CN112314595B - Stem cell transport case based on biotechnology - Google Patents

Abstract

The invention discloses a stem cell transport case based on biotechnology, which comprises a shell, wherein a moving groove with an upward opening is arranged in the shell, a first piston groove which is symmetrical about the left and right positions of the moving groove and has an upward opening is arranged in the shell, and a first piston block is connected in the first piston groove in a sliding manner; the storage bottle containing blood is protected by the shell, and meanwhile, the protective shell is arranged, so that the storage bottle can be protected when the storage bottle is accidentally overturned or dropped, the blood is moved into the storage bottle from the needle tube through the air pressure difference, the phenomenon that cells in the blood are broken due to overlarge pressure caused by overlarge thrust when the needle tube piston is manually pushed can be avoided, the base for storing the storage bottle and the shell are fixed through the air pressure difference, and the base can be separated from the shell only by damaging the first sealing block, so that the collected blood is prevented from being damaged maliciously or polluted in the transportation process.

Description

Stem cell transport case based on biotechnology

Technical Field

The invention relates to the technical field of stem cells, in particular to a stem cell transport case based on biotechnology.

Background

The stem cell therapy is a method in which a stem cell is isolated, cultured, and directionally induced and differentiated in vitro, thereby culturing a new, normal, and younger cell, tissue, organ, and the like. It is transplanted into body by means of special transplantation technology to replace dead cell and restore body function.

The stem cells need to be prevented from being contaminated by contact with the outside during transportation from extraction to a processing center for storage. However, most of the prior art uses blood bags for transportation, and the blood bags cannot be prevented from being broken due to accidental or artificial vandalism.

Disclosure of Invention

It is an object of the present invention to provide a biotechnology-based stem cell transport case that overcomes the above-mentioned drawbacks of the prior art.

The stem cell transport case based on biotechnology comprises a shell, wherein a moving groove with an upward opening is arranged in the shell, a first piston groove which is symmetrical in left-right position relative to the moving groove and has an upward opening is arranged in the shell, a first piston block is connected in the first piston groove in a sliding manner, connecting rods are fixedly arranged on the top surfaces of the first piston blocks, mounting plates are fixedly arranged on the top surfaces of the two connecting rods, a vertically penetrating mounting groove is arranged in the mounting plates, a sharp-prick rod is fixedly arranged on the bottom surface of the first piston block, a negative pressure cavity is communicated and arranged below the first piston groove through the first connecting groove, a first rubber block is arranged in the first connecting groove, a placing cavity is communicated and arranged below the moving groove through a second connecting groove, a matching groove which penetrates through the bottom surface of the shell is communicated and arranged below the placing cavity, and an air pressure cavity which is symmetrical in left-right position relative to the matching groove is arranged in the shell, an air exhaust pipe penetrating through the outer side surface of the shell is communicated with the outer wall of the air pressure cavity, a first sealing block is installed in the air exhaust pipe, the air pressure cavity is communicated with the matching groove through a connecting pipe, a base is connected in the matching groove in a sliding manner, a placing groove with an upward opening is formed in the base, a storage bottle is placed in the placing groove, a first rotating cavity with an upward opening and symmetrical in left and right positions relative to the placing groove is formed in the base, a first rotating shaft is rotatably connected in the first rotating cavity, a single-side-opening containing groove is communicated with the bottom wall of the first rotating cavity, a protective shell fixedly connected with the first rotating shaft and capable of covering the storage bottle is rotatably connected in the containing groove, an unfolding device capable of controlling the protective shell to rotate is arranged in the shell and the base, and a first sliding groove which is symmetrical in left and right positions and is opposite to the connecting pipe is formed in the base, first sliding tray sliding connection has can remove to the sealed piece of second in the connecting tube, the intercommunication is equipped with the first slide rail of upper and lower position symmetry in the first sliding tray top wall, first slide rail sliding connection have with the sealed piece fixed connection's of second first connecting block.

Optionally, the unfolding device includes a second piston groove disposed in the bottom wall of the negative pressure cavity on the left side and opposite to the first connecting groove, a second rubber block is fixedly disposed at the top of the second piston groove, a second piston block is slidably connected in the second piston groove, a second rotating cavity is disposed below the second piston groove, a rack rod extending into the second rotating cavity is fixedly disposed on the bottom surface of the second piston block, a second rotating shaft is rotatably connected to the rear wall of the second rotating cavity, a gear engaged with the rack rod is fixedly disposed on the second rotating shaft, a third rotating shaft is rotatably connected to the front wall of the second rotating cavity, a time delay device for delaying rotation of the protective housing is disposed on the second rotating shaft and the third rotating shaft, a first bevel gear is fixedly disposed on the third rotating shaft, and a gear rotating groove with a downward opening is disposed on the top wall of the mating groove, the bottom wall of the second rotating cavity is rotatably connected with a first power shaft extending to the gear rotating groove, the top end of the first power shaft is fixedly provided with a second bevel gear meshed with the first bevel gear, the bottom end of the first power shaft is fixedly provided with an internal gear, the left side of the first rotating cavity is provided with a third rotating cavity, the left side of the first rotating cavity extends into the third rotating cavity, the tail end of the left side of the first rotating shaft is fixedly provided with a third bevel gear, the bottom wall of the third rotating cavity is rotatably connected with a second power shaft extending to the gear rotating groove, the second power shaft is fixedly provided with a fourth bevel gear meshed with the third bevel gear, and the top end of the second power shaft is fixedly provided with a pinion meshed with the internal gear.

Optionally, the time delay device comprises a cam fixedly arranged at the rear end of the third rotating shaft, a first rotating groove with a rear opening is arranged in the cam, a first limiting groove with symmetrical positions is arranged in the side wall of the first rotating groove, a press switch is fixedly arranged on the inner wall of the first limiting groove, a matching wheel extending into the first rotating groove is fixedly arranged at the front end of the second rotating shaft, a second rotating groove with symmetrical positions is arranged on the outer side surface of the matching wheel in the first rotating groove, a fourth rotating shaft is rotatably connected in the second rotating groove, a push rod is fixedly arranged on the fourth rotating shaft, the push rod is fixedly connected with the inner wall of the second rotating groove through a coil spring, a third rotating groove is arranged on the outer surface of the matching wheel, a push rod is slidably connected in the third rotating groove, and a circular groove with symmetrical positions is arranged in the front wall and the rear wall of the third rotating groove, the ring channel sliding connection have with push rod fixed connection's second connecting block, the third rotates the inslot be equipped with the second sliding tray in the push rod side, sliding connection has the restriction piece in the second sliding tray, the restriction piece with through roof pressure spring fixed connection between the second sliding tray lateral wall, install the electro-magnet in the second sliding tray inner wall, the third rotates inslot wall and fits with a contraceptive ring and is equipped with a plurality of second spacing grooves, third axis of rotation upper left the second rotates the intracavity antetheca and is equipped with the third sliding tray, sliding connection has the restriction pole in the third sliding tray, the restriction pole leading flank with through reset spring fixed connection between the third sliding tray antetheca.

Optionally, the side wall of the placement groove is fixedly provided with a non-slip mat.

The invention has the beneficial effects that: the blood storage bottle is protected by the shell, and meanwhile, the protective shell is arranged, so that the storage bottle can be protected when the blood storage bottle is accidentally turned over or falls off; still will deposit the base and the shell of storage bottle through atmospheric pressure difference and fix, just can separate base and shell through destroying first sealed piece to avoid the artificial malicious damage in transit or pollute the blood of collection.

Drawings

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention; it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention.

FIG. 1 is a schematic diagram of a biotechnological-based stem cell transport case according to the present invention;

FIG. 2 is a schematic view of a portion of the deployment device of FIG. 1;

FIG. 3 is a schematic view of a portion of the deployment device of FIG. 1;

FIG. 4 is a schematic view of the structure at A-A in FIG. 2;

FIG. 5 is a schematic view of the delay device of FIG. 4;

FIG. 6 is a schematic view of the second rotary groove of FIG. 5;

fig. 7 is a schematic view of the structure at B-B in fig. 5.

Detailed Description

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Referring to fig. 1 to 7, a stem cell transportation box based on biotechnology according to an embodiment of the present invention includes a housing 19, a moving groove 18 with an upward opening is formed in the housing 19, first piston grooves 15 with an upward opening and symmetrical to the moving groove 18 are formed in the housing 19, a first piston block 16 is slidably connected to the first piston grooves 15, connecting rods 14 are fixedly arranged on top surfaces of the first piston blocks 16, mounting plates 11 are fixedly arranged on top surfaces of the two connecting rods 14, a vertically penetrating mounting groove 12 is formed in the mounting plate 11, a spike rod 17 is fixedly arranged on a bottom surface of the first piston block 16, a negative pressure chamber 22 is communicated with a lower portion of the first piston groove 15 through a first connecting groove 21, a first rubber block 20 is arranged in the first connecting groove 21, a mounting chamber 24 is communicated with a lower portion of the moving groove 18 through a second connecting groove 23, place 24 below intercommunications in chamber and be equipped with and run through the cooperation groove 81 of shell 19 bottom surface, be equipped with in the shell 19 about the air pressure chamber 25 of cooperation groove 81 bilateral position symmetry, the intercommunication is equipped with in the air pressure chamber 25 outer wall and runs through the exhaust tube 28 of shell 19 lateral surface, install first sealed piece 27 in the exhaust tube 28, air pressure chamber 25 with cooperation groove 81 passes through connecting pipe 26 intercommunication, sliding connection has base 37 in the cooperation groove 81, be equipped with the ascending standing groove 35 of opening in the base 37, lay storage bottle 34 in the standing groove 35, be equipped with in the base 37 opening upwards and about the first rotation chamber 69 of standing groove 35 bilateral position symmetry, first rotation chamber 69 internal rotation is connected with first rotation axis 70, the intercommunication is equipped with unilateral open-ended accomodating groove 33 in the first rotation chamber 69 diapire, accomodate groove 33 internal rotation be connected with first rotation axis 70 fixed connection and can with storage bottle 34 covers The protective housing 36 of living, the shell 19 with be equipped with in the base 37 and control protective housing 36 pivoted expansion device 101, be equipped with left right position symmetry in the base 37 and with the relative first sliding tray 32 in connecting pipe 26 position, sliding connection has in the first sliding tray 32 can remove extremely sealed piece 29 of second in the connecting pipe 26, the intercommunication is equipped with first slide rail 31 of longitudinal symmetry in the first sliding tray 32 roof, sliding connection has in the first slide rail 31 with sealed piece 29 fixed connection's of second first connecting block 30.

Preferably, the unfolding device 101 includes a second piston groove 38 disposed in the bottom wall of the negative pressure chamber 22 on the left side and opposite to the first connection groove 21, a second rubber block 80 is fixedly disposed on the top of the second piston groove 38, a second piston block 39 is slidably connected in the second piston groove 38, a second rotation chamber 47 is disposed below the second piston groove 38, a rack bar 40 extending into the second rotation chamber 47 is fixedly disposed on the bottom surface of the second piston block 39, a second rotation shaft 48 is rotatably connected to the rear wall of the second rotation chamber 47, a gear 49 engaged with the rack bar 40 is fixedly disposed on the second rotation shaft 48, a third rotation shaft 43 is rotatably connected to the front wall of the second rotation chamber 47, a time delay device 102 for delaying rotation of the protective housing 36 is disposed on the second rotation shaft 48 and the third rotation shaft 43, a first bevel gear 42 is fixedly disposed on the third rotation shaft 43, a gear rotating groove 71 with a downward opening is formed in the top wall of the matching groove 81, a first power shaft 46 extending to the gear rotating groove 71 is rotatably connected to the bottom wall of the second rotating cavity 47, a second bevel gear 44 engaged with the first bevel gear 42 is fixedly arranged at the top end of the first power shaft 46, an internal gear 72 is fixedly arranged at the bottom end of the first power shaft 46, a third rotating cavity 75 is arranged at the left side of the first rotating cavity 69, the first rotating shaft 70 at the left side of the first rotating cavity extends to the third rotating cavity 75, a third bevel gear 77 is fixedly arranged at the left end of the first rotating shaft 70, a second power shaft 76 extending to the gear rotating groove 71 is rotatably connected to the bottom wall of the third rotating cavity 75, a fourth bevel gear 74 engaged with the third bevel gear 77 is fixedly arranged on the second power shaft 76, and a pinion 73 engaged with the internal gear 72 is fixedly arranged at the top end of the second power shaft 76, after the second rubber block 80 is broken, the second piston block 39 slowly moves upwards due to the negative pressure in the negative pressure cavity 22, the second piston block 39 drives the rack bar 40 to move upwards, the rack bar 40 drives the second rotating shaft 48 to rotate through the gear 49, the second rotating shaft 48 drives the third rotating shaft 43 to rotate through the time delay device 102, the third rotating shaft 43 drives the second bevel gear 44 to rotate through the first bevel gear 42, the second bevel gear 44 drives the internal gear 72 to rotate through the first power shaft 46, the internal gear 72 drives the second power shaft 76 to rotate through the pinion 73, the second power shaft 76 drives the left third bevel gear 77 to rotate through the fourth bevel gear 74, the left third bevel gear 77 drives the protective shell 36 to rotate out from the accommodating groove 33 to protect the storage bottle 34, the storage bottle 34 can be protected, and the storage bottle 34 is protected when the storage bottle is turned over or inclined.

Preferably, the time delay device 102 includes a cam 41 fixedly disposed at the rear end of the third rotating shaft 43, the cam 41 is internally provided with a first rotating groove 52 with a rear opening, the side wall of the first rotating groove 52 is internally provided with a first position-symmetric limiting groove 63, the inner wall of the first limiting groove 63 is fixedly provided with a push switch 64, the front end of the second rotating shaft 48 is fixedly provided with a matching wheel 51 extending into the first rotating groove 52, the outer side surface of the matching wheel 51 in the first rotating groove 52 is provided with a second position-symmetric rotating groove 66, the second rotating groove 66 is rotatably connected with a fourth rotating shaft 67, the fourth rotating shaft 67 is fixedly provided with a push rod 65, the push rod 65 is fixedly connected with the inner wall of the second rotating groove 66 through a coil spring 68, the outer surface of the matching wheel 51 is provided with a third rotating groove 53, and the push rod 60 is slidably connected with the third rotating groove 53, annular grooves 55 with symmetrical positions are arranged in the front wall and the rear wall of the third rotating groove 53 in a communicating manner, a second connecting block 56 fixedly connected with the push rod 60 is connected in the annular groove 55 in a sliding manner, a second sliding groove 59 is arranged in the side surface of the push rod 60 in the third rotating groove 53, a limiting block 61 is connected in the second sliding groove 59 in a sliding manner, the limiting block 61 is fixedly connected with the side wall of the second sliding groove 59 through a jacking spring 57, an electromagnet 58 is arranged in the inner wall of the second sliding groove 59, a plurality of second limiting grooves 54 are annularly arranged on the inner wall of the third rotating groove 53, a third sliding groove 82 is arranged in the front wall of the second rotating cavity 47 above the left side of the third rotating shaft 43, a limiting rod 50 is connected in the third sliding groove 82 in a sliding manner, and the front side surface of the limiting rod 50 is fixedly connected with the front wall of the third sliding groove 82 through a return spring 83, the second rotating shaft 48 drives the matching wheel 51 to rotate when rotating, the matching wheel 51 drives the cam 41 to rotate through the pushing rod 65, when the cam 41 rotates to be in contact with the limiting rod 50, the cam 41 cannot rotate continuously due to the limitation of the limiting rod 50, at this time, the matching wheel 51 rotates continuously to enable the pushing rod 65 to rotate and disengage from the first limiting groove 63, at this time, the pushing rod 65 disengages from the pressing switch 64, the pressing switch 64 controls the electromagnet 58 to stop working, the limiting block 61 moves into the second limiting groove 54 under the action of the jacking spring 57, when the limiting block 61 moves into the second limiting groove 54, the pushing rod 60 swings along with the rotation of the matching wheel 51, the pushing rod 60 contacts with the inclined surface of the limiting rod 50 to press the limiting rod 50 to enable the limiting rod 50 to move forwards, at this time, the cam 41 rotates half a circle just, the pushing rod 65 rotates into the first limiting groove 63 under the action of the coil spring 68, the cam 41 can be driven to continue rotating, because the limiting rod 50 moves forwards for a certain distance, at the moment, the cam 41 can press the limiting rod 50 after being contacted with the inclined surface of the limiting rod 50, so that the limiting rod 50 moves forwards, the cam 41 can rotate over the limiting rod 50, meanwhile, because the pushing rod 65 rotates into the first limiting groove 63 to press the press switch 64 to restart the electromagnet 58, the attraction limiting block 61 moves into the second sliding groove 59 to be disconnected with the second limiting groove 54, therefore, the pushing rod 60 can rotate downwards to be vertical downwards under the action of gravity, the next rotation is waited, and the time delay purpose is completed.

Preferably, the sidewall of the mounting groove 12 is fixedly provided with a non-slip pad 13, and the non-slip pad 13 can prevent the needle tube from slipping.

In the initial state, the protective shell 36 is located in the receiving groove 33, the second sealing block 29 is located in the first sliding groove 32, the biasing spring 57 is in a compressed state, the coil spring 68 is in an unstressed state, and the push rod 65 is located in the first limiting groove 63.

When the installation work is carried out, the base 37 is placed into the matching groove 81, the first sliding groove 32 is aligned with the connecting pipe 26, the internal gear 72 is meshed with the pinion 73, then the air in the air pressure cavity 25 is pumped out through the air pumping pipe 28, at the moment, the air flow enters the air pressure cavity 25 through the connecting pipe 26 and flows out from the air pumping pipe 28, the second sealing block 29 is attracted to move into the connecting pipe 26, after the second sealing block 29 moves into the connecting pipe 26, the air pumping pipe 28 is sealed through the first sealing block 27, at the moment, the shell 19 is fixedly connected with the base 37, and the installation work is completed.

When stem cell transfer is carried out, a needle tube for drawing blood is placed into the placing groove 12, a needle head is downwards positioned in the moving groove 18, then the placing plate 11 is manually pressed downwards, so that the puncture needle rod 17 punctures the first rubber block 20, then the first piston block 16 is attracted to move downwards due to negative pressure in the first rubber block 20, the first piston block 16 drives the placing plate 11 and the needle tube arranged in the placing plate to move downwards through the connecting rod 14, the needle tube enters the placing cavity 24 through the second connecting groove 23, the needle head is punctured into the storage bottle 34, then the piston of the needle tube moves downwards due to the negative pressure in the storage bottle 34, dry cell blood is injected into the storage bottle 34 for storage, the needle tube is manually pulled out of the placing groove 12 after storage is finished, the puncture needle rod 17 is driven to move downwards during the downward movement of the first piston block 16, the puncture needle rod 17 continues to move downwards to puncture the second rubber block 80 after the needle tube is pulled out, the second piston block 39 will then move upwards with the second piston groove 38 to drive the protective shell 36 to rotate to protect the storage bottle 34, and complete the stem cell transfer.

When the storage bottle 34 needs to be taken out, the first sealing block 27 is manually punctured, the negative pressure in the air pressure cavity 25 is released, the second sealing block 29 moves into the first sliding groove 32, and the base 37 can be taken out of the matching groove 81.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (4)

1. A stem cell transport case based on biotechnology, includes the shell, its characterized in that: the improved pneumatic air compressor is characterized in that a moving groove with an upward opening is formed in the shell, a first piston groove with a symmetrical left position and a symmetrical right position and an upward opening is formed in the shell, a first piston block is connected in the first piston groove in a sliding mode, connecting rods are fixedly arranged on the top surface of the first piston block, mounting plates are fixedly arranged on the top surfaces of the two connecting rods, a vertically-penetrating mounting groove is formed in the mounting plates, a sharp-prick rod is fixedly arranged on the bottom surface of the first piston block, a negative pressure cavity is formed below the first piston groove in a communicated mode through a first connecting groove, a first rubber block is mounted in the first connecting groove, a placing cavity is formed below the moving groove in a communicated mode through a second connecting groove, a matching groove penetrating through the bottom surface of the shell is formed below the placing cavity in a communicated mode, an air pressure cavity with the symmetrical left position and the right position of the matching groove is formed in the shell, and an exhaust pipe penetrating through the outer side surface of the shell is communicated with the air pressure cavity, the air suction pipe is internally provided with a first sealing block, the air pressure cavity is communicated with the matching groove through a connecting pipe, the matching groove is internally and slidably connected with a base, the base is internally provided with a placing groove with an upward opening, a storage bottle is placed in the placing groove, the base is internally provided with a first rotating cavity with an upward opening and symmetrical with respect to the left and right positions of the placing groove, the first rotating cavity is rotatably connected with a first rotating shaft, the bottom wall of the first rotating cavity is communicated with a containing groove with a single-side opening, the containing groove is rotatably connected with a protective shell which is fixedly connected with the first rotating shaft and can cover the storage bottle, the shell and the base are internally provided with an unfolding device capable of controlling the protective shell to rotate, the base is internally provided with a first sliding groove which is symmetrical with the left and right positions and is opposite to the connecting pipe, and the first sliding groove is slidably connected with a second sealing block capable of moving into the connecting pipe, first slide rails with symmetrical upper and lower positions are communicated and arranged in the top wall of the first slide groove, and first connecting blocks fixedly connected with the second sealing blocks are slidably connected in the first slide rails.

2. The biotechnology-based stem cell transportation vessel of claim 1, wherein: the unfolding device comprises a second piston groove which is communicated with the bottom wall of the negative pressure cavity on the left side and is opposite to the first connecting groove in position, a second rubber block is fixedly arranged at the top of the second piston groove, a second piston block is connected in the second piston groove in a sliding manner, a second rotating cavity is arranged below the second piston groove, a rack rod extending into the second rotating cavity is fixedly arranged on the bottom surface of the second piston block, a second rotating shaft is rotatably connected to the rear wall of the second rotating cavity, a gear meshed with the rack rod is fixedly arranged on the second rotating shaft, a third rotating shaft is rotatably connected to the front wall of the second rotating cavity, time delay devices for delaying the rotation of the protective shell are arranged on the second rotating shaft and the third rotating shaft, a first bevel gear is fixedly arranged on the third rotating shaft, and a gear rotating groove with a downward opening is arranged on the top wall of the matching groove, the bottom wall of the second rotating cavity is rotatably connected with a first power shaft extending to the gear rotating groove, the top end of the first power shaft is fixedly provided with a second bevel gear meshed with the first bevel gear, the bottom end of the first power shaft is fixedly provided with an internal gear, the left side of the first rotating cavity is provided with a third rotating cavity, the left side of the first rotating cavity extends into the third rotating cavity, the tail end of the left side of the first rotating shaft is fixedly provided with a third bevel gear, the bottom wall of the third rotating cavity is rotatably connected with a second power shaft extending to the gear rotating groove, the second power shaft is fixedly provided with a fourth bevel gear meshed with the third bevel gear, and the top end of the second power shaft is fixedly provided with a pinion meshed with the internal gear.

3. The biotechnology-based stem cell transportation vessel of claim 1, wherein: the time delay device comprises a cam fixedly arranged at the rear end of the third rotating shaft, a first rotating groove with a rear opening is arranged in the cam, first limiting grooves with symmetrical positions are arranged in the side wall of the first rotating groove, a press switch is fixedly arranged on the inner wall of the first limiting groove, a matching wheel extending into the first rotating groove is fixedly arranged at the front end of the second rotating shaft, a second rotating groove with symmetrical positions is arranged on the outer side surface of the matching wheel in the first rotating groove, a fourth rotating shaft is rotatably connected in the second rotating groove, a push rod is fixedly arranged on the fourth rotating shaft, the push rod is fixedly connected with the inner wall of the second rotating groove through a coil spring, a third rotating groove is arranged on the outer surface of the matching wheel, a push rod is slidably connected in the third rotating groove, and a circular groove with symmetrical positions is communicated in the front wall and the rear wall of the third rotating groove, the ring channel sliding connection have with push rod fixed connection's second connecting block, the third rotates the inslot be equipped with the second sliding tray in the push rod side, sliding connection has the restriction piece in the second sliding tray, the restriction piece with through roof pressure spring fixed connection between the second sliding tray lateral wall, install the electro-magnet in the second sliding tray inner wall, the third rotates inslot wall and fits with a contraceptive ring and is equipped with a plurality of second spacing grooves, third axis of rotation upper left the second rotates the intracavity antetheca and is equipped with the third sliding tray, sliding connection has the restriction pole in the third sliding tray, the restriction pole leading flank with through reset spring fixed connection between the third sliding tray antetheca.

4. The biotechnology-based stem cell transportation vessel of claim 1, wherein: and the side wall of the placing groove is fixedly provided with an anti-slip pad.

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