JPH0584338U - Blood component separation circuit - Google Patents

Abstract

(57) [Abstract] [Purpose] To provide a blood component separation circuit that enables the blood components such as separated blood cells to be collected with a high yield by a simple operation. A blood container 2 for containing a blood component to be processed, a blood component separator 3 for supplementing and separating a specific component from the blood component supplied from the blood container 2, and the blood Bypass means 9 for communicating a specific portion upstream of the component separator 3 and a specific portion downstream of the component separator 3 without passing through the blood component separator 3, and the bypass means 9 concerned.
Provided in the middle of the blood component separator 3 and capable of storing the gas component existing in the blood component separator 3, the blood component from the blood container 2 to the bypass means 9 and the outflow from the blood component separator 3. The blood component separation circuit 1 is provided with inflow blocking means 91 and 92 for blocking the inflow of the blood component filtrate.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a blood component separation circuit. More specifically, the present invention relates to a blood component separation circuit that enables a separated blood component to be recovered in a high yield.

[0002]

[Prior Art]

 In the past, when performing component transfusion, in which only the components required by the patient are transfused, the operation of separating blood into blood cell components such as red blood cells, white blood cells, platelets and other plasma components has been widely performed. There is. Furthermore, an operation of selectively removing white blood cells and platelets from blood cell components and separating red blood cells is performed.

As described above, as a blood cell component separation circuit for capturing and separating blood cell components from a large amount of blood or a blood cell suspension by a simple operation and in a short time, a circuit as shown in FIG. It has been disclosed (Japanese Patent Laid-Open No. 63-311962).

That is, in the blood component separation circuit 100, the blood collection bag 101 and the physiological saline solution bag 102 are connected to the blood inlet 103 a of the blood component separator 103 by the tubes 106 and 107, respectively. In addition, clamps 106a and 107a are installed in the middle of the tubes 106 and 107, respectively, so that the channels of the tubes 106 and 107 can be opened and closed. The processed blood recovery bag 104 and the waste liquid bag 105 are connected to the filtrate outlet 103b of the blood component separator 103 by tubes 108 and 109, respectively. Further, clamps 108a and 109a are installed in the middle of the tubes 108 and 109, respectively, so that the flow paths of the tubes 108 and 109 can be opened and closed.

To perform a blood component separation operation using the blood component separation circuit 100, the tubes 107 and 109 are first opened by the clamps 107a and 109a, and the saline solution in the saline solution bag 102 is moved downward. The blood component separator 103 is washed with water, and the washed saline solution is collected in the waste liquid bag 105.

When the inside of the blood component separator 103 is filled with physiological saline, priming is terminated, the tube 107 is closed with a clamp 107a, and then the tube 106 is opened with a clamp 106a to collect the blood in the blood collection bag 101. Through the tube 106 to the blood component separator 103. When the treated blood (filtrate) that has not been captured in the blood component separator 103 starts to flow out, the tube 109 is closed by the clamp 109a and the tube 108 is opened by the clamp 108a to recover the treated blood. The processed blood is collected in the bag 104.

This operation is continued until the blood in the blood bag is exhausted, and all the filtrate is collected in the processed blood collection bag 104.

Subsequently, the tube 106 is closed and the tube 107 is opened by the clamps 106 a and 107 a, and the saline in the saline bag 102 is introduced into the blood component separator 103 through the tube 107. Introduce. The introduced physiological saline comes into contact with the filter material, the inner wall and the like in the blood component separator 103 to wash out the blood cell components adhering thereto. In this way, the washed physiological saline solution containing the blood cell component remaining in the blood component separator 103 is collected in the processed blood collection bag 104 through the tube 108. This operation is continued until there are no residual blood cell components in the blood component separator 103. When the blood cell component does not flow out of the blood cell component separator 103, the tubes 107 and 108 are closed by the clamps 107a and 108a, and the operation is completed.

[0009]

[Problems to be solved by the device]

 However, the above circuit has the following drawbacks. When the residual blood cells in the blood component separator 103 are washed out with physiological saline, the components trapped in the blood component separator 103 are released, which causes the target substance to be trapped in the treated blood. Can not perform accurate separation. Since it is necessary to add a large amount of physiological saline to the treated blood, the treated blood collecting bag 104 has to be upsized, which causes many operational problems.

Therefore, it is an object of the present invention to provide a blood component separation circuit that enables the blood components such as separated blood cells to be collected with a high yield by a simple operation.

[0011]

[Means for Solving the Problems]

 The present invention that achieves the above object has the following configurations (1) to (3). (1) A blood container for containing a blood component to be treated, a blood component separator that captures and separates a specific component from the blood component supplied from the blood container, and the blood component separator Bypass means for communicating the specific portion on the upstream side and the specific portion on the downstream side without passing through the blood component separator, and the gas component existing in the blood component separator provided in the middle of the bypass means. A gas storage container capable of storing a portion of the blood, and an inflow prevention unit for preventing the inflow of the blood component from the blood storage container and the filtrate flowing out of the blood component separator into the bypass unit. Blood component separation circuit. (2) A blood container for containing a blood component to be treated, a blood component separator for capturing and separating a specific component from the blood component supplied from the blood container, and one end of which is the blood container A bypass means configured to be aseptically communicable with the upper part of the container and having the other end communicated with a specific portion on the downstream side of the blood component separator; and a blood component from the blood container to the bypass means. A blood component separation circuit, comprising: an inflow blocking means for blocking the inflow of the filtrate flowing out from the blood component separator. (3) On the downstream side of the blood component separator, a chamber for removing bubbles in the treated blood is vertically arranged, and the bypass means is connected to the upper part of the chamber (1) or ( 2) The blood component separation circuit described above.

The separation of blood components in the present invention means separation and removal of blood cells such as red blood cells, white blood cells and platelets from blood or blood cell suspension, separation and removal of plasma, removal of denatured components and harmful components in blood. However, the present invention is not limited to this, and is a concept that includes all operations of performing filtration, removal of a target component using adsorption, and trapping.

Hereinafter, the present invention will be described in detail with reference to FIGS.

FIG. 1 is a circuit diagram showing a configuration of a blood component separation circuit according to a preferred embodiment of the present invention.

As shown in FIG. 1, the blood component separation circuit 1 A according to the present embodiment has a blood container 2 in which whole blood is to be housed, and a blood container arranged downstream of the blood container 2. The blood separator 3; the first tube 4 that can connect the blood component separator 3 to the blood container 2; the chamber 5 arranged downstream of the blood component separator 3; A second tube 6 that communicates the separator 3 with the chamber 5, a third tube 8 that supplies the patient with the treated blood that has flowed out of the chamber 5, the second tube 6 and the upper portion of the chamber 5. Is composed of a bypass tube 9 which is connected without passing through the blood component separator 3 and a gas storage container 10 provided in the middle of the bypass tube 9.

Specifically, the blood container 2 is connected to a blood collection tube (not shown) having a blood collection needle, and has a flexible capacity in which an anticoagulant such as ACD solution or CPD solution is enclosed. It is a container and a blood collection bag used for general blood collection can be used.

It is also possible to centrifuge a blood collection bag containing whole blood, and aseptically transfer the obtained concentrated red blood cells, and use the packed red blood cell containing bag. Such a blood container 2 has a discharge port 2a that can be punctured and communicated with a communication needle 41 described later.

As the blood component separator 3, a housing having a blood inlet 3a and a blood outlet 3b contains a filter material or an adsorbent, and a known material can be used. In particular, it is preferable that the filter or the adsorbent inside the housing can be arranged vertically for use.

As the shape of the filter medium, a fibrous structure such as a knitted woven fabric or a non-woven fabric, a porous body or the like can be applied. As the material of the fibrous structure, cotton and silk are used as the natural fibers, and recycled fibers are used. Cupra ammonium rayon, semi-synthetic fibers include cellulose acetate, and synthetic fibers include polyamide, aromatic polyamide, polyester, polyacrylonitrile, polytetrafluoroethylene, polymethylmethacrylate, polystyrene, polypropylene, etc. Be done.

Examples of the porous body include polyurethane and crosslinked polyvinyl alcohol.

As the adsorbent, a hydrophilic insoluble solid having an acidic functional group, a styrene-divinylbenzene type granular porous solid, an insoluble solid containing a low molecular weight substance containing sugar phosphoric acid, blood cells such as active bodies, proteins, An adsorbent that adsorbs electrolytes and harmful substances is preferable.

The blood component separator 3 can be connected to the blood container 2 by the first tube 4. Specifically, the proximal end of the first tube 4 is connected to the blood inlet 3a of the blood component separator 3, and the other end thereof is provided with a communicating needle 41 capable of puncturing the outlet 2a of the blood container 2. It has a structure provided.

A roller-type clamp 42 is disposed in the middle of the first tube 4, and the communication needle 41 is moved to the blood container 2 while the flow path of the first tube 4 is blocked by the clamp 42. The blood component separator 3 and the blood container 2 are put into communication with each other by puncturing the discharge port 2a.

After the blood component separator 3 and the blood container 2 are put into communication with each other, the amount of blood flowing through the first tube 4 can be adjusted by the clamp 42.

Instead of piercing the discharge port of the container with the communication needle 41 to establish communication, the discharge port 2a is formed by the connector A, and the tip of the first tube 4 can be fitted in the connector A in a liquid-tight manner. The connector B may be formed by a simple connector B, and the communication operation may be performed using the connectors A and B.

A cylindrical chamber 5 is provided on the downstream side of the blood connection separator 3 via a second tube 6. The chamber 5 temporarily stores the filtrate that has passed through the blood component separator 3 and separates and removes air bubbles from the filtrate.

The bubbles separated in the chamber 5 are stored in a gas storage container 10 via a bypass tube 9 described later. As such a chamber 5, specifically, a drip chamber having a volume of 7 to 22 cc and an inner diameter of 13 to 22 mm is preferably used.

A filter or the like for removing foreign matter in the stored blood may be arranged inside the chamber 5.

Further, during use, such a chamber 5 is arranged so as to extend in the vertical direction, whereby the bubble removing ability is suitably enhanced.

The treated blood from which air bubbles have been removed by the chamber 5 is introduced into the blood vessel of the patient via the third tube 8. Specifically, the third tube 8 has a structure in which the base end is connected to the blood outlet 3b of the blood component separator 3 and the other end is provided with a puncture needle 81 capable of puncturing a blood vessel of a patient. Is.

A roller type clamp 82 is disposed in the middle of the third tube 8, and the puncture needle 81 is punctured into the blood vessel of the patient in a state where the flow channel of the third tube 8 is blocked by the clamp 82. As a result, the blood component separator 3 and the blood vessel of the patient are brought into communication with each other.

After the blood component separator 3 and the blood vessel of the patient are put into communication with each other, the amount of blood flowing through the third tube 8 can be adjusted by the clamp 82.

Therefore, the blood component separation circuit 1 according to the present embodiment includes a bypass tube 9 that connects the upper portion of the chamber 5 and the first tube 4 without passing through the blood component separator 3. A gas storage container 10 provided in the middle of the bypass tube 9 is provided.

The connecting portion of the bypass tube 9 to the chamber 5 should be at or near the upper end surface of the chamber 5 in consideration of efficiently transferring the air bubbles separated in the chamber 5 through the bypass tube 9. Is preferred.

At the start of the blood component separation operation, the gas storage container 10 pushes out the gas remaining in the blood component separator 3, the first tube 4 and the second tube 6 with blood, and Is transferred and stored through the chamber 5 and the bypass tube 9, and after the blood separation operation is completed, the stored gas is transferred to the blood component separator 3 and a portion downstream thereof to It is for pushing out the blood components remaining in the site. As shown in FIG. 1, in the present embodiment, a gas injection port 9a is provided in the middle of the bypass tube 9, and a syringe having a tip shape that can be airtightly fitted into the gas injection port 9a is used as the gas storage container 10. is doing. However, the structure of the gas storage container 10 is not particularly limited as long as the gas can be stored and transferred as described above, and a flexible container such as a bag is also applicable.

Clemmes (inflow prevention means) 91 and 92 are provided at the upstream side of the gas inlet 9a of the bypass tube 9 and the downstream side of the gas inlet 9a of the bypass tube 9, respectively. The flow passages on the upstream side and the downstream side of the gas injection port 9a of the bypass tube 9 can be selectively opened and closed.

Next, a blood component separation operation using the blood component separation circuit 1A having such a configuration will be described.

First, blood is collected from the donor by using the blood collecting needle of the blood container 2, and 400 cc of blood, for example, is contained in the blood container 2.

It should be noted that the blood container 2 may contain a concentrated red blood cell solution obtained by previously centrifuging whole blood, instead of containing whole blood.

As described above, the blood container in which the whole blood or the concentrated red blood cell liquid is contained is suspended on a stand or the like (not shown). Then, the clamp 42 of the first tube 4 and the clamps 91, 92 of the bypass tube 9 are closed, and the communication needle 41 provided at the tip of the first tube 4 is punctured into the discharge port 2a of the blood container 2. To do. Then, the clamp 82 of the third tube 8 is closed, and the puncture needle 81 provided at the tip is punctured into the blood vessel of the patient.

Then, the clamp 42 is opened, and the blood or the concentrated red blood cell liquid in the blood container 2 is introduced into the blood component separator 3 through the first tube 4 by the drop. At this time, the blood component separator 3 and the chamber 5 are arranged vertically. Further, the clamp 82 is kept in the closed state.

Then, when the filtrate flows out from the blood outlet 3 b of the blood component separator 3 and is accumulated in the chamber 5 by about half, the clamp 82 is opened and the clamp 92 is closed. By this operation, the gas remaining in the blood component separator 3, the first tube 4 and the second tube 6 is pushed out by the blood or the concentrated red blood cell solution and transferred to the chamber 5, and further passes through the bypass tube 9. , Is transferred and stored in the gas storage container 10.

When the clamp 82 is opened, the filtrate (processed blood) is introduced into the blood vessel of the patient through the third tube 8.

This operation is continued until all the blood in the blood container 2 is exhausted, and all the filtrate is introduced into the blood vessel of the patient.

When the blood in the blood container 2 is exhausted, the clamp 42 is closed and the clamp 91 is opened.

Then, by pushing the pusher of the syringe which is the gas storage container 10, the gas stored in the gas storage container 10 is transferred to the upstream side of the gas injection port 9 a of the bypass tube 9 and the first tube 4. It is introduced into the blood component separator 3 through a portion downstream of the connection point. As a result, the blood remaining in the first tube 4 can be supplied to the blood component separator 3 to be separated and the blood component including the blood cell components remaining in the blood component separator 3 can be washed out. it can. Furthermore, the gas that has passed through the blood component separator 3 is sent into the blood vessel of the patient through the second tube 6, the chamber 5, and the third tube 8 so that the second tube 6, the chamber 5, and the third tube Blood components including blood cell components remaining in the blood vessel 8 can be introduced into the blood vessel of the patient.

In this way, the cleaning operation with gas is continued until the remaining components such as red blood cells disappear. When there are no remaining components, the clamps 42 and 82 are closed and the operation is completed.

As described above, since the residual blood is washed out by using the gas remaining in the blood component separator 3 or the like, the operation is simpler than that in the case of washing with physiological saline. Moreover, the blood component separation operation can be performed accurately. Further, due to the presence of the bypass tube 9, it is not necessary to perform a complicated operation such as discharging the gas in the circuit before the puncture needle 81 is punctured into the blood vessel of the patient.

In this method of use, the blood component separation operation is performed without performing the priming operation of the circuit. However, when the priming operation is required, the priming solution is used in the same manner as described above. Blood remaining in the blood component separator 3 is stored in the gas storage container 10, and after the blood component separation operation is completed, the residual gas component is washed out using the stored gas. Good. Further, the blood component separation circuit 1A according to the present embodiment is described as a circuit used for directly transfusing processed blood to a patient at the bedside, but the present invention is not limited to this, and for producing a red blood cell preparation. May be used for. In that case, a communication needle may be provided at the tip of the third tube 8 and the communication needle may be communicated with the preparation container containing the red blood cell preparation. In this case, the chamber 5 is not always essential.

Next, a blood component separation circuit according to another embodiment of the present invention will be described with reference to FIG.

The difference between the blood component separation circuit 1 B shown in FIG. 2 and the blood component separation circuit 1 A shown in FIG. 1 is that the connection point between the bypass tube 9 and the downstream side of the blood component separator 3 is located above the chamber 5. The point is that it is provided in the middle of the second tube 6 without being provided.

A blood component separation method using the blood component separation circuit 1B having such a circuit configuration will be described.

First, blood is collected from the donor by using the blood collection needle of the blood container 2, and 400 cc of blood, for example, is contained in the blood container 2.

It should be noted that the blood container 2 may not contain whole blood, but may contain a concentrated red blood cell liquid obtained by previously centrifuging whole blood.

As described above, the blood container in which whole blood or red blood cell concentrated liquid is contained is suspended on a stand (not shown), the tip of the third tube 8 is held, and the blood of the blood component separator 3 is collected. The portion downstream of the inlet 3a (indicated by C in the figure) is inverted (that is, the communication needle 81 is located at the highest position and the blood inlet 3a of the blood component separator 3 is located at the lowest position). Yes. Then, the clamp 42 of the first tube 4 and the clamps 93, 94 of the bypass tube 9 are closed, and the communication needle 41 provided at the tip of the first tube 4 is attached to the outlet 2a of the blood container 2. Puncture.

Then, the clamps 42 and 94 are opened, and the blood or the concentrated red blood cell liquid in the blood container 2 is introduced into the blood component separator 3 through the first tube 4 by the drop. At this time, the clamp 82 is kept closed. Then, when the filtrate flows out from the blood outlet 3b of the blood component separator 3 and is accumulated in the chamber 5 by about half, the clamp 82 is opened and the clamp 94 is closed. By this operation, the gas remaining in the blood component separator 3 and the first tube 4 is pushed out by the blood or the red blood cell concentrated liquid, passes through the bypass tube 9, and is transferred and stored in the gas storage container 10. To be done.

When the clamp 82 is opened, the filtrate that has passed through the second tube 6 is once stored in the chamber 5 as it is, and air bubbles are separated. As described above, by inversion of the portion C of the blood component separator 3 on the downstream side of the blood inlet 3a, the separated air bubbles are collected above the chamber 5 (the communication needle 81 side), and the third tube 8. It easily escapes from the circuit through the communication needle 81. Then, when a certain amount of blood is stored in the chamber 5, the grasping state of the third tube 8 is released, and the circuit is in a normal state (that is, the blood container 2 is at the uppermost position and the puncture needle 81 is at the lowermost position). When the processed blood reaches the tip of the puncture needle 81, the puncture needle 81 is punctured into the blood vessel of the patient.

As a result, bubbles in the filtrate derived from the blood component separator 3 are separated and removed in the chamber 5, and then introduced into the blood vessel of the patient through the third tube 8. The bubbles separated and removed in the chamber 5 are stored in the upper space of the chamber 5.

This operation is continued until all the blood in the blood container 2 is exhausted, and all the filtrate is introduced into the blood vessel of the patient.

When the blood in the blood container 2 is exhausted, the clamp 42 is closed and the clamp 93 is opened.

Then, by pushing the pusher of the syringe which is the gas storage container 10, the gas stored in the gas storage container 10 is transferred to the upstream side of the gas injection port 9 a of the bypass tube 9 and the first tube 4. It is introduced into the blood component separator 3 through a portion downstream of the connection point. As a result, the blood remaining in the first tube 4 can be supplied to the blood component separator 3 to be separated and the blood component including the blood cell components remaining in the blood component separator 3 can be washed out. it can. Furthermore, the gas that has passed through the blood component separator 3 is introduced into the blood vessel of the patient through the second tube 6, the chamber 5, and the third tube 8, so that the second tube 6, the chamber 5, and the third tube Blood components including blood cell components remaining in the blood vessel 8 can be introduced into the blood vessel of the patient.

In this way, the cleaning operation with gas is continued until the remaining components such as red blood cells disappear. When there are no remaining components, the clamps 42 and 82 are closed and the operation is completed.

As described above, since the residual blood is washed out by using the gas remaining in the blood component separator 3 or the like, the operation is simpler than that in the case of washing with physiological saline. Moreover, the blood component separation operation can be performed accurately.

In this method of use, the blood component separation operation is performed without performing the priming operation of the circuit. However, when the priming operation is required, the priming solution is used in the same manner as above. Blood remaining in the blood component separator 3 is stored in the gas storage container 10, and after the blood component separation operation is completed, the residual gas component is washed out using the stored gas. Good. Further, the blood component separation circuit 1B according to the present embodiment is described as a circuit used at the bedside for directly transfusing processed blood to a patient, but the present invention is not limited to this, and for producing a red blood cell preparation. May be used for. In that case, like the circuit 1 B ′ shown in FIG. 3, a communication needle 83 is provided at the tip of the third tube 8 and the communication needle 83 is communicated with the preparation container 7 containing the red blood cell preparation. Good. Further, in this case, the chamber 5 is not always indispensable, and the operation of inverting the downstream side of the circuit to discharge the gas in the circuit out of the circuit is not indispensable.

Next, a blood component separation circuit according to another embodiment of the present invention will be described with reference to FIG.

The difference between the blood component separation circuit 1C according to the embodiment shown in FIG. 4 and the blood component separation circuit 1B according to the embodiment shown in FIG. 2 is that the blood storage container 2 is punctured by a communication needle 96 described later. The point is that a gas inlet 2b that can communicate is provided, and a communication needle 96 that can puncture the gas outlet 2b is provided at the upstream end of the bypass tube 9.

A blood component separation method using the blood component separation circuit 1C having such a circuit configuration will be described.

First, blood is collected from the donor by using the blood collection needle of the blood container 2, and 400 cc of blood, for example, is contained in the blood container 2.

The blood container 2 may not contain whole blood, but may contain a concentrated red blood cell solution obtained by previously centrifuging whole blood.

As described above, the blood container in which the whole blood or the concentrated red blood cells is contained is suspended on a stand (not shown), the tip of the third tube 8 is gripped, and the blood of the blood component separator 3 is collected. The portion downstream of the inlet 3a (indicated by D in the figure) is inverted (that is, the puncture needle 81 is located at the highest position and the blood inlet 3a of the blood component separator 3 is located at the lowest position). Yes. Then, the clamp 42 of the first tube 4 and the clamp 95 of the bypass tube 9 are closed, and the communication needle 41 provided at the tip of the first tube 4 is punctured into the discharge port 2a of the blood container 2.

Then, the clamps 42 and 95 are opened, and the blood or the concentrated red blood cell liquid in the blood container 2 is introduced into the blood component separator 3 through the first tube 4 by the drop. At this time, the clamp 82 is kept closed. Then, when it is confirmed that a space is formed in the upper part of the blood container 2, the communication needle 95 is pierced into the gas inlet 2b of the blood container 2 to connect the bypass tube 9 and the upper part of the blood container 2 to each other. Communicate. Then, when the filtrate flows out from the blood outlet 3b of the blood component separator 3 and is stored in the chamber by about half, the clamp 82 is opened. By this operation, the gas remaining in the blood component separator 3 and the first tube 4 is pushed out by the blood or red blood cell concentrated liquid, passes through the bypass tube 9, and is transferred into the upper space of the blood container 2, Be stored.

When the clamp 82 is opened, the filtrate that has passed through the second tube 6 is once stored in the chamber 5 as it is, and air bubbles are separated. As described above, by inverting the portion C of the blood component separator 3 on the downstream side of the blood inlet port 3a, the separated air bubbles are accumulated above the chamber 5 (communication needle side), and the third tube 8, It easily escapes to the outside of the circuit through the puncture needle 81. Then, when a certain amount of blood is stored in the chamber 5, the grasped state of the third tube 8 is released, and the circuit is brought into a normal state (that is, the blood container 2 is at the uppermost position, and the puncture needle 81 is used). Is placed under gravity so that it is at the lowest position), and when the treated blood reaches the tip of the puncture needle 81, the puncture needle 81 is punctured into the blood vessel of the patient.

As a result, bubbles in the filtrate derived from the blood component separator 3 are separated and removed in the chamber 5, and then introduced into the blood vessel of the patient through the third tube 8. The bubbles separated and removed in the chamber 5 are stored in the upper space of the chamber 5.

This operation is continued until all the blood in the blood container 2 is exhausted, and all the filtrate is introduced into the blood vessel of the patient.

When the blood in the blood container 2 is exhausted, the clamp 42 is opened and the clamp 95 is closed.

Then, by pushing the pusher of the syringe which is the gas storage container 10, the gas stored in the gas storage container 10 is supplied to the upstream side of the gas injection port 9 a of the bypass tube 9 and the first tube 4. It is introduced into the blood component separator 3 through a portion downstream of the connection point. As a result, the blood remaining in the first tube 4 can be supplied to the blood component separator 3 to be separated and the blood component including the blood cell components remaining in the blood component separator 3 can be washed out. it can. Furthermore, the gas that has passed through the blood component separator 3 is sent to the blood vessel of the patient through the second tube 6, the chamber 5, and the third tube 8 so that the second tube 6, the chamber 5, and the third tube 8 Blood components including blood cell components remaining inside can be introduced into the blood vessel of the patient.

In this way, the cleaning operation with gas is continued until the remaining components such as red blood cells disappear. When there are no remaining components, the clamps 42 and 82 are closed and the operation is completed.

As described above, since the residual blood is washed out by using the gas remaining in the blood component separator 3 or the like, the operation is simpler than that in the case of washing with physiological saline. Moreover, the blood component separation operation can be performed accurately.

In this method of use, the blood component separation operation is performed without performing the priming operation of the circuit. However, when the priming operation is required, the priming solution is used in the same manner as above. Blood remaining in the blood component separator 3 is stored in the gas storage container 10, and after the blood component separation operation is completed, the residual gas component is washed out using the stored gas. Good. Although the blood component separation circuit 1C according to the present embodiment is a circuit used for transfusing processed blood directly to a patient at the bedside, it is used for producing a red blood cell preparation. Good. In that case, a communication needle may be provided at the tip of the third tube 8 and the communication needle may be communicated with the drug product container containing the red blood cell drug product. Moreover, the chamber 5 is not always essential, and the operation of inverting the downstream side of the circuit to discharge the gas in the circuit out of the circuit is not essential.

Further, the circuit according to each of the above embodiments is configured such that a clamp is arranged in the middle of the bypass tube 9 to open and close the flow path of the bypass tube 9, but the bypass tube 9 and the main line are not connected. It is also possible to make each connection using a three-way stopcock or the like, and thereby control the flow path of the bypass tube 9.

Next, the present invention will be described in more detail with reference to examples.

[0082]

【Example】

 [Example] A blood component separation circuit shown in FIG. 3 was produced. 1. Blood container: soft vinyl chloride, capacity 400cc 2. Blood component separation device: Leukocyte removal filter ・ Housing / (material) ABS, capacity 50 cc ・ Filter material / crosslinked polyvinyl alcohol 3. Chamber: Made of soft vinyl chloride, capacity 7 cc 4. Treated blood container (formulation container): made of soft vinyl chloride, capacity 600 cc 5. Gas storage container: Syringe (tip hole diameter: 4.5 mm, capacity: 60 cc) Each connecting tube is made of vinyl chloride with an inside diameter of 3.5 mm, and a plastic communication needle is provided at the tip of the first tube and the third tube 8. I installed it. Further, clamps 93 and 94 are attached to the bypass tube 9 on the upstream side and the downstream side of the gas storage container 10, respectively. Further, roller clamps 42 and 82 are attached immediately below the communicating needle 41 of the first tube 4 and immediately before the communicating needle 81 of the third tube 8, respectively. In addition, a T-shaped pipe is arranged in the middle of the bypass tube, the tip of the syringe is fitted and connected, and the lower end of the bypass tube 9 is connected to the T-shaped pipe in the middle of the second tube 6. Used to connect.

The following experiment was conducted using the circuit having the above configuration.

400 cc of blood was centrifuged to obtain 1 unit of erythrocyte concentrate, this operation was repeated 3 times, and after mixing 3 units of the obtained erythrocyte concentrate, the weight was adjusted to approximately the same. The blood was redistributed into units, and each unit was distributed and contained in three blood containers.

As described above, the blood container in which the whole blood or the concentrated red blood cells is contained is suspended on the stand, and the clamp 42 of the first tube 4 and the clamps 93, 94 of the bypass tube 9 are closed. did. Then, the communicating needle 41 provided at the tip of the first tube 4 was punctured into the outlet of the blood container 2 and the connecting needle 83 at the tip of the third tube 8 was communicated with the treated blood container 7.

Then, the clamps 42 and 92 were opened, and the blood or the concentrated red blood cell liquid in the blood container 2 was introduced into the blood component separator 3 through the first tube 4 by the drop. At this time, the clamp 82 was closed. Then, when the filtrate flowed out from the blood outlet 3b of the blood component separator 3 and had accumulated about half in the chamber, the clamp 82 was opened. By this operation, the gas remaining in the blood component separator 3, the first tube 4 and the second tube 6 is pushed out by the blood or the red blood cell concentrated liquid, and further passes through the bypass tube 9 to be stored in the gas storage container. Transferred to 10 and stored. The gas stored was 55 cc.

The filtrate passing through the second tube 6 was once stored in the chamber 5 as it was, and the air bubbles were separated. Then, the filtrate flowing out from the chamber 5 was stored in the treated blood storage container 7 through the third tube 8. After confirming that the blood in the blood container 2 was completely depleted, the clamp 42 was closed and the clamp 93 was opened.

Then, by pushing the pusher of the syringe which is the gas storage container 10, the gas stored in the gas storage container 10 is transferred to the upstream side of the bypass tube 9 and the downstream side of the connection point of the first tube 4. Was introduced into the blood component separator 3. In this way, the blood components including the blood cell components remaining in the second tube 6, the chamber 5, and the third tube 8 were washed out into the treated blood container 7.

Then, the gas cleaning operation was continued until the residual components such as red blood cells disappeared, and when the residual blood components disappeared, the clamps 42 and 82 were closed to complete the operation.

In this way, the composition of the concentrated red blood cell liquid contained in the treated blood storage container 7 was calculated, and the leukocyte removal rate, platelet removal rate, and red blood cell recovery rate were calculated by the following equations. The white blood cell count, platelet count, and red blood cell count per 1 μl were measured using Sysmex NE-6000 (manufactured by Toyo Medical Electronics Co., Ltd.). The results are shown in Table 1.

Number of blood cells (white blood cells, red blood cells, platelets) = [weight of blood in container (g) × number of blood cells per μl × 100] / specific gravity of blood in container (g / ml) Leukocyte removal rate = [(untreated White blood cell count in blood-white blood cell count in treated blood) x 100] / white blood cell count in untreated blood Platelet removal rate = [(platelet count in untreated blood-platelet count in treated blood) x 100] / Number of platelets in untreated blood Red blood cell recovery rate = [Number of red blood cells in untreated blood / Number of red blood cells in treated blood] / 100

Comparative Example 1 Using a circuit similar to that of the example, the washing operation with gas was not performed, and the blood component was allowed to stand for 10 minutes after all the blood flowed out from the blood storage container to complete the blood component separation operation. Other than that, the procedure was performed in the same manner as in Example, and the leukocyte removal rate, platelet removal rate, and red blood cell recovery rate were determined in the same manner as in Example. The results are shown in Table 1.

Comparative Example 2 Using the same circuit as in Example, after confirming that all the blood has finished flowing from the blood container 2, the connecting needle 41 is punctured into a 100 cc physiological saline bag, Physiological saline was introduced into the first tube 4. Then, this physiological saline was passed through the blood component separator 3, the second tube 6, the chamber 5, and the third tube 8 to wash out the remaining blood component into the treated blood container 7. After confirming that the remaining components such as red blood cells could not be washed out, the operation was terminated by closing the clamps 42 and 82, and the white blood cell removal rate, platelet removal rate, and red blood cell recovery rate were determined in the same manner as in the example. I asked. The results are shown in Table 1.

Table 1 Examples Comparative Example 1 Comparative Example 2 Leukocyte removal rate (%) 98.3 98.8 98.3 Platelet removal rate (%) 73.8 73.4 62.1 Red blood cell recovery rate (%) 93 .3 88.6 94.6 Filtration time (min) 10.51 8.77 9.45

From the results of Table 1, by using the blood component separation circuit according to the present invention to wash out the residual blood component by gas, the red blood cell recovery was significantly improved as compared with Comparative Example 1 in which no washout was performed. Improved. In Comparative Example 2, which was washed out with physiological saline, the red blood cell recovery rate was almost the same as that of the Example, but the platelet removal rate was considerably lower than that of the Example, and platelets leaked out. It was confirmed.

[0096]

[Effect of the device]

 As described above in detail, the blood component separation circuit according to the present invention includes a blood container for containing the blood component to be processed, and a specific component from the blood component supplied from the blood container. The blood component separator for capturing and separating, the bypass means for communicating the specific portion upstream and the specific portion downstream of the blood component separator without passing through the blood component separator, and the bypass means of the bypass means. A gas storage container provided on the way and capable of storing a gas component existing in the blood component separator, a blood component from the blood storage container to the bypass means, and a filtrate flowing out from the blood component separator. Since it is provided with an inflow blocking means for blocking the inflow, it is possible to recover the separated blood components such as blood cells with a high yield by a simple operation.

Further, another blood component separation circuit according to the present invention has a blood storage container for storing a blood component to be processed therein, and a specific component based on the blood component supplied from the blood storage container. A blood component separator for capturing and separating, and a bypass means, one end of which is configured to be aseptically communicable with the upper portion of the blood container, and the other end of which is communicated with a specific portion on the downstream side of the blood component separator. Since the inflow blocking means for blocking the inflow of the blood liquid component from the blood container and the filtrate flowing out of the blood component separator into the bypass means is provided, the separated blood cells can be easily operated. It is possible to recover blood components such as blood sugar in a high yield.

[Brief description of drawings]

FIG. 1 is a diagram showing a circuit configuration of a blood component separation circuit according to an embodiment of the present invention.

FIG. 2 is a diagram showing a circuit configuration of a blood component separation circuit according to another embodiment of the present invention.

FIG. 3 is a diagram showing a circuit configuration of a blood component separation circuit according to another embodiment of the present invention.

FIG. 4 is a diagram showing a circuit configuration of a blood component separation circuit according to another embodiment of the present invention.

FIG. 5 is a diagram showing a circuit configuration of a conventional blood component separation circuit.

[Explanation of symbols]

 1 Blood Component Separation Circuit 2 Blood Container 3 Blood Component Separator 4 First Tube 5 Chamber 6 Second Tube 7 Treated Blood Container 8 Third Tube 9 Bypass Tube 10 Gas Storage Container

Claims (3)

[Scope of utility model registration request] 1. A blood container for containing a blood component to be treated, a blood component separator for capturing and separating a specific component from the blood component supplied from the blood container, and the blood component. Bypass means for communicating a specific portion on the upstream side and a specific portion on the downstream side of the separator without passing through the blood component separator, and provided in the middle of the bypass means and present in the blood component separator A gas storage container capable of storing a gas component, and an inflow blocking unit for blocking the inflow of the blood component from the blood container and the filtrate flowing out of the blood component separator into the bypass unit. Blood component separation circuit. 2. A blood container for accommodating a blood component to be treated, a blood component separator for capturing and separating a specific component from the blood component supplied from the blood container, one end of which is By-pass means configured to be aseptically communicable to the upper part of the blood container and having the other end communicated with a specific portion on the downstream side of the blood component separator; and blood components from the blood container to the bypass means. And an inflow preventing means for preventing the inflow of the filtrate flowing out from the blood component separator. 3. A chamber for vertically removing air bubbles in the treated blood is arranged vertically downstream of the blood component separator, and the bypass means is connected to the upper portion of the chamber. The blood component separation circuit according to 1.