JP2019076070A - Porous scaffold for cells and uses thereof - Google Patents

Abstract

To provide porous scaffold substrates for cells with superior pore connectivity.SOLUTION: The invention provides a scaffold for cell culture with a defined porous structure comprising a polymer-containing matrix that determines the porous structure, where the matrix defines first pores of a first size communicating each other, and the third pores present on or near the inner surface of the first pores. The pore communication rate of the matrix may be 76% or more. The matrix may have a water absorption rate of 2000% or more or a porosity of 96% or more. Preferably, the first size being the average maximum width is 200-400 μm, the third size is 30-100 μm, and the second size is 100-170 μm.SELECTED DRAWING: None

Description

  The present specification relates to porous cell scaffolds and their use.

  Conventionally, porous cell scaffolds made of biocompatible polymers and the like have been used for producing three-dimensional structures by cells. One of the methods of producing such porous cell scaffolds is a method of forming pores corresponding to porogen in a polymer matrix using insoluble solid particles (porogen) called porogen-leaching method. In the porogen leaching method, in a solution in which a biocompatible polymer such as polylactic acid is dissolved in a non-aqueous solvent such as dioxane or chloroform, particles (porogen) insoluble in non-aqueous solvent such as carbohydrate or salt are mixed beforehand. It is a method of forming a porous structure in the polymer matrix by dissolving only the porogen with a solvent that dissolves the porogen after evaporating the non-aqueous solvent (Non-patent Document 1). The porogen-leaching method has an advantage that it can cope with complicated shapes and can form pores according to the size of the porogen.

Murphy et al., Tissue Eng. 2002, 8, 43-56

  However, in many cases, porous bodies obtained by the porogen leaching method often have independent pores whose pores are independent of one another, and the communication ratio is low in many cases. In the case of seeding cells on the surface of such a porous body, migration and proliferation of cells to the further inward direction of the porous body are likely to be impeded, and the intended cell structure is not necessarily obtained.

  The present specification provides a porous cell scaffolding substrate excellent in pore connectivity.

  The present inventors have been variously studying porogen leaching methods. Ice crystals grown from the surface of porogen or in the vicinity thereof are provided with a cavity derived from a connector formed by linking porogen. Succeeded in obtaining a porous material having a polymer matrix with pores derived from According to such porous materials, in order to provide pores derived from porogen, pores derived from the connecting portion of porogen and pores derived from ice crystals associated with porogen, high porosity and pore communication ratio We have found that we can satisfy This specification provides the following means based on such knowledge.

(1) defining a porous structure, comprising a matrix comprising a polymer,
A scaffold for cell culture, wherein the matrix defines a first pore communicating with each other and a third pore existing on or near an inner surface of the first pore.
(2) The scaffold according to (1), wherein the pore connection rate of the matrix is 76% or more.
(3) The scaffold according to (1) or (2), wherein the water absorption of the matrix is 2000% or more, or the porosity is 96% or more.
(4) The scaffold according to any one of (1) to (3), wherein the first size has an average value of maximum cross dimension of 200 μm to 400 μm.
(5) The scaffold according to any one of (1) to (4), wherein the third size of the third pore is such that the average value of the maximum cross dimension is 30 μm or more and less than 100 μm.
(6) (1) to (5), wherein the matrix at least partially has a frame and / or a wall defining a second pore, which is a communication hole between the first pore and the first pore The scaffold according to any one of the above.
(7) The scaffold according to (6), wherein in the second size, an average value of maximum crosswise dimensions is 100 μm or more and 170 μm or less.
(8) The polymer according to any one of (1) to (7), wherein the polymer includes at least one selected from polylactic acid, polyglycolic acid, a copolymer of polylactic acid and polyglycolic acid, and polycaprolactone. scaffold.
(9) Define a porous structure, comprising a matrix comprising a polymer,
A porous substrate defining a first pore of a first size in communication with each other, and a third pore existing on or near an inner surface of the first pore 10) A method for producing a porous substrate,
At least a part of a plurality of water-soluble particles which are water-soluble solids are mutually connected via water to obtain a connected structure of the water-soluble particles;
Preparing a base stock solution having the connection structure in a matrix stock solution in which a polymer is dissolved in a first liquid;
Providing a temperature condition that allows the first liquid and water to freeze to the base stock solution to obtain a frozen body obtained by freezing the base stock solution;
Sublimating the first liquid and the second liquid from the frozen body under reduced pressure conditions to obtain a dried body;
Removing the plurality of water soluble particles in the dried body;
A method comprising.
(11) The method according to (9), wherein the water-soluble solid is one or more selected from the group consisting of a salt and a derivative thereof and a sugar and a derivative thereof.
(12) The water-soluble solid according to (10) or (11), which is one or more selected from the group consisting of sodium hydroxide, potassium carbonate, magnesium chloride, calcium chloride and sodium chloride Production method.
(13) The polymer is one or more selected from the group consisting of polylactic acid, polyglycolic acid, a copolymer of polylactic acid and polyglycolic acid, and polycaprolactone, (10) to (12) The manufacturing method according to any one of the above.

FIG. 1 shows an overview of an example of the scaffold disclosed herein. It is a figure which shows a part of manufacturing process of a scaffold. It is a figure which shows a part of other manufacturing process of a scaffold. It is a figure which shows the SEM image of the porous substrate obtained by the Example. It is a figure which shows the image-analysis result based on the SEM image shown in FIG. It is a figure which shows the evaluation result about the porosity of the porous base material produced in the Example, and a water absorption. It is a figure which shows the evaluation result about the porosity of the porous base material produced in the Example, a water absorption, and a connection rate. It is a figure which shows the evaluation result as a scaffold for cell culture of the porous base material produced in the Example.

  The disclosure herein relates to porous cell scaffolds and uses thereof and the like. The porous cell scaffold disclosed herein (hereinafter, also simply referred to as the present scaffold) has a matrix containing a polymer. The outline of the matrix in this scaffold is illustrated in FIG.

  As illustrated in FIG. 1, the matrix 10 of the present scaffold 100 has a first pore 20 having a first size in communication with each other and a third size smaller than the first size, And a third pore 60 extending on and / or in the vicinity of the inner surface of the first pore 20. According to such a scaffold, since the first pores have a continuous cavity formed in communication with each other and the third pores 60 extending from the first pores 20, the high pore connection is achieved. Rate can be easily secured, and also cells can be attached to the inner surface of each pore 20, 60, and migration, proliferation, etc. based on the exertion of chemotaxis, etc., through each pore 20, 60, etc. It is possible to extend and extend, effectively promote cell culture, and is suitable, for example, for preparation of a transplant material and the like.

  Furthermore, the matrix 10 of the scaffold 100 can be provided with a second pore 40 as a communication hole obtained by connecting and communicating the first pore 20. By providing the second pores 40, a continuous cavity is formed.

  In addition, in this specification, it does not specifically limit with a "cell" and the well-known cell which can be culture | cultivated and proliferated can be mentioned. For example, animal cells, plant cells and the like can be mentioned. The animal cells may be cells that constitute tissues or organs of animals including humans. For example, various nerve cells such as central nerves and peripheral nerves may be mentioned, in addition to cells which may constitute or are derived from skin, bone, cartilage, ligament, muscle, trachea, esophagus, nose, blood vessels, pancreas, liver, etc. Be In addition, undifferentiated cells including various stem cells such as embryonic stem cells, pluripotent stem cells, and mesenchymal stem cells can be mentioned.

  As used herein, a "porous cell scaffold" is a scaffold for culturing cells. The porous cell scaffold can be, for example, a component (transplant material) of a material replacing at least a part of a tissue or organ of an animal including human or a material prosiding at least a part of the same. The porous cell scaffolds may be cells cultured in vitro and transplanted in vivo as scaffolds holding cultured cells, or they may be implanted in vivo to grow cells in vivo It may be a foothold.

  Hereinafter, this scaffold, its manufacturing method, etc. are demonstrated in detail.

(Porous cell scaffold)
(matrix)
The scaffold defines a porous structure and can comprise a matrix comprising a polymer. Hereinafter, description will be made with reference to FIG. 1 as appropriate. Although FIG. 1 exemplifies the present scaffold, the present scaffold is not limited to the one disclosed in FIG.

  The polymer constituting the matrix 10 of the scaffold 100 is not particularly limited, but a polymer having biocompatibility and / or bioabsorbability can be used. As such a polymer, for example, polylactic acid, polyglycolic acid, copolymer of polylactic acid and polyglycolic acid, synthetic polymer such as poly-ε-caprolactone, collagen, gelatin, cellulose, polyalginic acid, chitin, chitosan, starch And naturally occurring polymers such as hyaluronic acid, chondroitin sulfate, fibronectin and laminin. All of these polymers are biocompatible and bioresorbable. The polymers can be used alone or in combination of two or more.

  The matrix 10 in the scaffold 100 is a peripheral structure that defines a first pore 20, a second pore 40, and a third pore 60 described later. Also, the matrix 10 can constitute a structure at least partially comprising a wall and / or a frame, which encompasses and defines various pores. The thickness and shape of the wall and frame can take various forms depending on the size, number, shape, etc. of the pores to be contained.

  Also, the structures that are the walls and / or frames of the matrix 10 may themselves be porous. The matrix 10 is a porous body or the like provided with a large number of micropores having a pore size of about 20% or less, 10% or less, or 5% or less of the first size, the second size, and the third size described later. Can.

(Pore 1)
The matrix 10 can define first pores 20 of a first size in communication with one another. In the matrix 10, at least two adjacent first pores 20 are connected to form a cavity 22. Typically, for example, as shown in FIG. 1, a cavity 22 in which three or more or more first pores 20 are connected can be configured.

(The first size of the first pore)
The first size of the first pore 20 refers to the average value of the largest crosswise dimension in the non-connected portion of the first pore 20. Here, the largest transition dimension is, for example, the diameter of the cavity when the first pore 20 is substantially spherical, and the longest diameter of the cavity when the first pore 20 is substantially elliptical or the like. In the case of the substantially cubic shape or the substantially rectangular parallelepiped shape, the maximum inner dimension or the like is obtained. In addition, as described later, any of these maximum crossover diameters can be confirmed and measured in a microscopically observed image.

  The first size is not particularly limited, but can be determined in consideration of the size of cells to be cultured and the like. For example, the first size can be, for example, 200 μm or more and 400 μm or less. By providing such a size, a sufficient porosity can be secured. The first size is preferably 240 μm or more and 390 μm or less.

  The first size is, for example, in a scanning electron microscope, ImageJ software or other equivalent in accuracy and accuracy for the pores identified as the first holes 20 for 30 images of 1200 μm × 850 μm. Image analysis software can be used to measure using a point-to-point autoscale function. In addition, the distance between two points measures an intermediate diameter avoiding the long axis and the short axis of the hole.

(Second pore)
The matrix 22 can include, as a second pore 40, a connection portion (communication hole) in which the first pore 20 is connected and communicated in the cavity 22. By providing the second pores 40 as connection holes, it is possible to provide a high connection ratio of pores, a porosity, and the like. The second pore 40 is a constricted portion of the cavity 22 which can be said to be generally formed by the connection of the first pores 20. Therefore, although it is not an independent pore itself, when observing the cross-sectional structure of the matrix 10 of the present scaffold 100, it is smaller than the diameter of the adjacent first pore 20 and as a communication of the adjacent first pore It can be observed.

(The second size of the second pore)
The second size of the second pores 40 does not inherently exceed the first size of the first pores 20, and can have a second size smaller than the first size. Also, it is generally larger than the third size of the third pores 60 described later. The third size refers to the average value of the largest crosswise dimensions of the second pore 40 as the first pore 20 communication hole. Here, the largest transition dimension is, for example, the diameter of the opening or the like when the form of the second pore 40 is substantially circular, and the maximum width of the opening when it is substantially elliptical. In the case of the substantially rectangular shape, the maximum inner size and the like are obtained. In addition, as described later, any of these maximum crossover diameters can be confirmed and measured in a microscopically observed image.

  The second size is not particularly limited, but can be, for example, 90 μm or more. With such a size, in addition to the mobility and proliferation of cells, the mobility of the medium and the like can be sufficiently ensured. From the viewpoint of more efficient culture, for example, it is 100 μm or more, for example, 110 μm or more, and for example, 120 μm or more. The upper limit is not particularly limited, but is, for example, 180 μm or less, for example, 170 μm or less, and for example, 160 μm or less. The range of the second size can be set by appropriately combining these lower limits and upper limits, and can be, for example, 90 μm to 180 μm, or 100 μm to 170 μm.

  The second size can be measured in the same manner as the first size in the first pore.

(3rd pore)
The matrix 10 can also define a third pore 60. The third pores 60 can be present to bulge from the inner surface 24 of the first pores 20 to the matrix side 10. For example, as shown in FIG. 1, the matrix 10 communicates with the second pore 40 from the first pore 20, ie, the inner surface 24 of the cavity 22, and extends to the matrix 10 side, a protrusion or a matrix It can be provided as a cavity 42 through 10. In addition, the 3rd pore 60 is a pore based on a freeze-solid, as mentioned later.

  The cavity 62 has a cone-shaped cavity 62 in a form in which the distal side is narrowed as viewed from the first pore 20 side, and a pore diameter of approximately equal size from the proximal to the distal of the first pore 20 It may be a columnar cavity 62 or the like to be maintained.

  In addition, the third pore 60 may be present in the vicinity of the first pore 20. For example, the third pore 60 can exist independently of the first pore 20. The third pore 60 may exist independently of the first pore 20 but may be present in the vicinity of the first pore 20 and not in the vicinity of the first pore 20. Can also exist. In either form y, the third pore 60 is a pyramidal cavity 62 having a form in which one end is narrowed or a columnar cavity 62 maintaining a pore diameter of approximately equal size, It is also good.

(The third size of the third pore)
The second size of the third pore 60 refers to, for example, the average value of the largest cross dimension in the cavity of the third pore 60. Here, the largest crosswise dimension is, for example, the largest dimension in the transverse direction of the cavity when the third pore 60 has a tapered needle shape, and the third pore is columnar. Is the largest dimension in the lateral direction of the cavity. In addition, as with the first size of the first pores 20, all of these maximum dimensions can be confirmed and measured in the microscopic observation image.

  The third size may be designed to be smaller than the first size of the first pores 20 and also generally smaller than the second size of the second pores 40. The third size is not particularly limited, and is, for example, 30 μm or more, for example, 40 μm or more, for example, 50 μm or more although it depends on the first size etc. The second size is, for example, less than 100 μm, for example, 90 μm or less, for example, 80 μm or less, for example, 70 μm or less, although it depends on the first size. , 60 μm or less. The range of the second size can be set by combining these lower limits and upper limits as appropriate, but is, for example, 30 μm or more and 90 μm or less, and can be, for example, 40 μm or more and 80 μm or less.

  The third size can also be measured in the same manner as the first size.

(Pore connection rate)
The matrix 10 of the scaffold 100 can be provided with a high degree of pore connectivity. Here, in the present specification, the pore connection rate is obtained based on the water absorption rate and the porosity of the matrix 10, and is an index of the degree of connection of the pores of the matrix 10. The pore connection rate can be obtained, for example, by the following method.

(Porosity)
First, the porosity is measured. For the porosity, the bulk density (ρa) is calculated from the dry weight and the apparent volume of the matrix 10, and the true density (ρt) of the matrix 10 is obtained to obtain a bulk density == 、 a / ρt. Let p (ρa / ρt) be the porosity.

(Water absorption rate)
Further, in the present specification, the water absorption rate is expressed as a percentage of the water absorption amount per unit weight (g) of the matrix 10. Specifically, it is obtained by the following equation. The absorbed mass of water is the mass after immersing matrix 10 in 70% ethanol for 15 minutes at room temperature, and then immersing in water at 37 ° C. for 3 hours to completely replace 70% ethanol with water and fill with water. Measure

Water absorption (%) = (matrix mass after water absorption (g) -matrix mass when dried (g) / matrix mass when dried (g) × 100

(Consolidation rate)
The water absorption (theoretical absorption) per unit mass (g) of the matrix 10 capable of absorbing water is calculated based on the porosity. Furthermore, the ratio between the theoretical water absorption rate and the actual water absorption rate is calculated. The absorbed mass of water is the mass after immersing matrix 10 in 70% ethanol for 15 minutes at room temperature, and then immersing in water at 37 ° C. for 3 hours to completely replace 70% ethanol with water and fill with water. Measure

  The matrix 10 of the scaffold 100 can have, for example, a connection rate of 50% or more. When the pore connection rate is 50% or more, a scaffold that does not inhibit cell migration or cell proliferation can be provided because of the unprecedented high connection rate. The pore connection rate is a good indicator of the ease of cell growth and migration, and the high pore connection rate represents an excellent property as a cell culture scaffold.

  The matrix 10 may also have, for example, a pore connectivity of 55% or more, 60% or more, 65% or more, or 70% or more. It may be 75% or more, 76% or more, 77% or more, or 78% or more. It may be 79% or more, 80% or more, or 85% or more. Preferably, it is 65% or more, more preferably 70% or more, and still more preferably 75% or more.

  The matrix 10 has a porosity of, for example, 90% or more, for example, 95% or more, and for example, 96% or more. The water absorption rate of the matrix 10 is not particularly limited, but is, for example, 1500% or more, for example, 1600% or more, for example, 1700% or more, for example, 1800% or more, and For example, it is 1900% or more, for example, 2000% or more, for example, 2100% or more, for example, 2200% or more, for example, 2300% or more, for example, 2400% or more For example, it is 2500% or more. The porosity connection rate increases synergistically as the porosity and the air electrode water ratio increase.

(Porous substrate)
The matrix of the porous substrate disclosed herein can be used not only as a cell culture scaffold but also as a porous substrate for various applications because it has a novel pore structure.

  Since the scaffold 100 has such a pore structure, it is advantageous for cell migration, and can provide a scaffold for cell culture that can be promoted without restricting cell migration. This enables efficient culture of cells and is advantageous for the culture of cells that grow with high mobility. In addition, since the scaffold 100 has such a pore structure, it can provide a scaffold for cell culture capable of rapidly migrating cells not only to the surface but also to the inside thereof at the time of cell seeding.

(Method of manufacturing porous substrate)
The method for producing a porous substrate disclosed in the present specification (hereinafter simply referred to as the present production method) can be suitably used as a method for producing a porous substrate applicable to the matrix and the like of the present scaffold.

  The production method comprises the steps of mutually connecting at least a part of a plurality of water-soluble particles which are water-soluble solids via water to obtain a linked structure of the water-soluble particles, and forming a polymer in a first liquid Preparing a base stock solution provided with the connection structure in a dissolved matrix stock solution, and applying temperature conditions to which the first liquid and water can be frozen to the base stock solution, the base Obtaining a frozen body obtained by freezing the stock solution, sublimating the first liquid and the second liquid from the frozen body under reduced pressure conditions to obtain a dried body, and a plurality of the plurality of dried bodies in the dried body Removing water soluble particles.

  According to this manufacturing method, by using the linked structure in which the water-soluble particles are linked via water as a kind of disappearance template (first template), the cavity in the state where the water-soluble solid electrolyte is linked is made to the matrix It can be formed. In addition, by freezing the base stock solution, the water held by the connection structure freezes in the first liquid, and generates in situ a second elimination template that can be eliminated by subsequent drying. it can. According to the present manufacturing method, the in-situ generation of the second elimination template makes it possible to easily obtain a porous substrate that is more porous and has an excellent pore connection rate than in the past. Hereinafter, an example of the present manufacturing method will be described with reference to FIGS. 2A and 2B as appropriate.

(Acquisition process of connected structure)
In this step, at least a part of the plurality of water-soluble particles 110 which are water-soluble solids can be mutually connected via the water W to obtain the connected structure 120 of the water-soluble particles 110. The connection structure 120 obtained in this step becomes an elimination template for the cavity 22 having a structure by connecting the first pores 20 in the matrix 10 described above. The connection structure 120 may have a three-dimensional network-like or aggregate-like form.

  In this step, water-soluble particles 110 made of a water-soluble solid are used. Water soluble solids are substances that are soluble in water. The water-soluble solid is not particularly limited, and examples thereof include salts and derivatives thereof, sugars and derivatives thereof, and the like.

The constituent ions of the salts in the salts and their derivatives may be inorganic or organic, and monoatomic or polyatomic ions. For example, cations constituting the salt include ammonium NH ₄ ⁺ , calcium Ca ²⁺ , iron Fe ²⁺ and Fe ^{3 +} , magnesium Mg ²⁺ , potassium K ⁺ , pyridinium C ₅ H ₅ NH ⁺ , quaternary ammonium NR ₄ ⁺ , And sodium Na ⁺ but not limited thereto. Further, for example, the anion constituting the salt is acetate CH ₃ COO ⁻ , carbonate CO ₃ ²⁻ , chloride Cl ⁻ , citrate HOC (COO ⁻ ) (CH ₂ COO ⁻ ) ₂ , cyanide C≡N ⁻ , Hydroxides OH ⁻ , nitrates NO ₃ ⁻ , nitrites NO ₂ ⁻ , oxides O ²⁻ , phosphates PO ₄ ³⁻ , and sulfates SO ₄ ^2−, but not limited thereto. Nonlimiting examples of salts include cobalt chloride hexahydrate, copper sulfate pentahydrate, hexacyanoferrate, lead acetate, magnesium sulfate, manganese dioxide, mercury sulfide, sodium glutamate, nickel chloride hexahydrate, potassium bitartrate, Potassium chloride, potassium dichromate, potassium fluoride, potassium permanganate, sodium alginate, sodium chromate, sodium chloride, sodium fluoride, sodium iodate, sodium iodide, sodium iodide, sodium nitrate, sodium sulfate, and / or the like thereof Contains a mixture. Preferably, it is a salt which is deliquescent by water, and sodium hydroxide, potassium carbonate, magnesium chloride, calcium chloride, sodium chloride and the like can be mentioned. Preferably, it is sodium chloride.

  Also, sugars and derivatives thereof are not particularly limited, but, for example, compounds containing 1 to 10 monosaccharide units (eg, monosaccharides, disaccharides, trisaccharides, and 4 to 10 monosaccharide units) Containing oligosaccharides). When the parent monosaccharide has a (potentially) carbonyl group, the monosaccharide is a polyhydroxy aldehyde or polyhydroxy ketone having 3 or more carbon atoms, and these include aldoses, dialdoses, aldoketoses , Ketoses, and diketoses, as well as cyclic forms, deoxy sugars, and amino sugars and their derivatives. Oligosaccharides are compounds in which glycosidic bonds are added to at least two monosaccharide units. Depending on the number of units, these are disaccharides, trisaccharides, tetrasaccharides, pentasaccharides, hexasaccharides (hexaccharide), heptasaccharides (heptaaccharide), octasaccharides (octoaccharide), octasaccharides (nonoaccharide), decasaccharides (decoaccharide), etc. It is called. Oligosaccharides can be unbranched, branched or cyclic. Non-limiting examples of sugars include, for example, triose such as glyceraldehyde and dihydroxyacetone; tetrose such as erythrose, threose and erythrulose; peninose such as arabinose, lyxose, ribose, xylose, ribulose, xylulose; allose, Altrose, galactose, glucose, gulose, idose, mannose, talose, fructose, psicose, sorbose, tagatose, fucose, hexose like rhamnose; heptose like sedoheptulose and mannoheptulose; octulose and 2-keto Octose such as 3-deoxy-manno-octonate (octoose); nonose such as sialose; monosaccharides such as decose; For example, disaccharides such as sucrose, lactose, maltose, trehalose, cellobiose, gentiobiose, cogibios, kolimibiose, limanibios, mannobiose, melibiose, nigerose, rutinose, and xylobiose; Such oligosaccharides include trisaccharides, and / or mixtures thereof. Sugars also include sugar substitutes such as acesulfame potassium, alitame, aspartame, acesulfame, cyclamate, ducurtine, glucin, neohesperidin dihydrochalcone, neotame, saccharin and sucralose.

  The water-soluble particles 110 used in this step are made of such water-soluble solid. The water soluble particles 110 are extinct templates that are eventually removed in the polymer matrix, as used in conventional porogen leaching methods. The water soluble particles 110 will define the first size that the first pores 20 in the porous substrate (matrix) to be produced have. Thus, water-soluble particles 110 of average particle size corresponding to the intended first size can be used. Such water-soluble particles 110 can be prepared to have not only a preferred average particle size but also a particle size distribution, as intended.

  The form of the water-soluble particle 110 is not particularly limited. For example, various pyramidal shapes such as spheres, ellipsoids, polyhedrons, triangular pyramids, square pyramids, cones, cubes, rectangular parallelepipeds, cylinders, etc. It may be in the form of various cylinders, spindles, etc.

  The water-soluble particles 110 are not particularly limited, but, for example, the average particle diameter is 200 μm to 500 μm, for example, the average particle diameter is 220 μm to 400 μm, and for example, the average particle diameter is 240 μm to 390 μm or less Water soluble particles can be used. The average particle size of the water-soluble particles can be measured by sieving according to the mesh size or by an optical method.

  In this step, for example, as shown in (b) of FIG. 2A, at least a part of such a plurality of water-soluble particles are mutually connected via the water W to obtain the connected structure 120 of the water-soluble particles. . For example, as shown in (a) of FIG. 2A, after the plurality of water-soluble particles 110 are supplied into a suitable mold, the connection structure 120 is coated with water on the surface of the water-soluble particles 110 by a method such as coating or spraying. To partially dissolve the surface of the water-soluble particle 110, or, for example, relative humidity 50% or more, for example 60% or more, for example 70% or more, for example 80% As described above, for example, in an atmosphere of 90% or more and 95% or more, moisture absorption or the like on the surface of the water-soluble particle 110, for example, for 30 minutes or more, for example, 1 hour or more, It can be obtained by causing deliquescence and the like. In addition, the temperature conditions which perform such operation are although it does not specifically limit, For example, it can implement at 15 degreeC or more and 40 degrees C or less, for example, 20 degreeC or more and 40 degrees C or less.

  In this step, the connection state of the water-soluble particles 110 can be controlled by the amount of water W supplied to the plurality of water-soluble particles 110, the contact state of the water-soluble particles 110, the supply time of the water W, and the like. . When the amount of water is large, dissolution or deliquescence of the water-soluble particles 110 enlarges the connection portion of the water-soluble particles 110, and as a result, the connection portion of the water-soluble particles 110 in the connection structure 120 ( Corresponding) tends to be large. Further, when the connection structure 120 is manufactured in a state in which the water-soluble particles 110 are highly filled, the connection of the water-soluble particles 110 is promoted to obtain the connection structure 120 sufficiently including the communication portion (the same communication hole). be able to.

  In this step, although it is possible to arrange the plurality of water-soluble particles 110 at random to prepare the connection structure 120, the connection designed by arranging the plurality of water-soluble particles 110 in a certain pattern The structure 120 and thus the cavity 22 can be made. For example, the water-soluble particles 110 can be arranged in a grid in a planar manner, and furthermore, the water-soluble particles 110 can be stacked in the height direction and arranged in an intended three-dimensional structure.

  The conditions such as the temperature in this step are not particularly limited as long as the water-soluble particles 110 can maintain a solid state. For example, it can carry out at temperature, such as 25 degreeC or more and 40 degrees C or less. In addition, this step may be performed for a time in which a sufficient connection state can be obtained and an intended connection structure can be obtained. Although not particularly limited, for example, it is 10 minutes or more, for example, 20 minutes or more, for example, 30 minutes or more, for example, 60 minutes or more, for example, 1.5 hours It is above.

  This step may be carried out by arranging in a mold having a cavity having the three-dimensional shape in advance so that the plurality of water-soluble particles 110 can have the intended three-dimensional shape of the matrix 10 to be obtained. it can. The mold is preferably a material such as a cooled mold and / or a metal having high thermal conductivity.

(Step of preparing base stock solution)
In this step, it is possible to prepare the base stock solution 140 including the connecting structure 120 in the matrix stock solution 130 in which the polymer is dissolved in the first liquid. The base stock solution 140 obtained in this step is a raw material for obtaining the matrix 10 which is the porous base described above. An example of this process is shown in (c) of FIG. 2A.

  As the polymer, various polymers described above, preferably biocompatible or bioabsorbable polymers can be used. As the first liquid, a liquid capable of dissolving such a polymer can be used. The first liquid is, for example, a liquid having a freezing point of −20 ° C. or less in consideration of the subsequent freezing step and drying step, and the connecting structure of the water-soluble particles 110 until at least the first liquid is frozen. It is preferable that the liquid does not dissolve the water-soluble particles 110 to such an extent that the body 120 can be maintained and held in that state.

  When the water-soluble particle 110 is a salt or a derivative thereof or a sugar or a derivative thereof, examples of the first liquid include 1,4-dioxane, chloroform, dichloromethane, t-butanol, and xylene.

  In order to obtain the base stock solution 140, the connection structure 120 and / or the matrix stock solution 130 should not be dissolved or mixed in the matrix stock solution 130 or the connection state of the matrix stock solution 130 may not be released. Preferably, the connection structure 120 is brought into contact with the matrix stock solution 130 at low temperature or under low temperature conditions, or the freezing step is carried out immediately after the contact. It is preferable to prepare the base stock solution 140 by bringing the connection structure 120 and the matrix stock solution 130 into contact, for example, under conditions of −20 ° C. or less.

(Step of obtaining frozen body)
In this step, for example, as shown in (d) of FIG. 2B, the base solution 140 is given a temperature condition that allows the first liquid and water to freeze, and the base solution 140 is frozen. The frozen body 150 can be obtained. According to this step, the water W held by the connection structure 120, for example, the water W present on the surface of the water-soluble particles 110 can be frozen in the matrix stock solution 130 and sublimated in the drying step. Freezing molds, i.e., frozen bodies 160 can be generated in situ in the frozen body 150. The frozen body 160 may be formed in a state of being connected to the connection structure 120, or may be formed in the vicinity of or not near the connection structure 120. The water W attached to the connection structure 120 in the matrix stock solution 130 becomes frozen bodies 160, so that the solid water-soluble particles 110 and the frozen bodies 160 can be separated. The water-soluble particles 110 maintain a solid state.

  Further, according to this step, the first liquid other than the polymer in the base stock solution 140 is also frozen. By freezing, the polymer which is solid in the matrix stock solution 130 precipitates, so the polymer and the first liquid can be separated.

  The conditions for freezing in this step are not particularly limited as long as the base stock solution 140 freezes, but are, for example, 0 ° C. or less, for example, −5 ° C. or less, or, for example, It is −10 ° C. or less, for example, −20 ° C. or less, and for example, −30 ° C. or less. Also, the time for freezing is not particularly limited, but is, for example, 1 hour or more, for example, 2 hours or more, for example, 3 hours or more, for example, 4 hours or more For example, it is 5 hours or more, for example 6 hours or more, and for example 7 hours or more, for example 8 hours or more.

(Step of obtaining dry matter)
In this step, for example, as shown in (e) of FIG. 2B, the first liquid frozen in the frozen body 150 under reduced pressure and the frozen body 160 can be sublimated to obtain a dried body. According to this process, the frozen body 160 and the frozen body of the first liquid can be sublimated from the frozen body 150 to obtain the dried porous body 170 having the cavities corresponding to these portions. This porous body 170 contains water soluble particles 110 which are still water soluble solids.

  This step is a so-called freeze-drying step, and can be carried out according to a known reduced-pressure drying method. Drying conditions are not particularly limited, but, for example, 2 hours or more, for example 3 hours or more, for example 4 hours or more, for example 5 hours or more, for example 6 hours or more, for example 8 For example, it may be 10 hours or more, for example, 12 hours or more.

(Water-soluble particle removal process)
In this step, for example, as shown in (f) of FIG. 2B, the plurality of water-soluble particles 110 in the dried body 170 can be removed. According to this process, by removing the water-soluble particles 110 constituting the connection structure 120, the porous substrate 180 having the cavity 22 corresponding to the connection structure 120 can be obtained.

  In order to remove the water-soluble particles 110, a method of dissolving and extracting the water-soluble particles 110 using an aqueous medium that dissolves the water-soluble particles 110 can be used. Typically, it is water, or water containing alkali, acid or the like to adjust the solubility of the water-soluble particles, and furthermore, such water and alcohol miscible with water, acetonitrile, DMSO, DMF, etc. And mixtures thereof with organic solvents.

  This step can be performed, for example, by washing the dried body 170 one or more times with such an aqueous medium.

  If necessary, a step of drying the obtained porous substrate 180 can be carried out after such a removal step. In addition, if necessary, steps such as crosslinking of the polymer constituting the matrix 10 can be performed after the removing step or after the drying step. For the crosslinking step, known methods such as a method by radiation, a method by ultraviolet irradiation, a heat crosslinking, and a method using a crosslinking agent can be adopted.

  Furthermore, if necessary, various agents for cell culture, for example, epidermal growth factor (EGF), vascular growth factor (VEGF), nerve growth factor ( NGF), basic fibroblast growth factor (bFGF), platelet growth derived factor (PDGF), hepatocyte growth factor (HGF), insulin-like growth factor (IGF), transforming growth factor (TGF), bone formation induction protein It is also possible to impregnate any one or more of (BMP), vascular cell growth factor or nerve cell growth factor.

The porous substrate 180 obtained by the present manufacturing method has pores based on the first disappearance template which is the connection structure 120 and the second disappearance template which is the freezed body 160 of the water W accompanying the connection structure 120. The porous substrate 180 can be easily obtained. Such a porous substrate 180 has pores based on the second elimination template, ie, the second pores 40, and therefore, a porous group having sufficient porosity and pore connectivity. It is a material 180. Furthermore, the porous substrate 180 obtained by the present manufacturing method is provided with a porous polymer matrix obtained by the sublimation of the first liquid frozen body.

  Hereinafter, specific examples will be described to more specifically explain the disclosure of the present specification. The following examples are for the purpose of illustrating the disclosure of the present specification, and are not intended to be a basis for its scope.

(Preparation of porous substrate)
(1) PLLA (poly L-lactic acid) and 1,4-dioxane were placed in a vial so that the polymer concentration was 5% (w / w), and then stirred with a stirrer for 6 hours to dissolve PLLA. After PLLA was dissolved, sonication was performed for 30 minutes to prepare a matrix stock solution.

(2) Using a 24-well plate of polypropylene (500 μl / well) as a mold for obtaining a porous substrate, 1 g of NaCl was added to each well. Thereafter, the well plate was placed in an incubator at a relative humidity of 95% or more and a temperature of 37 ° C., and humidified for 1.5 hours. Thus, a linked structure of NaCl crystals was produced in the well.

(3) After removing the well plate from the incubator, 500 μl of matrix stock solution was supplied to each well to prepare a substrate stock solution in the wells.

(4) The well plate was placed in a freezer (−20 ° C.) and cooled for about 5 hours to freeze the stock solution in the wells. Thereafter, the well plate was put into a lyophilizer and dried for 12 hours. After drying, the dried product was taken out of the wells of the well plate and washed three times with ultrapure water to obtain a porous substrate.

  As a control, the matrix stock solution obtained in (1) above was lyophilized as it was under the same conditions as in (4) above to obtain the porous base material of Control Example 1. Moreover, the matrix undiluted | stock solution obtained by said (1) was dried as it is at 50 degreeC for 24 hours, and the porous base material of the control example 2 was obtained.

(Observation by SEM image)
The SEM observation image of the porous substrate of an Example and the porous substrate of the control example 1 is shown in FIG. As shown in FIG. 3, in the porous substrate of the example, a large number of pores, communicating pores of pores, and a large number of small-diameter pores in the vicinity of the pores could be confirmed. On the other hand, in the porous base material of the control example 1, the pore of the extent which a cell can pass was not able to be confirmed.

(Analysis from SEM observation image)
The structural analysis result by ImageJ using the SEM observation image of FIG. 3 is shown in FIG. As shown in FIG. 4, it was possible to observe pores based on NaCl crystals, contact holes based on connection of NaCl crystals, pores based on freeze-solids, and pores based on dioxane.

(Evaluation of porosity, water absorption rate and connection rate)
The evaluation result about the porosity of the porous base material of an Example and the porous base material of the comparative example 1 and 2 in FIG. 5A and 5B, a water absorption, and a connection rate is shown. In addition, these evaluations were performed by the following methods.

(1) Porosity As for the porosity, the bulk density (ρa) is calculated from the dry weight and the apparent volume of the matrix 10, and the true density (ρt) of the matrix 10 is obtained. Bulk density == ρa / ρt And 1-p (.rho.a / .rho.t) was taken as the porosity.
(2) Water Absorption Rate After measuring the weight of each porous substrate, the water was sufficiently absorbed, and then the weight was measured. The results were applied to the following equation to obtain the water absorption. The weight after water absorption was previously immersing the porous base material in 70% ethanol for 15 minutes, and then fully substituted with ultrapure water, and the weight after standing at 37 ° C. for 3 hours was taken as the weight after water absorption.
Water absorption (%) = (weight of porous material after water absorption-weight of porous material at drying) / porous wet weight at drying × 100
(3) Coupling rate The water absorption (theoretical absorption) per unit mass (g) of the matrix 10 capable of absorbing water was calculated based on the porosity. Furthermore, the ratio between the theoretical water absorption rate and the actual water absorption rate was calculated. The absorbed mass of water is the mass after immersing matrix 10 in 70% ethanol for 15 minutes at room temperature, and then immersing in water at 37 ° C. for 3 hours to completely replace 70% ethanol with water and fill with water. Was measured.

  As shown in FIGS. 5A and 5B, it was found that the porous substrate of the example has remarkable porosity, water absorption rate, and connection rate.

(Evaluation of cell seeding and infiltration)
After absorbing water to the porous substrates of the example and the porous substrates of the control example (each 14 mm in diameter × 6 mm in thickness), 1 ml of MC3T3-E1 cell suspension (2 × 10 ⁵ cells / ml) was inoculated . The next day, the porous substrate was cut and the viable cells in the substrate were evaluated with Calcein-AM. The results are shown in FIG. As shown in FIG. 6, according to the porous substrate of the example, it was found that the cells were infiltrated to the inside of the substrate even within 12 hours.

Claims (13)

Defining a porous structure, comprising a matrix comprising a polymer,
A scaffold for cell culture, wherein the matrix defines a first pore communicating with each other and a third pore existing on or near an inner surface of the first pore.   The scaffold according to claim 1, wherein the pore connectivity of the matrix is 76% or more.   The scaffold according to claim 1 or 2, wherein the water absorption of the matrix is 2000% or more, or the porosity is 96% or more.   The scaffold according to any one of claims 1 to 3, wherein the first size has an average value of maximum cross dimension of 200 μm or more and 400 μm or less.   The scaffold according to any one of claims 1 to 4, wherein the third size of the third pores is such that an average value of maximum crosswise dimensions is 30 μm or more and less than 100 μm.   The matrix according to any of the preceding claims, wherein the matrix at least partially comprises a frame and / or a wall defining a second pore, which is a connecting hole of the first pore and the first pore. Scaffold as described.   The scaffold according to claim 6, wherein the second size has an average value of maximum cross dimension of 100 μm or more and 170 μm or less.   The scaffold according to any one of claims 1 to 7, wherein the polymer comprises at least one selected from polylactic acid, polyglycolic acid, a copolymer of polylactic acid and polyglycolic acid, and polycaprolactone. Defining a porous structure, comprising a matrix comprising a polymer,
A porous substrate, wherein the matrix defines a first pore of a first size in communication with each other and a third pore present at or near an inner surface of the first pore. A method for producing a porous substrate, comprising
At least a part of a plurality of water-soluble particles which are water-soluble solids are mutually connected via water to obtain a connected structure of the water-soluble particles;
Preparing a base stock solution having the connection structure in a matrix stock solution in which a polymer is dissolved in a first liquid;
Providing a temperature condition that allows the first liquid and water to freeze to the base stock solution to obtain a frozen body obtained by freezing the base stock solution;
Sublimating the first liquid and the second liquid from the frozen body under reduced pressure conditions to obtain a dried body;
Removing the plurality of water soluble particles in the dried body;
A method comprising.   The method according to claim 10, wherein the water-soluble solid is one or more selected from the group consisting of a salt and a derivative thereof and a sugar and a derivative thereof.   The manufacturing method according to claim 10 or 11, wherein the water-soluble solid is one or more selected from the group consisting of sodium hydroxide, potassium carbonate, magnesium chloride, calcium chloride and sodium chloride.   The polymer according to any one of claims 10 to 12, wherein the polymer is one or more selected from the group consisting of polylactic acid, polyglycolic acid, a copolymer of polylactic acid and polyglycolic acid, and polycaprolactone. Manufacturing method.