KR101636680B1 - Method for preparing lowmolecular collagen peptide from fish - Google Patents

Abstract

The present invention relates to a method for producing a fish collagen peptide, and more particularly, to a method for producing a fish collagen peptide prepared by hydrolyzing a fish from a fish and filtering and purifying the fish . Particularly, it is characterized by high low molecular weight distribution compared to existing animal collagen, high content of hydroxy proline which is a main index component of collagen, chromaticity and imitation / odor component are greatly reduced for easy application to products. The low-molecular-weight fish collagen peptide developed as described below was found to be non-toxic at the cellular level, and a significant level of skin moisturizing effect was confirmed.

Description

TECHNICAL FIELD The present invention relates to a method for preparing low molecular weight collagen peptides derived from fish,

The present invention relates to a method for producing a fish collagen peptide, and more particularly, to a method for producing a fish collagen peptide prepared by hydrolyzing a fish from a fish and filtering and purifying the fish . Particularly, it is characterized by high low molecular weight distribution compared to existing animal collagen, high content of hydroxy proline which is a main index component of collagen, chromaticity and imitation / odor component are greatly reduced for easy application to products. The low-molecular-weight fish collagen peptide developed as described below was found to be non-toxic at the cellular level, and a significant level of skin moisturizing effect was confirmed.

Collagen is a protein found mostly in animals, and is a major protein that constitutes the flesh and connective tissue of mammals. It is so abundant that it accounts for 25% to 35% of the constituent proteins of the body. The increased fiber-like collagen is mainly present in the fibrous tissues such as tendons, ligaments, and skin, and also exists in the cornea, cartilage tissue, bone, blood vessels, digestive tract, and vertebral disc. In muscle tissue, collagen acts as a major constituent of the endocardium.

Collagen has a molecular weight of 300,000 and three α-molecules with a molecular weight of 100,000 are assembled into a γ-yarn, which forms a right-turning spiral that rotates once every 40 residues. It is a triple helix structure with a diameter of 1.5 nm and a length of 300 nm. α chains are strongly bound by hydrogen bonds. When microfibrils are gathered, they become collagen fibers by covalent crosslinking, and they are gathered to become fibers.

Collagen, like other proteins, determines structure, amount of synthesis, etc. based on genetic information. The study of molecular biology and biochemistry of collagen has been remarkably advanced in recent years and its structure has been elucidated in detail. When you search for a document called Collagen, you can see that more than a thousand documents are published every year. To date, more than 13 species have been reported, and more than 22 species have been reported as polypeptide chains. Generally, the difference from other proteins is that the collagen protein does not function as a single molecule, and many molecules associate to form a higher-order structure and thus play a role in the living body.

 Collagen is a protein that occupies the largest quantitative and functional part in the human body. It is a major constituent of the extracellular matrix, more specifically connective tissue, which forms the skeleton of all the cells in the human body. do. Human tissues containing large amounts of collagen include bone tissues such as skin, bones and cartilage, tendons, and ligaments. It is known that aging of these tissues causes human aging diseases such as skin wrinkles and sagging and osteoporosis, which is caused by decrease of collagen amount and function due to reduction of collagen synthesis of tissue.

The characteristic of collagen amino acid composition is that Glycine occupies about 1/3 of the whole. And 2/9 of the total is composed of Proline or Hydroxy-proline. Hydroxy-proline is produced when Proline on the translation peptide of the Collagen gene is hydrolyzed to the 4th carbon by molecular oxygen. The content of amino acids (Proline or Hydroxyproline) depends on the type of animal, especially the upper limit of body temperature in the animal, and 2/9 is the case of a constant-temperature animal such as a bird or mammal. In other words, the thermal stability of the collagen structure depends on the content of imino acid, especially on the amount of hydroxy-proline. For example, in the case of fish, the degradation temperature and the amino acid content are decreased in response to the surrounding temperature. Unlike other spherical proteins, collagen has a significantly lower content of hydrophobic amino acids.

Hydroxy-proline is rarely found in proteins other than collagen (some in elastin), and only Proline in the peptide is hydrolyzed to become a hydroxy-proline, so that the amount of collagen can be measured by quantification of hydroxyproline Hydroxy-proline is 100 μg, and collagen is about 1 mg, since the propylene content is about 10%).

Quantification of hydroxy-proline is used as an indicator of the total amount of collagen protein synthesis and degradation. However, the content of hydroxy-proline in collagen varies not only with the shape of collagen (gene) but also with the conditions of animal tissues and cells (environmental conditions).

The amounts of lysine and arginine are higher than those of glutamic acid and aspartic acid. The charge of all collagen peptide is positively charged at neutral pH. That is, the isoelectric point can be regarded as basic. Glycine is much, and the hydrophobic amino acid is small. Therefore, the molecule volume is small (0.75 in the case of the spherical protein and 0.70 in the collagen), and the average residual molecular weight of the amino acid is 100 or less (the spherical protein is generally 110).

The amount of collagen produced in the body decreases with age. In the 20s, the collagen production is the highest, and the 40s are produced at the level of 70%. Therefore, since collagen is not a substance produced in the body, it needs to be ingested by food or the like.

Collagen can be divided into polymer collagen and low molecular collagen depending on the molecular weight. Polymer collagen generally has a molecular weight of 5,000 Da. . The larger the molecular weight, the lower the absorption rate in the body, and it is difficult to exhibit the functionality. Therefore, polymer collagen having a molecular weight of 5,000 or more is used in general foods and the like. On the other hand, low molecular weight collagen has a molecular weight of 1,500 Da. Or less, and it is possible to expect the functionality such as skin elasticity because of the high absorption rate in the body. Generally, low-molecular collagen is used for health functional foods, cosmetics and general medicine.

Collagen is a constituent in the body, but it exists in meat and fish. It is known that there are many pig hulls, chicken wings, potatoes, chicken feet and so on. Generally, collagen is consumed through meat products among animal foods, but there is a small amount of collagen in vegetable foods. There are mainly dried persimmons, two-pancake tea, persimmon leaves, etc. However, it is difficult to expect a collagen effect through the ingestion of such foods. Collagen, which is most popular nowadays, is derived from fish. In particular, collagen extracted from fins and scales is used as a material. In particular, the results of studies on the difference in absorption rate show that fish collagen has an initial absorption rate about 1.5 times higher than that of meat collagen. These results are due to the fact that fish - derived collagen has a higher distribution of low molecular weight than meat collagen.

Fish-derived collagen is likely to remain as saliva as it is derived from fish. Even at domestic and overseas collagen, low-priced products have only a small amount of virgin remains. Therefore, a masking material is required when it is contained in foods and the like. In order to ingest alone collagen as in Japan, it is necessary to remove the vignetting through high purity purification (Japanese Patent Application No. 2009-189284, Japanese Patent Application No.: 2012-206999). However, such a process has a disadvantage in that the cost of collagen is increased due to the use of an organic solvent or a separate facility. Due to such a problem, a method of reducing the odor by adding a masking material to collagen has been invented (Korean Patent Application No. 2012-0020480, Japanese Patent Application No. 2012-0084742). However, in terms of 100% fish collagen, the addition of additives may cause the collagen to lose its meaning and can not be regarded as pure collagen. Therefore, the present invention has the advantage of improving not only the functional aspect but also the sensory characteristics through at least process improvement. The low-molecular-weight fish collagen peptide developed as described below was found to be non-toxic at the cellular level, and a significant level of skin moisturizing effect was confirmed.

Korean Patent Publication No. 10-2013-0098729

The present invention relates to a method for producing a fish collagen peptide, and more particularly, to a method for producing a fish collagen peptide prepared by hydrolyzing a fish scallop from a fish and filtering and purifying the fish collagen peptide , A low molecular weight distribution compared to existing animal collagen, a high content of hydroxyl proline as a major index component of collagen, a low molecular weight collagen peptide derived from fish having greatly reduced chromaticity and / Method.

According to an aspect of the present invention, there is provided a method for producing a fish meal, comprising: mixing a fish scale and purified water at a weight ratio of 1: 5 to 10; Softening the tissue by treating the mixture of juvenile and purified water at 90-100 DEG C for more than 8 hours in hot or weak acid; Proteolyzing the heat or weak acid treated mixture with proteolytic enzyme; Heat-treating the protease at 90 to 100 ° C for at least 1 hour to inactivate the protease; Filtering the enzyme hydrolyzate with a filter press; And a step of concentrating and pulverizing the filtered solution. The present invention also provides a method for producing a low molecular weight collagen peptide derived from fish.

The proteolytic enzyme is an endo-type proteinase (Alcalase), and 1.5-2.5 parts by weight of the protein is added to 100 parts by weight of the child. The protein degradation is carried out at pH 6-8.5, In the presence of water, for 8 to 16 hours.

The collagen peptide has a molecular weight of 500 to 3,000 Da. And to provide a method for producing a low molecular weight collagen peptide derived from fishes.

The present invention also provides a process for producing a low-molecular-weight collagen peptide derived from fish, wherein the filter press filtration process of the collagen peptide is performed twice or more to minimize odor and improve the chromaticity.

The fish collagen peptide prepared according to the present invention was developed using a child derived from a fish in a clean area. Compared to animal collagen, its safety has been proven and its low-molecular peptide distribution is high and its absorption rate is excellent. Also, the content of hydroxy proline amino acid, which is known as a functional index component, is 11%. In addition, collagen derived from fish generally has some aspect that it is somewhat inadequate to use as a stand-alone product because of the remnant of fish. Therefore, the activated carbon treatment process has been optimized to dramatically reduce the odor, and the chromaticity is also formed close to white, so that it has been developed to be free from problems when used as a single product.

FIG. 1 is a flow chart illustrating a process for producing a fish-derived collagen peptide according to an embodiment of the present invention.
FIG. 2 is a photograph for viewing the color and shape of a child.
3 is a bar graph showing the results of the measurement of the decomposition rate (Brix) according to the pretreatment conditions.
4 is a graph showing the main effect, alternating action, and reaction optimization result.
FIG. 5 is a bar graph showing the results of analyzing the molecular weight distribution according to the conditions of the alkaline enzyme treatment.
FIG. 6 is a bar graph comparing contents of fragrance components according to the amount of activated carbon treated.
7 is a bar graph comparing the odor components of domestic and foreign fish collagen products.
8 is a graph comparing the content of the perfume ingredients according to the treatment of the activated carbon two times.
Fig. 9 compares the chromaticity obtained by the treatment of activated carbon two times.
FIG. 10 is a graph showing the results of evaluation on cytotoxicity.
Fig. 11 shows the result of skin moisturizing effect evaluation.

Hereinafter, the present invention will be described in more detail by way of examples and accompanying drawings. The following examples are provided to further understand the present invention, but the present invention is not limited to the following examples.

Figure 1 shows a process for producing fish collagen peptides. 1, in order to improve the degradation rate and the content of low molecular peptide, a child was pretreated through a separate process. In order to decompose the pretreated child into a minimum peptide unit and to increase the content of hydroxyl proline, which is an index component of collagen, Degradation enzymes were selected and treated. After the inactivation of proteolytic enzymes, the activated carbon was treated to improve the odor and chromaticity. Collagen originating from children is likely to remain virulent even after powdering, which may be sensually annoying to consumers. Therefore, removal of odor is already an essential and important process. The collagen peptide developed through the present invention is characterized in that it has already significantly improved odor and chromaticity compared to other collagens in the world.

[Example 1] Selection of young fish

The main origin of the fish (scales) varies depending on the species of seawater, but Southeast Asia is the main state. Among Southeast Asia, Indonesia and Thailand have many catches. Therefore, the production of young fish (scales) is also very high in the two countries with large catches. The quality of fish produced in Southeast Asia differs by manufacturer and country. The fish scales should be close to white, and the size of the fingernails should be adequate, because they can directly affect the quality of the final product. The general color and shape of the fish scales are shown in Fig.

It was selected as Tilapia fish species which is suitable for collagen production and has high production cost, economical efficiency and easy to procure raw materials. The fish scales are produced by washing and removing calcium. The reason that calcium ions are removed is because the fish scales have a negative effect on the decomposition efficiency when they are subjected to processing such as enzymatic decomposition to be. For reference, the reason why the pH of the fish scales differ is dependent on the condition to be treated in the final flushing.

[Example 2] Optimization of a pretreatment process of a fish scale

The major component of the fish scales is protein, and a pretreatment process is required to maximize the efficiency of proteolytic enzymes. When the dried fish is added to distilled water and treated with the enzyme immediately, it is not only difficult to decompose, but also takes a long time. There are three methods to pretreat fishes (fish scales): mixing them in purified water of 90 ℃ or more, treating them for a long time, treating acid, and treating alkali. Treatment of acids and alkalis was also related to consumer awareness, so it was necessary to set the conditions carefully. Therefore, the experiment was conducted under three conditions: no treatment (control), neutralization after conditioning (condition 1), and neutralization after alkaline treatment (condition 2). 5N-HCl was added to the weak acid at about pH 2 ~ 4.5 and treated at 90 ~ 100 ℃ for 6 ~ 10 hours. The alkali was added to the pH 9 ~ 12 with 5N NaOH at 90 ~ 100 ℃ for 6 ~ 10h Respectively. The pH to be neutralized was 6.5, and the general enzymes were adjusted to the conditions showing the highest activity. After neutralization, two kinds of Alcalase and Delvolase, which had the highest decomposition rate, were used in the young selection process. Detailed experimental conditions are shown in Table 1.

No. fair Condition One Stirring speed (rpm) 300 to 800 2 Distilled water (ml) 6 to 10 times the number of sibs 3 Processing time 6 to 10 hours 4 Treatment temperature 90 ~ 100 ℃ 5 Neutralization pH 6.5

The degradation rate (Brix) and the molecular weight distribution after enzyme treatment were measured and compared to select the young pretreatment conditions. When the first decomposition rate was measured, the pretreatment process which neutralized after weak acid treatment showed the best results (Fig. 3). (12.5 → 14) in the weak acid treatment. On the other hand, in the case of alkali treatment, it was confirmed that the decomposition ratio does not show a great difference with the control. This could be attributed to the softening of the fish 's scales during the weak acid treatment so that the enzymatic action could occur well.

3 shows the results of the Brix measurement according to the pretreatment conditions. Referring to FIG. 3, the pretreatment effect was compared by measuring the molecular weight distribution along with the degradation rate (Brix). As described in the introduction, the higher the molecular weight distribution of the collagen, the higher the absorption rate and the additional functionality can be expected. Therefore, molecular weight distribution after pretreatment was measured by HPLC. The molecular weight measurement graph can be interpreted as having a low molecular weight distribution toward the right. This is because, in the case of a GPC (Gel chromatography) column, the packing material in the column is porous, and in the case of a low molecule, it takes a long time to pass.

As a result of analysis of the molecular weight distribution, the distribution of fish collagen, which is sold in domestic company A, has a molecular weight of 1,500 or less, which is 80%. In the control group, the distribution of the molecular weight of less than 1,500 was the lowest at 45%, and that of the weakly acid treated sample was 65%, which was 30% higher than that of the control group. Therefore, it was finally decided to neutralize the juvenile (scales) at pH 6.5 after pretreating at pH 2.5 for 8 hours at 95 ℃. However, in order to have a low-molecular-weight distribution at the level of domestic competitors, additional experiments were carried out because it was deemed necessary to optimize the enzyme decomposition process.

[Example 3] Optimization of decomposition conditions of juvenile (scaly) enzymes

The process performed after the optimization of the pretreatment process of juvenile scales is optimization of the enzymatic degradation process. The proteolytic enzymes for decomposing juvenile (scales) were selected by selecting Alcalase, which has the highest production rate of low molecular weight in the pretreatment process. The use of complex enzymes could increase efficiency, but there was no significant difference when compared to the single enzyme treatment group in preliminary preliminary experiments.

 The specs from Alcalase producers indicate that the temperature is between 50 and 60 ° C and the pH is between 6 and 8.5. Therefore, the enzyme treatment conditions were optimized through a complete factorial design, and the experimental conditions are shown in Table 2.

Temperature Enzyme Throughput (%)
(Relative to substrate) Results (Molecular weight distribution below 1,500%) 50 One 63.00% 55 One 68.00% 60 One 73.80% 50 2 68.00% 55 2 80.60% 60 2 76.80%

The results of the complete factor analysis are shown in Figs. 4 and 5. As expected, the enzyme treatment temperature and concentration showed a proportional relationship with the low molecular weight content. As a result of the optimization of the reaction, the low molecular weight distribution was expected to be the highest when the enzyme (2) parts by weight was compared with the substrate (young) part at 55 ° C. On the other hand, it was expected that the best result would be obtained when 2 parts by weight of the enzyme was treated at 60 캜 with respect to the substrate (young) part. However, when 2 parts by weight of the enzyme was treated at 55 캜 with respect to the substrate (young) 3 percent higher.

Hydroxyproline, a major index component of collagen, was also measured to be about 11% when treated with 2 parts by weight of enzyme (young) by weight at 55 ° C. Hydroxyproline content was measured at 9% level at 60 ℃ or higher and showed similar level at 50 ℃. It was confirmed that the content of hydroxy proline varies depending on the enzyme decomposition conditions.

 Therefore, it is preferable to treat 2 parts by weight of the enzyme (young) with respect to the substrate (young) at a temperature of 55 DEG C after the final pretreatment of the fish scales, but there is not a large variation if it is between 1.5 and 2.5 parts by weight.

 The pH and the amino acid content of the enzyme were estimated to be about the same. It was confirmed that the molecular weight distribution and the amino acid content were lowered by 10% or more when the pH was 6 or less or 8.5 or more.

[Example 4] Optimization of decolorization / deodorization process

Young fish (scales) are derived from fish and require decolorization / deodorization processes. Collagen can be ingested directly in powder form in Japan, which is a major cause of the occurrence of a claim.

The most suitable process for the decolorization / deodorization process of fish collagen in the field is activated carbon treatment and filter press filtration method. The effect of activated carbon increased proportionally depending on the amount of treatment. However, when the amount of activated carbon is higher than a certain level, the effect does not appear efficiently.

The content of fragrant components was measured by GC-MS in order to examine the removal efficiency of the odor component by the activated carbon treatment. Since the odor component was not defined as a specific component, the content of total fragrance component in the collagen product was measured. The fractions were extracted by headspace extraction method. The extracted fragrance components were adsorbed on SPME fiber and quantitatively analyzed by gas chromatograph / mass spectrometer (GC / MS; Agilent Technologies / 7890A GC / 5975C MSD). 3g of collagen powder was immersed in 20ml vial, heated at 60 ℃ for 20 minutes and extracted into headspace. The extracted fragrance components were adsorbed to the fiber at 60 ° C for 30 minutes using SPME fiber (Supelco; 65um PDMS / DVB blue plain (CAT No.57311)), Was used to quantify the fragrance components. At this time, the inlet temperature was maintained at 250 ° C and the column oven temperature was maintained at 70 ° C for 2 minutes, and then the temperature was raised to 230 ° C at 20 ° C / min. The column used HP5-MS (60 m> 0.25 mm> 0.25 μm), the carrier gas was 99.999% purity and the flow rate was kept constant at 1.0 mL / min. Quantitative analysis of aroma components was analyzed by TIC (Total Ion Current) mode.

 The amount of activated carbon treated was 1, 1.5, and 2 parts by weight based on the total weight parts. When 2 parts by weight of the total liquid weight portion was treated, it was confirmed that the off-odor component was hardly analyzed. When the treatment was carried out at 2% or more, there was a limit in the amount of the odor component that can be collected by the activated carbon, It was confirmed that it did not increase. The results of the GC / MS analysis are shown in FIG.

Referring to FIG. 6, when the activated carbon was treated at a weight ratio of 2 to the total liquid weight ratio, it was confirmed that the off-odor was reduced. However, in order to secure a competitive advantage, it was compared with domestic and overseas competitor products. As a result of comparison, it was confirmed that a small amount of odor component was already present in comparison with one of the Japanese products.

As a result, the activated carbon treatment process was improved secondarily. The process of treating 2 parts by weight with respect to the conventional one total weight part was improved and the treatment was repeated twice in succession. As a result of the experiment, the odor component was remarkably reduced and the chromaticity was also made closer to white than the collagen product of Japanese company B.

[Example 5] Drying and pulverization of the filtrate

The filtered enzyme-decomposed liquid may be dried and pulverized. There is no limitation on the drying method, and general drying methods such as vacuum drying, hot air drying, spray drying and freeze drying are used.

[Example 6] Evaluation of cytotoxicity and evaluation of skin moisturizing efficacy

MTS (Promega, Madison, USA) assay was performed to measure the effect of collagen peptide on cell viability. HaCaT cells were pre-incubated at 37 ° C and 5% CO ₂ for 24 hours at a concentration of 1 × 10 ⁴ cells / mL in a 96-well plate (Nunc). The collagen peptides were incubated at 0, 25, 50, , 400 ug / ml, and cultured for 24 hours. Thereafter, the MTS reagent was treated at a concentration of 0.25 mg / ml and reacted for 2 hours. The absorbance at 490 nm was measured to investigate the effect of collagen peptide on cytotoxicity and proliferative effect. As a result, it was confirmed that there was no effect on cytotoxicity even at high concentration treatment (FIG. 10).

The human HaCaT (Immortal human keratinocyte line) cells used in the experiment were purchased from the dermatology department of Seoul National University College of Medicine. The cell lines were cultured in DMEM medium supplemented with 10% fetal bovine serum (FBS; Hyclone, Texas, USA) and 1% penicillin-streptomycin (Sigma Co.) at 37 ° C and 5% CO _2. 9 cell lines were used for the experiments. Cell 60? Dishes were plated at 1 × 10 ⁵ and incubated for 1 day until reaching a confluency of about 60% and further cultured for 1 day in FBS-free medium. After the medium was removed, the cells were washed with phosphate buffered saline (PBS), and the DMEM medium without FBS was treated with collagen peptide at a concentration of 25,100 mg / L and incubated in a CO ₂ incubator for 1 hour. The control group was obtained by culturing in the same medium as described above without addition of the test substance. To evaluate the expression of AQP3, the cultured cells were washed with PBS, transferred to a 1.5-mL microtube, and cell precipitates were disrupted by the addition of Pro-prep protein extraction solution (Intron Biotechnology, Seoul, Korea) Centrifugation for 20 min and supernatant was taken to separate proteins. The separated proteins were quantified by BCA method, electrophoresed using 12% SDS polyacrylamide gel, and transferred to PVDF membrane. Membrane was blocked with 5% skim milk solution for 1 h, then incubated with primary antibody for 3 ~ 4 h at room temperature and treated with secondary antibody conjugated with horseradish peroxidase. Chemiluminescence kit was used to confirm the intensity of the developed band. β-actin was used as a control to check whether each sample contained the same amount of protein. As a result of the experiment, it was confirmed that the skin moisturizing effect was significant. The results are shown in Fig.

Claims (4)

Mixing the fish scales and the purified water at a weight ratio of 1: 5 to 10;
The mixture of young and purified water is stirred at 90 to 100 ° C for 6 to 10 hours to neutralize the treated tissue by weak acid treatment at a pH of 2 to 4.5;
Proteolysis of the slightly acid-treated mixture with a proteolytic enzyme added in an amount of 2.0 parts by weight based on 100 parts by weight of the child, at a pH of 6 to 8.5 and a temperature of 55 to 60 ° C for 8 to 16 hours;
Heat-treating the protease at 90 to 100 ° C for at least 1 hour to inactivate the protease;
Treating the enzyme hydrolyzate with at least 2 parts by weight of activated carbon per total weight part of the enzyme solution, and filtering the enzyme hydrolyzate with a filter press; And
And concentrating and pulverizing the filtered liquid,
Wherein the L value of the collagen peptide is 95 or more, the collagen peptide is subjected to the filter press filtration process twice or more continuously,
Molecular weight of 500 to 3,000 Da. Collagen peptide and has a molecular weight of 1,500 Da. Or less of collagen peptide and more than 10% of hydroxy proline. The method of claim 1, wherein
Wherein the proteolytic enzyme is endo-type proteinase (Alcalase).
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