JPH11192081A - Collagen molding and its preparation - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for preparing a collagen molding neither shrinking nor distorting even if it is brought into contact with a physiological salt solution. SOLUTION: A solute composition except collagen in a collagen solution is equilibrated into a state capable of gelatinizing collagen and collagen is gelatinized to prepare a collagen molding. Preferably the collagen solution is brought into contact with a physiological salt solution through a semipermeable membrane capable of passing other solutes but not collagen so that the physiological salt solution is equilibrated to gelatinize collagen. The collagen uniformly gelatinized under physiological salt conditions is obtained by gelatinizing collagen while equilibrating the solute composition in the collagen solution with the physiological salt solution.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to a method for producing a collagen molded article. Specifically, for use as a substrate for culturing cells or tissues, skin wounds such as burns, wounds, pressure ulcers or skin ulcers, to reconstruct or treat the epidermis and defective tissues including the epidermis early. The present invention relates to a collagen molded article used for cultured skin used for the above.

[0002]

2. Description of the Related Art In recent years, a molded product of collagen has been used as a substrate for cell culture or an implant for cultured skin or the like. Collagen molded articles have low antigenicity, good biocompatibility, and good physical strength, and are attracting attention as materials suitable for the above-mentioned applications.
Among such collagen molded products, a sponge-shaped molded product is often produced as a material suitable for a wide range of uses. Such a sponge-like molded body is usually produced by the following method. The first method is to prepare an acidic solution of collagen, gel the collagen solution in an ammonia atmosphere, wash and remove ammonium salts present in the system as needed, and then freeze and dry the solution. This is a method in which a sponge-like body is formed, and crosslinking is performed by UV irradiation. In the second method, the gelation step is performed by directly mixing the collagen acidic solution with a neutral solution and / or a basic solution such as a phosphate buffered saline solution to perform gelation.
The other method is the same as the first method. In the third method, the gelation step is performed by preparing a neutral collagen solution at a low temperature using a neutral solvent such as a phosphate buffered saline solution and heating the mixture to gel, and performing the other steps. This is a method performed in the same manner as the first method.

[0003]

However, it is known that the collagen molded article obtained by the first method gradually shrinks in the course of its use under normal physiological conditions. The morphological change and physical property change due to shrinkage have caused not only stable cell culture but also inconvenience in producing implants such as cultured skin. In the second method, a pH and a buffering capacity suitable for gelation are imparted by mixing with a neutral solvent and / or a basic solvent added to the collagen acidic solution. In order to obtain a pH and a buffering capacity suitable for gelation, it is necessary to use a large amount of the neutral solvent and / or the basic solvent. As a result, it is difficult to obtain a collagen gel having a desired concentration. On the other hand, if a high-concentration neutral solvent or basic solvent is used to reduce the decrease in collagen concentration during gelation, uniform gelation is difficult due to the high viscosity of the collagen acidic solution. In the third method, it is difficult to produce a collagen gel having a high concentration even by this method because collagen has low solubility in a neutral solvent such as a phosphate buffered saline at a low temperature. Therefore, a novel collagen molded article and a method for producing a collagen molded article that do not cause such a problem have been desired.

[0004]

Means for Solving the Problems When the collagen solution is gelled, the collagen solution is equilibrated with a physiological salt solution to form a gel. The present inventors have found that a collagen molded body produced through this process can be produced in a homogeneous state, and that the collagen molded body produced through this process does not undergo remarkable shrinkage even under physiological conditions. Thus, the present invention has been completed.

[0005] The present invention is a method for producing a collagen molded article by gelling collagen by equilibrating a solute composition other than collagen in a collagen solution to a state where collagen can be gelled. According to the present invention, a solute composition other than collagen in a collagen solution (hereinafter referred to as the present solute composition) is equilibrated to a state where collagen can be gelled. In other words, the present solute composition surrounding the collagen molecule is gradually shifted to a state where the collagen can be gelled. Therefore, a homogeneous collagen gel can be obtained. Further, gelation under the conditions of collagen concentration and electrolyte, which has not been achieved by the conventional method for producing a collagen gel, becomes possible, and a collagen gel having an unprecedented collagen concentration and properties can be obtained. Such a collagen gel is used as it is as a collagen molded article, or freeze-dried or the like to obtain a collagen molded article of another embodiment. A collagen molded article obtained through such a gel, like the gel,
It is possible to obtain a collagen molded article that is homogeneous and has an unprecedented collagen concentration and properties.

In the present invention, the collagen solution is brought into contact with a physiological salt solution through a semipermeable membrane (hereinafter, referred to as the present semipermeable membrane) which does not allow collagen to pass through but allows other solutes to pass through. In a preferred embodiment, the gel is formed by equilibration with a typical salt solution. By using the present semipermeable membrane, the gel can be easily equilibrated into a gelable state, and can be gelled without greatly reducing the collagen concentration of the collagen solution, and a gel having a desired collagen concentration can be obtained. When the present solute composition in a collagen solution is gelled while being equilibrated with a physiological salt solution, a collagen gel which is uniformly gelled under physiological salt conditions is obtained. For this reason, a collagen molded article which does not shrink or distort even when contacted with a physiological salt solution is obtained.

Further, in the present invention, the collagen solution is brought into contact with a physiological salt solution through a collagen gel membrane obtained by gelling the surface of the collagen solution to equilibrate with the physiological salt solution to gel. Is also a preferred embodiment. The collagen gel membrane is a semipermeable membrane that allows other solutes to pass through without passing through collagen, and is included in the present semipermeable membrane. In particular, according to this embodiment, the gel is easily equilibrated and gelled.

[0008] The present invention is also a collagen molded article obtained by equilibrating a collagen solution with a solute composition other than collagen in the collagen solution to a state where collagen can be gelled to gel collagen. Also,
By bringing the collagen solution into contact with a physiological salt solution through a semipermeable membrane that does not allow the passage of collagen but allows the passage of other solutes, the solute composition other than collagen in the collagen solution is equilibrated to the physiological salt solution. It is a collagen molded article obtained through gelation. Further, the collagen solution is brought into contact with a physiological salt solution via a collagen gel membrane obtained by gelling the surface of the collagen solution to form a collagen solution obtained through equilibration and gelation with the physiological salt solution. Body. In these collagen molded articles, it is a preferred embodiment that the area retention of the molded article after immersion in a physiological salt solution is 85% or more. Further, in a preferred embodiment, the collagen molded article is any one of a cell culture substrate, a cultured skin substrate, and a wound dressing. In a preferred embodiment, the skin is a cultured skin using the above-mentioned collagen molded body as a culture substrate.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to embodiments. The present invention is characterized in that when a collagen solution is gelled, the present solute composition is equilibrated to a state where collagen can be gelled by using a desired gelling solution. That is, according to the present invention, the environment in which collagen is present is changed from a state in which collagen is dissolved to a state in which it can be gelled. As a result, a collagen gel and a collagen molded article under desired conditions can be obtained.

(Collagen Solution) The collagen solution contains at least collagen as a solute. As collagen constituting a collagen solution, it is already widely used medically and various types are commercially available. In the present invention, these can be used without particular limitation. Preferably, collagen is extracted from bovine or porcine skin or tendons because of its easy availability and high denaturation temperature. Furthermore, when it is necessary to further reduce the antigenicity and enhance safety, atelocollagen from which the telopeptide is removed as much as possible by treating the collagen with a protease such as pepsin or the like is used. further,
Various types of collagen are appropriately used depending on the use of the collagen gel or molded article. For example, in order to add the function of the dermis to cultured skin, I close to the main constituent of the dermis
It is preferable to use the type III and the type III alone or in combination.

The collagen solution can be used irrespective of its liquidity (pH). However, it is preferable that collagen is dissolved in a solvent capable of dissolving it at a high concentration.
The acidic solution is preferable in that a solution having a high collagen concentration can be prepared. In addition, the acidic solution is preferable in that it is convenient to gel while equilibrating with a neutral salt solution or a physiological salt solution. Particularly preferably, an acidic solution of atelocollagen can be used. In order to prepare an acidic solution of collagen, hydrochloric acid, citric acid, lactic acid and the like are usually used, but other inorganic acids and organic acids can be used without particular limitation. However, it is preferable that the obtained collagen gel or molded article does not show toxicity to a living body or a culture system. The pH can be appropriately selected within a range of less than 7, but is preferably 5 or less, more preferably 4 or less in consideration of collagen solubility. Further, in consideration of stability against denaturation, it is preferably 2 or more, more preferably 3 or more. The ionic strength is not particularly limited as long as gelation in the equilibration step can be completed. The collagen concentration is preferably adjusted to 0.05 w / v% or more, more preferably 1 w / v% or more. Also, 2w /
It is preferable to adjust it to v% or less.

[0012] The collagen solution may contain another polymer that forms a gel together with collagen. Specifically, it is a biocompatible polymer, a bioabsorbable polymer, a biodegradable polymer, and more specifically, gelatin, hyaluronic acid, chitin, chitosan, and mucopolysaccharide. Synthetic polymers such as saccharides, polylactic acid, and polyglycolic acid, or copolymers thereof, high water-containing polymers such as polyhydroxyethyl methacrylate, and proteins such as fibrin and albumin can be mixed.

(Equilibration of the present solute composition in the collagen solution) In the present invention, in order to equilibrate the present solute composition in the collagen solution to a state in which collagen can be gelled, the collagen solution is not allowed to pass through the collagen solution. It is preferable to equilibrate by contacting the gelling solution via the present semipermeable membrane or collagen gel membrane through which the solute can pass.

(Gelling Solution) The gelling solution may be any one that can form a state in which collagen can be gelled on the collagen solution side in the process of equilibrating the present solute composition or in a state where equilibration is completed. . That is, at any stage until the present solute composition is completely equilibrated, on the collagen solution side, pH, ionic strength, etc.,
What is necessary is just to be able to provide the solution conditions which can gelatinize collagen. The composition of the gelling solution is set in consideration of the collagen concentration on the collagen solution side, the ionic strength, the pH, the buffering property, and the like, and is appropriately set according to the state in which the gelation is desired. . Preferably pH
Is set to 6-9.

In order to form a collagen gel through equilibration, the gelling solution preferably has a neutral pH. Further, a neutral salt solution is more preferable. When the present solute composition in a collagen solution is equilibrated with a neutral salt solution to a neutral salt solution and gelled, a collagen gel gelled under neutral salt conditions or under conditions similar thereto is obtained. The neutral salt solution used in the present invention is a salt solution having a pH in a neutral region. Examples of such a neutral salt solution include solutions of various salts such as sodium chloride and potassium chloride. Preferably, the neutral salt solution has a pH buffering capacity.

[0016] More preferably, the gelling solution is a physiological salt solution. When the present solute composition of the collagen solution is gelled while being equilibrated with a physiological salt solution with a physiological salt solution, a collagen gel gelled under physiological salt conditions or under conditions similar thereto is obtained. Such a collagen gel suppresses contraction even when it comes into contact with a medium such as a physiological salt solution or the like, which is prepared to maintain the survival of cells, or a living body.

The physiological salt solution used in the present invention is a salt solution having a pH and an osmotic pressure suitable for cell survival. Examples of such a physiological salt solution include physiological saline (0.9% NaCl aqueous solution), and K ⁺ ,
A salt solution having a composition to which several main ions in a cell solution such as Ca ²⁺ are added can be given. Na ⁺ , K ⁺ , Ca ²⁺ , M
A balanced salt solution, which is a salt solution prepared so as to maintain the equilibrium of g ²⁺ ions or further added with a buffer system so as to maintain a stable pH, may be mentioned. Also,
Various cell culture solutions can be mentioned.

Examples of the physiological salt solution include Ringer's solution, Ringer-Rock's solution, Tyrode's solution, Earl's solution, Hanks' solution, Rock's solution, Morgan, Morton, and Parker's synthetic culture No. 199, and Evans et al. Culture solution NCTC109, Park
er et al., CMRL-1066, McCoy et al., 5a, Ea
gle minimum essential culture, Dulbecco's modified Eagle culture,
Leibovitz L-15 culture, Ham synthetic culture F12, Moor
RPMI-1640 culture medium, Williams et al. Culture medium E, Katsut
a DM-160 culture of SFM-101 culture, RITC of Yamane et al.
80-7 culture medium, serum-free culture medium ASF104 (RITC62-8) Grace insect cell synthetic culture medium, Schneider culture medium, Mitsuhas
Examples of the culture solution include i-Maramorosh culture solution, Knop solution, and Gautheret culture solution. In the present invention, an electrolyte solution that is not the above-mentioned physiological salt solution but is similar to the above-mentioned physiological salt solution can be preferably used as well as the physiological salt solution.

(Equilibration) Equilibration with the gelling solution is preferably performed with the present semipermeable membrane. The semipermeable membrane is appropriately selected so as to obtain a desired equilibration rate. In the case where a composite collagen gel is prepared using other polymers together with collagen, it is preferable to use a semipermeable membrane that does not allow the other polymers to pass through as the present semipermeable membrane. In this case, the semipermeable membrane is appropriately selected in consideration of the molecular weight of the collagen used as well as the molecular weight of another polymer.

[0020] Equilibration is also preferably performed with a collagen gel membrane. The same semi-permeability as the present semi-permeable membrane can also be obtained by the collagen gel membrane. Equilibration with a collagen gel membrane usually involves gelling only the surface of the collagen acidic solution to form a collagen gel membrane, and through this collagen gel membrane, the collagen acidic solution inside the membrane and the outside of the collagen gel membrane. This is performed by contacting with a gelling solution. Such a collagen gel film can be obtained by exposing the surface of the collagen acidic solution to an ammonia atmosphere for a short time. According to the collagen gel membrane,
There is an advantage that it is not necessary to use an expensive semipermeable membrane. At this time, the thickness of the collagen gel membrane is not particularly limited, and is appropriately selected so as to obtain a desired equilibration speed. The selection is made in consideration of the molecular weight of collagen as a gel constituent molecule or the molecular weight of another polymer.

As described above, when equilibration is performed by contacting the gel solution with the gel solution through the semipermeable membrane or the collagen gel membrane, the collagen concentration of the collagen solution is almost maintained, and the collagen can be gelled. Therefore, a gel having a desired collagen concentration can be obtained.
In particular, a gel with a high collagen concentration can be obtained. The temperature in the equilibration may be any temperature at which collagen is not denatured. It is known that collagen fibrosis is accelerated by heating (generally up to about 37 ° C.). Therefore, upon equilibration, the system containing the collagen solution and the gelling solution can be heated in the range of 25 to 37 ° C. as long as the collagen is not denatured or the gelation of the collagen is not hindered. . However, until the present solute composition reaches the desired gelling conditions, the temperature is kept below 25 ° C. in order to avoid denaturation of collagen as much as possible, and 25 to 37 when the desired gelling conditions are obtained by equilibration. It is preferred to heat to ° C.

When a neutral collagen solution is used as the collagen solution, gelation is likely to occur, so that the equilibration is performed at a temperature as low as possible. In addition, during equilibration or gelation, ionic strength, pH, temperature, collagen concentration, properties of semipermeable membrane, thickness of collagen gel membrane, etc. are adjusted to adjust equilibration time, time until gelation, gel strength. And the properties of the gel can be adjusted. The ionic strength, pH and the like are mainly adjusted in the gelling solution. Collagen concentration is adjusted in the collagen solution.

The obtained collagen gel can be used as it is as a gel-like collagen molded article for various uses. Further, the form of the gel-like molded article can be selected according to the use of the molded article, such as a film, a rod, a sphere, a spindle, and a cylinder. Further, the gel-like collagen molded article can be dried or freeze-dried to obtain a collagen molded article such as a dried molded article or a sponge-shaped molded article. In these various molded articles, crosslinking by ultraviolet irradiation or gamma-ray irradiation or crosslinking by a chemical reagent is possible.

If the collagen gel is gelled under neutral or near-neutral conditions, a collagen gel or a collagen molded article adapted in advance to neutral conditions can be obtained. When the collagen gel is gelled under physiological conditions or under conditions similar thereto, a collagen gel or a collagen molded article that has been adapted to physiological conditions in advance is obtained.

When various collagen molded articles obtained by the method of the present invention are immersed in a physiological salt solution, the area of the molded article in the initial state (initial area) and the area of the molded article after immersion in the physiological salt solution are measured. When the area (equilibrium area) of the molded article in a state where the change is almost eliminated and the ratio (%) of the equilibrium area to the initial area is defined as the area retention rate of the collagen molded article, the collagen molded article of the present invention is: 8
It has an area retention of 0% or more, preferably 85% or more, more preferably 90% or more.
The initial area of the collagen gel is the area of the molded body before immersion in the physiological salt, and the initial area of the collagen molded body obtained by drying the collagen gel is that the collagen molded body before immersion in the physiological salt solution absorbs water. It refers to the area in the dry state that has not been done. In addition, the initial area and the equilibrium area in calculating the area retention may be not only the entire area of the collagen molded article but also a part of the area that can be associated with each other.

These various molded articles are conventionally used for various applications. In particular, a culture substrate for culturing cells, tissues, organs or organs, a wound covering material, a hemostatic material, a contact lens, an artificial cornea, a corneal bandage material, various transplant materials, various tissue regeneration materials, artificial valves, DDS (Drug Delive)
ry System), used as a material. Preferably,
The collagen molded article of the present invention, which is used as a cultured skin substrate and in which dermal cells or epidermal cells are cultured, is used as cultured skin.

In particular, when a collagen molded article obtained through equilibration and gelation in a physiological salt solution is used as a culture substrate for cells, etc., the substrate during culture in a physiological salt solution is Shrinkage is suppressed. Even when a cultured skin is formed by using it as a substrate for culturing skin cells, contraction of the substrate during culturing in a physiological salt solution and contraction when applied as cultured skin are suppressed. Further, when used for a wound dressing such as a burn, a wound, a pressure sore or a skin ulcer, the contraction of the wound dressing during use is suppressed.

[0028]

According to the present invention, since a collagen solution is equilibrated with a solute composition other than collagen in a collagen solution to a state where collagen can be gelled, collagen is gelled under non-conventional conditions. Provided is a collagen molded article.

[0029]

EXAMPLES Hereinafter, the present invention will be described specifically with reference to examples. It should be noted that the present invention is by no means limited to these examples. (Example 1) Preparation of atelocollagen gel using the present semipermeable membrane In this example, 50 ml of a 1 w / v% atelocollagen hydrochloric acid solution was maintained in a non-gelled state while a semipermeable membrane (regenerated Cellulose tube: plane width 100 mm, length about 200 mm, molecular weight cut off 6000
8000), and a metal frame provided with holes of about 120 mesh size in total.
It was fixed so as to form a substantially rectangular parallelepiped of about 90 mm × about 200 mm. The semipermeable membrane tube in which the collagen solution is sealed contains 2 L of a phosphate buffer (1 liter contains 8000 mg of sodium chloride, 200 mg of potassium chloride, 1150 mg of sodium monohydrogen phosphate, and 200 mg of potassium dihydrogen phosphate. ) And gelled at 37 ° C. for about 72 hours.
As a result, a white atelocollagen gel was obtained.

The gel was released from the semipermeable membrane tube, cut into a disk having a diameter of 51 mm, and immersed in the phosphate buffer for 7 days. The ratio of the bottom area (equilibrium area) after immersion for 7 days to the bottom area (initial area) before immersion in this gel was 100%.

(Example 2) Preparation of atelocollagen sponge-like body using this semipermeable membrane An atelocollagen gel gelled by the same method as in Example 1 was freeze-dried to obtain an atelocollagen sponge. The obtained sponge was released from the mold and immersed in the phosphate buffer for 8 days. The ratio of the bottom area (equilibrium area) after immersion for 8 days to the bottom area (initial area) before immersion in this sponge-like body was 95%.

(Example 3) Preparation of atelocollagen gel by preliminarily gelling the surface and then equilibrating with a gelling solution Polystyrene case (inner dimension 95 mm x 60 mm x 10 m
m) 15 ml of 1 w / v% atelocollagen hydrochloride acid solution
Was placed in an ammonia atmosphere for 6 minutes to gel only the surface. Next, the entire case was immersed in 2 L of the above-mentioned phosphate buffer solution and gelled at 37 ° C. for about 24 hours. As a result, a white atelocollagen gel was obtained.
The obtained gel was released from the mold and immersed in the phosphate buffer for 11 days. Bottom area (95 mm ×
The ratio of the bottom area (equilibrium area) after immersion for 11 days to the 60 mm portion (initial area) was 97%.

Example 4 Preparation of Atelocollagen Sponge by Preliminarily Gelling the Surface and Equilibrating with Gelation Solution Polystyrene Case (Inner Size: 95 mm × 60 mm × 10 m)
m) 15 ml of 1 w / v% atelocollagen hydrochloride acid solution
Was placed in an ammonia atmosphere for 3 minutes to gel only the surface. Next, the entire case was immersed in 2 L of the above-mentioned phosphate buffer solution, and gelling was performed at 37 ° C. for about 19 hours. As a result, a white atelocollagen gel was obtained.
This gel was freeze-dried to obtain an atelocollagen sponge-like body. The obtained atelocollagen sponge was released from the mold and irradiated with ultraviolet rays to crosslink.

The entire atelocollagen sponge was subjected to a Dulbecco's Modified Eagle's Minimum Essential Medium (DMEM) (hereinafter, DMM) containing 10 v / v% fetal calf serum (FCS).
It is called EM (FCS). ) Dipped in 30 ml for 2 days. In this sponge-like body, the bottom area before immersion (9
The ratio of the bottom area (equilibrium area) after immersion for 2 days to the part corresponding to 5 mm × 60 mm (initial area) was 100%.

(Comparative Example 1) Preparation of atelocollagen gel using ammonia gas Polystyrene case (inner size 95 mm x 60 mm x 10 m
m) 15 ml of 1 w / v% atelocollagen hydrochloride acid solution
Was placed in an ammonia atmosphere for 2 hours to gel to obtain a white atelocollagen gel. Next, the gel was washed with water and released from the mold, and the whole was immersed in 2 L of the phosphate buffer for 10 days. In this gel, the ratio of the bottom area (equilibrium area) after immersion for 10 days to the bottom area (95 mm × 60 mm portion, initial area) before immersion was 67%.

(Comparative Example 2) Preparation of atelocollagen sponge-like body using ammonia gas Polystyrene case (inner size 95 mm x 60 mm x 10 m
m) 15 ml of 1 w / v% atelocollagen hydrochloride acid solution
Was placed in an ammonia atmosphere for 2 hours to gel to obtain a white atelocollagen gel. Next, after washing the gel with water, the gel was freeze-dried to obtain an atelocollagen sponge-like body. The obtained sponge-like body was released, and the whole was immersed in DMEM (FCS) for 2 days. In this sponge-like body, the bottom area before immersion (95 m
The ratio of the bottom area (equilibrium area) after immersion for 2 days to the part corresponding to mx 60 mm (initial area) was 76%.

Claims (9)

[Claims] 1. A method for producing a collagen molded article by gelling collagen by equilibrating a solute composition other than collagen in a collagen solution to a state where collagen can be gelled. 2. The method according to claim 2, wherein the collagen solution is brought into contact with a physiological salt solution through a semipermeable membrane that does not allow collagen to pass through but allows other solutes to pass through and equilibrate with the physiological salt solution to form a gel. 2. The method for producing a collagen molded article according to 1. 3. The collagen solution according to claim 1, wherein the collagen solution is brought into contact with a physiological salt solution via a collagen gel membrane obtained by gelling the surface of the collagen solution to equilibrate with the physiological salt solution and gel. A method for producing a collagen molded article. 4. A collagen molded article obtained by equilibrating a collagen solution with a solute composition other than collagen in the collagen solution to a state in which collagen can be gelled to gel the collagen. 5. The collagen solution is brought into contact with a physiological salt solution through a semipermeable membrane that does not allow collagen to pass through but allows other solutes to pass therethrough, so that the composition of the solute other than collagen in the collagen solution can be adjusted to the physiological salt solution. A collagen molded article obtained through equilibration with a salt solution and gelation. 6. The collagen solution is brought into contact with a physiological salt solution through a collagen gel membrane obtained by gelling the surface of the collagen solution, whereby the collagen solution is equilibrated with the physiological salt solution and gelled. Collagen molded body. 7. The method according to claim 4, wherein the area retention of the molded article after immersion in a physiological salt solution is 85% or more.
Gen molded body. 8. The collagen molded article according to claim 4, which is any one of a cell culture substrate, a cultured skin substrate and a wound dressing. 9. A cultured skin comprising the collagen molded article according to claim 4 as a culture substrate.