JP3935096B2 - Highly engraftable corneal epithelial substitute cell sheet, production method and use thereof - Google Patents

Description

[Industrial application fields]
[0001]
The present invention relates to a highly engraftable corneal epithelial substitute cell sheet in the fields of biology, medicine, etc., a production method, and a treatment method using them.
[Prior art]
[0002]
Due to the remarkable development of medical technology, in recent years, organ transplants that attempt to replace difficult-to-treat organs with other organs have become common. The target organs are very diverse, such as skin, cornea, kidney, liver, heart, etc., and the progress after surgery has improved remarkably, and has already been established as a medical technology. Taking corneal transplantation as an example, an eye bank was established in Japan about 40 years ago and transplantation activities began. However, the number of donors is still small, and there are about 20,000 patients who need corneal transplantation in Japan alone, whereas only about 1/10 patients who can actually undergo transplantation treatment are about 2000. It is said. Despite the almost established technology of corneal transplantation, the current situation is that the next medical technology is required due to the shortage of donors.
[0003]
Against this background, techniques for transplanting artificial substitutes or cells that have been cultured and organized have attracted attention. Representative examples thereof include artificial skin and cultured skin. However, artificial skin using a synthetic polymer may cause rejection and the like, and is not preferable as skin for transplantation. On the other hand, since the cultured skin is obtained by culturing a part of the normal skin of the person to a desired size, even if it is used, there is no concern about rejection or the like, and it can be said to be the most natural masking agent.
[0004]
Conventionally, such cell culture has been performed on the surface of a synthetic polymer subjected to various treatments. For example, various containers and the like subjected to surface treatment using polystyrene as a material, for example, γ-ray irradiation, silicone coating, and the like are widely used as cell culture containers. Cells cultured and proliferated using such a cell culture container are peeled and collected from the container surface by treatment with a protease such as trypsin or a chemical.
[0005]
However, when recovering cells grown by chemical treatment as described above, the treatment process becomes complicated, the possibility of contamination is increased, and the grown cells are altered or damaged by chemical treatment. Disadvantages have been pointed out that there are cases where the original function of cells is impaired. In order to overcome such drawbacks, several techniques have been proposed so far.
[0006]
In Japanese Patent Publication No. 2-23191, keratinized epidermis cells derived from human newborns are cultured in a culture container under the condition that a keratinous tissue film is formed on the surface of the container. A method for producing an implantable membrane of keratinous tissue, characterized in that it is exfoliated using Specifically, a technique is disclosed in which 3T3 cells are grown and layered as a feeder layer, and a cell sheet is recovered using dispase, which is a proteolytic enzyme. However, the method described in the publication has the following drawbacks.
(1) Dispase is derived from bacteria, and the collected cell sheet needs to be thoroughly washed.
(2) Dispase treatment conditions differ for each cultured cell, and skill is required for the treatment.
(3) The epidermal cells cultured by dispase treatment are pathologically activated.
(4) The extracellular matrix is degraded by dispase treatment.
(5) Therefore, the affected part transplanted with the cell sheet is easily infected.
[0007]
In order to solve this problem, recently, a technique has been devised in which corneal epithelial cells and conjunctival epithelial cells are cultured and organized on the amniotic membrane from which the sponge layer and the epithelial layer have been removed, and the amnion is used as a cell piece for transplantation. (Japanese Patent Laid-Open No. 2001-161353). Amniotic membrane is convenient as a support for transplanted cell debris because it has sufficient membrane strength and is not antigenic. However, amniotic membrane is not originally in the eye and more precisely in the intraocular tissue. In order to construct the above, it has been desired that a sheet having sufficient strength is produced only with cells in the eye, and that the sheet is in direct contact with the corneal parenchyma.
[0008]
In Japanese Patent Application No. 2001-226141, an anterior ocular segment-related cell is cultured on a cell culture support in which a temperature-responsive polymer having an upper or lower critical solution temperature in water of 0 to 80 ° C. is coated on the substrate surface. However, if necessary, it is possible to produce a cell sheet with sufficient strength by layering the cultured cell layer by a conventional method and peeling the cultured cell sheet simply by changing the temperature of the support. . In addition, this cell sheet also retains a basement membrane-like protein, and the engraftment to the tissue is clearly improved as compared with the above-mentioned dispase-treated one. However, considering the reduction of actual patient burden, further improvement in the engraftment has been desired.
[0009]
Recently, various methods have been proposed in the medical field. For example, in a daily newspaper article dated May 10, 2001, a technique has been proposed in which a cultured oral mucosa is pasted instead of the cornea to encourage the patient's cornea regeneration to a patient with corneal disease. However, the cultured oral mucosa here was peeled off by the above-mentioned dispase, and had a problem that adhesion to the corneal tissue to the patient was poor and a remarkable therapeutic effect could not be expected.
[Problems to be solved by the invention]
[0010]
The present invention has been made with the intention of solving the problems of the prior art as described above. That is, an object of the present invention is to provide a highly engraftable corneal epithelial substitute cell sheet or a multilayered sheet thereof having good adhesion to the anterior segment tissue. Moreover, an object of this invention is to provide the manufacturing method and its utilization method.
[Means for Solving the Problems]
[0011]
In order to solve the above-mentioned problems, the present inventors have studied and developed from various angles. As a result, corneal epithelial substitute cells are cultured under specific conditions on a cell culture support with specific conditions coated with a temperature-responsive polymer, and then the culture solution temperature is equal to or higher than the upper critical solution temperature or lower critical solution. Adhering the cultured corneal epithelial substitute cell sheet or its stratified sheet to a specific carrier at a temperature lower than the temperature, and exfoliating it with the carrier as it is while suppressing the contraction of the cell sheet. It has been found that a sexual corneal epithelial substitute cell sheet or a multilayered sheet thereof can be obtained. The present invention has been completed based on such findings.
[0012]
That is, the present invention provides a highly-adherent corneal epithelial substitute cell sheet or a multilayered sheet thereof that has good adhesion to an anterior segment tissue and is in close contact with a carrier.
[0013]
In the present invention, cells are cultured on a cell culture support having a base surface coated with a temperature-responsive polymer having an upper or lower critical solution temperature in water of 0 to 80 ° C. Layer the cultured cell layer, and then
(1) The culture solution temperature is set to the upper critical solution temperature or higher or the lower critical solution temperature or lower,
(2) Adhering the cultured corneal epithelial cell sheet or its multilayered sheet to a carrier,
(3) Provided is a method for producing a highly adherent corneal epithelial substitute cell sheet or a multilayered sheet thereof, which is characterized by peeling with a carrier as it is.
[0014]
In addition, the present invention provides the above-mentioned highly engrafted corneal epithelial substitute cell sheet or a stratified sheet thereof for treating tissue that has been deeply damaged and / or wounded deeply.
[0015]
In addition, the present invention provides a treatment method characterized by transplanting the highly engrafted corneal epithelial substitute cell sheet or a stratified sheet thereof to a tissue that has been deeply damaged and / or wounded.
[0016]
Furthermore, the present invention provides not only a medical field but also a highly engraftable corneal epithelial substitute cell sheet or a multilayered sheet thereof useful as cells for safety evaluation of chemical substances, toxic substances, or pharmaceuticals.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
As described above, the present invention provides a highly engraftable corneal epithelial substitute cell sheet or a multilayered sheet thereof that is in close contact with a carrier. As a suitable cell used for the production of the highly engraftable corneal epithelial substitute cell sheet or the multilayered sheet of the present invention, for example, any of oral mucosal cells, hair root cells, conjunctival epithelial cells present in the buccal membrane, gingiva, or Although the mixture of two or more or a mixture of these and a corneal epithelial cell is mentioned, the kind is not restrict | limited at all. When preparing these cell sheets, it is not necessary to add special additives during the culture of corneal epithelial substitute cells. For example, when oral mucosa cells are used as corneal epithelial substitute cells, oral mucosa cells The cell culture sheet can be prepared by culturing using the standard cell culture method.
[0018]
In the present invention, the highly engrafted corneal epithelial substitute cell sheet means a sheet in which various cells described above are cultured in a single layer on a culture support and then peeled off from the support, and the multilayered sheet is The highly engrafted corneal epithelial substitute cell sheet means a sheet laminated in a state of being combined with a sheet composed of a single cell or other cells.
[0019]
The highly engraftable corneal epithelial substitute cell sheet or the stratified sheet according to the present invention is not damaged by proteolytic enzymes represented by dispase, trypsin and the like during culture. Therefore, the highly engrafted corneal epithelial substitute cell sheet peeled from the base material or the layered sheet thereof has a high strength because the cell-cell desmosome structure is maintained, there are few structural defects. In addition, in the sheet of the present invention, the basement membrane-like protein between the cell and the substrate formed during the culture is not damaged by the enzyme. As a result, it is possible to adhere well to the affected tissue at the time of transplantation, and an efficient treatment can be performed. Specifically, when using a normal proteolytic enzyme such as trypsin, the cell-cell desmosome structure and the cell, the basement membrane-like protein between the substrates is hardly retained, Therefore, the cells are separated and separated in an individual state. Among them, dispase, a proteolytic enzyme, is known to be able to be detached in a state where the cell-cell desmosome structure is maintained at 10 to 60%. The obtained cell sheet is weak because it almost destroys the protein. In contrast, the cell sheet of the present invention is in a state where 80% or more of the desmosome structure and the basement membrane-like protein remain, and can obtain various effects as described above.
[0020]
The highly engraftable corneal epithelial substitute cell sheet or its multilayered sheet in the present invention engrafts very well on the anterior ocular tissue which is a living tissue. It has been found that this property is realized by suppressing the shrinkage of the regenerated corneal epithelial cell sheet peeled from the support surface or its multilayered sheet. At that time, the contraction rate of the corneal epithelial substitute cell sheet or the multilayered sheet thereof is desirably 20% or less, preferably 10% or less, more preferably 5% or less, in the length in any direction in the sheet. Preferably there is. When the length in any direction of the sheet is 20% or more, the detached cell sheet sags, and even if it adheres to the living tissue in that state, it does not adhere to the tissue, and the high engraftment as shown in the present invention Sex cannot be expected.
[0021]
The method of not shrinking the corneal epithelial substitute cell sheet or the multilayered sheet thereof is not limited as long as the method does not shrink the cell sheet, but for example, the corneal epithelial substitute cell sheet or the multilayered sheet thereof from the support is not limited. When peeling, a method of peeling a cell sheet together with the carrier, such as a ring-shaped carrier with a central portion cut out, may be mentioned.
[0022]
The carrier used when closely attaching the highly engraftable corneal epithelial substitute cell sheet or the multilayered sheet thereof is a structure for holding the cell sheet of the present invention so as not to contract, such as a polymer film or a polymer film. It is possible to use a structure, a metallic jig, etc. molded from the above. For example, when a polymer is used as the carrier material, specific examples of the material include polyvinylidene difluoride (PVDF), polypropylene, polyethylene, cellulose and derivatives thereof, papers, chitin, chitosan, collagen, urethane, and the like. Can be mentioned.
[0023]
In the present invention, close contact refers to a state in which the cell sheet does not shift or move on the carrier at the boundary surface between the cell sheet and the carrier so that the cell sheet does not contract. Even if they are in close contact, they may be in close contact via a liquid (for example, a culture solution or other isotonic solution) existing between the two.
[0024]
The shape of the carrier is not particularly limited. For example, when the obtained highly engrafted corneal epithelial substitute cell sheet or a multilayered sheet thereof is transplanted, a part of the carrier is similar to the transplant site or the transplant site. When a larger cutout is used, the cell sheet is fixed only to the peripheral portion of the cutout, and it is only necessary to apply the cellsheet in the cutout portion to the transplantation site.
[0025]
The highly engraftable corneal epithelial substitute cell sheet or the stratified sheet of the present invention is a binocular that does not have corneal epithelial cells, in addition to, for example, an affected part in which a part or all of the anterior ocular tissue is damaged or missing It can be used in treating refractory keratoconjunctival disease. The anterior ocular tissue of the present invention is not particularly limited as long as it is an anterior ocular segment, and generally includes corneal epithelial tissue, Bowman tissue, corneal parenchymal tissue, and the like. Here, the term “refractory keratoconjunctival disease” includes diseases such as Stevens-Johnson syndrome, pemphigoid, burns, alkaline corrosion, and acid corrosion.
[0026]
As described above, the highly engrafted corneal epithelial substitute cell sheet or the stratified sheet according to the present invention is a cell sheet that can adhere very well to the anterior ocular tissue that is a living tissue, and is completely obtained from the prior art. It was not.
[0027]
The present invention also provides a method for producing the highly engraftable corneal epithelial substitute cell sheet of the present invention described above or a multilayered sheet thereof by the following production method. That is, cells are cultured on a cell culture support having a substrate surface coated with a temperature-responsive polymer having an upper or lower critical solution temperature in water of 0 to 80 ° C., and if necessary, a cultured cell layer is prepared by a conventional method. Layered, then
(1) The culture solution temperature is set to the upper critical solution temperature or higher or the lower critical solution temperature or lower,
(2) Adhering the cultured corneal epithelial cell sheet or its multilayered sheet to a carrier,
(3) Provided is a method for producing a highly engraftable corneal epithelial substitute cell sheet or a multilayered sheet thereof, which is characterized by peeling with a carrier as it is.
[0028]
The temperature-responsive polymer used for coating the substrate in the cell culture support has an upper critical solution temperature or a lower critical solution temperature of 0 ° C to 80 ° C, more preferably 20 ° C to 50 ° C in an aqueous solution. If the upper critical lysis temperature or the lower critical lysis temperature exceeds 80 ° C., the cells may die, which is not preferable. Further, if the upper critical lysis temperature or the lower critical lysis temperature is lower than 0 ° C., the cell growth rate is generally extremely reduced or cells are killed, which is also not preferable.
[0029]
The temperature-responsive polymer used in the present invention may be either a homopolymer or a copolymer. Examples of such a polymer include polymers described in JP-A-2-21865. Specifically, for example, it can be obtained by homopolymerization or copolymerization of the following monomers. Examples of the monomer that can be used include a (meth) acrylamide compound, an N- (or N, N-di) alkyl-substituted (meth) acrylamide derivative, or a vinyl ether derivative. Two or more of these can be used. Furthermore, copolymerization with monomers other than the above monomers, grafting or copolymerization of polymers, or a mixture of polymers and copolymers may be used. Moreover, it is also possible to crosslink within a range that does not impair the original properties of the polymer.
[0030]
Examples of the base material to be coated include substances that can generally give form, such as glass, modified glass, polystyrene, polymethylmethacrylate, and the like, which are usually used for cell culture, such as polymers other than those described above. All compounds, ceramics, etc. can be used.
[0031]
The method for coating the support with the temperature-responsive polymer is not particularly limited, and may be, for example, the method described in JP-A-2-21865. That is, such coating is performed by applying a substrate and the above monomer or polymer to one of electron beam irradiation (EB), γ-ray irradiation, ultraviolet irradiation, plasma treatment, corona treatment, organic polymerization reaction, or physical application such as coating and kneading. It can be performed by, for example, mechanical adsorption.
[0032]
The coverage of the temperature responsive polymer may have a range of 0.4~4.5μg / cm ^2, preferably 0.7~3.5μg / cm ^2, more preferably 0.9~3.0μg / Cm ² . When the coating amount is less than 0.2 μg / cm ² , the cells on the polymer are difficult to peel off even when a stimulus is applied, and the working efficiency is remarkably deteriorated. On the other hand, if it is 4.5 μg / cm ² or more, it is difficult for cells to adhere to the region, and it becomes difficult to sufficiently attach the cells.
[0033]
The form of the support in the present invention is not particularly limited, and examples thereof include a dish, a multiplate, a flask, and a cell insert. Among them, cell inserts are particularly advantageous because, for example, 3T3 feeder cells necessary for stratifying corneal epithelial cells can be cultured separately from corneal epithelial cells. At that time, the corneal epithelial cells may be on the cell insert side or on the dish side on which the cell insert is mounted, and at least the surface on which the corneal epithelial cells are cultured is coated with a temperature-responsive polymer. There is a need.
[0034]
In the present invention, cells are cultured on the cell culture support produced as described above. The culture medium temperature is not particularly limited as long as the polymer coated on the substrate surface has an upper critical solution temperature or lower, and when the polymer has a lower critical solution temperature or higher, the temperature is not particularly limited. However, it goes without saying that culturing in a low temperature range where cultured cells do not proliferate or in a high temperature range where cultured cells die is inappropriate. The culture conditions other than the temperature may be in accordance with conventional methods and are not particularly limited. For example, the medium to be used may be a medium to which serum such as known fetal calf serum (FCS) is added, or a serum-free medium to which such serum is not added.
[0035]
In the method of the present invention, in order to peel and collect the cultured cells from the support material, the cultured highly engrafted corneal epithelial substitute cell sheet or a multilayered sheet thereof is closely attached to the carrier, and the support material to which the cells are attached By setting the temperature to the upper limit critical dissolution temperature or lower limit critical dissolution temperature of the support polymer of the support substrate, it can be peeled off with the carrier as it is. Note that peeling of the sheet can be performed in a culture solution in which cells are cultured or in another isotonic solution, and can be selected according to the purpose.
[0036]
In the present invention, after the cell sheet is applied to the affected area, the cell sheet may be peeled off from the carrier. The method of peeling is not limited at all, but for example, a method of wetting the carrier to weaken the adhesion between the carrier and the cell sheet, or using a knife such as a knife, scissors, laser light, plasma wave, etc. Also, a method of cutting may be used. For example, when using a cell sheet that is in close contact with a carrier that has been partially cut out as described above, cutting along the boundary line of the affected area using laser light or the like avoids attachment of the cell sheet to an extra area other than the affected area. It is convenient.
[0037]
The highly engrafted corneal epithelial substitute cell sheet shown in the present invention, the method for fixing the multilayered sheet and the living tissue are not particularly limited, and the cell sheet and the living tissue may be sutured, or the present invention Since the highly engraftable corneal epithelial substitute cell sheet or its multi-layered sheet as shown in FIG. 5 is rapidly engrafted with the living tissue, the cell sheet attached to the affected area does not need to be sutured to the living body side. In particular, in the latter case, a contact lens may be used in combination to protect the transplanted cell sheet.
[0038]
The production method of the multilayered sheet in the present invention is not particularly limited. For example, a generally known method of proliferating and multilayering 3T3 cells as a feeder layer, or high engraftment in close contact with the above carrier Examples include a method of producing by using a sex corneal epithelial substitute cell sheet. Specifically, the following method is exemplified.
(1) A cell sheet adhered to a carrier is adhered to a cell culture support, and then the medium is added to peel the carrier from the cell sheet, and further, a cell sheet adhered to another carrier is repeatedly adhered to the cell. A method of layering sheets.
(2) The cell sheet in close contact with the carrier is inverted and fixed on the carrier side on the cell culture support, another cell sheet is attached to the cell sheet side, and then the medium is added to peel off the carrier from the cell sheet. A method of layering cell sheets by repeating the operation of attaching another cell sheet.
(3) A method in which cell sheets in close contact with a carrier are brought into close contact with each other on the cell sheet side.
(4) A method in which a cell sheet in close contact with a carrier is applied to an affected part of a living body, the cell sheet is attached to a living tissue, the carrier is peeled off, and another cell sheet is stacked again.
[0039]
The stratified sheet in the present invention does not necessarily need to be composed only of corneal epithelial substitute cells. For example, corneal endothelial cell sheets produced by operating in the same manner as the corneal epithelial cell sheet can be superposed. Such a technique is extremely effective in making it closer to the anterior ocular tissue in the living body.
[0040]
For the purpose of detaching and recovering the highly engraftable corneal epithelial substitute cell sheet or its layered sheet with high yield, the cell culture support is tapped or shaken, and the medium is stirred using a pipette. The methods and the like may be used alone or in combination. In addition, the cultured cells may be separated and recovered by washing with an isotonic solution or the like as necessary.
[0041]
The use of the highly engraftable corneal epithelial substitute cell sheet or the stratified sheet thereof shown in the present invention is not limited at all. For example, as described above, a part or all of the anterior ocular tissue is damaged or missing. In addition to the affected area, it is effective in treating binocular intractable keratoconjunctival diseases that do not have corneal epithelial cells.
[0042]
The highly engrafted corneal epithelial substitute cell sheet obtained by the above-mentioned method or its multi-layered sheet is extremely superior in terms of non-invasiveness at the time of detachment compared to those obtained by the conventional method, and transplantation. Clinical applications such as corneas are strongly expected. In particular, unlike the conventional transplanted sheet, the highly engraftable corneal epithelial substitute cell sheet of the present invention or its multi-layered sheet has a high engraftment with the living tissue, and thus engrafts in the living tissue very quickly. This is considered to be an extremely effective technique that improves the treatment efficiency of the affected area and further reduces the burden on the patient. The cell culture support used in the method of the present invention can be used repeatedly.
【Example】
[0043]
Hereinafter, the present invention will be described in more detail based on examples, but these do not limit the present invention in any way.
[0044]
Examples 1 and 2
On a commercially available culture dish for 3.5 cmφ cell culture (Falcon 3001 manufactured by Becton Dickinson Labware), 30% of N-isopropylacrylamide monomer (Example 1) and 35% (Example 1) 0.1 ml of a solution dissolved in isopropyl alcohol was applied as in Example 2). An electron beam with an intensity of 0.25 MGy was irradiated to immobilize N-isopropylacrylamide polymer (PIPAAm) on the surface of the culture dish. After irradiation, the culture dish was washed with ion-exchanged water to remove residual monomer and PIPAAm not bound to the culture dish, dried in a clean bench, and sterilized with ethylene oxide gas to obtain a cell culture support material. . Was measured thermoresponsive polymer weight in the substrate surface, each 1.4 .mu.g / cm ² (Example 1), 1.5 [mu] g / cm ² (Example 2) was found to be coated. On the other hand, oral mucosal tissue was collected under deep anesthesia from a white rabbit of a keratoconjunctival epitheliosis model prepared by a conventional method, and the epithelial cells were obtained on the cell culture support material according to a conventional method. Cultured with 3T3 cells (Medium used: Cornepack (Kurabo Co., Ltd., 37 ° C., 5% CO ₂ ) As a result, the epithelial cells on any cell culture support material normally attached and proliferated did.
[0045]
Cells cultured after 6 days of culture become confluent, and a carrier molded from a polyvinylidene difluoride (PVDF) film having a diameter of 2.3 cm cut into a circular shape having a diameter of 1.8 cm on the cells cultured for 7 days. The medium was gently aspirated, and the cell culture support material was incubated at 20 ° C. for 30 minutes and cooled, so that the cells on any of the cell culture support materials were detached together with the covered carrier. The obtained cell sheet was sufficiently strong as a single sheet having a shrinkage rate of 5% or less.
[0046]
In each of the above examples, “low temperature treatment” was performed under the condition of incubation at 20 ° C. for 30 minutes. However, in the present invention, “low temperature treatment” is not limited to these temperatures and times. A preferable temperature condition for the “low temperature treatment” in the present invention is 0 ° C. to 30 ° C., and a preferable treatment time is 2 minutes to 1 hour.
[0047]
The oral mucosal cell sheets obtained in Examples 1 and 2 were transplanted according to a conventional method into white rabbits, which are keratoconjunctival epithelial disease models in which the corneal epithelial tissue part was defective. The oral mucosa cell sheet was allowed to adhere to the wound part for 15 minutes, and then the cell sheet that overlapped with the area other than the affected part was excised using a scalpel. At that time, the cell sheet and the living body were not sutured. In Example 2, a contact lens was attached to the affected area after transplantation. After 3 weeks, when the affected area was observed, the oral mucosal cell sheet in both Examples 1 and 2 was well engrafted in the eyeball.
[0048]
Example 3
The same as in Example 1 except that epithelial stem cells were collected as normal cells from the root tissue of white rabbit skin under deep anesthesia and cultured together with 3T3 cells on the cell culture support material of Example 1. The method was carried out. As a result, the hair root cells on the culture support material adhered normally and proliferated. After culturing for 2 weeks, a carrier molded from a polyvinylidene difluoride (PVDF) membrane with a diameter of 2.1 cm cut out into a circle with a diameter of 1.5 cm is covered, the medium is gently aspirated, and the cell culture support The whole material was incubated at 20 ° C. for 30 minutes and cooled, so that the cell sheet on the cell culture support material was peeled off together with the carrier covered. The peeled multilayered sheet was sufficiently strong as a single sheet having a shrinkage rate of 5% or less.
[0049]
The cell sheet obtained in Example 3 was transplanted to a white rabbit, which is a model of keratoconjunctival epitheliosis in which the corneal epithelial tissue portion was defective, according to a conventional method. The hair root cell sheet was allowed to adhere to the wounded part for 15 minutes, and then the cell sheet that overlapped the part other than the affected part was excised using a laser beam. At that time, the cell sheet and the living body were not sutured. Three weeks later, when the affected area was observed, the cell sheet was well engrafted in the eyeball.
[0050]
Example 4
The same as in Example 1 except that conjunctival epithelial cells were collected from the conjunctival tissue of white rabbit skin under deep anesthesia as a cell on the cell culture support material of Example 1 and cultured with 3T3 cells. The method was carried out. As a result, conjunctival epithelial cells on the culture support material adhered normally and proliferated. After culturing for 2 weeks, a carrier molded from a polyvinylidene difluoride (PVDF) membrane with a diameter of 2.1 cm cut out into a circle with a diameter of 1.5 cm is covered, the medium is gently aspirated, and the cell culture support The whole material was incubated at 20 ° C. for 30 minutes and cooled, so that the cell sheet on the cell culture support material was peeled off together with the carrier covered. The peeled multilayered sheet was sufficiently strong as a single sheet having a shrinkage rate of 3% or less.
[0051]
The cell sheet obtained in Example 4 was transplanted to a white rabbit, which is a model of keratoconjunctival epitheliosis in which the corneal epithelial tissue portion was defective, according to a conventional method. The conjunctival epithelial cell sheet was allowed to adhere to the wounded part for 15 minutes, and then the cell sheet that overlapped the part other than the affected part was excised using a laser beam. At that time, the cell sheet and the living body were not sutured. After 3 weeks, when the affected area was observed, the conjunctival cell stratification sheet satisfactorily adhered to the eyeball, and no blood vessel invasion from the conjunctiva was observed.
[0052]
Comparative Example 1
An oral mucosa cell sheet was produced in the same manner as in Example 1 except that an oral mucosa cell sheet was prepared in Example 1, and the cell sheet was peeled and contracted without using a carrier. The shrinkage at that time was 38%.
[0053]
The oral mucosal cell sheet obtained in the same manner as in Example 1 was transplanted to a rabbit lacking the corneal epithelial tissue according to a conventional method. The corneal epithelial cell sheet was allowed to adhere to the wounded part for 15 minutes, and then the cell sheet that overlapped the area other than the affected part was excised using a scalpel. At that time, the cell sheet and the living body were not sutured. When the affected area was observed one day after the transplantation, the oral mucosa cell sheet was poorly engrafted on the eyeball, and had fallen from the affected area.
[0054]
From the above results, it has been found that according to the present technology, it is possible to prepare a highly engraftable corneal epithelial substitute cell sheet or a multilayered sheet thereof having good adhesion to the anterior segment tissue. This is considered to be an extremely effective technology that can reduce the burden on patients by simplifying treatment and increasing efficiency, and that these cell sheets sufficiently cover and firmly adhere to the affected area, thus significantly reducing the patient's pain. It is done.
【The invention's effect】
[0055]
The highly engraftable corneal epithelial substitute cell sheet or its multi-layered sheet obtained by the present invention has extremely high engraftment properties to living tissues, and clinical applications such as corneal transplantation, corneal disease treatment, and myopia treatment are strongly expected. Therefore, the present invention is extremely useful in the fields of medicine, biology, etc., such as cell engineering and medical engineering.

Claims (13)

  A corneal epithelial substitute cell sheet comprising any of oral mucosal cells, hair root cells, conjunctival epithelial cells, or a mixture of two or more thereof, or a mixture of these with corneal epithelial cells, in close contact with a carrier with a cut-out center. Or its multilayered sheet.   The corneal epithelial substitute cell sheet or its multilayered sheet according to claim 1, wherein the corneal epithelial substitute cell sheet or its stratified sheet is peeled from the support without being treated with a proteolytic enzyme, and the contraction rate of the peeled cell sheet is kept at 20% or less.   The corneal epithelial substitute cell sheet according to claim 1 or 2, or a multilayered sheet thereof, wherein the carrier has a ring shape.   4. The corneal epithelial substitute cell sheet or a multilayered sheet thereof according to any one of claims 1 to 3, wherein the oral mucosal cells are derived from the buccal membrane.   The multilayered sheet is any one of oral mucosal cells, hair root cells, conjunctival epithelial cells, a mixture of two or more, or a mixture of these and corneal epithelial cells, which are stratified and cultured. The corneal epithelial substitute cell sheet according to claim 1 or a stratified sheet thereof.   The corneal epithelial substitute cell sheet according to any one of claims 1 to 5 or a stratified sheet thereof for treating an affected part in which a part or all of the anterior ocular tissue is damaged or missing.   7. The corneal epithelial substitute cell sheet or a stratified sheet thereof according to claim 6, wherein the treatment covers the corneal epithelial substitute cell sheet or the stratified sheet thereof without stitching the affected part.   8. The corneal epithelial substitute cell sheet or a stratified sheet thereof according to claim 7, which is cut along the size and shape of the affected part when the affected part is covered.   9. The corneal epithelial substitute cell sheet or a stratified sheet thereof according to any one of claims 6 to 8, wherein the treatment target is a bilateral intractable keratoconjunctival disease. Oral mucosal cells, hair root cells, conjunctival epithelial cells or two or more on a cell culture support whose surface is coated with a temperature-responsive polymer having an upper or lower critical dissolution temperature in water of 0 to 80 ° C. Or a mixture of these and corneal epithelial cells is cultured, and if necessary, the cultured cell layer is layered by a conventional method,
(1) The culture solution temperature is set to the upper critical solution temperature or higher or the lower critical solution temperature or lower,
(2) Adhering the cultured corneal epithelial cell sheet or the multilayered sheet thereof to a carrier having a shape obtained by cutting out the center,
(3) A method for producing a corneal epithelial substitute cell sheet or a stratified sheet thereof, wherein the corneal epithelial substitute cell sheet or the multilayered sheet is peeled off together with the carrier.   11. The method for producing a corneal epithelial substitute cell sheet or a stratified sheet thereof according to claim 10, wherein the carrier has a ring shape.   12. The method for producing a corneal epithelial substitute cell sheet or a stratified sheet thereof according to claim 10 or 11, wherein the temperature-responsive polymer is poly (N-isopropylacrylamide).   The method for producing a corneal epithelial substitute cell sheet or a multilayered sheet thereof according to any one of claims 10 to 12, wherein the detachment is not treated with a proteolytic enzyme.