JP3859137B2 - Cell washing rotor, washing liquid distribution element used therefor, and cell washing centrifuge equipped with the same - Google Patents

Description

[0001]
[Field of the Invention]
The present invention relates to a cell washing centrifuge that uses a centrifugal force to wash biological cells such as erythrocytes, and further relates to a cell washing rotor used therein and a washing liquid dispensing element that dispenses washing liquid.
[0002]
[Prior art]
Conventionally, for anti-globulin test, cross-match test, irregular antibody screening, etc. at the time of blood transfusion test, it is necessary to wash the red blood cells with a washing solution such as physiological saline and remove the excess antibody in the suspension. Various cell washing centrifuges are known for this purpose.
For example, in Japanese Patent Application Laid-Open No. Sho 50-22669, nozzles are radially installed from the outer periphery of the bottom surface of a conical container, and the cleaning liquid injected from the center of the cleaning liquid distribution element is distributed equally by centrifugal force due to rotation, A cleaning liquid distribution element having a structure for supplying a cleaning liquid from a nozzle into a number of test tubes held by a test tube holder is disclosed.
Further, for example, Japanese Utility Model Laid-Open No. 2-81640 discloses a structure in which the cleaning liquid is supplied into a large number of test tubes held by a test tube holder from holes drilled in the cleaning liquid distribution element.
[0003]
[Problems to be solved by the invention]
In order to perform a good blood transfusion test or the like using a centrifuge for the purpose of automating cell washing, it is desirable that the amount of washing liquid supplied into a large number of test tubes by the washing liquid distribution element is equal. When there are variations in the amount of cleaning liquid supplied into a large number of test tubes, for example, in a test tube with a small amount of cleaning liquid supply, a larger amount of foreign matter such as antibodies remains in the suspension than in other test tubes. Conversely, in a test tube with a large amount of cleaning liquid supplied, there are few residual foreign substances such as antibodies in the suspension, and this difference results in a difference in the test results due to the reagent reaction performed in the subsequent process. Causes serious errors. Also, if there is a test tube with a small amount of cleaning liquid, supply the cleaning liquid to other test tubes according to the cleaning liquid supply amount of this test tube. Things overflow from the test tube, causing the problem of precious cell samples being lost. Furthermore, there is a problem that the cleaning process takes a long time if the number of times of cleaning is determined in accordance with a small amount of cleaning liquid.
There are several possible causes for the uneven amount of the cleaning liquid supplied to the test tube. The first cause is due to the non-uniformity of the channel resistance of the cleaning liquid distribution element. For example, in a cleaning liquid distribution element that supplies cleaning liquid into a large number of test tubes held by a test tube holder from radially drilled holes shown in Japanese Utility Model Publication No. 2-81640, the holes are processed by drilling or the like. It is difficult except for machining. However, hole machining by machining tends to cause errors in the shape of the hole entrance / exit and the roughness of the inner surface of the hole, which causes uneven flow resistance, resulting in variations in the amount of cleaning liquid supplied to many test tubes. Cause it to occur.
Japanese Patent Laid-Open No. 50-22893 discloses a structure in which a metal pipe is embedded in a cleaning liquid distribution element, and the cleaning liquid is supplied into a number of test tubes through the metal pipe as a flow path. A processing error occurs in the processing shape of the pipe end face and the pipe length, which causes a non-uniform flow path resistance as described above, resulting in variations in the amount of cleaning liquid supplied into a large number of test tubes.
The second cause of the uneven amount of cleaning liquid is due to leakage of the cleaning liquid. For example, if the distance between the cleaning liquid outlet of the cleaning liquid distribution element and the test tube port is large, the cleaning liquid from the liquid distribution element may not completely enter the test tube due to an error in the hole processing direction. This is a cause of variation in the amount of supplied cleaning liquid.
Also, if the tip of the metal pipe is installed near the test tube so that the cleaning solution can completely enter the test tube, the test tube holder will be tested for lateral length variations and variations in the test tube length when rotating. The tube and the tip of the metal pipe come into contact with each other, causing a problem that causes the test tube to break.
The third cause of the uneven amount of the cleaning liquid is due to foreign matters in the cleaning liquid. While the cleaning liquid sent out by the pump reaches the liquid distribution element, it entraps dust and cotton dust in the air, and when these foreign substances become clogged in the holes and pipes of the cleaning liquid distribution element, the flow path is blocked, and as a result Reduce the amount of cleaning fluid supplied to the corresponding test tube. In addition, when physiological saline or the like is used as the cleaning liquid as a cause of the foreign matter, solid matter such as sodium chloride deposited in the tank or the flow path may block the flow path and cause a decrease in the supply amount of the cleaning liquid.
In the above-mentioned cleaning liquid distribution element, it is not possible to see foreign substances that block such a flow channel from the outside, and the cleaning process is temporarily stopped periodically to check the supply amount of cleaning liquid distributed to the test tubes. It was necessary. Furthermore, in the above-described cleaning liquid distribution element, the cleaning liquid is always supplied by the number of holes or pipes regardless of the increase or decrease of the number of test tubes to be processed. Therefore, when the number of test tubes is small, the cleaning liquid is wasted.
An object of the present invention is to provide a cleaning liquid distribution element capable of supplying an equal amount of cleaning liquid into a large number of test tubes in view of the above-described problems of the prior art.
Another object of the present invention is to provide a cell washing rotor that has good washing characteristics and high reliability and can easily cope with increase / decrease in the number of test tubes by using the washing liquid distribution element as described above, and cells equipped with the same. It is to provide a washing centrifuge.
[0004]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides a cleaning liquid molecular element for supplying a cleaning liquid into a test tube, comprising a circular flat plate upper distribution element having a cleaning liquid introduction hole in the center and a circular flat plate lower distribution element. One of the features is that a plurality of radial grooves are provided in one or both of the upper distribution element and the lower distribution element.
With this configuration, it is possible to manufacture the upper distribution element and the lower distribution element by molding with resin or ceramics, and a highly accurate flow path can be formed, so that the flow resistance can be made uniform. An effect is obtained. In particular, the effect is great when the groove provided in one of the upper distribution element and the lower distribution element and the space surrounded by the plane of the other element are used as a flow path for the cleaning liquid.
Another feature of the present invention is that the center lines of a plurality of grooves provided in one or both of the upper distribution element and the lower distribution element do not coincide with the straight line connecting the test tube holder center and the rotor center. Specifically, there is another feature in that the center line of the groove is provided at a position advanced in the rotational direction of the rotor from the straight line connecting the center of the test tube holder and the center of the rotor. With this configuration, there is an effect that leakage of the cleaning liquid can be prevented.
Another feature of the present invention is that a center line of a plurality of grooves provided in one or both of the upper distribution element and the lower distribution element is formed in an angle with a straight line or a curved line passing through the rotor center. It is in. This is also effective for preventing leakage of the cleaning liquid.
Still another feature of the present invention resides in that a groove end portion on the rotor center side of a plurality of grooves is configured with a smooth curved surface. This configuration is effective in reducing the flow resistance and making the amount of cleaning liquid uniform.
Still another feature of the present invention resides in that a part or all of the upper distribution element is made of a transparent member. With this configuration, it is possible to easily determine whether a foreign object is blocking the flow path.
Still another feature of the present invention is that a cylindrical grasping portion is provided at the center of the upper distribution element, and a plurality of anti-slip concave portions or anti-slip convex portions are formed in the longitudinal direction of the outer periphery of the grasping portion. There is. This is a convenient structure when manually rotating the cell washing rotor forward and backward to promote the reagent reaction.
Still another feature of the present invention resides in that, in the outermost circumferences of the upper distribution element and the lower distribution element, a portion where the groove is disposed is convex outward from the other portions.
If comprised in this way, it will become easy for a washing | cleaning liquid to enter into a test tube from a washing | cleaning-liquid distribution element, and it is effective in preventing the leakage of a washing | cleaning liquid.
[0005]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a perspective view for explaining the structure and component structure of a cell washing rotor according to an embodiment of the present invention. In this embodiment, the cell washing rotor 1 is composed of a rotor 2 and a washing liquid distribution element 5, and the disk-shaped rotor 2 has 24 square holes arranged on the outer periphery, and 24 test tube holders 3 are placed in the holes. It is installed. When the rotor 2 rotates, the test tube holder 3 into which the test tube 4 is inserted can freely move in the horizontal direction around the mounting portion by centrifugal force. In this embodiment, the rotor 2 and the test tube holder 3 are manufactured by pressing a stainless plate, but can also be manufactured by a resin molded product. A cleaning liquid distribution element 5 for supplying a cleaning liquid to the test tube 4 is mounted on the rotor 2. The cleaning liquid distribution element 5 rotates together with the rotor 2 because the lower convex portion is engaged with the elongated hole of the rotor 2. Even if the cleaning liquid distribution element 5 is attached to and detached from the rotor, the positional relationship between the rotor 2 and the test tube holder 3 and the cleaning liquid distribution element 5 does not change.
FIG. 2 is a perspective view for explaining the structure and component structure of a cleaning liquid distribution element according to an embodiment of the present invention. In this embodiment, the cleaning liquid distribution element 5 includes an upper distribution element 6 and a lower distribution element 8, and 24 grooves 9 that are radially equal to the number of test tubes 4 are formed in the lower distribution element 8. By arranging the upper distribution element 6 and the lower distribution element 8 in combination, a space formed by the groove 9 of the lower distribution element 8 and the flat portion of the upper distribution element 6 becomes a flow path for the cleaning liquid. According to this embodiment, it is possible to manufacture the upper distribution element 6 and the lower distribution element 8 only by resin molding by forming the cleaning liquid flow path into a shape surrounded by a groove and a plane. By molding the upper distribution element 6 and the lower distribution element 8 using a high-precision mold, the shape of the groove 9 of the lower distribution element 8 becomes uniform with high accuracy by the same cleaning liquid distribution element 5, and performance is improved. Therefore, it is possible to manufacture a large amount of the cleaning liquid distribution element 5 having a uniform flow path resistance at any time.
In the above embodiment, the groove may be provided in one or both of the upper distribution element 6 and the lower distribution element 8, or these may be manufactured from ceramics instead of resin. Considering the ease of making and the uniformity of the flow path resistance, a groove is formed in the lower distribution element 8 as in the above embodiment, and a space formed between the flat surface of the upper distribution element 6 is used as the flow path. Best.
In FIG. 2, a cylindrical grasping portion 14 is provided at the center of the upper distribution element 6. A plurality of anti-slip recesses 26 and anti-slip projections 27 are provided on the outer periphery of the grasping portion 14 in the vertical direction. This is convenient when the rotor 1 is manually rotated forward and backward in small increments after completion of the cell washing step, and the red blood cells in the test tube 4 and the reagent are mixed well to promote the reaction.
FIG. 10 is a longitudinal sectional view showing the overall configuration of the cell washing centrifuge 20 according to the present invention. The function of the cleaning liquid distribution element 5 will be described in more detail with reference to FIG. In FIG. 10, the cell washing rotor 1 is attached to the drive shaft 22 of the motor 21. A drive voltage is applied to the motor 21 from a drive circuit (not shown) in the figure, and the drive shaft 22 is rotated. The cell washing rotor 1 is rotationally driven by a drive shaft 22, and the test tube holder 3 and the test tube 4 in which an appropriate amount of biological cells such as red blood cells are put in advance are rocked in the horizontal direction by centrifugal force.
At this time, when the pump 23 is operated and the cleaning liquid is sent from the external cleaning liquid tank to the nozzle 25 located at the upper part of the cell cleaning centrifuge 20, the cleaning liquid is ejected downward from the nozzle 25, and the center of the rotating cell cleaning rotor 1 is rotated. The cleaning liquid distribution element 5 enters the cleaning liquid introduction hole 7. The cleaning liquid that has entered the cleaning liquid distribution element 5 moves to the outer periphery due to centrifugal force, and flows into 24 flow paths constituted by the grooves 9 of the lower distribution element 8 and the flat portion of the upper distribution element 6, and distributes the cleaning liquid. Popping out of the outer periphery of the element 5 vigorously. The cleaning liquid that has jumped out hits the inner wall of the test tube 4 located outside the cleaning liquid distribution element 5, travels along the wall surface, and floats the living cells at the bottom of the test tube 4 to create a suspended state. When an appropriate amount of cleaning liquid enters the test tube 4, the pump 23 stops and the cleaning liquid injection process ends.
Subsequently, the rotation is continued until the floating living cells gather at the bottom of the test tube 4. Thereafter, the rotation is stopped and the test tube holder 3 is returned to the vertical position. Next, in this embodiment, the motor 21 is rotated at a low speed while functioning the magnetic element 28 as a means for restricting the horizontal movement of the test tube holder 3. Since the test tube holder 3 is made of a magnetic material such as SUS430, the test tube holder 3 is attracted by the magnetic force of the magnetic element 28 and rotates while maintaining a vertical state or tilting the opening of the test tube 4 slightly outward. The cleaning liquid in the tube 4 is discharged to the outside by centrifugal force. The living cells at the bottom of the test tube 4 remain as they are, and only the washing solution disappears.
By repeating such steps, the cell washing centrifuge 20 separates and removes foreign substances such as antibodies from the living cells in the test tube 4. Since the washing process is performed in such a process, it is desirable from the viewpoint of the performance of the cell washing centrifuge 20 that the amount of the washing solution supplied into many test tubes is equal.
According to the embodiment of FIG. 2, since the upper distribution element 6 and the lower distribution element 7 of the cleaning liquid distribution element 5 are made of high-precision resin molded products, they are compared with the perforated holes and metal pipe flow paths. Thus, the shape of the groove 9 of the lower distribution element 8 can be made uniform with high accuracy. Accordingly, it is possible to manufacture a large amount of the cleaning liquid distribution element 5 having a uniform flow resistance and capable of distributing an equal amount of the cleaning liquid as compared with the perforated hole or the flow path of the metal pipe with high reproducibility. It becomes.
After the cell washing step of the cell washing centrifuge 20 is completed, for example, after washing with red blood cells, a reagent such as antiglobulin serum is dropped on the test tube 4 and the cell washing rotor 1 is manually rotated forward and backward in small increments. In the embodiment shown in FIG. 2, a grasping portion 14 is provided at the center of the upper distribution element 6 and an anti-slip recess 26 is provided on the outer periphery. By providing the non-slip protrusion 27, it is easy to manually rotate forward and backward in small increments, and there is an effect that a reliable reagent reaction can be promoted.
FIG. 3 is a plan view of a cell washing rotor according to an embodiment of the present invention. When the rotation speed of the motor 21 is increased to shorten the processing time of the cell washing centrifuge 20, the flight direction is bent by the wind pressure of the rotation until the cleaning liquid that has jumped out of the outer periphery of the cleaning liquid distribution element 5 enters the test tube 4, and is completely In some cases, the test tube 4 does not enter. In the embodiment of FIG. 3, the groove 9 is provided at a position where the center line 10 of the groove 9 is advanced in the rotation direction of the rotor 2 from the straight line connecting the center of the test tube holder 3 and the rotation center of the rotor 2. . In this way, the bending of the cleaning liquid in the flight direction can be corrected and reliably injected into the test tube 4 as shown in the figure. The advance angle depends on the rotational speed of the rotor 2 and the distance between the cleaning liquid distribution element 5 and the test tube 4, but is preferably 0.5 to 5 degrees, and more preferably 1 to 3 degrees.
FIG. 4 is a plan view of a cell washing rotor according to an embodiment of the present invention. A center line 10 of the groove 9 is a straight line or a curved line and is installed at an angle with a straight line passing through the center of the rotor. Also in this example, the bending of the cleaning liquid in the flight direction can be corrected by advancing the angle formed by the center line 10 of the groove and the straight line passing through the rotor center in the rotation direction of the rotor 2.
FIG. 5 is a plan view of the lower distribution element 8 according to an embodiment of the present invention. In this embodiment, the groove end 11 of the groove 9 on the center side of the rotor 2 is formed with a smooth curved surface. By adopting such a shape, it is possible to suppress a variation in flow path resistance when the cleaning liquid enters the cleaning liquid distribution element 5 from the cleaning liquid introduction hole 7 and flows into the plurality of grooves 9. In particular, the configuration between the adjacent groove end portions 11 as a semicircular arc as in this embodiment is effective in reducing variations in flow resistance.
5 and FIG. 2, the upper distribution element 6 and the lower distribution element 8 are provided with a convex portion 15 at the outermost periphery so that the portion where the groove 9 is disposed is convex outward from the other portions. Is provided. By setting it as such a shape, the distance which the test tube 4 and the washing | cleaning liquid distribution element 5 interfere can be made small. As a result, the distance between the cleaning liquid distributing element 5 and the test tube 4 can be set small, and the flight direction is bent by the wind pressure of the rotation until the cleaning liquid that has jumped out of the convex portion 15 enters the test tube 4, so The trouble of not entering was also reduced. Moreover, the useless part of the outer periphery of the cleaning liquid distribution element 5 can be deleted, and as a result, the load of the motor 21 can be reduced by reducing the weight of the cleaning liquid distribution element 5.
FIG. 6 is a cross-sectional view of the cleaning liquid distribution element 5 according to an embodiment of the present invention. A porous filter 12 detachable from above was attached to the cleaning liquid introduction hole 7 located at the center of the upper distribution element 6. With this configuration, foreign matters in the cleaning liquid can be removed before entering the cleaning liquid distribution element 5, clogging the groove 9 and closing the flow path, resulting in a reduction in the amount of cleaning liquid supplied to the test tube 4. I was able to prevent it. In this embodiment, the porous filter 12 is a polypropylene resin sintered molded product having a filtration accuracy of 50 μm, and after a long period of use, the filter is clogged and can be replaced with a new one before the flow rate decreases. In addition, there is no practical problem even if the porous filter 12 is made of a screen mesh made of metal such as stainless steel.
In FIG. 6, the upper distribution element 6 is entirely made of a transparent member. As a result, the groove 9 of the lower distribution element 8 can be visually observed from above, and even if the flow path is blocked by a foreign substance in the cleaning liquid, the position can be instantly identified and can be dealt with early. If the groove 9 can be observed, the same effect can be obtained even if only a part of the upper distribution element 6 is made of a transparent member.
FIG. 7 is a perspective view illustrating the structure and component configuration of a cleaning liquid distribution element according to another embodiment of the present invention. The above-described cell washing rotor 1 holds 24 test tube holders 3, but the washing treatment of the 24 test tubes 4 is not necessarily performed in one washing treatment, and in some cases, 12 test tubes 4. May be processed. In this case, since the cleaning liquid is supplied and injected also into the portion where the test tube 4 is not provided, the cleaning liquid is wasted.
In the embodiment shown in FIG. 7, the cleaning liquid distribution element 5 is composed of an upper distribution element 6, a lower distribution element 8, and a plug member 16. The plug member 16 is held between the upper distribution element 6 and the lower distribution element 8, and the end of the groove. 11 is in close contact with and engaged with the structure. As a result, the cleaning liquid flow in the groove 9 engaged with the plug member 16 could be completely stopped. Accordingly, when the washing process is performed using 12 test tubes 4 in the cell washing rotor 1 having 24 test tube holders 3, the plug members 16 are closely attached to the 12 groove end portions 11 where the test tubes 4 are not installed. By engaging, useless supply of the cleaning liquid part can be stopped. Of course, it is desirable that the plug member 16 is installed at a symmetrical position with respect to the center of the cell washing rotor 1. Furthermore, since part or all of the upper distribution element 6 is made of a transparent member, the position of the plug member 16 can be confirmed from above, and the test tube 4 can be reliably installed at the cleaning liquid supply location. Further, the plug member 16 is made of an elastic material such as silicon rubber, thereby further improving the adhesion with the groove end portion 11 and reliably stopping the flow of the cleaning liquid.
FIG. 8 is a perspective view for explaining the structure and component structure of a cleaning liquid distribution element according to another embodiment of the present invention. In the embodiment shown in FIG. 8, the cleaning liquid distribution element 5 includes an upper distribution element 6, a lower distribution element 7, and a central distribution element 17 in which a groove 9 is formed. With such a configuration, the cleaning liquid distribution element 5 can easily cope with the increase or decrease in the number of test tube treatments by sequentially replacing the central distribution elements 17 having different numbers of grooves, and as a result, the cleaning liquid section is wasted. It can be surely lost.
FIG. 9 is a sectional view of the cleaning liquid distribution element 5 having this configuration. The central distribution element 17 is coupled to the positioning convex portion 18 or the positioning concave portion 19 of the upper distribution element 6 and the lower distribution element 8, and the positional relationship thereof is uniquely determined. Therefore, even when the central distribution element 17 is replaced, a corresponding test is performed. There is no change in the relative position of the tube 4, and there is no error in installing the test tube 4 at a position where no cleaning liquid is supplied.
Further, the central distribution element 17 is configured such that the outer dimensions thereof are larger than those of the upper distribution element 6 and the lower distribution element 8, and the portion where the groove 9 is disposed is convex outward from the other portions. . As a result, the distance at which the test tube 4 and the cleaning liquid distribution element 5 interfere with each other can be reduced, and as a result, the distance between the cleaning liquid distribution element 5 and the test tube 4 can be set small. The flight direction was bent by the wind pressure of rotation before entering, and the trouble of not entering the test tube 4 was reduced. Further, the central distribution element 17 is made of an elastic material such as silicon rubber, so that the test tube 4 is not damaged even if the test tube 4 is arranged at a distance in contact with the central distribution element 17 and the reliability is improved. can do.
Further, by attaching the porous filter 12 to the cleaning liquid introduction hole 7 of the upper distribution element 6, it becomes possible to remove foreign matters in the cleaning liquid, clogging the groove 9, closing the flow path, and as a result, supplying the cleaning liquid to the test tube 4. Decrease can be prevented. Furthermore, as a result of manufacturing the upper distribution element 6 with a transparent member, even if the flow path is blocked by a foreign substance in the cleaning liquid, the position can be instantly identified and can be dealt with early.
[0006]
【The invention's effect】
As described above, in the present invention, the cleaning liquid distribution element includes the circular flat plate-like upper distribution element having the cleaning liquid introduction hole in the center and the circular flat plate-shaped lower distribution element, and the upper distribution element and the lower distribution element. A structure in which a plurality of radial grooves are provided in one or both of them, or a circular flat plate-like upper distribution element having a cleaning liquid introduction hole in the center and a circular flat plate shape having a plurality of radially arranged grooves With the structure including the central distribution element and the circular flat plate-shaped lower distribution element, the flow path can be formed with high accuracy.
For this reason, it becomes possible to supply a uniform amount of cleaning liquid into a large number of test tubes. As a result, the cell cleaning rotor having good cleaning characteristics and high reliability, and easily adapting to the increase or decrease in the number of test tubes, and There is a remarkable effect that the equipped cell washing centrifuge can be provided.
[Brief description of the drawings]
FIG. 1 is a perspective view for explaining the structure and component configuration of a cell washing rotor according to an embodiment of the present invention.
FIG. 2 is a perspective view for explaining the structure and component configuration of a cleaning liquid distribution element according to an embodiment of the present invention.
FIG. 3 is a plan view of a cell washing rotor according to an embodiment of the present invention.
FIG. 4 is a plan view of a cell washing rotor according to an embodiment of the present invention.
FIG. 5 is a plan view of a lower distribution element according to an embodiment of the present invention.
FIG. 6 is a cross-sectional view of a cleaning liquid distribution element according to an embodiment of the present invention.
FIG. 7 is a perspective view illustrating the structure and component configuration of a cleaning liquid distribution element according to another embodiment of the present invention.
FIG. 8 is a perspective view illustrating the structure and component configuration of a cleaning liquid distribution element according to another embodiment of the present invention.
FIG. 9 is a cross-sectional view of a cleaning liquid distribution element according to another embodiment of the present invention.
FIG. 10 is a cross-sectional view of a cell washing centrifuge according to an embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Cell washing rotor 2 Rotor 3 Test tube holder 4 Test tube washing liquid distribution element Upper distribution element Cleaning liquid introduction hole Lower distribution element 9 Groove 10 Center line 11 Groove end 12 Porous filter 13 Transparent member 14 Grasping part 15 Protrusion part 16 Plug member 17 Central distribution element 18 Positioning convex part 19 Positioning concave part 20 Cell washing centrifuge 21 Motor 22 Drive shaft 23 Pump 25 Nozzle 26 Anti-slip concave part 27 Anti-slip convex part 28 Magnetic element 29 Anti-rotation convex part 30 Slot

Claims (30)

A rotor, a plurality of test tube holders rotatably mounted on the rotor, and capable of moving outward by centrifugal force when the rotor rotates, and a rotor mounted on the rotor and rotated together with the rotor, and held by the test tube holder In the cell washing rotor comprising a washing liquid distribution element for supplying a washing liquid into a large number of test tubes, the washing liquid distribution element includes a circular flat plate-like upper distribution element and a circular flat plate-like lower distribution element having a washing liquid introduction hole in the center. comprising a, have a plurality of radial grooves on either one or both of the upper distributing element and a lower distribution element, the center line of a plurality of grooves provided on one or both of the upper distributing element or the lower distribution element The groove is arranged radially on a straight line passing through the rotor center, and the center line of the groove does not coincide with a straight line connecting the test tube holder center and the rotor center. Cell cleaning rotor that.   2. The cell washing rotor according to claim 1, wherein the upper distribution element and the lower distribution element are manufactured by molding resin or ceramics. 2. The cell washing rotor according to claim 1, wherein a space surrounded by a groove provided in one of the upper distribution element and the lower distribution element and a plane of the other element is used as a flow path for the washing liquid. 2. The center line of the plurality of grooves according to claim 1 , wherein a center line of the plurality of grooves is advanced in a rotation direction of the rotor when viewed from above the rotor, rather than a straight line connecting the center of the test tube holder and the center of the rotor. Cell washing rotor. A rotor, a plurality of test tube holders rotatably mounted on the rotor, and capable of moving outward by centrifugal force when the rotor rotates, and a rotor mounted on the rotor and rotated together with the rotor, and held by the test tube holder In the cell washing rotor comprising a washing liquid distribution element for supplying a washing liquid into a large number of test tubes, the washing liquid distribution element includes a circular flat plate-like upper distribution element and a circular flat plate-like lower distribution element having a washing liquid introduction hole in the center. A plurality of radial grooves in one or both of the upper distribution element and the lower distribution element, and center lines of the plurality of grooves provided in one or both of the upper distribution element and the lower distribution element are A cell washing rotor characterized in that it forms a certain angle with a straight line or a curved line passing through the center of the rotor. According to claim 1 or 5, cells washed rotor, wherein the groove ends of the rotor center side of the plurality of grooves that are configured with smooth surface. According to claim 1 or 5, wherein the upper distribution device, cell washing rotor, wherein a part or the whole is formed of a transparent member. According to claim 1 or 5, wherein the center of the upper distributing element has a grasping portion of the cylindrical, a plurality of slip recesses or slip protrusions for slip longitudinally on the outer periphery of the grasping portion is formed A cell washing rotor characterized by that. According to claim 1 or 5, wherein the upper distribution element and the lower distribution element at its outermost periphery, and wherein a convex portion of the convex shape toward the outside than other parts groove is disposed portion Cell washing rotor. A washing liquid distribution element in a cell washing rotor, comprising a circular flat plate-like upper distribution element having a washing liquid introduction hole at a central portion, and a circular flat plate-like lower distribution element, wherein the upper distribution element and the lower distribution element provided one or both a plurality of grooves arranged radially, the groove with a washing solution flow path, the center line of the plurality of grooves kicked set to one or both of the upper distributing element or bottom distributor element Are arranged radially on the straight line passing through the center of the rotor, and the center line of the groove does not coincide with the straight line connecting the center of the test tube holder and the center of the rotor . 11. The cleaning liquid distribution element according to claim 10, wherein the upper distribution element and the lower distribution element are manufactured by molding resin or ceramics. 11. The cleaning liquid distribution element according to claim 10, wherein a space surrounded by a groove provided in one of the upper distribution element and the lower distribution element and a plane of the other element is a flow path for the cleaning liquid. 11. The center line of the plurality of grooves according to claim 10 , wherein the center line of the plurality of grooves is advanced in the rotational direction of the rotor as viewed from above the straight line connecting the test tube holder center and the rotor center. Cleaning liquid distribution element. A washing liquid distribution element in a cell washing rotor, comprising a circular flat plate-like upper distribution element having a washing liquid introduction hole at a central portion, and a circular flat plate-like lower distribution element, wherein the upper distribution element and the lower distribution element A plurality of grooves arranged radially in either one or both are provided, and the groove is used as a cleaning liquid flow path, and the center lines of the plurality of grooves provided in one or both of the upper distribution element and the lower distribution element are A cleaning liquid distribution element characterized in that it forms a certain angle with a straight line or a curved line and a straight line passing through the center of the rotor. 15. The cleaning liquid distribution element according to claim 10 , wherein groove end portions on the rotor center side of the plurality of grooves are configured with smooth curved surfaces. 15. The cleaning liquid distribution element according to claim 10 , wherein a part or all of the upper distribution element is made of a transparent member. 15. The upper distribution element according to claim 10 , wherein the upper distribution element has a cylindrical grasping portion, and a plurality of non-slip recesses or anti-slip projections are formed on the outer periphery of the grasping portion in the longitudinal direction. A cleaning liquid distribution element. 15. The upper distribution element and the lower distribution element according to claim 10 or 14 , characterized in that, at the outermost periphery, the portion where the groove is arranged has a convex portion that protrudes outward from the other portion. Cleaning liquid distribution element.   A rotor, a plurality of test tube holders rotatably mounted on the rotor, and capable of moving outward by centrifugal force when the rotor rotates, and a rotor mounted on the rotor and rotated together with the rotor, and held by the test tube holder In the cell washing rotor comprising a washing liquid distribution element for supplying a washing liquid into a large number of test tubes, the washing liquid distribution element is composed of a circular flat plate-like upper distribution element and a circular flat plate-like lower distribution element having a washing liquid introduction hole in the center. A plug member that has a plurality of radial grooves in one or both of the upper distribution element and the lower distribution element, and that engages with the upper distribution element, the lower distribution element, and the groove and blocks the flow of fluid. A cell washing rotor comprising: The cell washing rotor according to claim 19 , wherein the plug member is made of an elastic material. A rotor, a plurality of test tube holders rotatably mounted on the rotor, and capable of moving outward by centrifugal force when the rotor rotates, and a rotor mounted on the rotor and rotated together with the rotor, and held by the test tube holder and the cells washed rotor comprising a cleaning liquid distributor for supplying the cleaning liquid to a number of in vitro, the rotor drive mechanism for rotating the pre-Symbol rotor, and a cleaning liquid supply mechanism for supplying cleaning liquid to the cell cleaning rotor The cleaning liquid distribution element includes a circular flat plate-shaped upper distribution element having a cleaning liquid introduction hole in the center and a circular flat plate-shaped lower distribution element, and one or both of the upper distribution element and the lower distribution element have a plurality of radial grooves, the center line of a plurality of grooves provided on one or both of the upper distributing element or bottom distributor element is a straight line passing through the rotor center Arranged radially, cell washing centrifuge center line of the groove, characterized in that does not match the straight line connecting the rotor center and the test tube holder center. The cell washing centrifuge according to claim 21, wherein the upper distribution element and the lower distribution element are manufactured by molding a resin or ceramics. The cell washing centrifuge according to claim 21, wherein a space surrounded by a groove provided in one of the upper distribution element and the lower distribution element and a plane of the other element is used as a flow path for the washing liquid. According to claim 21, characterized in that the center line of said plurality of grooves, wherein the straight line connecting the test tube holder center and the rotor center, which look at the rotor from above, has been advanced in the direction of rotation of said rotor Cell washing centrifuge. A rotor, a plurality of test tube holders rotatably mounted on the rotor, and capable of moving outward by centrifugal force when the rotor rotates, and a rotor mounted on the rotor and rotated together with the rotor, and held by the test tube holder A cell washing rotor comprising a washing liquid distribution element for supplying the washing liquid into a large number of test tubes, a rotor drive mechanism for rotating the rotor, and a washing liquid supply mechanism for supplying the washing liquid to the cell washing rotor. The cleaning liquid distribution element includes a circular flat plate-like upper distribution element having a cleaning liquid introduction hole in a central portion and a circular flat plate-shaped lower distribution element, and one or both of the upper distribution element and the lower distribution element are radially provided. A plurality of grooves,
The upper distribution element and the center line of a plurality of grooves provided on one or both of the lower distribution element, cell washing, characterized in that it forms an angle with the straight line passing through the rotor center by a straight line or curved Centrifuge. 26. The cell washing centrifuge according to claim 21 or 25 , wherein a groove end portion on the rotor center side of the plurality of grooves is formed by a smooth curved surface. 26. The cell washing centrifuge according to claim 21 or 25 , wherein a part or all of the upper distribution element is formed of a transparent member. 26. A cylindrical gripping portion at the center of the upper distribution element according to claim 21 or 25 , wherein a plurality of anti-slip recesses or anti-slip projections for anti-slip are formed on the outer periphery of the grip portion in the vertical direction. A cell washing centrifuge characterized by being made. 26. The upper distribution element and the lower distribution element according to claim 21 or 25 , characterized in that, at the outermost periphery thereof, the portion in which the groove is arranged has a convex portion that protrudes outward from the other portion. Cell washing centrifuge. A rotor, a plurality of test tube holders rotatably mounted on the rotor, and capable of moving outward by centrifugal force when the rotor rotates, and a rotor mounted on the rotor and rotated together with the rotor, and held by the test tube holder A rotation mechanism comprising a fluid distribution element that supplies fluid into a large number of test tubes, a rotor drive mechanism for rotating the rotor, and a fluid supply mechanism for supplying fluid to the cell washing rotor, The fluid distribution element includes a circular flat plate-shaped upper distribution element having a fluid introduction hole in a central portion and a circular flat plate-shaped lower distribution element, and one or both of the upper distribution element and the lower distribution element are radial. have a plurality of grooves, the center line of a plurality of grooves provided on one or both of the upper distributing element or bottom distributor element is arranged radially on a straight line passing through the rotor center Cells washed centrifuge center line of the groove, characterized in that does not match the straight line connecting the rotor center and the test tube holder center.

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