KR100210511B1 - Method for purifying sodium hyaluronate and apparatus used therein - Google Patents

Abstract

The present invention relates to a method and apparatus for easily recovering the sodium hyaluronate in high yield when it is purified, and the step of introducing an aqueous sodium hyaluronate solution and an organic solvent into a precipitation tank with a baffle is rotated with a shaker, and the inflow liquid has a certain height. When the sediment is reached, the sediment is transferred to a recovery tank equipped with a recovery network through a sediment discharge valve, recovering hyaluronic acid precipitated in the precipitation tank, and sodium hyaluronate from the precipitate transferred to the recovery tank. According to the method of recovering sodium hyaluronate of the present invention comprising the step of recovering the sediment through the sediment discharge valve of the recovery tank, the sodium hyaluronate of various molecular weights using various solvents may be It can be easily recovered in the precipitation tank in high yield.

Description

Method for purifying sodium hyaluronate and apparatus used therein

The present invention relates to a method for easily recovering it in high yield in a purification process of sodium hyaluronate and a device used therein.

Sodium hyaluronate is a polymer mucopolysaccharide found in metabolites of human connective tissue, eyeball, placenta, chicken crust, Streptococcus microorganisms, cataract surgery aids, degenerative arthritis drugs, surgical adhesion inhibitors, dry eye medicines and cosmetics. It is used. CPC (cetyl pyridinium chloride) or an organic solvent is mainly used to precipitate sodium hyaluronate in aqueous solution during the purification of sodium hyaluronate. Representative organic solvents include ethanol, methanol, isopropyl alcohol, acetone, and the like. The amount of organic solvent used for the sodium hyaluronate precipitation varies from case to case but is usually used in an amount of 1.5 to 4 times the volume of the aqueous sodium hyaluronate solution. Therefore, there is no problem in the case of small production, but the size of the settling tank becomes a problem when the production scale is large. For example, when using two volumes of ethanol to precipitate 50 l of sodium hyaluronate, 100 l of ethanol is required, which requires more than 150 l of vessel and a stirring device to stir it. In addition, when this precipitation process is used for the final stage of sodium hyaluronate purification, the vessel and agitator used for precipitation should be kept aseptic, and aseptic state is maintained even when sodium hyaluronate is recovered from the precipitate after stirring. This requires a separate sterile facility for this purpose. In addition, the size of the agitation and sedimentation tanks should vary according to the production scale, and the size of the aseptic equipment should be increased in proportion to the economic burden.

In Japanese Patent Laid-Open No. 2-142801, a device for precipitating, recycling, and stirring ethanol and sodium hyaluronate has been developed. When stirring by using the precipitated sodium hyaluronate sticks to the impeller, the recovery is not easy, there is a disadvantage that the labor load of the worker is increased and the degree of contamination is relatively increased. In addition, during the precipitation and recycling of sodium hyaluronate and ethanol, there is a problem in that the precipitated mass becomes large and the use tube is clogged.

Accordingly, in order to solve these problems, the Korean patent application No. 96-340 discloses an aqueous solution of sodium hyaluronate and ethanol as an organic solvent in a sedimentation tank with a baffle and stirred with a shaker to precipitate sodium hyaluronate. By reaching a certain height, the sediment can be discharged and a device for recovering the precipitated sodium hyaluronate can be developed.Therefore, there is no need to change the size of the sedimentation tank during mass production and eliminate the internal agitator such as the impeller. Loss of sodium hyaluronate was minimized.

However, with this device, the sediment should be discharged at the same rate as the inflow of the influent during the sodium hyaluronate precipitation, thus preventing the loss of sodium hyaluronate going through the sediment discharge valve and discharging the discharge line directly. It is not only contaminated because it is passed through, but it is applicable only to precipitation of high molecular weight sodium hyaluronate because it uses ethanol as organic solvent, and it is possible to precipitate low molecular weight sodium hyaluronate or to remove methanol, isopropyl alcohol, acetone, etc. When attempting to precipitate the sodium hyaluronate using an organic solvent, a problem that the recovery rate is rapidly reduced to 50% or less was found.

It is an object of the present invention to effectively precipitate and recover high molecular weight as well as low molecular weight sodium hyaluronate using other organic solvents other than ethanol while minimizing the possibility of loss and contamination of sodium hyaluronate through the discharge valve by eliminating this disadvantage. It is to provide a method and an apparatus used therefor.

1 is a schematic view showing an example of an apparatus used for the purification of sodium hyaluronate according to the present invention.

* Explanation of symbols for main parts of the drawings

10 sedimentation tank 11: sodium hyaluronate inlet valve

12 organic solvent inlet valve 13 air inlet and outlet valve

14: sediment discharge valve 15: sedimentation tank recovery cap

16: baffle 17: shaker

20: recovery tank 21: recovery network

22: sediment discharge valve 23: recovery tank inlet valve

24: recovery tank recovery cap 30: waste container

In order to achieve the above object, in the present invention, the aqueous solution of sodium hyaluronate and the organic solvent into the baffle sedimentation tank is rotated by a shaker, and when the inflow reaches 5 to 10 cm, the sediment is recovered through a discharge valve Recovering the sodium hyaluronate precipitated in the sedimentation tank, and recovering the sodium hyaluronate in the sediment transferred from the sedimentation tank to the recovery tank through the recovery tank and removing only the sodium hyaluronate precipitate. It provides a method for recovering sodium hyaluronate comprising the step of discharging through the sediment discharge valve of the recovery tank.

In addition, the present invention provides a sodium hyaluronate recovery device consisting of a precipitation tank and a recovery tank. Here, the settling tank is a plurality of baffles, sodium hyaluronate inlet valve, organic solvent inlet valve, sediment discharge valve, air inlet valve with a filter for adjusting the pressure in the vessel, installed on the bottom of the settler tank A shaker, a sedimentation tank recovery cap, the recovery tank including a recovery network, a sediment inlet valve, a sediment discharge valve and a recovery tank recovery cap.

Hereinafter, the present invention will be described in detail.

In the present invention, while turning the baffle sedimentation tank in a shaker operating at a constant speed, the aqueous solution of sodium hyaluronate and organic solvent are introduced and stirred effectively to precipitate sodium hyaluronate, and when the inflow reaches a certain height, the sediment discharge valve of the sedimentation tank Open the sediment containing some sodium hyaluronate to the recovery tank, recover the sodium hyaluronate precipitated in the sedimentation tank through the sedimentation tank recovery cap, and the recovery network of the recovery tank from the sodium hyaluronate containing sediment transferred to the recovery tank Sodium hyaluronate is recovered, and the precipitate is discharged through the precipitate outlet.

As an organic solvent for precipitation of sodium hyaluronate in the process of the present invention, ethanol, methanol, isopropyl alcohol, acetone or a mixed solvent thereof may be used.

According to the method of the present invention, because the precipitate is discharged while performing stirring, precipitation and recovery at the same time, the settling tank and the sterile facility can be maintained at a constant size regardless of the throughput. In addition, because baffles are used instead of an internal agitator such as an impeller or a magnetic bar, it is easy to settle and recover sodium hyaluronate and prevent loss due to adhesion. In addition, the cover of the settling tank and the upper part of the recovery tank is opened to facilitate recovery regardless of the size of sodium hyaluronate precipitate, and has a separate recovery tank equipped with a recovery network when using a solvent other than ethanol or low molecular weight sodium hyaluronate. Sedimentation can also minimize the loss of sodium hyaluronate through the discharge valve. In addition, the sedimentation tank and recovery tank can be separated from the waste container to reduce the possibility of contamination.

An example of the sodium hyaluronate recovery device of the present invention is shown in FIG. 1, and the device of the present invention will be described in detail with reference to this.

The apparatus of the present invention includes a settling tank 10 and a recovery tank 20, wherein the settling tank 10 has a sodium hyaluronate inlet valve 11, an organic solvent inlet valve 12, and an air inlet and outlet valve with a filtration filter ( 13), a sediment discharge valve 14, a sedimentation tank recovery cap 15, a baffle 16, and a shaker 17 provided at the lower end thereof, and the recovery tank 20 has a recovery network 21 and a sediment discharge. A valve 22, a settling liquid inlet valve 23, and a recovery cap 24 are provided.

As an aspect of the present invention, the sedimentation tank body and the recovery tank body may be formed of a cylindrical glass having a diameter of 100-400 mm, a height of 100-400 mm, the upper portion of the settling tank 10 and the recovery tank 20 is respectively the diameter It can be covered with detachable glass caps 15 and 24 which are 100-400 mm. A plurality of baffles 16 are attached to the inner wall and the bottom of the settling tank, for example, three on the side and four on the bottom to facilitate stirring of the inflow solution. The length of the side baffles is preferably 80-320 mm and the diameter of the bottom baffles is 50-200 mm. The shaker 17 is installed on the bottom of the settling tank, and the inflow of the inflow liquid in the settling tank 10 is performed by rotation thereof. The rotation speed of the shaker 17 is preferably 100-450 rpm. If the speed of the shaker is less than 100 rpm, the mixing effect is significantly reduced, the amount of sodium hyaluronate coming out of the discharge valve increases, and if it exceeds 500 rpm, it is difficult to perform a stable process. It is preferable that the diameters of the inflow valves 11, 12, and 23 and the discharge valves 14 and 22 be 5-20 mm. The recovery network 21 used in the recovery tank 20 is preferably made of stainless steel or Teflon, the pore size of the network is suitable 250-2000 ㎛. If the pore size is less than 250 μm, the coating may be blocked by sodium hyaluronate, preventing smooth recovery. If the pore size is larger than 2000 μm, the precipitate may escape through the net.

When the sodium hyaluronate precipitation and recovery device as described above is added to the aqueous solution of sodium hyaluronate and an organic solvent that has passed through a disinfection filter (not shown) at a ratio of 1: 1.5-4, the hyaluronic acid is carried out. It is possible to recover 4-5 g of sodium hyaluronate per 10 liters of aqueous sodium lonate solution (0.05-0.06%).

The present invention will be described in more detail with reference to the following examples. However, the scope of the present invention is not limited only to the following Examples.

Example 1

Two cylindrical glass vessels with a diameter x height of 230 x 180 mm were used as settling tanks and recovery tanks, respectively. Three settling tanks were installed at the side and four baffles at the bottom. The collection tank was equipped with a stainless steel mesh having a pore size of about 1 mm. Installed. Subsequently, the inlet valves 11 and 12 were charged with 0.05% (w / v) aqueous sodium hyaluronate solution and 95% ethanol and 99% methanol at a flow rate of 300 ml / min, 600 ml / min and 300 ml / min, respectively. ) And the shaker was rotated at a speed of 250 rpm. Agitation was facilitated thanks to the bottom baffle even after the solution had increased by at least 5-10 cm. When the solution reaches 5 to 10 cm, the discharge valve 14 is opened to introduce the sediment into the recovery tank at a rate of 1200 ml / min, and the sodium hyaluronate discharged together with the precipitate through the recovery network in the recovery tank is recovered. Only the precipitate was discharged through the discharge valve 22. The amount of sodium hyaluronate out through the outlet was higher than that of ethanol alone, but no sodium hyaluronate passed through the recovery tank. The time to process 50 liters of sodium hyaluronate was about 180 minutes. The entire upper part of the settling tank and the recovery tank can be opened, so that sodium hyaluronate can be easily recovered after the process. After 50 L treatment, about 23 g of sodium hyaluronate was obtained, which showed 92% recovery. The amount of sodium hyaluronate obtained through the recovery network was about 10% of the total recovered sodium hyaluronate.

Example 2

Precipitation and recovery process in the same manner as in Example 1, except that 0.1% (w / v) of low molecular weight sodium hyaluronate solution and 95% ethanol were added to the settling tank at a flow rate of 300 ml / min and 900 ml / min, respectively. Was carried out. While high molecular weight sodium hyaluronate forms agglomerates during ethanol precipitation, low molecular weight sodium hyaluronate is not formed as agglomerates, and a considerable amount is recovered through the discharge tank 14 through the discharge valve 14 together with the sediment. . After 20 liters of treatment, about 17 g of sodium hyaluronate was obtained, which showed 85% recovery. The amount of sodium hyaluronate obtained through the recovery network reached about 8g corresponding to 50% of the total recovered sodium hyaluronate.

Example 3

A precipitation process was performed in the same manner as in Example 1 by adding 0.05% (w / v) aqueous sodium hyaluronate solution and 99% methanol to a precipitation tank at a flow rate of 250 mL / min and 1000 mL / min, respectively. When the solution in the settling tank reached a certain height, the settling liquid discharge valve 14 was opened to discharge the settling liquid into the recovery tank at a rate of 1250 ml / min. When the solvent was used as methanol, sodium hyaluronate formed a precipitate in a form similar to when low molecular weight sodium hyaluronate was precipitated with ethanol, and a considerable amount of sodium hyaluronate passed through the outlet 14 together with the precipitate. It was recovered through the recovery network of the recovery tank. About 50 g of sodium hyaluronate was obtained by treating 50 L aqueous sodium hyaluronate solution, and sodium hyaluronate obtained through the recovery network was about 15 g, which was 68% of the total recovery.

Example 4

A precipitation process was performed in the same manner as in Example 1 by adding 0.05% (w / v) aqueous sodium hyaluronate solution and 95% isopropyl alcohol to the precipitation tank at a flow rate of 450 ml / min and 900 ml / min, respectively. When the solution in the settling tank reached a certain height, the settling liquid discharge valve 14 was opened to discharge the settling liquid into the recovery tank at a rate of 1350 ml / min. In the case where the solvent is isopropyl alcohol, the precipitation of sodium hyaluronate did not form agglomerates and all exited through the outlet 14 together with the precipitate. As a result, it was impossible to recover sodium hyaluronate in the sedimentation tank, and all could be recovered only through the recovery network of the recovery tank. 20 L was processed to recover 8.7 g of sodium hyaluronate.

As can be seen from the above results, by using the method and apparatus for recovering sodium hyaluronate of the present invention, sodium hyaluronate of various molecular weights is maintained at least 10% and at most 80%, while maintaining the aseptic state using various solvents. The recovery rate can be increased.

By using the method and apparatus for recovering sodium hyaluronate of the present invention, it is proved that the recovery rate of sodium hyaluronate of various molecular weights can be increased by at least 10% and at most 80% or more while maintaining aseptic conditions using various solvents. It became.

Increasing the recovery rate by minimizing the loss of sodium hyaluronate by recovering the sodium hyaluronate discharged with the precipitate using the recovery network by introducing the precipitate discharged from the sedimentation tank again into the recovery tank equipped with a recovery network, Using various solvents, sodium hyaluronate of various molecular weights can be easily recovered in high yield in a settling tank of any size regardless of its throughput.

Claims (5)

Injecting aqueous solution of sodium hyaluronate and organic solvent into the settling tank attached to the baffle and rotating it with a shaker.When the inflow reaches a certain height, the settling liquid is transferred to a collecting tank equipped with a recovering network through the settling discharge valve and precipitated in the settling tank. Recovering the sodium hyaluronate, and recovering the sodium hyaluronate from the precipitate transferred to the recovery tank through the recovery network and discharging only the precipitate through the precipitate discharge valve of the recovery tank. Recovery method of the. The method of claim 1, The organic solvent is ethanol, methanol, isopropyl alcohol, acetone or a mixed solvent thereof. The method of claim 1, A method of introducing a sodium hyaluronate aqueous solution and an organic solvent in a ratio of 1: 1.5 to 4. A plurality of baffles, sodium hyaluronate inlet valves, organic solvent inlet valves, filtration filters for pressure adjustment in the vessel are installed on the inner wall and bottom of the sedimentation tank. Precipitation tank equipped with; And a recovery tank including a recovery network, a precipitate inflow valve, a precipitate discharge valve, and a recovery tank recovery cap. The method of claim 4, wherein Apparatus characterized in that the pore size of the recovery network ranges from 250 to 2000㎛.

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