JP2012010630A - Cell cultured product transfer tool - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cell culture product transfer tool which can surely and simply hold a sheet-like cell culture product and highly accurately transfer the culture product to a desired position without breaking the culture product.SOLUTION: The cell culture product transfer tool 10 includes an outer cylinder 14, an inner cylinder 16 movably disposed in the outer cylinder 14, a plunger 18 inserted into the inner cylinder 16, and an absorbing member 20 disposed in the inner cylinder 16 and pressed with the plunger 18. The adsorbing part 28 of the inner cylinder 16 is contacted with a sheet-like cell culture product 52 in a state that the absorbing member 20 is compressed with the plunger 18, and the compression state of the absorbing member 20 is released to adsorb the sheet-like cell culture product 52 to the adsorbing part 28. The sheet-like cell culture product 52 is transferred together with the cell culture product transfer tool 10 including the inner cylinder 16.

Description

  The present invention relates to a cell culture transfer device capable of transferring a sheet-like cell culture used for treatment to a desired position.

  In recent years, in the treatment of myocardial infarction and the like, a treatment method for transplanting a sheet-like cell culture obtained by culturing and organizing a patient's own cells to an affected area is widely known. Such a sheet-like cell culture is fragile because it is thin, and has high self-adhesion because it contains moisture, and is removed from the cultured container and transferred to the affected area or other containers. Requires advanced techniques. Therefore, a transfer device for transferring such a sheet-shaped cell culture is used.

  In this transfer device, for example, a slide member is slidably provided inside a hollow outer cylinder, and a flexible sheet support is provided at the tip of the slide member. Then, the sheet support is provided so as to be accommodated inside the outer cylinder by displacing the slide member with respect to the outer cylinder, and the sheet-like cell is formed on the sheet support that is planar outside the outer cylinder. The sheet-like cell culture is accommodated in the outer cylinder by placing the culture and pulling the slide member. And after arrange | positioning the front-end | tip part of an outer cylinder to the position which faces a patient's affected part, a sheet-like cell culture is transplanted to the said affected part by pushing out a slide member (for example, refer patent document 1).

JP 2009-511 A

  However, when the sheet-shaped cell culture is placed on the sheet support and accommodated in the outer cylinder, the sheet-shaped cell culture is deformed into a curved shape together with the sheet support, so that the sheet-shaped and fragile sheet-shaped cell culture There are concerns about breakage, deformation, etc.

  Further, when the sheet-shaped cell culture is placed on a sheet support, it is difficult to peel the sheet-shaped cell culture from a culture container or the like, while the sheet-shaped cell culture is removed from the sheet support. Since transplantation is performed so as to slide onto the affected area, for example, when the surface of the affected area is uneven, it is difficult to transplant the sheet-shaped cell culture to a desired position.

  The present invention has been made in consideration of the above-mentioned problems, and is capable of reliably and simply holding a sheet-like cell culture and transferring it to a desired position with high accuracy and without being damaged. An object is to provide a culture transfer device.

To achieve the above object, the present invention provides a cell culture transfer device for transferring a sheet-like cell culture,
Body,
An absorbent body provided at an end of the body and capable of absorbing liquid with an elastic force;
A holding portion that is formed at an end of the body and has a communication path that contacts the cell culture and communicates the inside and outside of the body;
A pressing body, which is provided so as to be displaceable along the axial direction of the body, and compresses the absorber against the elastic force;
With
The absorber is provided between an end of the body and the pressing body.

  According to the present invention, an absorbent body having elasticity and capable of absorbing liquid is provided at an end portion of the body, and the end portion is provided with a holding portion that comes into contact with a sheet-shaped cell culture, and the holding The part is provided with a communication path that communicates the inside and the outside of the body. Then, the holding part is brought into contact with the cell culture in a state where the absorbent body is compressed by the pressing body, and the liquid present around the cell culture is returned through the communication path when the compressed absorbent body is restored by elastic force. Absorbed by the absorber, the cell culture is adsorbed to the holding part. In addition, the presence of the absorber prevents a liquid such as moisture from flowing back, and it is possible to maintain the state in which the cell culture is reliably held in the holding portion. Therefore, the sheet-like cell culture can be easily and reliably held in the holding unit and transferred to the affected area of the patient.

  In addition, as described above, the cell culture held in the holding unit releases the absorbed liquid by compressing the absorber again under the action of displacing the pressing body, and accordingly, the holding state in the holding unit is changed. It can be easily and reliably released. As a result, after the cell culture transfer device is moved to the affected area of the patient, the cell culture can be reliably and easily transplanted to the affected area by releasing the holding state of the cell culture at the position facing the affected area.

  That is, a cell culture transfer device securely and simply holds a sheet-like cell culture, transfers it to a desired position in the affected area with high precision, and transplants it, or transfers it from a culture container (petri dish) to another culture container (petri dish). Can be transferred to.

  The body is provided between the first body, the second body slidably provided in the first body, and the first body and the second body, and the second body is used as the cell culture. A first elastic member that urges in a direction away from the first elastic member, and the absorber and the holding portion may be provided in the second body.

  Furthermore, it is good to provide the displacement control means which controls the relative displacement along the axial direction of the 2nd body with respect to a 1st body. As a result, it is possible to avoid applying unnecessary pressure to the cell culture, and the operation can be performed without damaging the cell culture.

  Furthermore, the displacement restricting means is provided on the second body and has an elastic force in a radially outward direction, an engagement portion formed on the first body and engaged with a part of the arm, It is good to have. Thereby, when the second body is displaced with respect to the first body, the arm is displaced radially outward by a resilient force at a position facing the engaging portion, and is engaged with the engaging portion, whereby the first body The relative displacement along the axial direction of the second body with respect to is reliably restricted.

  Furthermore, the first body is provided with a release mechanism for releasing the displacement restricted state of the second body by the displacement restricting means, so that, for example, the transfer of the cell culture by the cell culture transfer device is completed, and the second body When canceling the displacement regulation state of the body, it is possible to perform the release operation simply and reliably using the release mechanism. This makes it possible to continuously transfer a plurality of cell cultures.

  Further, when the second body is provided with a second elastic member having an elastic force that urges in the same direction as the absorber, the elastic force of the absorber is restored when the absorber compressed by the pressing body is returned. In addition, since the elastic force of the second elastic member can be urged against the pressing body, the liquid can be reliably absorbed by the absorber.

  Furthermore, after the elastic force of the first elastic member is set larger than the elastic force of the absorber and the second elastic member, the absorber and the second elastic member are compressed by the pressing body against the elastic force. The pressing body can displace the second body relative to the first body against the elastic force of the first elastic member. Thereby, it is possible to prevent the cell culture from being damaged due to the backflow of air from the holding unit that occurs when the absorber is compressed after the holding unit comes into contact with the cell culture.

  Furthermore, when the holding part is formed of a material having flexibility and hydrophobicity, when the cell culture held in the holding part is transplanted to the affected part, even if the affected part is uneven, The holding part can be suitably deformed so as to follow the affected part, and liquid such as surrounding water is difficult to adhere to the holding part, so that the cell culture can be transplanted reliably and stably. be able to.

  Still further, the communication path may be a plurality of holes spaced at equal intervals in the holding portion. Thereby, when holding a cell culture by a holding part, it becomes possible to take in peripheral water etc. suitably to an absorber side through a hole.

  According to the present invention, the following effects can be obtained.

  That is, an absorber having elasticity and capable of absorbing liquid is provided at the end of the body, and at the end, a holding portion that contacts the sheet-like cell culture is provided, and the holding portion includes the By providing a communication path that connects the inside and the outside of the body, and the absorbent body is compressed by the pressing body, the holding portion is brought into contact with the cell culture, and the compressed absorbent body is restored by elastic force. At this time, the liquid present around the cell culture is absorbed by the absorber through the communication path, and accordingly, the cell culture is adsorbed to the holding portion. As a result, the sheet-like cell culture can be easily and reliably held in the holding portion, and transferred to a desired position in the affected area of the patient with high accuracy and transplanted.

1 is an overall configuration diagram of a cell culture transfer device according to an embodiment of the present invention. 2A is an external perspective view of an inner cylinder constituting the cell culture transfer device of FIG. 1, and FIG. 2B is a cross-sectional view taken along IIB-IIB of FIG. 2A. It is a top view which shows the adsorption | suction part in the inner cylinder of FIG. 4A is an external perspective view showing a modified example of the inner cylinder constituting the cell culture transfer device of FIG. 1, and FIG. 4B is a cross-sectional view taken along IVB-IVB of FIG. 4A. FIG. 5A shows a state in which the cell culture transfer device of FIG. 1 is inserted into a culture container, and FIG. 5B is an operation explanatory view showing a state in which the absorber is compressed by pressing the plunger. 6A shows a state in which the plunger is further pressed in the cell culture transfer device of FIG. 5B to displace the inner cylinder, and FIG. 6B releases the pressing force of the plunger and expands the adsorbing portion with elastic force. It is operation | movement explanatory drawing which shows the state. FIG. 7A shows a state in which the sheet-shaped cell culture adsorbed on the adsorbing portion in FIG. 6B is transferred to the affected area of the patient, and FIG. 7B shows a state in which the sheet-shaped cell culture is placed on the affected area. It is operation | movement explanatory drawing shown. FIG. 8A shows a state where the plunger is pressed again in the cell culture transfer device of FIG. 7B and the sheet-like cell culture is transplanted to the affected part, and FIG. 8B shows a state where the cell culture transfer device is detached from the affected part. It is operation | movement explanatory drawing which shows. FIG. 9A and FIG. 9B are overall configuration diagrams of a cell culture transfer device provided with a lock release mechanism that can release the displacement restriction state of the inner cylinder by the stopper mechanism. It is a whole block diagram of the cell culture transfer instrument provided with the 1st ring body on the outer periphery of the inner cylinder. FIG. 11A and FIG. 11B are overall configuration diagrams of a cell culture transfer device provided with a displacement regulating means for regulating the displacement of the inner cylinder. 12A and 12B are general configuration diagrams of a cell culture transfer device including a stopper mechanism having a second ring body provided on the outer periphery of the inner cylinder. It is a whole block diagram of the cell culture culture transfer instrument provided with the stopper mechanism which has a stopper wall in the front-end | tip of an outer cylinder part.

  A preferred embodiment of the cell culture transfer device according to the present invention will be described below and described in detail with reference to the accompanying drawings.

  In FIG. 1, reference numeral 10 indicates a cell culture transfer device according to an embodiment of the present invention.

  This cell culture transfer device 10 is used, for example, for transplanting a sheet-shaped cell culture to an affected area of a patient. As shown in FIGS. 1 to 8, the cell culture transfer device 10 includes an outer cylinder (first body) 14 having a collar 12, and an inner portion that is displaceably provided in the outer cylinder 14. A cylindrical body (second body) 16, a plunger (pressing body) 18 inserted into the inner cylindrical body 16, an absorber 20 provided inside the inner cylindrical body 16 and pressed by the plunger 18, And a stopper mechanism (displacement restricting means) 22 for restricting the relative displacement of the inner cylinder 16 with respect to the outer cylinder 14. 1 and 2, the upper side of the cell culture transfer device 10 is the “proximal end” side (arrow A direction), and the lower side of the cell culture transfer device 10 is the “distal end” side (arrow B direction). The same applies to the other figures.

  The outer cylinder body 14 includes, for example, a main body portion 24 formed in a cylindrical shape from a resin material, and a flange portion 12 provided on the base end side of the main body portion 24 and protruding outward in the radial direction. The buttocks 12 are used when an operator (not shown) grasps and operates the cell culture transfer device 10. The main body 24 is formed with substantially the same diameter along the axial direction (arrows A and B directions).

  A plurality of holes 26a and 26b are provided near the tip of the outer cylinder 14 so as to penetrate in the radial direction and engage with a claw 34 of a stopper mechanism 22 described later. The holes 26 a and 26 b are provided at a position slightly on the proximal side (in the direction of arrow A) from the distal end of the outer cylindrical body 14, and at least two or more are provided along the circumferential direction of the outer cylindrical body 14. .

  The inner cylindrical body 16 is slightly smaller in diameter than the main body portion 24 of the outer cylindrical body 14 and is formed in a cylindrical shape having the same diameter, and the tip is closed by a suction portion (holding portion) 28. The adsorbing portion 28 is formed in a planar shape orthogonal to the axis of the inner cylindrical body 16, and is, for example, a flexible and hydrophobic material (for example, fluororesin, Teflon (registered trademark), Teflon). A resinous material coated with

  Further, the suction portion 28 is formed with a plurality of openings (communication passages) 30 that communicate the outside and the inside of the inner cylindrical body 16, and the openings 30 are formed in a circular shape having substantially the same diameter, for example. And arranged so as to be spaced apart from each other at equal intervals. Instead of providing the opening 30 for the suction portion 28, the suction portion 28 may be formed in a mesh shape. That is, the adsorbing portion 28 is not limited to the form as long as the adsorbing portion 28 has a plurality of holes that allow the inside and the outside of the inner cylindrical body 16 to communicate with each other.

  Further, a stopper mechanism 22 is provided in the vicinity of the tip of the inner cylindrical body 16, and the stopper mechanism 22 is formed integrally with the inner cylindrical body 16 and has a plurality of arms having a resilient force toward the radially outward direction. And a claw portion (engagement portion) 34 formed at the tip of the arm portion 32 (see FIGS. 2A and 2B). The quantity of the arm part 32 and the claw part 34 is set corresponding to the quantity of the hole parts 26a, 26b in the outer cylinder body 14, and the claw part 34 is inserted into the hole parts 26a, 26b, thereby the inner cylinder. The relative displacement of the body 16 along the axial direction (arrow A, B direction) with respect to the outer cylindrical body 14 is restricted (see FIG. 6A).

  The stopper mechanism 22 is not limited to the case where the arm portion 32 and the claw portion 34 are formed integrally with the inner cylinder 16 as described above. For example, the stopper mechanism 22 is shown in FIGS. 4A and 4B. Like the stopper mechanism 22a, for example, a spring material 36 made of a metal material and a resin material may be provided in the recess 38 formed on the outer peripheral surface of the inner cylinder body 16. The spring member 36 has an inner peripheral portion mounted in the recess 38, an outer peripheral portion projecting radially outward with respect to the inner peripheral portion, and an end portion projecting with respect to the outer peripheral surface of the inner cylindrical body 16. Yes. Further, the spring member 36 has a resilient force in the radially outward direction with the inner peripheral part as a fulcrum, and the outer peripheral part is tiltable in the radially inward direction.

  Then, the outer peripheral portion of the spring material 36 is inserted into the holes 26 a and 26 b of the outer cylinder body 14, whereby the inner cylinder body 16 to which the spring material 36 is attached is displaced relative to the outer cylinder body 14. That is blocked.

  Furthermore, an absorber 20 having elasticity is provided at the tip of the inner cylinder 16 so as to be held by the suction portion 28. The absorbent body 20 is made of, for example, a water-absorbing sponge, is formed in a cylindrical shape having a predetermined height along the axial direction, and is disposed coaxially with the inner cylindrical body 16 and the outer cylindrical body 14. The And the absorber 20 is provided so that it can expand-contract along an axial direction (arrow A, B direction), and the diameter is set so that it may become larger than the external shape of the sheet-like cell culture 52. FIG.

  In detail, the absorber 20 is good to form from a polyurethane sponge, a polypropylene urethane sponge, a nylon nonwoven fabric, cotton pulp etc., for example.

  Further, a first spring (second elastic member) 40 made of, for example, a coil spring is provided on the outer peripheral side of the absorber 20, and is interposed between the suction portion 28 and a plunger 18 described later. The plunger 18 is urged in a direction away from the suction portion 28 (in the direction of arrow B). The first spring 40 is formed of a material having biocompatibility such as stainless steel, and is provided coaxially with the absorber 20.

  On the other hand, a second spring (first elastic member) 42 is interposed in the inner cylindrical body 16 between the outer peripheral surface near the base end thereof and the inner peripheral surface of the outer cylindrical body 14. It is biased toward the base end side (arrow A direction). The second spring 42 is formed of a coil spring like the first spring 40 and has a large elastic force with respect to the first spring 40.

  The plunger 18 is formed at the tip of the plunger 18 and is inserted into the inner cylindrical body 16 to be in contact with the absorber 20 and the first spring 40. The plunger 18 is connected to the pressing portion 44 and is connected to the proximal end side (in the direction of arrow A). And a grip portion 48 provided at the proximal end of the shaft portion 46 and gripped by an operator (not shown). The plunger 18 is guided by a guide means (not shown) so as to be displaceable along the axial direction (in the directions of arrows A and B) coaxially with the inner cylinder 16.

  The pressing portion 44 is formed in a disk shape whose diameter is increased radially outward with respect to the shaft portion 46, and is formed with a diameter substantially equal to or slightly larger than the diameter of the absorber 20, and the outer peripheral surface thereof is an inner cylinder. It is in sliding contact with the inner peripheral surface of the body 16. For this reason, the inside of the inner cylindrical body 16 is sealed by the pressing portion 44. The surgeon grips the grip portion 48 and displaces the plunger 18 toward the inner cylinder body 16 (in the direction of arrow B), whereby the absorber 20 and the first spring 40 are pressed by the pressing portion 44. Compressed.

  The cell culture transfer device 10 according to the embodiment of the present invention is basically configured as described above. Next, the operation and effects thereof will be described. Here, for example, the case where the sheet-like cell culture 52 cultured in a culture container 50 such as a petri dish is transferred to the affected part 56 of the patient 54 using the cell culture transfer device 10 will be described.

  First, as shown in FIG. 5A, a culture vessel 50 in which a sheet-like cell culture 52 is cultured is prepared, and an operator (not shown) transfers the cell culture while holding the buttocks 12 of the outer cylindrical body 14. The instrument 10 is moved above the culture vessel 50. Then, the tip of the cell culture transfer device 10 is arranged so as to be substantially in line with the sheet-shaped cell culture 52, and is gradually lowered toward the sheet-shaped cell culture 52 and the culture container 50 to be removed. The tip of the cylinder 14 is brought into contact with the culture vessel 50. At this time, the diameter of the outer cylinder 14 is set larger than the size of the sheet-shaped cell culture 52, and the sheet-shaped cell culture 52 is covered with the outer cylinder 14.

  Next, as shown in FIG. 5B, the surgeon (not shown) grasps the grasping portion 48 of the plunger 18 and presses it downward (in the direction of arrow B), whereby the absorber 20 is absorbed by the pressing portion 44. And the 1st spring 40 is pressed toward the adsorption | suction part 28 side (arrow B direction), and is compressed gradually. Then, as shown in FIG. 6A, in a state where the absorber 20 and the first spring 40 are completely compressed, the plunger 18 is further pressed downward (in the direction of arrow B), thereby compressing the compressed absorber. The suction portion 28 is pressed downward together with the first spring 40 and the first spring 40, and accordingly, the inner cylinder 16 is displaced downward along the outer cylinder 14 while gradually compressing the second spring 42. As the inner cylinder 16 is lowered, the adsorbing portion 28 of the inner cylinder 16 comes into contact with the sheet-like cell culture 52.

  In addition, the claw portion 34 constituting the stopper mechanism 22 is inserted into the holes 26 a and 26 b of the outer cylindrical body 14 in a state where the adsorption portion 28 of the inner cylindrical body 16 is in contact with the sheet-like cell culture 52. The relative displacement along the axial direction of the inner cylinder 16 with respect to the outer cylinder 14 is restricted.

  The locking position of the inner cylindrical body 16 is set to a position where the end surface of the adsorbing portion 28 is slightly on the proximal end side (arrow A direction) with respect to the distal end of the outer cylindrical body 14. In other words, the end surface of the adsorption unit 28 is set to a position where it does not contact the surface of the culture vessel 50 (for example, a position separated from the surface of the culture vessel 50 by 0.05 mm to 3 mm). It is avoided that the culture 52 is crushed.

  Then, with the operator holding the outer cylinder 14, the plunger 18 is gradually released from the downward pressing force against the plunger 18 as shown in FIG. Under the elastic action of 40, the absorber 20 is pressed upward (in the direction of arrow A), and the absorbent body 20 expands upward. As the absorbent body 20 expands, the water (liquid) around the sheet-shaped cell culture 52 is absorbed by the absorbent body 20 through the opening 30 of the adsorbing section 28, and accordingly the sheet-shaped cell culture 52. Is peeled off from the culture vessel 50 and is adsorbed to the adsorbing portion 28 in a planar shape.

  In other words, the sheet-like cell culture 52 is adsorbed to the adsorbing portion 28 together with the moisture present in the vicinity.

  In this case, since the inner cylindrical body 16 is fixed to the outer cylindrical body 14 via the stopper mechanism 22, even if the operator releases the pressing force against the plunger 18, the inner cylindrical body 16 remains above the outer cylindrical body 14 (arrows). (A direction) is not displaced.

  Next, as shown in FIG. 6B and FIG. 7A, in a state where the sheet-shaped cell culture 52 is adsorbed to the adsorption portion 28 of the inner cylinder 16, the operator holds the cell culture transfer device 10 in the affected area of the patient 54. Move to 56. Then, as shown in FIG. 7A, after the cell culture transfer device 10 is arranged so that the sheet-shaped cell culture 52 faces the affected area 56 of the patient 54, the cell culture transfer device 10 is gradually lowered and the tip of the outer cylinder 14 is moved to the affected area. 56 (see FIG. 7B).

  Then, as shown in FIG. 8A, the surgeon slowly presses the plunger 18 again downward (in the direction of arrow B) and compresses the absorber 20 and the first spring 40 via the pressing portion 44. As a result, the moisture absorbed in the absorber 20 flows out to the sheet-shaped cell culture 52 side through the opening 30, and the adsorption force of the sheet-shaped cell culture 52 by the adsorption unit 28 is also released. It will be. As a result, the sheet-like cell culture 52 is separated from the adsorbing part 28 together with moisture and transplanted (attached) to the affected part 56 facing the adsorbing part 28.

  Finally, as shown in FIG. 8B, the cell culture transfer device 10 is moved away from the affected area 56 while maintaining the pressing force against the plunger 18, whereby the sheet-like cell culture 52 of the patient 54 is affected by the affected area 56. The transplant is complete.

  When another sheet-shaped cell culture is transplanted using the above-described cell culture transfer device 10 after the transplantation of the sheet-shaped cell culture 52 is completed, the claw portion 34 of the stopper mechanism 22 is attached to the outer cylinder. By pressing from the outer peripheral side of the body 14 to the inner peripheral side and releasing the engaged state, the inner cylindrical body 16 rises due to the elastic force of the second spring 42 and returns to the initial state shown in FIG. Can be made.

  Further, as in the cell culture transfer device 60 shown in FIGS. 9A and 9B, the displacement restriction state of the inner cylinder 16 by the stopper mechanism 22 can be released at a position facing the holes 26 a and 26 b of the outer cylinder 14. A simple lock release mechanism (release mechanism) 62 may be provided.

  The lock release mechanism 62 is provided on the outer peripheral portion of the outer cylindrical body 14 and includes a pair of release arms 64 that can be tilted inward in the radial direction, and the distal end of the release arm 64 faces the inner cylindrical body 16 side. Thus, a protruding portion 66 is formed. The protrusion 66 is disposed so as to face the holes 26a and 26b of the outer cylindrical body 14, and after the transplantation of the sheet-like cell culture 52 to the affected part 56 is completed, the operator removes the release arm 64 from the inner cylindrical body. By tilting toward the 16th side and inserting the projection 66 into the holes 26a and 26b, the claw 34 of the stopper mechanism 22 is pressed inward in the radial direction by the projection 66, and the engagement with the holes 26a and 26b. The combined state is released.

  As a result, the displacement regulation state of the inner cylinder body 16 is released, and the inner cylinder body 16 can be easily and reliably returned to the initial state in which the inner cylinder body 16 is displaced upward under the elastic action of the second spring 42. Accordingly, it becomes possible to continuously transfer a plurality of cell cultures.

  As described above, in the present embodiment, the absorbent body 20 having water absorption is brought close to the sheet-shaped cell culture 52 in a compressed state under the pressing action of the plunger 18, and the absorbent body 20 by the plunger 18 is used. By releasing the compressed state, the sheet-shaped cell culture 52 can be adsorbed to the adsorbing portion 28 of the inner cylindrical body 16 by utilizing the force of absorbing moisture into the absorber 20. As a result, the sheet-like cell culture 52 can be easily and reliably removed from the culture vessel 50 and transferred with the cell culture transfer device 10.

  On the other hand, the sheet-shaped cell culture 52 adsorbed by the cell culture transfer device 10 releases the absorbed moisture by pressing the plunger 18 downward again and compressing the absorbent body 20, and the sheet-shaped cell culture is released. The adsorption state of the object 52 is easily and reliably released. As a result, after the cell culture transfer device 10 is moved to the affected part 56 of the patient 54, the sheet-like cell culture 52 is released by releasing the adsorbed state of the sheet-like cell culture 52 at a position facing the affected part 56. Can be transplanted (attached) to the affected area 56 reliably and easily.

  That is, it becomes possible to take out the sheet-like cell culture 52 from the culture vessel 50 by the cell culture transfer device 10 and transfer it, and to transplant it to the affected part 56 of the patient 54 for treatment. Similarly, the sheet-like cell culture 52 can be taken out from the culture vessel 50 by the cell culture transfer device 10 and reliably transferred to another culture vessel.

  Moreover, since the adsorption | suction part 28 of the inner cylinder 16 is formed in planar shape, when adsorb | sucking the sheet-like cell culture 52, it can peel and adsorb | suck in the state cultured with the culture container 50. At the same time, it can be transplanted (attached) to the affected area 56. As a result, it can be stably transferred without changing the form of the sheet-like cell culture 52, and self-adhesion and damage of the sheet-like cell culture 52 can be avoided.

  Further, since a plurality of openings 30 are provided at equal intervals in the adsorbing portion 28 of the inner cylindrical body 16, moisture is reliably and averagely absorbed when adsorbing the sheet-like cell culture 52. Absorbed into the body 20, the sheet-like cell culture 52 can be stably peeled and adsorbed. On the other hand, when the adsorbed sheet-like cell culture 52 is removed, water can be reliably and averagely released from the plurality of openings 30, so that the sheet-like cell culture 52 can be reliably given to the adsorbing portion 28. It is possible to remove the needle and transplant (paste) it to the affected part 56.

  In addition, by providing the absorbent body 20, when the sheet-shaped cell culture 52 is adsorbed, moisture does not flow backward, and the sheet-shaped cell culture 52 can be reliably maintained adsorbed by the adsorption unit 28. Is possible.

  Furthermore, since the adsorbing portion 28 of the inner cylindrical body 16 is flexible, the sheet-like cell culture cell 52 is also applied when the sheet-like cell culture 52 is affixed to the affected part 56 having a slight unevenness. The adsorbing portion 28 to which the culture 52 is adsorbed can be deformed so as to become familiar with the affected area 56, and the sheet-like cell culture 52 can be reliably transplanted (attached).

  Furthermore, since the adsorbing part 28 is formed of a hydrophobic material, it is possible to prevent moisture and the like from adhering to the adsorbing part 28, and the sheet-like cell culture 52 is allowed to adhere to the adsorbing part 28. It is suitable when separating from.

  Further, since the sheet-shaped cell culture 52 is adsorbed substantially coaxially with the axes of the outer cylinder 14, the inner cylinder 16, and the plunger 18 constituting the cell culture transfer device 10, the sheet-shaped cell culture 52 is used. Can be easily positioned and can be transplanted (attached) to the affected area 56 with high accuracy.

  Furthermore, by setting the elastic force of the second spring 42 to be larger than the elastic force of the first spring 40, the absorber 20 and the second spring 42 are compressed by the plunger 18 against the elastic force, and then The plunger 18 can displace the inner cylinder body 16 with respect to the outer cylinder body 14 against the elastic force of the second spring 42. Thus, the sheet-like cell culture caused by the backflow of air from the adsorption portion 28 that occurs when the absorber 20 is compressed after the adsorption portion 28 of the inner cylinder 16 contacts the sheet-like cell culture 52. The breakage of 52 can be prevented.

  Furthermore, the claw 34 constituting the stopper mechanism 22 is inserted into the holes 26a and 26b of the outer cylinder 14 in a state where the adsorbing part 28 of the inner cylinder 16 is in contact with the sheet-like cell culture 52. Since the relative displacement along the axial direction of the inner cylindrical body 16 with respect to the outer cylindrical body 14 is restricted, the inner cylindrical body 16 including the adsorbing portion 28 with respect to the sheet-like cell culture 52 is removed. The transfer operation can be performed without damaging the sheet-like cell culture 52 without applying pressure more than necessary.

  Instead of the second spring 42 described above, a first ring body 72 having an elastic force with respect to the outer peripheral surface of the inner cylindrical body 16 is provided as in the cell culture transfer device 70 shown in FIG. It may be. The first ring body 72 is made of, for example, an O-ring, and is attached to an annular groove formed on the outer peripheral surface of the inner cylindrical body 16, and its outer peripheral surface is in sliding contact with the inner peripheral surface of the outer cylindrical body 14. Yes.

  That is, since the first ring body 72 becomes a sliding resistance when the inner cylinder body 16 descends along the inside of the outer cylinder body 14, the magnitude of the sliding resistance is determined by the first spring 40 and the absorber. The second spring 42 can be made unnecessary by setting it to be larger than the elastic force of 20, and after the first spring 40 and the absorber 20 are compressed, the inner cylinder 16 is slid. It can be displaced downward against dynamic resistance. Further, instead of the first ring body 72 described above, the claw portion 34 of the stopper mechanism 22 may be provided so as to be in sliding contact with the inner peripheral surface of the outer cylindrical body 14. Since the inner cylindrical body 16 becomes a sliding resistance when descending along the inside of the outer cylindrical body 14, the magnitude of the sliding resistance is set larger than the elastic force of the first spring 40 and the absorber 20. Thus, the second spring 42 can be dispensed with.

  Further, instead of the second spring 42, a displacement regulating means for regulating the downward displacement of the inner cylinder 16 by the pressing portion 44 of the plunger 18 as in the cell culture transfer device 80 shown in FIGS. 11A and 11B. 82 may be provided on the inner cylinder 16. The displacement regulating means 82 includes a lock arm 84 provided on the outer peripheral portion of the inner cylindrical body 16 and an engagement groove 86 formed on the inner peripheral surface of the outer cylindrical body 14 and engaged with the lock arm 84. The tip end of the lock arm 84 is provided so as to be tiltable in the radially inward direction.

  11A, before the first spring 40 and the absorber 20 are compressed by the plunger 18, the pressing portion 44a of the plunger 18 formed thick along the axial direction causes the lock arm 84 to move. The tilting operation is restricted and the engagement groove 86 is engaged. Therefore, the inner cylinder 16 is not displaced relative to the outer cylinder 14 along the axial direction. Next, as shown in FIG. 11B, when the first spring 40 and the absorber 20 are compressed by the plunger 18, the pressing portion 44 a moves downward of the lock arm 84. The tilt restriction state is released, and tilting is performed in the radial inward direction. As a result, the lock arm 84 is separated from the engagement groove 86, and the inner cylinder body 16 can be displaced downward by releasing the displacement restricting state of the inner cylinder body 16.

  On the other hand, instead of providing the inner cylinder 16 with the arm part 32 and the claw part 34 constituting the stopper mechanism 22, the outer periphery of the inner cylinder 16 is like a cell culture transfer device 90 shown in FIGS. 12A and 12B. A second ring body 92 (for example, an O-ring) may be provided on the surface, and the second ring body 92 may be provided in a radially compressed state between the second ring body 92 and the inner peripheral surface of the outer cylindrical body 14. Good. In this case, the second ring body 92 is provided at a position substantially the same as the claw portion 34 with respect to the inner cylindrical body 16. When the inner cylinder body 16 is lowered under the pressing action of the plunger 18, the second ring body 92 is radially outward at a position facing the holes 26 a and 26 b formed on the inner peripheral surface of the outer cylinder body 14. It expands and is inserted into the holes 26a and 26b. Thereby, the relative displacement along the axial direction (arrow A, B direction) of the inner cylinder 16 with respect to the outer cylinder 14 is regulated.

  Further, instead of the arm part 32 and the claw part 34 described above, like the cell culture transfer device 100 shown in FIG. 13, an annular projecting radially inward from the inner peripheral surface is provided at the tip of the outer cylindrical body 14. A stopper mechanism 104 including the stopper wall 102 may be provided. The stopper wall 102 is substantially orthogonal to the axis of the outer cylinder 14 and is formed on the base end side (arrow A direction) by a predetermined distance with respect to the tip. Specifically, the stopper wall 102 is provided at a position where the adsorbing portion 28 can come into contact with the sheet-shaped cell culture 52 when the inner cylindrical body 16 descends and comes into contact with the stopper wall 102.

  When the inner cylinder body 16 is lowered under the pressing action of the plunger 18, the suction portion 28 provided at the tip of the inner cylinder body 16 is locked by coming into contact with the stopper wall 102, so that the outer cylinder body 14 is locked. The relative displacement along the axial direction (arrows A and B directions) of the inner cylinder 16 is restricted, and the adsorbing portion 28 comes into contact with the sheet-shaped cell culture 52. In other words, it is avoided that the inner cylinder 16 is lowered too much toward the sheet-shaped cell culture 52, and pressure is not applied to the sheet-shaped cell culture 52.

  In addition, the cell culture transfer instrument according to the present invention is not limited to the above-described embodiment, and it is needless to say that various configurations can be adopted without departing from the gist of the present invention.

10, 60, 70, 80, 90, 100 ... Cell culture transfer device 14 ... Outer cylinder 16 ... Inner cylinder 18 ... Plunger 20 ... Absorber 22, 22a, 104 ... Stopper mechanism 28 ... Adsorption part 30 ... Opening DESCRIPTION OF SYMBOLS 40 ... 1st spring 42 ... 2nd spring 44, 44a ... Press part 50 ... Culture container 52 ... Sheet-like cell culture 56 ... Affected part 62 ... Lock release mechanism 72 ... 1st ring body 82 ... Displacement control means 92 ... 2nd Ring body 102 ... stopper wall

Claims (9)

In a cell culture transfer device for transferring a sheet-like cell culture,
Body,
An absorbent body provided at an end of the body and capable of absorbing liquid with an elastic force;
A holding portion that is formed at an end of the body and has a communication path that contacts the cell culture and communicates the inside and outside of the body;
A pressing body, which is provided so as to be displaceable along the axial direction of the body, and compresses the absorber against the elastic force;
With
The cell culture transfer device, wherein the absorber is provided between an end of the body and the pressing body. The cell culture transfer device according to claim 1,
The body includes a first body;
A second body movably provided within the first body;
A first elastic member that is provided between the first body and the second body and biases the second body in a direction away from the cell culture;
With
The cell culture transfer device, wherein the absorber and the holding part are provided in the second body. The cell culture transfer device according to claim 2,
A cell culture transfer device comprising displacement restriction means for restricting relative displacement along an axial direction of the second body with respect to the first body. The cell culture transfer device according to claim 3,
The displacement regulating means is provided on the second body, and has an elastic force in a radially outward direction;
An engaging portion formed on the first body and engaged with a part of the arm;
A cell culture transfer device comprising: The cell culture transfer device according to claim 3 or 4,
The cell culture transfer device, wherein the first body is provided with a release mechanism for releasing the displacement restriction state of the second body by the displacement restriction means. The cell culture transfer device according to claim 2,
The cell culture transfer device, wherein the second body is provided with a second elastic member having an elastic force for urging in the same direction as the absorber. The cell culture transfer device according to claim 6,
The cell culture transfer device, wherein the elastic force of the first elastic member is set larger than the elastic force of the absorber and the second elastic member. In the cell culture transfer instrument according to any one of claims 1 to 7,
The cell culture transfer device, wherein the holding part is made of a material having flexibility and hydrophobicity. In the cell culture transfer device according to any one of claims 1 to 8,
The cell culture transfer device, wherein the communication path includes a plurality of holes spaced apart at equal intervals in the holding part.

Images