JP2005281397A - Polysaccharide obtained from tegmen of unicellular algae - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To readily obtain an agar-like polysaccharide from an algae without collecting secretion product from a unicellular algae of the genus Chlorella, or without extracting from other unicellular alga. <P>SOLUTION: The polysaccharide constituting a tegmen separated from the unicellular algae belonging to the Pelagophyceae is obtained by using the unicellular algae belonging to the Pelagophyceae as the unicellular algae. The polysaccharide can be formed into a powder by drying the polysaccharide. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a polysaccharide obtained from a unicellular alga coat belonging to the Pelagophyceae that can be used, for example, in water purification agents, plastic raw materials or cosmetics, and a method for producing the same.

  It has been conventionally known that polysaccharides such as agar are generally obtained from means such as extraction with hot water from multicellular algae such as red algae plants, amanori or funori.

  A polysaccharide obtained from unicellular algae and a method for producing the same are obtained by culturing chlorella unicellular green algae in a culture solution and purifying the supernatant of the culture solution, Polysaccharide produced extracellularly by unicellular green algae belonging to the genus, that is, a polysaccharide secreted from algal cells, exhibiting antitumor activity, and containing 80% by weight or more of galactose in total neutral sugar Is known. (See Patent Document 1)

  The polysaccharide produced by the single-cell green algae of the genus Chlorella (polysaccharide secreted from the cells) is recognized as a short polysaccharide having a molecular weight of 15,000 to 25,000. It can be separated into chlorella cells.

  Further, the single-celled algae belonging to the haptophyte family are used as the unicellular algae, and the polysaccharide technology obtained by drying the outer shell peeled off from the haptophyte family to form a powder is the same inventor as the present invention. The invention is publicly known. (See Patent Document 2)

JP-A-6-248003 JP 2004-27092 A

  Thus, the polysaccharide is generally obtained by means such as extraction with hot water from multicellular algae, and the polysaccharide or haptophyte envelope secreted from the unicellular green algae of the genus Chlorella is used. The technology of polysaccharides dried and powdered is known, but it is not known to obtain polysaccharides from other unicellular algae.

  In addition, when trying to obtain a polysaccharide from the envelope of many unicellular algae such as Chlorella, most of the envelope is integrated with the unicellular algae itself, that is, to give the unicellular algae stickiness. In general, it is difficult to separate the envelope from the unicellular algae because it exists in a state that grows around the unicellular algae. Is not completely separated, but also pulverizes the unicellular algae itself, so that the obtained polysaccharide contains impurities of the algae itself.

  Therefore, if the agar-like polysaccharide can be easily obtained from the algal body in addition to collecting the secretion from the single-celled green algae belonging to the genus Chlorella or extracting it from other single-celled algae, it is highly useful for industrial use. The present invention was completed by paying attention to the above.

  As a specific means for solving the problems of the conventional examples described above, the present invention is a polysaccharide constituting a unicellular algae, which is a polysaccharide constituting an envelope peeled from a unicellular algae belonging to the class Pelagogae. The polysaccharide obtained from the envelope of the unicellular algae is provided.

  In the present invention, the polysaccharide is dried to form a powder; the polysaccharide is mainly composed of glucose and xylose.

  When a general unicellular algae is used, it is very difficult to separate the envelope from the unicellular algae. The algae has a relatively thick envelope, and it has been found that only the envelope can be easily separated by heating and / or acidifying the single-cell algae.

  And about the polysaccharide obtained from the jacket of the unicellular algae concerning this invention, and its manufacturing method, put the unicellular algae which belong to Pelagophyceae in the required amount of water, and mix or stir to produce an algal suspension. Then, this is heated and / or acidified to peel off the outer shell, separated into single cell algae residue and outer filtrate by continuous filtration means or centrifugal separation means, and the outer filtrate is dried to a powder. Thus, an agar-like polysaccharide can be easily obtained from an algal body, and can be obtained from a specific single-cell algae, and the single-cell algae are easy to cultivate, culture and harvest, and are produced. The powdered polysaccharide is easy to store and transport.

  The polysaccharide obtained from the envelope of the unicellular algae according to the present invention is a polysaccharide obtained by drying the envelope peeled from the unicellular algae belonging to the Pelagophyceae to a powder, which is mainly composed of components of glucose and xylose It has an excellent effect that it can be used as a water purification agent, plastic raw material, cosmetics, etc., and can also be used as a general polysaccharide material substantially the same as cellulose or hemicellulose in pulp.

  And since the unicellular algae belonging to the Pelagophyceae used in the present invention can be easily cultivated by means such as aquaculture by photosynthesis, the polysaccharides separated therefrom are not depleted, and low pollution biodegradation It can be supplied as a natural resource.

Next, the present invention will be described in detail based on specific embodiments.
The polysaccharide obtained from the unicellular algae envelope according to the present invention (named by the inventor as PELAGOSE) is obtained by separating a relatively thick envelope of unicellular algae belonging to the class Pelagogae. . As the unicellular algae belonging to the Pelagophyceae, naturally occurring unicellular algae can be used, but it is preferable to use cultured or cultivated unicellular algae in consideration of a stable supply.

  As the culture or cultivation method, an artificial cultivation pond having a required size can be created, and clean seawater can be drawn into the cultivation pond for cultivation. For example, if the size of one artificial pond is about 100 m long x 40 m wide x 0.5 m deep for the convenience of management, and 30 days are required for culturing or cultivating single cell algae, , 30 cultivation ponds are made and seeded algae are inoculated to the 30 cultivation ponds one by one every day, and from the cultivation pond after 30 days, i.e., one by one in turn. The cultivated unicellular algae can be harvested. From the experimental data of the present invention, it is possible to produce 100 Kg of powdered polysaccharides from one cultivation pond, create 30 cultivation ponds, and harvest single cell algae from one cultivation pond in order every day. 100 kg of powdered polysaccharides can be continuously produced every day.

  Harvested unicellular algae are mixed with the required amount of water to produce an algae suspension. At this time, before the unicellular algae are mixed in water, the unicellular algae may be spun down to remove most of the seawater, and this may be mixed and suspended in water. Even after the mixture is mixed or stirred to produce an algae suspension, the remaining salt of the seawater may be removed by centrifugal precipitation or filtration.

  By heating and / or acidifying the algae suspension produced by removing the salts, the relatively thick envelope surrounding the unicellular algae belonging to the Pelagophyceae can be completely peeled off. It is.

  As this heat treatment, for example, the container containing the algae suspension may be boiled, and the temperature of the algae suspension may be raised to 75 ° C. or higher, preferably about 95 ° C. It is maintained for 5 minutes and then allowed to cool. Alternatively, the algae suspension may be passed through a pipe submerged in hot water.

  In addition, as the acidification treatment, for example, a strongly acidic substance or the like may be added to the algae suspension, and the algae suspension may be adjusted to pH 2 or less, and preferably maintained at pH 1 or less for about 5 minutes, Thereafter, an aqueous caustic soda solution or the like is added to neutralize the algal suspension. As this strongly acidic substance, for example, concentrated hydrochloric acid or the like can be used.

  In this way, after the algae suspension is subjected to the treatment of peeling the single-cell algae, the algal suspension is subjected to a continuous filtration means or a centrifugal separation means, and the unicellular alga body residue and the cover filtrate are removed. And can be separated.

  In the separated envelope filtrate, only the envelope peeled off from the periphery of the unicellular algae is present, and the unicellular alga bodies themselves are not included. An agar-like polysaccharide can be easily obtained from unicellular algae other than the chlorella unicellular green algae.

  The polysaccharide in the outer filtrate can be used as it is depending on the application, but it is preferable to dry the outer filtrate to form a powdered polysaccharide. Thus, by making a polysaccharide powder, the polysaccharide can be easily stored and transported.

  Examples of a method for drying the outer filtrate to form a powder include spray drying or freeze drying. Further, a solution obtained by concentrating the outer filtrate with a rotary evaporator or the like may be dried by the same spray drying or freeze drying.

Below, an example of the method of manufacturing a polysaccharide from the jacket of a unicellular algae is shown.
In this Example 1, unicellular algae belonging to the order of Chromophyta Pelagophyceae Sarkinochrysidales collected from Miyakojima (Pulvinaria (same genera as Chrysoreinhardia in the phylogenetic analysis by 16SrRNA)) ) Was used after culturing. This single-cell algae has a polysaccharide outer coat of about 5 to 10 micrometers in thickness on the surface of an algal body of about 5 micrometers in diameter.

  In this culture, an agar medium is prepared by adding a nutrient salt to an artificial seawater mixture (Aquamarine (registered trademark): Hachishu Pharmaceutical), and the seed algae of the unicellular algae is inoculated on the agar medium, The seed algae on the agar medium were cultured with shaking in a conventional manner in 50 ml and 500 ml Erlenmeyer flasks, and cultured with aeration and stirring in a 100 liter tank.

  The culture conditions were such that the temperature was approximately 20 ° C., the light period (approximately 2000 lux) was set to 16 hours, and the dark period was set to 8 hours, and the cells were cultured for 30 days. After 30 days, single cell algae cultured by filtering and concentrating the artificial seawater in the 100 liter tank were collected by a continuous filter using hollow fiber (manufactured by Kuraray, MS-8102-VG). The wet weight of the collected single cell algae was about 500 grams.

  The collected single-cell algae were centrifuged (8000 × g, 10 minutes), mixed with 2 liters of water to form an algae suspension, and further centrifuged to remove salts in the medium. .

  This algae suspension of unicellular algae is heated and maintained at a temperature of about 95 ° C. for about 5 minutes to peel off the relatively thick envelope surrounding the unicellular algae, and then left to reach about room temperature. Allow to cool.

  In this way, the algae suspension from which the outer shell existing around the unicellular algae is peeled is separated from the unicellular alga bodies (precipitation residue) and the supernatant (light yellowish brown transparent) by a continuous filter or a centrifuge. The supernatant liquid, that is, the outer filtrate, was collected.

  The collected outer filtrate was concentrated using a rotary evaporator (Tokyo Rika Kikai, N-11), and then dried using a flash evaporator (Tokyo Rika Kikai, SZ-1000) to obtain a powder. At this time, the yield of the obtained powder was approximately 14 grams per 100 liters of medium (approximately 500 g of wet single cell algae).

  Table 1 shows the results of analyzing the chemical components of the powder thus obtained.

  In this Example 2, a strongly acidic substance is added to the algae suspension in place of the process of removing the outer shell of the single-cell algae by the heat treatment in Example 1 (maintaining a temperature of about 95 ° C. for about 5 minutes). Then, after maintaining at pH 2 or lower, preferably pH 1 or lower for 5 minutes, the only difference is that a step of adding a caustic soda aqueous solution to return to neutrality is performed, and other treatments such as culture, centrifugal precipitation, continuous Since processes such as filtration, centrifugation, and drying are the same as those in the first embodiment, detailed descriptions thereof are omitted.

When the chemical component of the sugar in the acid hydrolyzate obtained in Example 1 and Example 2 was analyzed, the result of Formula 1 was obtained.
[Formula 1]
Glucose: xylose = 1: 1

  As the saccharides in Table 1, almost no saccharides other than the two types of glucose and xylose were detected. Moreover, in the manufacturing method which concerns on this invention, it was hardly decomposed | disassembled by available sugar hydrolase.

  Moreover, when the process by an acid was performed beforehand, it turned out that the ratio in which ash content is contained is reduced significantly to 20% or less. However, since it is complicated to neutralize a large amount of algae suspension after acid treatment and further desalinate, the reduction of ash content is preferably included in the subsequent step. .

  Furthermore, in the obtained polysaccharide, it was confirmed that the molecular weight exceeds about 1.5 million, and about 3% of protein is mixed.

  Since the polysaccharide obtained in the present invention is mainly composed of components of glucose and xylose, it can be used, for example, in water purification agents, plastic raw materials, cosmetics, etc., and cellulose and hemicellulose in pulp It can be used as a general material in substantially the same manner as above.

  That is, when the obtained powdered polysaccharide is dispersed in water and mixed, it can be used as a water purification agent for adsorbing and precipitating impurities contained in water. Moreover, the polysaccharide which consists of glucose and xylose can be used also as an alternative raw material of a plastic raw material. Furthermore, the polysaccharide has antibacterial properties. When this polysaccharide is mixed with cosmetics and the like, adverse effects on the skin due to various bacteria can be prevented depending on the part where the cosmetics are used.

Claims (3)

A polysaccharide constituting a unicellular algae,
A polysaccharide obtained from the envelope of a unicellular alga, which is a polysaccharide constituting the envelope peeled from a unicellular algae belonging to Pelagophyceae. The polysaccharide is
The polysaccharide obtained from the envelope of the unicellular algae according to claim 1, wherein the polysaccharide is dried to a powder. The polysaccharide is
The polysaccharide obtained from the unicellular algae envelope according to claim 1 or 2, wherein the polysaccharide is mainly composed of glucose and xylose.