished mochi barley sample by heating-treatment at 65 C. to 70 C. for about three hours, which is an effective preservation method from the view point of food hygiene.

(28) As illustrated in FIG. 5, based on the results of analyzing GABA content of GABA mochi barley given above including that mochi barley containing GABA at high concentration can be obtained by soaking polished mochi barley in a glutamic acid solution with concentration of from 0.1% to 3%, it was determined which pH range of a glutamic acid solution is expected to give favorable GABA production.

(29) Analysis results of the sample of the previous paragraph 0028 are illustrated in FIG. 6. Favorable GABA production was obtained by adjusting a glutamic acid solution to pH 3 to 9.

(30) Next, an investigation was made as to the time for soaking polished mochi barley in a glutamic acid solution. Soaking in a glutamic acid solution was carried out for 1 hour or more to overnight (about 15 hours). After draining, the polished mochi barley grains were kept overnight at room temperature (25 C.)

(31) Analysis results of the sample of the previous paragraph 0030 are illustrated in FIG. 7. Favorable GABA production was observed when soaking in a glutamic acid solution was carried out for 1 hour or more to overnight.

(32) In the experiment of the previous paragraph 0030, the polished mochi barley grains after draining were further kept overnight (about 15 hours) at room temperature. When it was soaked overnight in a glutamic acid solution, GABA was produced in accordance with the degree of polishing as illustrated in FIG. 4. Almost the same level of GABA production was observed even when incubation after draining was skipped.

Example 2

(33) Explanations are given for FIG. 8 with reference to the numerals. When mochi barley bran and a glutamic acid solution (#12) are mixed with each other (Step #9) and kept overnight (about 15 hours), 30% GABA production (#11) was observed for the mochi barley bran and bran supernatant (i.e., supernatant after centrifugal separation). Centrifugal separation treatment (1000g, for 10 min, Step #10)) was carried out. As a result, the supernatant (solution) and bran (precipitates) were obtained (#10). Processes and results of the experiment are illustrated in FIG. 8. After mochi barley was polished to 20 to 25% with a barley milling device, a GABA mochi barley bran product can be produced by using the remaining bran as a raw material. Further, the supernatant obtained after the centrifugal treatment can be used as GABA-containing mochi barley bran supernatant. Drying GABA mochi barley bran by heat treatment for about 3 hours at 65 C. to 70 C., which achieves sterilization, is an effective preservation method.

(34) According to the production method given in the Examples 1 and 2, GABA mochi barley and GABA mochi barley bran, each containing GABA, and GABA-containing bran supernatant are produced from unpolished mochi barley, and therefore unpolished mochi barley can fully be utilized as a food material without wasting any of it.

INDUSTRIAL APPLICABILITY

(35) A GABA-containing food material produced by a production method according to the present invention can be applied to various food materials by grinding and then adding the GABA-containing mochi barley product to other food material, during a process for producing noodles including Japanese noodles or pasta, by cooking steamed rice in which GABA mochi barley grains are mixed, by producing a food product using GABA barley bran supernatant, or by adding it into other food products, for example.

REFERENCE NUMERALS

(36) 1 MOCHI BARLEY 2 MILLING 3 L-GLUTAMIC ACID 4 SOAKING 5 DRAINING 6 KEEPING TEMPERATURE 7 DRYING 8 SAMPLE 9 MIXING MOCHI BARLEY BRAN AND GLUTAMIC ACID SOLUTION 10 KEEPING OVERNIGHT (ABOUT 15 HOURS) 11 GABA PRODUCTION FIG. 1 1 MOCHI BARLEY 2 MILLING (IF NECESSARY, HEATING (70 C., FOR 3 HOURS)) pH Co-factor (Co-enzyme) pH ADJUSTMENT 3 0.5% L-Glu SOLUTION (100 mL, IN PLASTIC BAG) 1% L-Glu SOLUTION (6 L, IN TANK) 4 SOAKING (25 C., TIME REQUIRED FOR SOAKING OR MORE TO OVERNIGHT) 5 DRAINING 6 KEEPING (25 C., 0 HOUR OR MORE TO OVERNIGHT) (IF NECESSARY, STEAMING (30 MINUTES)) 7 DRYING (65 TO 80 C., 5 HOURS) PRODUCT 8 10 g SAMPLE MILL EXTRACTING WITH 2% SULFOSLAICYLIC ACID solution OR 70% ETHANOL AMINO ACID ANALYSIS FIG. 2 WITHOUT Co-factor (or co-enzyme) PN: PYRIDOXINE (VITAMIN B6) CONTENT OF L-Glu AND GABA (mg/100 g) BARNYAR MILLET () BARNYAR MILLET (PN) PANICUM MILIACEUM () PANICUM MILIACEUM (PN) MOCHI BARLEY () MOCHI BARLEY (PN) FIG. 3 : WITHOUT Co-factor (or co-enzyme) PN: PYRIDOXINE (VITAMIN B6) CONTENT OF L-Glu or GABA (mg/100 g) UNPOLISHED BARLEY POLISHED BARLEY FIG. 4 CONTENT OF GABA (mg/100 g) UNPOLISHED BARLEY DEGREE OF POLISHING (%) FIG. 5 CONTENT OF L-Glu (mg/100 g) CONTENT OF GABA (mg/100 g) L-Glu CONCENTRATION (%) FIG. 6 CONTENT OF L-Glu (mg/100 g) CONTENT OF GABA (mg/100 g) FIG. 7 CONTENT OF GABA (mg/100 g) 1 HOUR 2 HOURS 6 HOURS OVERNIGHT TIME FOR SOAKING IN L-Glu SOLUTION FIG. 8 BRAN (25 g) L-Glu SOLUTION (1%, 100 ml) 25 C., OVERNIGHT SOLUTION (90 ml) Precipitate (25 g)