WO2018062474A1 - Method for improving drinkability of drinking water to which reduced indigestible dextrin has been added, drinking water to which reduced indigestible dextrin has been added in which drinkability is improved by said method, drinking water for inhibiting fat absorption containing reduced indigestible dextrin, and method for inhibiting dietetic fat absorption - Google Patents

Abstract

Drinking water containing reduced indigestible dextrin, wherein the drinking water has a hardness of 10-110.

Description

Method for improving the ease of drinking of drinking water containing reduced indigestible dextrin, drinking water containing reduced indigestible dextrin with improved ease of drinking by the method, suppression of fat absorption including reduced indigestible dextrin Drinking water and method for inhibiting dietary fat absorption

The present invention relates to a method for improving the ease of drinking of drinking water blended with reduced indigestible dextrin, a drinking water blended with reduced indigestible dextrin with improved ease of drinking by the method, The present invention relates to a fat absorption suppressing drinking water and a method for suppressing dietary fat absorption.

Indigestible dextrin has been used in various foods in recent years because it has an intestinal regulating effect, a postprandial blood glucose level increase inhibitory effect, a postprandial blood neutral fat level increase suppressive effect, and the like. However, indigestible dextrins are pale yellow and are difficult to formulate into colorless or pale foods.
On the other hand, the reduced indigestible dextrin produced by adding hydrogen to the indigestible dextrin is non-brown and is expected to be used for colorless or light-colored foods. As an example, it has been studied to impart functionality by adding a reduced indigestible dextrin to water (see, for example, Patent Document 1).

However, when a reduced resistant digestible dextrin is blended in drinking water, the taste derived from the reduced resistant digestible dextrin is imparted to the drinking water, which makes it difficult to drink.

JP 2005-287454 A

An object of the present invention is to improve the ease of drinking of drinking water containing reduced indigestible dextrin.

As a result of studying in view of the above problems, the present inventors reduced the taste derived from reduced indigestible dextrin by adjusting the hardness of drinking water containing reduced indigestible dextrin, and made it easier to drink. It was found that it can be improved.

Furthermore, the present inventors have also found that when drinking water containing reduced indigestible dextrin is ingested, the effect of suppressing the increase in postprandial blood neutral fat level can be obtained. At present, verification of the effect of reducing the postprandial blood neutral fat level by reducing indigestible dextrin has not been conducted.

ADVANTAGE OF THE INVENTION According to this invention, the drinking water etc. which mix | blended the reduction indigestible dextrin improved the following ease of drinking can be provided.
1. A drinking water comprising a reduced indigestible dextrin having a hardness of 10 to 110.
2. 2. The drinking water according to 1, wherein the weight ratio of calcium to magnesium (Ca / Mg) in the drinking water is 1-8.
3. 3. The drinking water according to 1 or 2, wherein the reduced resistant digestible dextrin in the drinking water is 1 to 16 g per 500 g of drinking water.
4). The drinking water according to any one of 1 to 3, which is colorless and transparent.
5). 5. Drinking water according to any one of 1 to 4, comprising natural water.
6). A method of improving the ease of drinking drinking water containing reduced indigestible dextrin,
Adjusting the hardness of the drinking water.
7). The method according to 6, wherein the hardness of the drinking water is adjusted to 10 to 110.
8). The method according to 7, wherein the weight ratio of calcium to magnesium (Ca / Mg) in the drinking water is 1-8.
9. The method according to any one of 6 to 8, wherein the hardness of the drinking water is adjusted by adding at least one of a magnesium salt and a calcium salt.
10. The method according to any one of 6 to 9, wherein the hardness of the drinking water is adjusted by blending a plurality of types of water having different hardnesses.
11. The method according to any one of 6 to 10, wherein a dose of the reduced resistant digestible dextrin in the drinking water is 1 to 16 g per 500 g of drinking water.
12 Drinking water for fat absorption suppression containing reduced indigestible dextrin.
13. 12. The drinking water for inhibiting fat absorption according to 12, wherein the drinking water has a hardness of 10 to 110.
14 The drinking water for fat absorption inhibition according to 13, wherein the weight ratio of calcium to magnesium (Ca / Mg) in the drinking water is 1 to 8.
15. The drinking water for suppressing fat absorption according to any one of 12 to 14, wherein a dose of the reduced resistant digestible dextrin in the drinking water is 1 to 16 g per 500 g of drinking water.
16. The drinking water according to any one of 12 to 15, which is colorless and transparent.
17. A method for suppressing dietary fat absorption,
The said method including ingesting 555 mL of the drinking water for fat absorption suppression containing 5 g of reduced indigestible dextrins with a meal once a day.

According to the present invention, it is possible to provide drinking water blended with reduced indigestible dextrin with improved ease of drinking. Moreover, according to this invention, the drinking water for fat absorption suppression containing a reduced indigestible dextrin can be provided.

FIG. 1 is a graph showing the change over time in blood neutral fat level in Example 2. FIG. FIG. 2 is a diagram showing the area under the blood concentration curve (AUC) of blood triglyceride value in Example 2. FIG. 3 is a graph showing the amount of change in blood triglyceride value (Δblood triglyceride value) in Example 2. FIG. 4 is a view showing the area (AUC) under the blood concentration curve of the amount of change in blood triglyceride value (Δblood triglyceride value) in Example 2.

[Method for improving ease of drinking drinking water containing reduced indigestible dextrin]
The method for improving the ease of drinking of the drinking water blended with the reduced resistant digestible dextrin of the present invention includes adjusting the hardness of the drinking water blended with the reduced resistant digestible dextrin.

According to the present invention, in drinking water containing reduced indigestible dextrin, the taste derived from reduced indigestible dextrin (see Test Example 1 described later) can be reduced, and the ease of drinking is improved. Can do.

In the present invention, the “reducible indigestible dextrin” is an indigestible dextrin obtained by enzymatic digestion of roasted dextrin and then hydrogenation to reduce the carbonyl group at the reducing end. Specific examples of such reduced indigestible dextrin include powder type Fiber Sol 2H (trade name) sold by Matsutani Chemical Industry Co., Ltd.

In the present invention, “hardness” is a value obtained by converting the concentration of calcium salt and magnesium salt in water (total hardness) into the concentration of calcium carbonate in units of “mg / L”. 1).

[CaCO ₃ ] (mg / L) = [Calcium ion] (mg / L) × 2.5 + [Magnesium ion] (mg / L) × 4.1 (1)

In the method of the present invention, it is preferable to adjust the hardness of drinking water to 10 to 110.

In the method of the present invention, the water constituting the drinking water is not particularly limited. For example, natural water, tap water, pure water, ultrapure water, RO water (water treated using a reverse osmosis membrane (RO membrane)) Etc., and two or more of these may be mixed as appropriate.
In the present invention, in order to adjust the hardness, water having a specific hardness (water may be one kind or a mixture of two or more kinds) may be any one approved as a food additive. At least one of a calcium salt and a magnesium salt may be added, or a plurality of types of water having different hardnesses may be blended.
In the present invention, when the hardness of the water constituting the drinking water (water may be one kind or a mixture of two or more kinds) is already within the range of 10 to 110, it is anew. There is no need to adjust the hardness.

In the method of the present invention, the weight ratio of calcium to magnesium in the drinking water (Ca / Mg) is preferably 1-8.

The dose of the reduced resistant digestible dextrin in the drinking water is not particularly limited and can be appropriately determined. For example, it is 1 to 16 g per 500 g of drinking water.

The drinking water is preferably colorless and transparent. In this invention, colorless and transparent drinking water can be provided by mix | blending not a non-digestible dextrin but a non-brown-modified reduced resistant digestible dextrin.
The drinking water may be light in color.

[Drinking water containing reduced indigestible dextrin]
The drinking water containing the reduced indigestible dextrin of the present invention has a hardness of 10 to 110.
The drinking water containing the reduced indigestible dextrin of the present invention has a hardness in a specific range of 10 to 110, so that the taste derived from the reduced indigestible dextrin is reduced and the ease of drinking is improved. is there.

Further, the drinking water containing the reduced indigestible dextrin of the present invention preferably has a weight ratio (Ca / Mg) of calcium to magnesium in the drinking water of 1 to 8.

The dose of the reduced resistant digestible dextrin in the drinking water is not particularly limited and can be appropriately determined. For example, it is 1 to 16 g per 500 g of drinking water.

The drinking water of the present invention is preferably colorless and transparent. In the present invention, colorless and transparent drinking water can be provided by including non-brown-modified reduced resistant digestible dextrin instead of resistant digestible dextrin.
The drinking water may be light in color.

The other characteristics of the drinking water containing the reduced resistant digestible dextrin of the present invention are as described for the method for improving the ease of drinking drinking water containing the reduced resistant digestible dextrin of the present invention described above. .

[Drinking water for reducing fat absorption containing reduced indigestible dextrin]
The drinking water for inhibiting fat absorption according to the present invention is characterized by containing a reduced indigestible dextrin.
The drinking water for suppressing fat absorption according to the present invention has an effect of suppressing fat absorption, and can particularly suppress an increase in blood neutral fat level due to dietary fat.

By including the reduced indigestible dextrin in the drinking water, there is a problem that the taste derived from the reduced indigestible dextrin is imparted to the drinking water and it becomes difficult to drink, but the reduced indigestible dextrin of the present invention described above is used. Such a problem can be solved by applying a method for improving the ease of drinking the blended drinking water.

The drinking water for suppressing fat absorption according to the present invention preferably has a drinking water hardness of 10 to 110 from the viewpoint of improving ease of drinking. The weight ratio of calcium to magnesium (Ca / Mg) in the drinking water is preferably 1-8.

In the drinking water for suppressing fat absorption of the present invention, the dose of the reduced resistant digestible dextrin in the drinking water is not particularly limited and can be determined as appropriate, and is, for example, 1 to 16 g per 500 g of drinking water.

The drinking water of the present invention is preferably colorless and transparent. In the present invention, colorless and transparent drinking water can be provided by including non-brown-modified reduced resistant digestible dextrin instead of resistant digestible dextrin.
The drinking water may be light in color.

The intake amount and frequency of intake of drinking water for fat absorption suppression of the present invention are not particularly limited, and any amount can be ingested at any frequency. For example, 555 mL of drinking water containing 5 g of reduced indigestible dextrin can be taken with a meal once a day. In addition, for example, 555 mL of drinking water containing 5 g of reduced indigestible dextrin can be ingested together with meals for the number of meals per day.

In addition, it is considered that the drinking water for inhibiting fat absorption according to the present invention is useful for prevention of postprandial hyperlipidemia and lifestyle-related diseases and arteriosclerotic diseases.

[Method for suppressing dietary fat absorption]
The method for suppressing dietary fat absorption of the present invention comprises ingesting 555 mL of fat absorption-suppressing water containing 5 g of reduced resistant digestible dextrin once daily with a meal. To do.
According to the method of the present invention, absorption of dietary fat can be suppressed. Moreover, by this, by suppressing fat absorption, it is possible to suppress an increase in blood neutral fat level due to dietary fat.

Hereinafter, the present invention will be described more specifically with reference to examples. However, the scope of the present invention is not limited to the description of these examples.

Test example 1
About the drinking water which mix | blended the reduced indigestible dextrin with water, the ease of drinking was sensory-evaluated.
Specifically, as a test beverage, 500 g of drinking water adjusted to contain 2 g, 5 g, 10 g, and 15 g of reduced indigestible dextrin (trade name: Fiber Sol 2H, manufactured by Matsutani Chemical Industry Co., Ltd.) and a control, respectively. About the drinking water which does not mix | blend a reduced indigestible dextrin as a drink, according to the scale of Table 4 mentioned later by 7 expert panels, the strength of the taste of a reduced indigestible dextrin and ease of drinking were evaluated. As the water constituting the test beverage and the control beverage, RO water treated with a reverse osmosis membrane (RO membrane) was used.

Further, the concentrations of calcium ions and magnesium ions contained in the test beverage and the control beverage were analyzed by ICP-AES, and the hardness was calculated according to the formula (1) from the concentrations of calcium ions and magnesium ions. The results are shown in Table 1.

As shown in Table 1, the drinking water (test beverage) formulated with reduced indigestible dextrin has a reduced indigestible dextrin taste compared to drinking water (control beverage) that does not contain reduced indigestible dextrin. It was felt strong and difficult to drink.

Example 1
Various drinking waters containing reduced indigestible dextrin were prepared, sensory evaluation was performed on these drinking waters, and the influences of minerals (calcium ions, magnesium ions) and hardness contained in the drinking water were evaluated.

The drinking water to be evaluated is the ultrapure water obtained by mixing the natural water shown in Table 2 with the formulation shown in Table 3 and containing natural minerals and the Milli Q water production device (Merck Millipore). Minerals (calcium gluconate (C ₁₂ H ₂₂ CaO ₁₄ ), magnesium sulfate (MgSO ₄ )) were added to water to prepare drinking water with a predetermined dose of reduced indigestible dextrin (trade name: Fiber Sol). 2H, manufactured by Matsutani Chemical Industry Co., Ltd.). The dose of reduced resistant digestive dextrin was 2 g / 500 g, 5 g / 500 g, and 15 g / 500 g with respect to 500 g of drinking water.
The control drinking water was ultrapure water obtained by a Milli Q water production device (Merck Millipore).

The concentration of calcium ions and magnesium ions contained in the drinking water was analyzed by ICP-AES, and the hardness of the drinking water was calculated according to the formula (1) from the concentrations of calcium ions and magnesium ions.

In addition, according to the scale shown in Table 4, the sensory evaluation of drinking water was performed by seven specialist panels. Tables 5 to 7 show the results of sensory evaluation for drinking water containing natural minerals, and Tables 8 to 10 show the results of sensory evaluation for drinking water obtained by adding minerals to ultrapure water.

From Table 3, it was confirmed that the control ultrapure water and the reduced indigestible dextrin 1% aqueous solution did not contain minerals.

From the results of Tables 4 to 6, when the hardness was 14.4 to 106.3, the taste of the reduced indigestible dextrin was reduced and the ease of drinking was improved compared to the control. .
From the results of Tables 8 to 10, when the hardness was 14.4 to 106.3, it was possible to reduce the taste of the reduced indigestible dextrin and improve the ease of drinking compared to the control. .
In addition, when the weight ratio of calcium to magnesium (Ca / Mg) was 1.4 to 7.4, the taste of the reduced indigestible dextrin was reduced and the ease of drinking could be improved.

Example 2
The postprandial blood neutral fat elevation inhibitory effect of a reduced-digestible dextrin-containing soft drink was tested according to the following procedure.

(subject)
The subjects were 89 men and women (69 men and 20 women) aged 20 to 65 who had a fasting blood triglyceride level of 120-200 mg / dL, which was slightly higher than the normal high level in the preliminary examination. . The average age of the subjects was 46.2 ± 8.5 years old, BMI was 24.4 ± 2.9, and fasting triglyceride was 147.8 ± 22.0 mg / dL.

(Test drink)
As a test beverage, adjusted to contain 5 g of reduced indigestible dextrin (trade name: Fibersol 2H, manufactured by Matsutani Chemical Co., Ltd.) as dietary fiber, and drinking water with an appropriate amount of vitamin C added as an antioxidant Got ready. As a control beverage, a drinking water was prepared that did not contain reduced indigestible dextrin and added vitamin C in the same amount as the test beverage. These were made into 555 mL capacity | capacitance PET bottle drinks, and it confirmed that the distinction by the external appearance and flavor was not made.

(Load food)
Loaded food is hamburger (trade name: Yoshokutei hamburger (with Demigrass sauce), Ajinomoto Frozen Foods Co., Ltd.) 180g, French fries (trade name: Cavendish shoe string potato, Miho Japan Co., Ltd.) 50g, bread ( Product name: One butter roll (30 g, manufactured by Tablemark) and one bread (trade name: Neo Butter Roll, manufactured by Fujipan Co., Ltd.). The amount of fat in the loaded food was 40.9 g (720 kcal).

(Test method)
The test was performed by a double blind randomized crossover method in which the subjects were randomized into two groups and two test beverages (test beverage and control beverage) were exchanged and ingested.
Specifically, the dinner on the day before the test day was completed by 20:00, then fasting was permitted (only water allowed), and the next morning, fasting blood was collected from the cubital vein in the hungry state. The subject was allowed to ingest the test beverage and the loaded food within 1 hour after blood collection, and blood was collected after 2, 3, 4, and 6 hours had elapsed since the start of ingestion. The intake time of the test beverage and the loaded food was generally within 20 minutes. The animals were fasted until the blood collection was completed 6 hours after ingestion, and the sitting position was rested. Then, after a one week rest period, two types of test beverages (test beverage and control beverage) were exchanged, and the test beverage and the loaded food were again taken to collect blood.

(Measurement and evaluation items)
Neutral fat, RLP-cholesterol, phospholipid, and β-lipoprotein in the collected blood were measured by outsourcing to LSI Medians Central Research Laboratory. The primary endpoint was the time-dependent change in blood triglyceride value and the area under the curve (AUC), which was expressed as mean ± standard error (SE), and measured values and changes were evaluated. . RLP-cholesterol, phospholipid, and β-lipoprotein were secondary evaluation items.

(Statistical analysis)
The validity of the double-blind randomized crossover method was verified by a generalized linear model (GLM) using the model of the following equation (2). The examination on the timing effect and the order effect was performed using blood neutral fat AUC.

Y _ijkl = μ + α _i + β _j + γ _k + ε _{(1) kl} + ε _{(2) ijkl} (2)
Y _ijkl (i, beverage; j, time; k, order; l, subject);
μ, overall average;
α, beverage effect; β, time effect; γ, sequence effect;
ε ₍₁₎ , subject effect (variation between subjects);
ε ₍₂₎ , individual measurement error (variation within subject)

The time effect and order effect of blood neutral fat AUC were P = 0.075 and P = 0.830, respectively, which were not significant, and the crossover method was determined to be appropriate.

The effect of the test beverage was analyzed by a paired t-test using the control beverage intake as a comparative control. The significance level was 5% by two-sided test, and the IBM SPSS Statistics 24 (Japan IBM Corporation) was used as the statistical analysis software.

(result)
With respect to the blood triglyceride level, the time course is shown in FIG. 1, and the area under the blood concentration curve (AUC) is shown in FIG. Regarding the amount of change in blood triglyceride value (Δ blood triglyceride value), the change with time is shown in FIG. 3, and the area under the blood concentration curve (AUC) is shown in FIG.
The blood triglyceride level was 146.2 ± 56.0 mg / dL and 149.9 ± 53.8 mg / dL before taking the test beverage and before taking the control beverage, respectively, and there was no significant difference. .

About the blood triglyceride level of FIG. 1, after the loading food intake 2, 3, 4, and 6 hours, the test drink ingestion showed a significantly low value compared with the control drink ingestion (Ingestion 2) 4, 6 hours later: P <0.05, 3 hours after ingestion: P <0.01).
The blood neutral fat AUC in FIG. 2 was significantly lower when the test beverage was ingested than when the control beverage was ingested (P <0.01).

The Δ blood triglyceride level in FIG. 3 was significantly lower when the test beverage was ingested 2, 3, 4 and 6 hours after the ingestion of the loaded food than when the control beverage was ingested (ingestion). 2, 3, 4 hours later: P <0.01, 6 hours after ingestion: P <0.05).
About (DELTA) blood neutral fat AUC of FIG. 4, the test drink ingestion showed the significantly low value compared with the control drink ingestion (P <0.01).

From the above results, it was shown that soft drinks containing reduced indigestible dextrin suppress the increase in blood neutral fat level due to dietary fat.

Table 11 shows changes with time of RLP-cholesterol, phospholipid, and β-lipoprotein. In Table 11, for each measurement item, the upper row is the result of the test beverage, and the lower row is the result of the control beverage.

PLR-cholesterol was significantly lower (P <0.05) 6 hours after ingestion of the loaded food and when the test beverage was ingested than when the control beverage was ingested.
Phospholipids showed significantly lower values after ingestion of the loaded food at 2, 4 and 6 hours and at the time of ingestion of the test beverage compared to the intake of the control beverage (2, 4 hours after ingestion: P <0. 05, 6 hours after ingestion: P <0.01).
β-lipoprotein showed a significantly lower value when the test beverage was ingested 2, 3, 4 and 6 hours after ingestion of the loaded food compared to the intake of the control beverage ( ingestion 2, 3, 4 hours). After: P <0.05, 6 hours after ingestion: P <0.01.

Dietary fat is absorbed from the intestinal tract and then re-synthesized into chylomicron containing a large amount of neutral fat in small intestinal epithelial cells and transferred into the blood. Chylomicron is catabolized into a chylomicron remnant by lipoprotein lipase and taken into the liver. Research reports that remnant-like lipoprotein, an intermediate metabolite produced at this time, stays in the blood cause the development of arteriosclerosis. Therefore, in addition to postprandial blood triglyceride levels, it suppresses the rise in RLP-cholesterol reflecting remnant-like lipoproteins, and is a substance that is considered to contribute to arteriosclerosis related to fat metabolism. Suppressing the rise of lipids and β-lipoprotein is considered useful for preventing arteriosclerotic diseases.

The subjects were stratified into a subject having a fasting blood neutral fat value of 150 mg / dL or more and a subject having a fasting blood triglyceride value of less than 150 mg / dL, and a stratified analysis was performed.
For subjects with fasting blood triglyceride values of 150 mg / dL or higher (n = 38), blood triglyceride levels were 165.1 ± 66.4 mg / mL, respectively, before ingesting the test and control beverages. 170.4 ± 58.1 mg / mL, and no significant difference was observed. The blood triglyceride level after ingestion of the loaded food tended to show a lower value when the test beverage was ingested, after 2, 3, 4, and 6 hours of ingestion of the ingested food compared to the intake of the control beverage (2 hours after ingestion: P = 0.057, 3 hours after ingestion: P = 0.076, 4 hours after ingestion: P = 0.057, 6 hours after ingestion: P = 0.054). ΔThe blood triglyceride level was significantly lower at 2, 3, 4, and 6 hours after ingestion of the test beverage than at the time of ingestion of the control beverage (after 2, 3, 4, and 6 hours of ingestion). : P <0.05). The blood neutral fat AUC at the time of ingesting the test beverage tended to show a lower value than that at the time of ingesting the control beverage (P = 0.054), and the Δ blood neutral fat AUC at the time of ingesting the test beverage The value was significantly lower than that of the control drink (P <0.01).

For subjects with fasting blood triglyceride levels of less than 150 mg / dL (n = 51), blood triglyceride levels were 132.1 ± 42.2 mg / mL, respectively, before ingesting the test and control beverages. 134.6 ± 45.3 mg / mL, and no significant difference was observed. The blood triglyceride level after ingestion of the load food tended to show a lower value when the test beverage was ingested than after the intake of the control beverage 3 and 4 hours after ingestion of the load food (3 hours of ingestion). After: P = 0.056, 4 hours after ingestion: P = 0.089). ΔThe blood triglyceride level was significantly lower at 3 hours after ingesting the test beverage than at the time of ingesting the control beverage (P <0.05), and after 2, 4 hours, the control beverage was ingested. Compared with time, there was a tendency to show a low value (2 hours after ingestion: P = 0.057, 4 hours after ingestion: P = 0.056). The blood neutral fat AUC at the time of ingestion of the test beverage tended to show a lower value than that at the time of ingestion of the control beverage (P = 0.069). The value was significantly lower than that of the control drink (P <0.05).

From the above, by taking the test beverage before meals, not only adult men and women whose fasting blood triglyceride level is slightly higher than the normal high level, but also adult men and women whose fasting blood triglyceride value is within the reference value In contrast, it was shown that an effect of suppressing the increase in blood triglycerides after meals can be expected.

ADVANTAGE OF THE INVENTION According to this invention, the ease of drinking can be improved in the drinking water containing a reduced indigestible dextrin. Moreover, according to this invention, the drinking water containing the reduced indigestible dextrin which provided the function of fat absorption suppression can be provided.
Drinking water can be comfortably incorporated and consumed in normal eating habits, and by continuously and regularly ingesting the drinking water for inhibiting fat absorption of the present invention, postprandial hyperlipidemia and lifestyle-related diseases It is thought that it is also effective for prevention.

Although several embodiments and / or examples of the present invention have been described in detail above, those skilled in the art will appreciate that these exemplary embodiments and / or embodiments are substantially without departing from the novel teachings and advantages of the present invention. It is easy to make many changes to the embodiment. Accordingly, many of these modifications are within the scope of the present invention.
The contents of the documents described in this specification and the specification of the Japanese application that is the basis of Paris priority of the present application are all incorporated herein.

Claims (17)

1. Drinking water containing reduced indigestible dextrin and having a hardness of 10 to 110.
2. The drinking water according to claim 1, wherein the weight ratio of calcium to magnesium (Ca / Mg) in the drinking water is 1-8.
3. The drinking water according to claim 1 or 2, wherein the dose of the reduced resistant digestible dextrin in the drinking water is 1 to 16 g per 500 g of drinking water.
4. The drinking water according to any one of claims 1 to 3, which is colorless and transparent.
5. The drinking water according to any one of claims 1 to 4, comprising natural water.
6. A method of improving the ease of drinking drinking water containing reduced indigestible dextrin,
   Adjusting the hardness of the drinking water.
7. The method according to claim 6, wherein the hardness of the drinking water is adjusted to 10 to 110.
8. The method according to claim 7, wherein the weight ratio of calcium to magnesium (Ca / Mg) in the drinking water is 1-8.
9. The method according to any one of claims 6 to 8, wherein the hardness of the drinking water is adjusted by adding at least one of a magnesium salt and a calcium salt.
10. The method according to any one of claims 6 to 9, wherein the hardness of the drinking water is adjusted by blending a plurality of types of water having different hardnesses.
11. The method according to any one of claims 6 to 10, wherein a dose of the reduced resistant digestible dextrin in the drinking water is 1 to 16 g per 500 g of drinking water.
12. Drinking water for fat absorption suppression containing reduced indigestible dextrin.
13. The drinking water for fat absorption suppression according to claim 12, wherein the drinking water has a hardness of 10 to 110.
14. The drinking water for inhibiting fat absorption according to claim 13, wherein the weight ratio of calcium to magnesium (Ca / Mg) in the drinking water is 1 to 8.
15. The drinking water for inhibiting fat absorption according to any one of claims 12 to 14, wherein a dose of the reduced indigestible dextrin in the drinking water is 1 to 16 g per 500 g of drinking water.
16. The drinking water according to any one of claims 12 to 15, which is colorless and transparent.
17. A method for suppressing dietary fat absorption,
    The said method including ingesting 555 mL of the drinking water for fat absorption suppression containing 5 g of reduced indigestible dextrins with a meal once a day.

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