KR20110133000A - A method for purifying fucoxanthin from seaweeds - Google Patents

Abstract

PURPOSE: A method for purifying fucoxanthin derived from seaweeds is provided to obtain stable fucoxanthin and to resolve a problem of yield reduction. CONSTITUTION: A method for purifying stabilized fucoxanthin comprises: a step of mixing one year old brown algae collected during March to May and 0.1-0.5 % of vitamin C; a step of isolating chlorophyll from the brown algae using an organic solvent; and a step of removing alcohol by concentrating the obtained fucoxanthin fraction and removing water using non-polar organic solvent.

Description

Purification method of fucoxanthin derived from seaweed {A METHOD FOR PURIFYING FUCOXANTHIN FROM SEAWEEDS}

The present invention relates to a method for purifying fucoxanthin from seaweed, and more particularly, to a method for providing more stabilized fucoxanthine using vitamin C, which is a water-soluble antioxidant, in the process of extracting furosanthin from brown algae. .

Recently, research results have been reported that ingredients contained in seaweed are beneficial to human health. In particular, fucoxanthin is a unique carotenoid found abundantly in brown algae and has been reported to have an anti-obesity effect (K. Miyashita, Lipid Technology, August / September 2009, Vol. 21, No. 8/9). .

Fucoxanthine's anti-obesity mechanism induces the expression of uncoupling protein 1 (UCP 1) in the white adipose tissue (WAT) mitochondria, resulting in fatty acid oxidation and heat production in WAT, resulting in fat cell apoptosis ( apoptosis) action.

UCP 1 is a key molecule in the anti-obesity effect. Expression of UCP 1 is known as an important factor of body energy consumption, and obesity is likely to occur when UCP 1 causes dysfunction.

Experiments showing the relationship between fucoxanthin and UCP 1 expression and their experimental results are disclosed in this document. In this experiment, mice received 13% soybean oil (control), 12.5% soybean oil + 0.5% Undaria lipids (Fucoxanthin (Fuco): 0.05%) and 11% soybean oil + 2% brown rice lipids (Fuco : 0.2%) was taken. As can be seen in FIG. 1, UCP 1 was expressed in 0.2% fucoxanthin-supplied mouse WAT, but little UCP 1 was expressed in control mouse WAT. In addition, mRNA of UCP 1 was expressed in 0.2% fucoxanthin-supplied mouse WAT, but mRNA of UCP 1 was hardly expressed in control mouse WAT. These findings indicate that fucoxanthin induces the expression of UCP 1 protein and mRNA in WAT.

This seems to be due to the structural features of fucoxanthin, ie, additional hydroxy substituents and allene bonds on the side chain groups of the fucoxanthin metabolites, fucoxanthinol and amaurociaxanthin A (H Maeda, Molecular Medicine Reports 2: 897-902, 2009; and K. Miyashita, homologous).

Fucoxanthin is known to be obtained by extracting, separating and purifying from brown algae by acetone extraction or hexane extraction. However, in the case of extracting fucoxanthin by the conventional method, due to the high antioxidant properties of fucoxanthin, there is a problem that fucoxanthin is gradually destroyed over time, the fucoxanthin yield is lowered during extraction and purification.

In order to overcome this problem, there have been attempts in the art to stabilize or immobilize the pigments by treating ash with seaweed samples (Bull. Korean Fish Soc. 3 (2)). Oriza Oil & Fat Chemical Co., Japan, also protects fucoxanthin by oxidizing tocopherols first using a fat-soluble antioxidant, tocopherol, or by using cyclodextrins. Fucoxanthin is protected by encapsulating xanthine. However, this prior art has not reached a satisfactory level of stabilization of fucoxanthin.

Therefore, an object of the present invention is to solve the problem that the fucoxanthin is destroyed over time due to the high antioxidant properties of fucoxanthin, resulting in a decrease in yield.

The object of the present invention is to provide a more stabilized fucoxanthin by using a water-soluble antioxidant vitamin C in the process of extracting fucoxanthin from brown algae.

In the case of extracting fucoxanthin by the method of the present invention, there is an excellent effect that the fucoxanthin is more stabilized to solve the problem of yield decrease over time.

1 shows the results of UCP 1 expression in fucoxanthin-fed mouse WAT.
2 is a graph showing the HPLC results of fucoxanthin according to the present invention.

The present invention relates to a method for the separation and purification of fucoxanthin, more specifically

Adding and mixing 0.1 to 5.0% of vitamin C based on its weight in the process of separating fucoxanthin from brown algae;

Extracting and removing chlorophyll from the brown algae using an organic solvent; And

It relates to a method for purifying fucoxanthin comprising the step of concentrating the obtained fucoxanthin fraction to remove alcohol and then removing water using a nonpolar organic solvent.

In addition, the present invention may optionally include the step of adding tocopherol or cyclodextrin weight ratio 1: 1 to the fucoxanthin obtained by extraction. In this case, not only did the antioxidants of fucoxanthine have an excellent effect of increasing the viscosity and improving the physical properties of the cosmetics.

In the present invention, 'algae' refers to brown algae, for example, seaweed ( Undaria pinnatifida ), kelp ( Laminaria ), 톳 ( Hijikia fusiforme ), Sargassum fulvellum ). Brown algae in the present invention is preferably seaweed. The lowest photosynthetic radiation and seawater temperatures during March, April and May sunshine increase the formation of zeaxanthin to fucoxanthin, so brown algae harvested in March, April and May Preferred in terms of xanthine content. Also, fresh brown algae are preferred.

Brown algae are scalded in boiling water to remove salts and enzymes. After that, wash with running water and cool again to remove salt. After washing, remove the water.

Vitamin C used in the present invention may be any of those used in the art, preferably in powder form. Vitamin C is used in an amount of 0.1 to 5.0% by weight of brown algae, preferably 1 g of vitamin C per kg of brown algae is used. Vitamin C encapsulates fat-soluble fucoxanthin and stabilizes fucoxanthin by oxidizing vitamin C itself first.

In the present invention, the term "extraction" refers to supercritical extraction by immersion in an organic solvent such as ethanol or methanol or using CO ₂ .

As the extraction solvent used in the present invention, an organic solvent obtained by mixing hexane and ethanol in a weight ratio of 3: 7 is preferable for removing chlorophyll, and hexane is preferable for separating water.

In addition, tocopherol may be added to the extracted fucoxanthin to improve storage stability. In this case, fucoxanthin and the same amount of tocopherol are preferably added. Centrifugal Partition Chromatography (CPC) and High Pressure Liquid Chromatography (HPLC) can then be performed to obtain high purity (eg 95%) of fucoxanthine.

In addition, cyclodextrin may be added to the extracted fucoxanthin to realize commercialization with improved viscosity and physical properties. At this time, fucoxanthin is mixed with the same amount of cyclodextrin, i.e., weight ratio 1: 1, and homogenized with vigorous or gradual pressure.

The present invention is explained in more detail by the following specific examples, but the present invention is not limited by the following examples.

Example : Fucoxanthine  Extraction and Purification

Sample Preparation

1 kg of annual brown algae collected in March, April and May were prepared. Brown algae were boiled in boiling water for 5 minutes to remove salt and deactivate the enzyme present in brown algae. It was then washed well with running water to cool and the remaining salts were removed. Drained after washing. Subsequently, evenly sprayed with 1 g of vitamin C in powder form, which is a water-soluble antioxidant, was mixed well to prepare a brown algae sample. Samples were cut at 5 mm intervals.

extraction

The cut samples were extracted at 25 ° C. three times for 2 hours using 3 L of 99% ethanol. After adding the organic solvent mixed with hexane and ethanol at a weight ratio of 3: 7 to the primary extract repeatedly extracted three times, shake the mixture well, and then separate and remove chlorophyll three times. made. Again, a tertiary extract was prepared by removing ethanol from the secondary extract using a vacuum evaporator at 80 ° C. and 200 bar. After adding hexane to the tertiary extract and shaking well to separate the fucoxanthin fraction, the fraction was removed again using a vacuum evaporator. This gave about 5% fucoxanthin (dw) concentrate.

analysis

Fucoxanthine samples obtained according to the extraction method were analyzed by the following HPLC analysis conditions.

colume ： YMC corotenoid S ₃ (1.6 × 100)

Flow rate: 1ml / min

Movile phase A: MeOH: MTBE (10:90), B: MeOH: H ₂ O (95: 5)

Gradient condition: 0min = B -100%

45min = B-30% (10min, B-17.5%)

50min = B-30%

55min = B-100%

carotenoid detection = 445nm

injection volume = 10 mL

HPLC was performed according to the above conditions and it was confirmed that fucoxanthin was present in the final concentrate (FIG. 2).

refine

The final extract identified as the fucoxanthin fraction was purified using CPC (Centrifugal partition chromatography) over primary and secondary, and fucoxanthin having a purity of 95% or more was extracted (Table 1).

The fucoxanthin stabilized by the method of the present invention can be used to produce an anti-obesity functional food or an anti-obesity functional cosmetics, which is a very useful invention in the cosmetic and processed food industries.

Claims (2)

Adding to 0.1% to 5.0% of vitamin C by weight based on the weight of annual fresh brown algae collected in March to May;
Extracting and removing chlorophyll from the brown algae using an organic solvent; And
A method for purifying stabilized fucoxanthin comprising the step of removing the alcohol by concentrating the obtained fucoxanthin fraction and then using a nonpolar organic solvent.
The method according to claim 1,
The method for purifying stabilized fucoxanthin further comprising the step of adding the same amount of tocopherol or cyclodextrin to the fucoxanthin obtained.

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