JPH08131539A - Blood component separating device, and blood platelet extraction method - Google Patents

Abstract

PURPOSE: To improve a blood platelet yield of a separation device by supplying buffy coat among blood components centrifugally separated in a blood storing space to a buffy coat container, discharging the other components from the blood storing space to be transferred, returning buffy coat to the blood storing space, and performing centrifugal separation again for recovering blood plateles. CONSTITUTION: Blood in a blood bag 104 is introduced into a rotor 42 in a centrifugal bowl 4 through tubes 101, 103 to be centrifugally separated into plural blood components and collected in a blood storing space. A separated blood plasma layer is recovered from an upper part of the storing space to a blood plasma bag 21. Buffy coat is recovered from an outflow port 44 into a buffy coat bag 25. Next, a pump is inversely rotated to return red bood corpuscles left in the centrifugal bowl 4 into the blood bag 104. Buffy coat in the buffy coat 25 is then returned to the blood storing space, and it is processed with blood in the blood bag 104.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a blood component separating device for separating a predetermined blood component from blood and a platelet collecting method for collecting platelets from blood.

[0002]

2. Description of the Related Art When collecting blood, at present, for the purpose of effective use of blood and reduction of burden on the donor, the collected blood is separated into blood components by centrifugation etc. Blood is collected from other components that are collected and returned to the donor.

In the case of obtaining a platelet preparation in such component blood collection, blood collected from a blood donor is introduced into a blood component separation circuit, and plasma is collected by a centrifuge called a centrifugal bowl installed in the blood component separation circuit. , White blood cells, platelets and red blood cells are separated, and the platelets therein are collected in a container to obtain a platelet preparation, and the remaining plasma, white blood cells and red blood cells are returned to the donor. And
In order to secure a target number of platelets, a series of blood processing steps including blood collection, centrifugation of collected blood, collection of platelets, and blood return are performed multiple times.

However, in this method, since the specific gravity between white blood cells and platelets is a slight difference, the interface between them is not clear, and they are recognized as an integral buffy coat layer containing white blood cells and platelets. There is a problem that the removal rate of white blood cells (particularly lymphocytes) in the obtained platelets becomes low, and as a result, the probability of infection with hepatitis, AIDS, GVHD and the like increases when the platelet preparation is used.

Therefore, a method (surge method) has been proposed in which plasma obtained before the lower part of the centrifuge bowl is supplied to float the platelets, and the platelets are recovered, but it can be obtained by one centrifugation. The amount of buffy coat is small, the thickness of the buffy coat layer in the centrifuge bowl is thin, and the plasma supply rate is relatively high (200 ml / min or more). Low, the above problem is not solved.

[0006]

SUMMARY OF THE INVENTION It is an object of the present invention to provide a blood component separation device and a platelet collection method in which the yield of platelets obtained by centrifugation or the removal rate of leukocytes in the platelets is high. .

[0007]

These objects are achieved by the present invention described in (1) to (11) below.

(1) A blood component separating device for separating blood into a plurality of blood components and transferring the separated blood components, which is in communication with a rotatable rotor having a blood storing space therein and the blood storing space. A centrifuge having an inflow port and an outflow port, for centrifuging the blood introduced from the inflow port into a plurality of blood components in the blood storage space by rotation of the rotor, and a centrifuge connected to the inflow port. 1 line, a second line connected to the outlet, a container for storing buffy coat, one end connected to the container, the other end to the first line and / or the second line And a third line connected, the blood is introduced into the blood storage space through the first line and the rotor is rotated, the blood is centrifuged to separate into a plurality of blood components, Then The buffy coat thus obtained is transferred to the container via the third line, and blood components other than the buffy coat are discharged and transferred from the blood storage space, and then the buffy coat in the container is transferred to the container. It is operated to return to the blood storage space through a third line, centrifuge the blood component containing the buffy coat again, and collect the platelets in the buffy coat through the second line. Blood component separator.

(2) The third line is connected to the first line, and a pump is installed in the middle of the first line between the connecting portion and the inlet. ).

(3) The blood component separation apparatus according to (1), wherein a pump is installed in the middle of the first line and in the middle of the third line.

(4) The blood component separation device according to (2) or (3), which has at least control means for controlling the operation of the pump.

(5) At least one of the first line, the second line and the third line is provided with a flow path opening / closing means for opening / closing the flow path, and the control means is The blood component separation device according to (4) above, which controls the operation of the flow path opening / closing means together with the operation of the pump.

(6) The blood component according to any one of (1) to (5) above, wherein at least a part of the first line is used both for introducing blood into the blood storing space and for introducing plasma. Separation device.

(7) The blood component separation device according to any one of (1) to (6) above, wherein the second line has a plurality of branch lines for collecting different blood components.

(8) A platelet collection method for separating platelets from blood using a centrifuge having a rotor having a blood storage space formed therein, and collecting the platelets by introducing blood into the blood storage space. The first step in which the blood is centrifuged to separate the blood into a plurality of blood components, and the buffy coat among the blood components separated in the first step is discharged from the blood storage space and once stored in a container. A second step of storing and discharging a blood component other than the buffy coat from the blood storage space, and transferring the blood component to another place; a third step of returning the buffy coat in the container to the blood storage space; A fourth step of collecting the separated platelets by rotating the rotor and centrifuging the blood component containing the buffy coat,
A method for collecting platelets, which comprises performing the third step and the fourth step after performing the step and the second step at least once.

(9) In the fourth step, plasma is supplied to the blood storage space from below under the rotation of the rotor,
The method of collecting platelets according to (8) above, wherein the platelets are floated and collected.

(10) The supply rate of plasma is 10 to 90 ml /
The method for collecting platelets according to the above (9), wherein min is set.

(11) In the third step, after the buffy coat is returned to the blood storage space, the container and the flow path of the buffy coat are washed, and the liquid used for the washing is returned to the blood storage space. The method for collecting platelets according to any one of 8) to 10).

[0019]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The blood component separating apparatus and platelet collecting method of the present invention will be described below in detail with reference to the preferred embodiments shown in the accompanying drawings.

FIG. 1 shows a first blood component separating apparatus according to the present invention.
FIG. 2 is a plan view showing an embodiment, and FIG. 2 is a block diagram showing a control system of the blood component separation device shown in FIG. As shown in these drawings, the blood component separation device 1A includes a centrifuge bowl (centrifugal separator) 4, a rotation driving device 5 thereof, and a first line 2 for selectively introducing blood and plasma into the centrifuge bowl 4. (A blood or plasma introduction line), a second line 3 (blood component collection line) for collecting the blood component separated in the centrifugal bowl 4, a buffy coat bag 25 which is a container for storing the buffy coat, Buffy coat bag 25
A third line 8 for introducing the buffy coat therein to the centrifuge bowl 4, optical sensors 61, 62, and control means 7,
It has a fourth line 10 (a blood removal / returning line assuming a blood donor) having a blood reservoir 106, and a pump 91 installed in the first line 2.

As shown in FIG. 1, the fourth line 10 is
Mainly, a tube 101 and a tube 1 which is connected to the tube 101 via a branch-shaped branch connector 102 in the middle of the tube 101.
03 and blood bags 104 and 105 connected to the tips of the tubes 101 and 103, respectively.
The blood reservoir 106 is formed by the blood bags 104 and 105.
Is configured.

The base end of the tube 101 is connected to one ends of the tubes 13 and 20 via a T-shaped branch connector 12. In the middle of the tube 101, the tube 1
A valve 83, which is a flow path opening / closing means capable of blocking and opening the internal flow path 01, is installed.

The first line 2 is composed of a tube 13 and a branch connector 12 connected to one end thereof. The other end of the tube 13 is connected to the inflow port 4 of the centrifuge bowl 4.
3, a tube 91 is provided with a pump 91 for feeding liquid, which is, for example, a roller pump, in the middle of the tube 13.

As shown in FIG. 3, the centrifuge bowl 4 has a vertically extending tubular body 41 having an inflow port 43 formed at its upper end.
And a rotor 42 that rotates around the tubular body 41 and is liquid-tightly sealed to the upper portion 45. An annular blood storage space 46 is formed inside the rotor 42 along the inner surface of the rotor peripheral wall. The blood storage space 46 has a shape (taper shape) such that the inner and outer diameters thereof gradually decrease from the lower part to the upper part in FIG. The lower portion of the blood storage space 46 communicates with the lower end opening of the tubular body 41 via a substantially disc-shaped flow passage 47 formed along the bottom of the rotor 42, and the upper portion of the blood storage space 46 passes through a flow passage 48. It communicates with the outlet 44. Further, in the rotor 42, the volume of the blood storage space 46 is, for example, about 100 to 350 ml.

The rotor 42 as described above is rotated by the rotary drive device 5 under predetermined centrifugal conditions (rotation speed and rotation time) set in advance. By this centrifugation condition, the separation pattern of blood in the rotor 42 (for example, the number of blood components to be separated) can be set. In the present embodiment, as shown in FIG. 3, the centrifugation conditions are set so that the blood is separated from the inner layer into the plasma layer 31, the buffy coat layer 32, and the red blood cell layer 33 in the blood storage space 46.

As shown in FIG. 3, the rotary drive device 5 includes a housing 51 for accommodating the centrifuge bowl 4, a leg portion 52, and
It is composed of a motor 53 which is a drive source and a disk-shaped fixed base 55 which holds the centrifugal bowl 4.

The housing 51 is placed and fixed on the upper portion of the leg portion 52. Further, the motor 5 is attached to the lower surface of the housing 51 by a bolt 56 via a spacer 57.
3 is fixed. A fixed base 55 is fitted on the tip of the rotary shaft 54 of the motor 53 so as to rotate coaxially with the rotary shaft 54 and integrally with the rotary shaft 54.
A recess 551 to which the bottom of the rotor 42 is fitted is formed. The upper portion 45 of the centrifuge bowl 4 is fixed to the housing 51 by a fixing member (not shown).

In such a rotary drive device 5, the motor 5
3 is driven, the fixed base 55 and the rotor 42 fixed to the fixed base 55 are rotated at, for example, 3000 to 6000 rpm.
To rotate.

On the inner wall of the housing 51, the rotor 42
An optical sensor 61 that optically detects the position of the interface of the separated blood components in the inside, that is, the position of the interface B between the buffy coat layer 32 and the red blood cell (thickened red blood cell) layer 33 is installed and fixed by the mounting member 58. There is. This optical sensor 6
A line sensor that can scan in the up-down direction along the outer peripheral surface of the rotor 42 is used as 1. That is, L
A light-emitting element such as an ED and a light-receiving element such as a photodiode are arranged in a row, and the reflected light of the blood component of the light emitted from the light-emitting element is received by the light-receiving element, and the received light amount is photoelectrically converted. Is configured to. Since the buffy coat layer 32 and the red blood cell layer 33 that have been separated have different reflected light intensities, the position corresponding to the light receiving element in which the amount of received light, that is, the output voltage has changed is detected as the position of the interface B.

As shown in FIG. 1, one end of the tube 14 is connected to the outlet 44 of the centrifuge bowl 4, and the tube 1
The other end of 4 is connected to one ends of tubes 16 and 18 via a T-shaped branch connector 15.

The other end of the tube 16 is connected to the platelet bag 17
A valve 85 that opens and closes the flow path in the tube 16 is installed in the middle of the tube 16. Also,
The other end of the tube 18 is connected to a bubble removing chamber 19, and a valve 86 for opening and closing a flow path in the tube 18 is installed in the middle of the tube 18.

The other end of the tube 20, one end of which is connected to the branch connector 12, is connected to the bubble removing chamber 19, and a valve 84 for opening and closing the flow path inside the tube 20 is installed in the middle of the tube 20. Has been done.

The air storage bag 22 is a bag for discharging air from the inside of the plasma bag 21 after a series of treatments and storing the air. Therefore, the plasma bag 21 and the air storage bag 22 are connected by the tube 23. The insides of the two communicate with each other. Further, one end of the tube 24 is connected to the plasma bag 21, and the other end of the tube 24 is connected to the bubble removal chamber 19.

In such a structure, the tubes 14,
The second line 3 is constituted by 16, 18, 20, 23, 24, the branch connector 15, the chamber 19 and the bags 17, 21, 22. Of these, tube 1
8, the chamber 19, the tubes 23 and 24, and the bags 21 and 22 constitute a plasma recovery branch line for collecting plasma, and the tubes 14 and 16 and the platelet bag 17 are for collecting platelets for collecting platelets. Configure a branch line.

Although not shown, the plasma bag 2
1 may be set in a device (bag swinging device) capable of selectively orienting the connection side end of the tube 24 upward or downward.

A branch connector 28 is installed near the outflow port 44 of the tube 14, and one end of the tube 26 is connected to the branch connector 28. The other end of the tube 26 is connected to the buffy coat bag 25, and a valve 87 that opens and closes a flow path inside the tube 26 is installed in the middle of the tube 26. This tube 2
6 and the branch connector 28 form a third line 8.

Such a buffy coat bag 25 is
A plurality of them may be installed, and their connection pattern is not particularly limited. The capacity of the buffy coat bag 25 is not particularly limited, but the total capacity is usually 100 to 8
About 100 ml is preferable, and about 400 to 500 ml is more preferable. Although not shown, the buffy coat bag 25 may be set in the same bag rocking device as described above.

An optical sensor 62 capable of detecting the concentration of platelets in the blood component flowing in the tube 14 is installed in the middle of the tube 14. The optical sensor 62 is composed of a light projecting unit (light source) 63 and a light receiving unit (photodiode) 64 that are opposed to each other via the tube 14. The light (for example, laser light) emitted from the light projecting unit 63 passes through the tube 14 and is received by the light receiving unit 64, and is converted into an electric signal according to the received light amount. Since the transmittance changes according to the inside platelet concentration and the amount of light received by the light receiving unit 64 changes, this change can be detected as a change in the output voltage from the light receiving unit 64.

Each of the valves 83 to 87 is operated by a drive source such as a solenoid, an electric motor, a cylinder (hydraulic pressure or pneumatic pressure), and the drive source is operated based on a signal from a control means 7 described later. To do. In the present invention, the flow path opening / closing means is not limited to the valve (cock), but may be, for example, a clamp that holds a flexible tube and can close the lumen thereof.

Each bag 17, 21, 22, 25, 1
Each of 04 and 105 is made by stacking flexible sheet materials made of resin, and fusing (permanently heat-fusing, high-frequency fusing, etc.) or adhering peripheral edges thereof into a bag shape.

Each bag 17, 21, 22, 25, 10
For example, soft polyvinyl chloride is preferably used as the constituent material of the sheet material forming the parts 4 and 105. Examples of the plasticizer in this soft polyvinyl chloride include di (ethylhexyl) phthalate (DEHP) and di- (n
-Decyl) phthalate (DnDP) and the like are used. The content of such a plasticizer is 10% by weight of polyvinyl chloride.
The amount is preferably about 30 to 70 parts by weight with respect to 0 parts by weight.

In addition, each bag 17, 21, 22, 25,
As the other constituent material of the sheet material of 104 and 105, polyolefin, that is, a polymer obtained by polymerizing or copolymerizing olefins or diolefins such as ethylene, propylene, butadiene and isoprene can be used. For example, polyethylene, polypropylene, Examples thereof include an ethylene-vinyl acetate copolymer (EVA), a polymer blend of EVA and various thermoplastic elastomers, and any combination thereof. Further, polyesters such as polyethylene terephthalate (PET), polybutylene terephthalate (PBT), poly-1,4-cyclohexanedimethyl terephthalate (PCHT), and polyvinylidene chloride can also be used.

The sheet material constituting the platelet bag 17 is preferably one having excellent gas permeability in order to improve the shelf life of the platelets. Therefore, for example, as the sheet material, the polyolefin or DnDP plasticized polychlorinated material is used. Vinyl or the like is used, and the thickness of the sheet material is relatively thin (for example, about 0.1 to 0.5 mm, particularly 0.1 to 0.
3 mm) is preferable.

Blood is stored in advance in at least one of the blood bags 104 and 105. In this blood, for example, ACD-A solution, CPD solution, CPD-A1
Solution, anticoagulant such as sodium heparin solution is preferably added. The number of blood bags installed in the blood storage unit 106 may be one or three or more, and the connection method and connection pattern thereof may be arbitrary. For example,
It is also possible to use one or more blood bags aseptically connected and exchanged by the tube connecting device described in Japanese Utility Model Publication No. 6-26877. The platelet bag 17 may be empty, but may be filled with a platelet preservation solution such as physiological saline, GAC, PAS, or PSM-1 in advance.

Tubes 101, 103, 13, 14, 1
Examples of the constituent materials of 6, 18, 20, 23, 24, 26, 27 include polyvinyl chloride, polyethylene, polypropylene, polyester such as PET and PBT, ethylene-vinyl acetate copolymer, polyurethane, polyester elastomer, Examples thereof include thermoplastic elastomers such as styrene-butadiene-styrene copolymer, and among them, polyvinyl chloride is particularly preferable. This is because if each tube is made of polyvinyl chloride, sufficient flexibility and flexibility can be obtained, so that it is easy to handle, and it is also suitable for clogging due to a clamp or the like. In addition, the branch connector 10
As the constituent materials of 2, 12, 15, 28 and 29, the same constituent materials as those of the tube can be used.

As shown in FIG. 2, the blood component separation device 1A
Has a control means 7 composed of, for example, a microcomputer, to which the pump 91, valves 83 to 87, optical sensors 61 and 62, and rotary drive device 5 are electrically connected, respectively. There is.

The detection signal (interface position detection information) from the optical sensor 61 and the detection signal (platelet concentration information) from the optical sensor 62 are input to the control means 7 as needed. The control means 7 controls the rotation / stop of the pump 91, the rotation direction (normal rotation / reverse rotation), and the rotation speed based on the detection signals from the optical sensors 61 and 62.
The opening / closing of the valves 83 to 87 and the operation of the rotary drive device 5 are controlled as necessary.

The blood component separating apparatus 1A using the centrifugal bowl 4 as described above has an advantage that the collected platelets are hardly pelleted (become clumped) as compared with the method of centrifuging blood in a bag. There is.

Next, a preferred embodiment of the platelet collection method of the present invention using the blood component separation device 1A shown in FIG. 1 will be described. The operating states of the valves 83 to 87, the rotor 42, and the pump 91 in the following steps are shown in Table 1 below, and will be described with reference to Table 1.

[0050]

[Table 1]

[1a] Each of the blood bags 104 and 105 is filled with, for example, 400 ml of blood to be collected, the tube 103 is closed with a clamp, and the valve opening / closing pattern is (1) in Table 1 and the pump is used. 91 is operated (normal rotation). As a result, the blood in the blood bag 104 is transferred via the tubes 101 and 13, and flows from the inflow port 43 of the centrifuge bowl 4 through the tube body 41 to the rotor 42.
Introduced within. The rotation speed of the pump 91 is set so that the blood discharge amount (blood supply speed) is, for example, about 30 to 80 ml / min.

[2a] Further, at the same time as the blood transfer in the step [1a], the rotary drive device 5 is operated to rotate the rotor 4
2 is preferably 3000-6000 rpm (for example, 48
Rotate at 00 rpm). The blood flowing out from the lower end opening of the tubular body 41 radially flows through the flow path 47 toward the outer peripheral direction due to the centrifugal force generated by the rotation of the rotor 42, and the blood storage space 46.
In the blood storage space 46 from the inner layer to the plasma layer 3
1, the buffy coat layer 32 and the red blood cell layer 33 are separated.

[3a] When the plasma layer 31 reaches the upper part of the blood storage space 46 while continuing the steps [1a] and [2a], the valve opening / closing pattern is set to (2). As a result, the plasma in the rotor 42 overflows from the outflow port 44 and is collected in the plasma bag 21 via the tubes 14, 18, the chamber 19, and the tube 24.

[4a] As the plasma is discharged from the rotor 42, the interface B between the buffy coat layer 32 and the red blood cell layer 33 also gradually rises. This interface B is the optical sensor 6
1 is detected at any time, and when it is detected that the interface B has reached a predetermined level, that is, the level at which the buffy coat begins to flow out from the outlet 44, the control means 7 is detected.
Controls the valve opening / closing pattern to (3) based on the detection signal (interface position detection information). As a result, thereafter, the buffy coat flowing out from the outflow port 44 is
Buffy coat bag 25 through tubes 14 and 26
Will be transferred and collected.

[5a] When the optical sensor 61 detects that the interface B has reached a predetermined level, that is, a level at which almost all the buffy coat is discharged from the blood storage space 64, the control means 7 causes that Based on the detection signal (interface position detection information), the rotation driving device 5 is stopped, the valve opening / closing pattern is set to (4), and the pump 91 is controlled to rotate in the reverse direction. As a result, the red blood cells remaining in the centrifuge bowl 4 pass through the tubular body 41, the tubes 13 and 101,
The blood is returned to the blood bag 104.

[6a] The valve opening / closing pattern is set to (5), the pump 91 is operated (normal rotation), and all or part of the plasma in the plasma bag 21 is transferred to the tube 24 and the chamber 1.
9, put into the rotor 42 through the tubes 20 and 13.

[7a] Subsequently, the valve opening / closing pattern is set to (6), the pump 91 is rotated in the reverse direction, and the plasma bag 21 is rotated.
The plasma in the centrifuge bowl 4 transferred from is returned to the blood bag 104 via the tube 41, the tubes 13 and 101.

[8a] The tube 101 between the branch connector 102 and the blood bag 104 is sealed by, for example, fusion bonding, and the sealed portion is cut and separated. As a result, the blood bag 104 containing the platelet poor blood for blood return is obtained. The platelet poor blood in the blood bag 104 is returned to the donor as needed.

The number of blood bags to be processed is n (n =
If it is an integer of 3 or more), the above steps [1a] to [8a] are repeated for up to n-1 blood bags,
The following steps are performed on the nth blood bag.

[9a] Operate the rotary drive unit 5 to rotate the rotor 42 at, for example, 3000 to 6000 rpm, and open the valve opening / closing pattern with the connection side end of the tube 26 of the buffy coat bag 25 facing downward. Then, the pump 91 is rotated in the reverse direction. As a result, the buffy coat stored in the buffy coat bag 25 is returned to the blood storage space 46 via the tubes 26, 14, the outlet 44, and the flow path 48.

[10a] Tube 10 by Klemme
Release the blockage of 3 and set the valve opening and closing pattern to (8),
Operate the pump 91 under the same conditions as the above process [1a] (normal rotation)
To do. As a result, the blood in the blood bag 105 is transferred through the tubes 103, 101, and 13, and flows from the inflow port 43 of the centrifugal bowl 4 through the tube body 41 to the rotor 42.
The blood is introduced into the blood storage space 46, and the blood is separated from the inner layer into the plasma layer 31, the buffy coat layer 32, and the red blood cell layer 33 in the blood storage space 46.

In this case, the buffy coat layer 32 is composed of a buffy coat in an amount obtained from the total blood in a plurality of blood bags (blood bags 104 and 105 in the illustrated configuration) corresponding to a plurality of blood collections. Therefore, the layer thickness becomes thicker, and during the surge process described later, the platelets float,
The concentration is more clearly performed, and the platelet yield and the leukocyte removal rate in the recovered platelets are improved.

[11a] When plasma flows out from the outlet 44, the valve opening / closing pattern is set to (9). As a result, the plasma flowing out from the outlet 44 is
It is introduced into the buffy coat bag 25 via Nos. 4 and 26, and the flow paths of the tubes 14 and 26 and the inside of the buffy coat bag 25 are cleaned. At this time, rocking the buffy coat bag 25 is preferable because the cleaning effect on the inside thereof is enhanced.

[12a] With the end of the tube 26 of the buffy coat bag 25 facing downward, the valve opening / closing pattern is set to (10) and the pump 91 is rotated in the reverse direction. As a result, the plasma (cleaning liquid) that has been used for cleaning the inside of the buffy coat bag 25 or the like is returned to the blood storage space 46 via the tubes 26, 14, the outlet 44, and the flow path 48. The buffy coat bag 25 may be placed at a high place, a predetermined air vent may be provided if necessary, and the cleaning liquid in the buffy coat bag 25 may be transferred to the blood storage space 46 by a drop, or the buffy coat bag 25 may be The cleaning liquid may be discharged and transferred by being pinched or pressed by a pair of pressure plates or the like.

By washing the inside of the buffy coat bag 25 and collecting the washing liquid in the blood storage space 46, platelets do not remain inside the buffy coat bag 25 and the yield of platelets is improved. .

[13a] Set the valve opening / closing pattern to (11)
Then, the pump 91 is operated (normal rotation). As a result, the plasma in the plasma bag 21 is transferred to the tube 24 and the chamber 1.
It is fed into the rotor 42 via 9, tubes 20, 13 and tube 41, then flows through tubes 14, 16 and the surge circuit is primed with plasma.

[14a] Next, the valve opening / closing pattern is set to (12). As a result, the plasma in the rotor 42 flows out from the outflow port 44 and is collected in the plasma bag 21 via the tubes 14, 18, the chamber 19 and the tube 24.

[15a] The optical sensor 61 allows the interface B to have a predetermined surge start level, that is, the blood storage space 46.
Red blood cell layer 33 existing in the blood storage space 46 with respect to the volume of
When it is detected that the volume ratio has reached 70-96%, more preferably 85-94%, the control means 7 outputs the detection signal (interface position detection information). Based on this, the valve opening / closing pattern is controlled to be (13). As a result, the plasma in the plasma bag 21 is transferred to the tube 24, the chamber 19, the tubes 20, 1
It is supplied into the rotor 42 through the tube 3 and the pipe body 41. The plasma flowing out from the lower end opening of the tubular body 41 radially flows in the flow passage 47 toward the outer peripheral direction by the centrifugal force generated by the rotation of the rotor 42, and rises in the blood storage space 46 via the lower portion of the blood storage space 46. Thereby, the buffy coat layer 3
Platelets in 2 float up (float) against centrifugal force,
It flows out of the outflow port 44 through the flow path 48, and is collected in the platelet bag 17 through the tubes 14 and 16 (surge step). Note that the outflow of platelets is detected by the optical sensor 62.
It is detected by an increase in platelet concentration due to.

In this surge process, the control means 7
By controlling the rotation speed (plasma discharge amount) of the pump 91, the supply rate of plasma into the rotor 42 is preferably 10 to 90 ml / min, more preferably 10 to 70 ml / mi.
Set to n. If the plasma supply rate is less than 10 ml / min,
This is because it takes a long time to collect platelets, and if it exceeds 90 ml / min, the floating amount of leukocytes increases with the platelets, and the removal rate of leukocytes in the collected platelets decreases.

During the collection of platelets, the supply rate of plasma may be appropriately changed within the range of 10 to 90 ml / min. For example, a method may be mentioned in which plasma is first supplied at a predetermined rate and then at least one cycle of supplying plasma at a lower rate is performed. In such a case, the maximum supply rate of plasma is 25 to 90 ml / min, especially 30 to 70 ml.
/ Min is preferable. Such a change in the plasma supply rate can be performed based on, for example, a timer built in the control means 7 or according to platelet concentration information detected by the optical sensor 62.

[16a] When the platelet concentration detected by the optical sensor 62 becomes equal to or lower than a preset reference value, it is considered that the collection of platelets into the platelet bag 17 is completed, and the control means 7 outputs the detection signal. Based on (platelet concentration information), the rotation driving device 5 is stopped, the valve opening / closing pattern is set to (14), and the pump 91 is controlled to rotate in the reverse direction. As a result, the red blood cells, white blood cells and plasma remaining in the centrifuge bowl 4 are returned to the blood bag 105 via the tube 41, the tubes 13 and 101.

[17a] Set the valve opening / closing pattern to (15)
Then, the pump 91 is operated (normal rotation), and the plasma bag 21
The plasma remaining inside is put into the rotor 42 via the tube 24, the chamber 19, and the tubes 20 and 13.

[18a] Subsequently, the valve opening / closing pattern is set to (16), the pump 91 is rotated in the reverse direction, and the plasma bag 2
The plasma in the centrifuge bowl 4 transferred from No. 1 is returned to the blood bag 105 via the tube 41, the tubes 13 and 101.

[19a] The middle of the tube 103 is sealed by, for example, fusion bonding, and the sealed portion is cut and separated. As a result, the blood bag 105 containing platelet poor blood for blood return is obtained. The platelet poor blood in the blood bag 105 is returned to the donor as needed.

[20a] The tube 16 in the vicinity of the platelet bag 17 is sealed by, for example, fusion bonding, and the sealed portion is cut and separated to obtain the platelet bag 17 containing the platelet preparation.

As described above, in the present invention, the buffy coat in the amount obtained from the total blood in the plurality of blood bags (the blood bags 104 and 105 in the illustrated configuration) is collected, and the surge process is performed at one time. As a result, the layer thickness of the buffy coat layer 32 in the blood storage space 46 at the time of surge is increased, so that the flotation and concentration of platelets from the buffy coat layer 32 are performed more clearly, and the yield and collection of platelets are increased. The removal rate of white blood cells in the isolated platelets is improved.

Particularly, in the surge step, the plasma supply rate is set to 10 to 90 ml / min to optimally adjust the floatation of platelets, and thus a high-quality platelet preparation having an extremely high leukocyte removal rate can be obtained. . Moreover, since the optical sensor 61 detects the interface of the separated blood components and controls the timing of the start of plasma supply (the end of blood supply) based on that, it becomes possible to perform more precise control together with the automation. And the removal rate of leukocytes in the collected platelets are further improved. Therefore, when the platelet preparation is used, hepatitis, AIDS, G
It is possible to prevent infections such as VHD with a higher probability,
High safety. Moreover, since the surge process only needs to be performed once, the overall processing time can be shortened.

FIG. 4 shows a second blood component separation device according to the present invention.
It is a top view which shows the structure of an Example typically. The blood component separation device 1B shown in the figure is the same as the blood component separation device 1A except that the configuration of the third line 8 is different.

In the blood component separation device 1B, one end of two tubes 26, 27 are connected to the buffy coat bag 25. The other end of the tube 26 is connected to the middle of the tube 14 via the branch connector 28 as described above, and the other end of the tube 27 is connected to the branch connector 2
It is connected via 9 to the pump 91 of the tube 13 and the inflow port 43. In the middle of the tube 26,
A valve 87 that opens and closes the flow path in the tube 26 is installed. The tubes 26 and 27 and the branch connectors 28 and 29 form a third line.

A platelet collecting method using such a blood component separating device 1B is as follows, and is basically the same as the platelet collecting method by the blood component separating device 1A except for the step [12a].

[1b] to [11b] The same steps as [1a] to [11a] are performed with the tube 27 closed with a clamp.

[12b] Under the operation (normal rotation) of the pump 91, the valves 83 and 86 are opened and the other valves are closed. Further, the blockage of the tube 27 due to the clamp is released, the buffy coat bag 25 is placed at a high place, and the connection side end of the tube 26 is directed downward, and the cleaning liquid in the buffy coat bag 25 is passed through the tube 27 by the drop. To the first line 2. As a result, the cleaning liquid is mixed with the blood sent from the pump 91 in the branch connector 29, and the tube 1
3, transferred to the blood storage space 64 via the inflow port 43 and the tube 41.

[13b] to [20b] [13a] to [2] with the tube 27 closed again with a clamp.
0a] is performed.

In such a platelet collection method, the step [1
Since the washing liquid (including platelets) in 2b] can be returned without stopping the transfer of blood from the blood reservoir 106 into the rotor 42, there is an advantage that the overall processing time can be shortened. is there.

FIG. 5 shows a third embodiment of the blood component separation device of the present invention.
It is a top view which shows the structure of an Example typically. The blood component separation device 1C shown in the same drawing is the same as the blood component separation device 1B except that the position of the pump 91 is different.

That is, in the blood component separator 1C, the pump 91 is installed between the branch connector 29 of the tube 13 and the inflow port 43. The platelet collection method using such a blood component separation device 1C is as follows. Valves 83 to 87 and rotor 42 in each process
The operating state of the pump 91 is shown in Table 2 below, and will be described with reference to Table 2.

[0087]

[Table 2]

[1c] to [8c] The same steps as those in [1a] to [8a] are performed with the tube 27 closed with a clamp.

[9c] The rotary drive device 5 is operated to rotate the rotor 42 at a predetermined number of rotations, the tube 103 is not blocked by the clamp, and the valve opening / closing pattern is set to (8) in Table 2 to 91 in the step [1
It operates (normal rotation) under the same conditions as a]. As a result, the blood in the blood bag 105 is transferred through the tubes 103, 101 and 13, and is introduced into the rotor 42 from the inflow port 43 of the centrifugal bowl 4 via the tube body 41, and the blood storage space 4
At 6, the blood is separated from the inner layer into the plasma layer 31, the buffy coat layer 32, and the red blood cell layer 33.

[10c] Simultaneously with the step [9c],
With the end of the buffy coat bag 25 on the connection side of the tube 26 facing downward, the blockage of the tube 27 due to the clamp is released. This allows the buffy coat bag 2
The buffy coat stored in 5 is supplied to the first line 2 via the tube 27 by the operation of the pump 91, and in the branch connector 29, the blood storing section 106.
Tube 13 mixed with blood sent from the side,
It is transferred to the blood storage space 64 via the inflow port 43 and the pipe 41, and is subjected to centrifugation. Buffy coat bag 25
After almost all the buffy coat is discharged from the tube, the tube 27 is closed again with a clamp.

In the blood storage space 46, the blood bag 10
The blood from 5 and the buffy coat from the buffy coat bag 25 are mixed and centrifuged, and the separated buffy coat layer 32 has a plurality of blood bags corresponding to a plurality of blood collections (the configuration shown in the figure). Blood bag 104,
Since it is composed of buffy coat in an amount obtained from the total blood in (105), the layer thickness becomes thicker, and during the surge process, platelets float and concentrate more clearly, yielding and recovering platelets. The removal rate of leukocytes in platelets is improved.

[11c] When plasma flows out from the outlet 44, the valve opening / closing pattern is set to (9). As a result, the plasma flowing out from the outlet 44 is transferred to the tubes 14 and 2.
6 is introduced into the buffy coat bag 25 through the flow path of the tubes 14 and 26 and the buffy coat bag 2.
The inside of 5 is washed. At this time, if the buffy coat bag 25 is swung, the cleaning effect inside the bag is enhanced,
preferable.

[12c] With the end of the buffy coat bag 25 on the connecting side of the tube 26 facing downward, the valve opening / closing pattern is set to (10), and the blockage of the tube 27 by the clamp is released again. As a result, the plasma (cleaning liquid) used for cleaning the inside of the buffy coat bag 25,
The blood is returned to the blood storage space 46 by the same route as in the step [10c].

By cleaning the inside of the buffy coat bag 25 and collecting the cleaning liquid in the blood storage space 46, platelets do not remain in the buffy coat bag 25 and the yield of platelets is improved. .

[13c] to [20c] [13a] to [2c] with the tube 27 closed again with a clamp.
0a] is performed.

In such a platelet collection method, the step [1
0c] buffy coat return and process [12
The cleaning liquid (including platelets) in c] can be returned during the transfer of blood from the blood reservoir 106 into the rotor 42. In particular, the buffy coat and the cleaning liquid can be reliably and promptly returned by driving the pump 91. Therefore, the overall processing time can be further shortened.

FIG. 6 shows a fourth embodiment of the blood component separation device of the present invention.
It is a top view which shows the structure of an Example typically. The blood component separation device 1D shown in the figure is the same as the blood component separation device 1B except that a pump 92 is installed in the middle of the tube 27. A roller pump, for example, is used as the pump 92, and its drive is controlled by the control means 7 in FIG. The pump 92 only needs to be rotatable in only one direction. In this configuration, when the pump 92 is stopped, the flow path of the tube 27 is closed,
A valve (not shown) similar to the above may be separately provided in the middle of the tube 27.

A platelet collecting method using such a blood component separation device 1D is as follows. Valves 83 to 87, rotor 42 and pumps 91 and 92 in each process
Table 3 below shows the operating states of the above, and description will be given with reference to Table 3.

[0099]

[Table 3]

[1d] to [8d] The same steps as [1a] to [8a] are performed with the pump 92 stopped.

[9d] The rotary drive device 5 is operated to rotate the rotor 42 at a predetermined number of rotations, the tube 103 is released from the blockage due to the clamp, and the valve opening / closing pattern is set to (8) in Table 3 to set the pump. 91 in the step [1
It operates (normal rotation) under the same conditions as a]. As a result, the blood in the blood bag 105 is transferred through the tubes 103, 101 and 13, and is introduced into the rotor 42 from the inflow port 43 of the centrifugal bowl 4 via the tube body 41, and the blood storage space 4
At 6, the blood is separated from the inner layer into the plasma layer 31, the buffy coat layer 32, and the red blood cell layer 33.

[10d] Simultaneously with the step [9d],
The pump 92 is operated (normal rotation) in a state where the connection side end of the tube 26 of the buffy coat bag 25 is directed downward. As a result, the buffy coat stored in the buffy coat bag 25 is transferred to the first via the tube 27.
Is supplied to the line 2 of the
The blood is mixed with the blood sent from the blood storage section 106 side, transferred to the blood storage space 64 via the tube 13, the inflow port 43, and the tubular body 41, and is subjected to centrifugation. When almost all of the buffy coat is discharged from the buffy coat bag 25, the pump 92 is stopped.

[11d] When the plasma flows out from the outlet 44, the valve opening / closing pattern is set to (9). As a result, the plasma flowing out from the outlet 44 is
It is introduced into the buffy coat bag 25 via Nos. 4 and 26, and the flow paths of the tubes 14 and 26 and the inside of the buffy coat bag 25 are cleaned. At this time, rocking the buffy coat bag 25 is preferable because the cleaning effect on the inside thereof is enhanced.

[12d] With the end of the tube 26 of the buffy coat bag 25 facing downward, the valve opening / closing pattern is set to (10) and the pump 92 is operated (normal rotation). As a result, the plasma (cleaning liquid) used for cleaning the inside of the buffy coat bag 25, etc.
It is returned to the blood storage space 46 by a route similar to that of d]. By such an operation, similarly to the above, the platelets do not remain in the circuit and the yield thereof is improved.

[13d] to [20d] The same steps as [13a] to [20a] are performed with the pump 92 stopped.

In such a platelet collection method, the step [1
0d] buffy coat return and process [12
The cleaning liquid (including platelets) in d) can be returned during the transfer of blood from the blood reservoir 106 into the rotor 42, and in particular, the buffy coat and the cleaning liquid can be reliably and promptly returned by driving the pump 92. Therefore, the overall processing time can be further shortened.

In the blood component separator 1D, one end of the tube 20 may not be connected to the branch connector 12, but may be connected to the middle of the tube 27 by using a branch connector (not shown). Next, the present invention will be described in more detail based on specific examples.

Example 1 Using the blood component separation device 1A having the configuration shown in FIGS. 1 and 2, the steps [1a] to
According to [20a], 5 blood bags having a blood storage volume of 400 ml were subjected to blood treatment to prepare a platelet preparation. The conditions in each step are shown in Table 4 below.

[0109]

[Table 4]

(Embodiment 2) Using the blood component separation device 1C having the configuration shown in FIGS. 5 and 2, the above-mentioned steps [1c] to
According to [20c], 5 blood bags having a blood storage volume of 400 ml were subjected to blood treatment to prepare a platelet preparation. The conditions in each corresponding step were the same as those shown in Table 4 above.

(Embodiment 3) Using the blood component separation device 1D having the configuration shown in FIGS. 6 and 2 (however, the pump 92 is connected to the control means 7), the steps [1d] to [20] described above are used.
According to d], blood treatment was performed on five blood bags having a blood storage volume of 400 ml to prepare a platelet preparation. The conditions in the corresponding steps were the same as those shown in Table 5 above.

[0112]

[Table 5]

(Comparative Example) In the apparatus shown in FIG. 1, a circuit having no buffy coat bag 25 and the third line 8 was used, and each of the five blood bags having a stored blood volume of 400 ml was processed. Perform surge process, surge 5
A batch of platelets was collected and used as a platelet preparation. The plasma supply in each surge process was 40 seconds at a pump discharge rate (plasma supply rate) of 220 ml / min.

[Evaluation] With respect to the platelet preparations obtained in Examples 1 to 3 and Comparative Example, the amount recovered, the number of platelets, the number of white blood cells, the platelet recovery rate and the treatment time were determined. The results are shown in Table 6 below. The number of platelets was counted using a hemocytometer (Toa Denshi Co., Sysmex K-2000 type),
The white blood cell count was measured by the Negeotte chamber method.

[0115]

[Table 6]

As shown in Table 6 above, Examples 1 to 3
Compared to the comparative examples, both the collection rate of platelets and the removal rate of leukocytes in the collected platelets are high, and the total processing time is short.

Although the present invention has been described based on the respective embodiments, the circuit configuration and the like used in the apparatus and method of the present invention are not limited to those shown in the drawings. For example, the fourth line 10 is With a puncture needle that punctures the blood vessel of a blood donor
It may be a blood return line. Further, the plasma recovery branch line or the platelet recovery branch line may be omitted. Further, a flow path opening / closing means such as a valve may be provided in the middle of the tube 13 or 24. Moreover, a pump may be provided in the second line 3 or the fourth line 10.

The container for temporarily storing the buffy coat is not limited to the bag shown in the figure, but may be a hard container such as a bottle. Further, in the platelet collection method of the present invention, the order of predetermined steps among the above steps may be different, any step may be added, and predetermined steps (for example, cleaning the buffy coat bag). And the step of returning the cleaning liquid) may be omitted.

The buffy coat bag or the like may be washed with a separately prepared washing solution such as physiological saline. In this case, the container in which the cleaning liquid is stored in advance may be connected to the buffy coat bag, for example, in the middle of the third line. Needless to say, the blood component separation device and the platelet collection method of the present invention are not limited to the case of being used for manufacturing the above-mentioned platelet preparation.

[0120]

As described above, according to the blood component separation device and the platelet collection method of the present invention, more accurate separation and transfer can be achieved when performing separation into a plurality of blood components and transfer of blood components. In particular, when applied to component blood collection, a high-quality blood product having a high recovery rate of platelets and an extremely high removal rate of leukocytes (particularly lymphocytes) in the recovered platelets can be obtained. As a result, hepatitis, AIDS, GVH
Infection of D etc. can be prevented with a higher probability, and the safety is high. Further, according to the present invention, since the platelets are collected at once, the total processing time can be shortened.

In the fourth step, when the method of supplying plasma from the lower side of the blood storage space to levitate and recover the platelets is adopted, especially the plasma supply rate is 10 to 90 ml / min.
In that case, the platelet recovery rate and leukocyte removal rate are further improved. Further, when the container storing the buffy coat is washed and the liquid used for the washing is returned to the blood storage space, platelets do not remain, and the platelet recovery rate is further improved.

[Brief description of drawings]

FIG. 1 is a plan view schematically showing the configuration of a first embodiment of a blood component separation device of the present invention.

FIG. 2 is a block diagram showing a control system of the blood component separation device of the present invention.

FIG. 3 is a partial sectional front view showing a configuration example of a centrifuge bowl and a rotation drive device according to the present invention.

FIG. 4 is a plan view schematically showing the configuration of the second embodiment of the blood component separation device of the present invention.

FIG. 5 is a plan view schematically showing the configuration of the third embodiment of the blood component separation device of the present invention.

FIG. 6 is a plan view schematically showing the configuration of a fourth embodiment of the blood component separation device of the present invention.

[Explanation of symbols]

 1A to 1D Blood component separation / transfer device 2 First line 3 Second line 4 Centrifugal bowl 41 Tubular body 42 Rotor 43 Inlet port 44 Outlet port 45 Upper part 46 Blood storage space 47, 48 Channel 5 Rotation drive device 51 Housing 52 Leg Part 53 Motor 54 Rotating shaft 55 Fixing base 551 Recessed part 56 Bolt 57 Spacer 58 Mounting member 61, 62 Optical sensor 63 Light emitting part 64 Light receiving part 7 Control means 8 Third line 83-87 Valve 91, 92 Pump 10 Fourth Line 101 Tube 102 Branch connector 103 Tube 104, 105 Blood bag 106 Blood storage part 12 Branch connector 13, 14 Tube 15 Branch connector 16 Tube 17 Platelet bag 18 Tube 19 Chamber 20 Tube 21 Plasma bag 22 Air storage bag 23 , 24 tube 25 buffy coat bag 26, 27 tube 28, 29 branch connector 31 plasma layer 32 buffy coat layer 33 red blood cell layer B interface

Claims (7)

[Claims] 1. A blood component separating device for separating blood into a plurality of blood components and transferring the separated blood components, wherein a rotatable rotor having a blood storing space therein and a flow communicating with the blood storing space. A centrifuge having an inlet and an outlet, for centrifuging the blood introduced from the inlet by the rotation of the rotor into a plurality of blood components in the blood storage space, and a first separator connected to the inlet Line, a second line connected to the outlet, a container for storing buffy coat, one end connected to the container, and the other end connected to the first line and / or the second line And a third line that has been formed, introducing blood into the blood storage space through the first line and rotating the rotor, centrifuging the blood to separate it into a plurality of blood components, and , The buffy coat thus obtained is transferred to the container through the third line, and blood components other than the buffy coat are discharged and transferred from the blood storage space, and then the buffy coat in the container is transferred to the first part. And returning to the blood storage space through the line 3 and again centrifuging the blood component containing the buffy coat to collect the platelets in the buffy coat through the second line. Blood component separation device. 2. The third line is connected to the first line, and a pump is installed in the middle of the first line between the connecting portion and the inflow port. 1. The blood component separation device according to 1. 3. The middle of the first line and the third line
The blood component separation device according to claim 1, wherein a pump is installed in each of the lines. 4. A method for collecting platelets by separating platelets from blood by using a centrifuge having a rotor having a blood storage space formed therein, wherein blood is introduced into the blood storage space and the rotor is used. A first step of rotating and centrifuging the blood to separate it into a plurality of blood components, and a buffy coat of each blood component separated in the first step is discharged from the blood storage space and temporarily stored in a container. And a second step of discharging blood components other than the buffy coat from the blood storage space and transferring them to another place; and a third step of returning the buffy coat in the container to the blood storage space.
A first step and a fourth step of collecting the separated platelets by rotating the rotor and centrifuging the blood component containing the buffy coat in the blood storage space A method for collecting platelets, which comprises performing the third step and the fourth step after performing the second step at least once. 5. The platelet collection method according to claim 4, wherein in the fourth step, plasma is supplied to the blood storage space from below under the rotation of the rotor to float and collect platelets. 6. The method for collecting platelets according to claim 5, wherein the plasma supply rate is 10 to 90 ml / min. 7. In the third step, after the buffy coat is returned to the blood storage space, the flow path of the container and the buffy coat is washed, and the liquid used for the washing is returned to the blood storage space. 7. The platelet collection method according to any one of 1 to 6.