JP5297463B2 - Blood processing equipment - Google Patents

Description

  The present invention relates to a blood processing instrument used for separating and removing predetermined blood components such as white blood cells and platelets from blood.

  Conventionally, a blood processing instrument used for separating and removing leukocytes and the like from blood is provided between a pair of resin sheets and a pair of resin sheets as disclosed in, for example, Patent Document 1. The blood processing filter member is divided into a blood inflow chamber and a blood outflow chamber, a blood inflow port communicating with the blood inflow chamber, and a blood outflow port communicating with the blood outflow chamber.

Japanese translation of PCT publication No. 2003-512093 (refer to claim 1 and FIG. 1)

  However, according to the conventional blood processing instrument, the resin sheet on the blood outflow chamber side may be in close contact with the blood processing filter member, blocking the blood flow path in the blood processing filter member, clogging filtration, poor filtration, There was a problem that hemolysis occurred.

  Therefore, in view of the above problems, the present invention prevents the resin sheet on the blood outflow chamber side constituting the housing from coming into close contact with the blood processing filter member, and ensures a blood flow path in the blood processing filter member. Another object of the present invention is to provide a blood processing instrument that does not cause filtration clogging, poor filtration, hemolysis, and the like.

In order to solve the above-described problem, a blood treatment device according to claim 1 is provided with a housing made of a pair of resin sheets, a blood inflow chamber interposed between the pair of resin sheets, and the housing. A blood processing filter member that is divided into blood outflow chambers, and a blood inflow chamber side resin sheet that constitutes the blood inflow chamber of the pair of resin sheets, and the blood processing filter member; A blood inflow port communicating with the inflow chamber; a blood outflow chamber side resin sheet constituting the blood outflow chamber of the pair of resin sheets; and the blood treatment filter member; a blood treatment device and a blood outlet port communicating with the surface area of the blood outflow chamber side resin sheet, you Te size Kuna' compared to the surface area of the blood inlet chamber side resin sheet The blood outflow chamber side resin sheet and the blood inflow chamber side resin sheet are welded with their peripheral edges overlapped, and the blood outflow chamber side resin sheet rises on the back side of the surface facing the blood inflow chamber side resin sheet. It is characterized by that.

According to the present invention, when the blood inflow chamber side resin sheet is manufactured by overlapping and welding the peripheral edges of the blood inflow chamber side resin sheet and the blood outflow chamber side resin sheet so as to sandwich the blood processing filter member, Since the surface area of the blood outflow chamber side resin sheet is larger than the surface area of the blood outflow chamber, the blood outflow chamber side resin sheet rises on the back side of the surface facing the blood inflow chamber side resin sheet.
Therefore, since the blood flow-out chamber side resin sheet that has risen is separated from the blood processing filter member, it is possible to secure a blood flow path in the blood processing filter member, and filtration clogging, poor filtration, hemolysis, etc. do not occur. .

  Moreover, the blood processing device according to claim 2 is the blood processing device according to claim 1, wherein the blood outflow port extends into the housing. .

  According to the above configuration, since the blood outflow port extends in the housing, the blood processing filter member is separated from the blood outflow chamber side resin sheet by the diameter of the blood outflow port. The blood flow path can be secured, and filtration clogging, poor filtration, hemolysis, etc. do not occur.

  Further, the blood processing device according to claim 3 is the blood processing device according to claim 1, wherein the blood processing filter member has a sheet-shaped frame and a periphery of the sheet-shaped frame. The blood outflow port is welded between the sheet-like frame and the blood outflow chamber side resin sheet, and extends into the housing at least to the periphery of the filtration membrane. It is characterized by that.

  According to the above configuration, since the blood outflow port extends to the peripheral edge of the filtration membrane, the blood processing filter member is separated from the blood outflow chamber side resin sheet by the diameter of the blood outflow port. The blood flow path in the filter member can be secured, and filtration clogging, poor filtration, hemolysis, etc. do not occur.

  The blood treatment device according to claim 4 is the blood treatment device according to claim 1, wherein the blood inflow port extends into the housing. .

  According to the above configuration, since the blood inflow port extends into the housing, the blood processing filter member and the blood inflow chamber side resin sheet are separated from each other by the diameter of the blood inflow port. Therefore, the blood flowing into the blood inflow chamber can be spread over the entire surface of the blood processing filter member, and the filtration efficiency is improved.

  Moreover, the blood processing device according to claim 5 is the blood processing device according to claims 1 to 4, wherein the blood processing filter member comprises a plurality of filter bodies, The filter body is characterized by comprising a sheet-like frame and a filtration membrane whose periphery is welded to the sheet-like frame.

  According to the above configuration, since the blood processing filter member is composed of a plurality of filter bodies, that is, has a plurality of sheet-like frames, the plurality of filtration membranes can be divided into the plurality of sheet-like frames. Can be easily welded to the sheet-like frame.

  According to the present invention, it is possible to prevent the resin sheet on the blood outflow chamber side constituting the housing from coming into close contact with the blood processing filter member, to secure the blood flow path in the blood processing filter member, and to clog the filtration. It is possible to provide a blood processing instrument that does not cause defects or hemolysis.

It is the front view which looked at the blood processing instrument in the embodiment from the blood outflow chamber side. FIG. 2 is a cross-sectional view of the blood processing apparatus shown in FIG. 1 taken along line AA. FIG. 3 is a front view of a blood processing filter member used in a blood processing device as viewed from the blood inflow chamber side. It is a front view of the blood inflow port and blood outflow port of other embodiment. It is a general view of the blood collection instrument provided with the blood processing instrument in embodiment.

  Next, embodiments of the present invention will be described in detail with reference to the drawings. 1 is a front view of the blood processing apparatus according to the present invention as viewed from the blood outflow chamber side, and FIG. 2 is a cross-sectional view of the blood processing apparatus shown in FIG. 3 is a front view of the blood processing filter member used in the blood processing instrument shown in FIG. 1 as viewed from the blood inflow chamber side.

(Blood treatment instrument 1)
As shown in FIG. 1, the blood processing instrument 1 according to the embodiment has a housing 10, a blood processing filter member 20 that is interposed in the housing 10 and processes blood, and the collected blood flows into the housing 10. A blood inflow port 30 and a blood outflow port 31 through which processed blood flows out of the housing 10 are formed.

(Housing 10)
As shown in FIGS. 1 and 2, the housing 10 is a bag-like container for storing blood to be processed, and welds the entire circumference of a pair of resin sheets 11 made of a soft resin such as polyvinyl chloride described later. It becomes.
Further, when welding the entire circumference of the peripheral edge of the pair of resin sheets 11, the inside of the housing 10 is blood-treated as shown in FIG. The filter member 20 is divided into a blood inflow chamber 14 and a blood outflow chamber 15.

  As shown in FIGS. 1 and 2, the pair of resin sheets 11 includes a blood inflow chamber side resin sheet 12 constituting the blood inflow chamber 14 and a blood outflow chamber side resin sheet 13 constituting the blood outflow chamber 15. Here, the surface area of the blood outflow chamber side resin sheet 13 is larger than the surface area of the blood inflow chamber side resin sheet 12. For this reason, if the entire circumference of the blood inflow chamber side resin sheet 12 and the blood outflow chamber side resin sheet 13 is welded, the blood outflow chamber side resin sheet 13 having a large surface area rises as shown in FIG. Become. The surface area ratio between the blood outflow chamber side resin sheet 13 and the blood inflow chamber side resin sheet 12 is preferably in the range of 20:19 to 10: 7.

(Filter member 20 for blood treatment)
The blood processing filter member 20 divides the inside of the housing 10 into a blood inflow chamber 14 and a blood outflow chamber 15, and serves as a flow path when blood in the blood inflow chamber 14 moves to the blood outflow chamber 15. It is a member that separates and removes blood components. As shown in FIGS. 1 and 2, the configuration of the blood processing filter member 20 includes a sheet-like frame 21 welded between a pair of resin sheets 11 and a plurality of peripheral edges welded to the sheet-like frame 21. Of the filter membrane 23.

(Sheet frame 21)
As shown in FIG. 3, the sheet-like frame 21 is a member for joining a filtration membrane 23 described later between a pair of resin sheets 11, and includes a material (for example, polyurethane) constituting the filtration membrane 23 and a polychlorinated salt. Made of a mixed resin with vinyl.
The configuration of the sheet-like frame 21 includes a substantially O-shaped main body portion 21a having an opening in the center, an extension portion 21b extending from one end side of the main body portion 21a to which the blood inflow port 30 is welded, and the like. It consists of the extension part 21c by which the blood outflow port 31 is welded to the end side.
The opening formed in the center of the main body portion 21a is a flow path for blood in the blood inflow chamber 14 to flow to the blood outflow chamber 15, and the size of the opening is the filtration membrane 23. Is formed so as to be slightly smaller than the filtration membrane 23 so that the entire periphery of the inner periphery of the filter body can be welded to the entire periphery of the inner edge of the main body 21a.
Further, the outer edge side of the main body portion 21 a and the extending portions 21 b and 21 c are welded between the pair of resin sheets 11, so that the sheet frame 21 is fixed between the pair of resin sheets 11. Yes.

(Filtration membrane 23)
The filtration membrane 23 is a member for separating and removing blood components such as leukocytes and platelets from blood, and is directly welded so as to cover an opening formed at the center of the sheet-like frame 21 that is a blood flow path. Has been.
The filtration membrane 23 is preferably a sponge-like porous body or a nonwoven fabric. The sponge-like porous body or non-woven fabric has a large number of fine continuous holes communicating from one surface to the other surface, and a polyurethane-like sponge-like porous body is more preferable.
Here, in FIG. 2, six filtration membranes 23 are laminated, but the number of filtration membranes 23 is preferably 2 to 10 in the case of a sponge-like porous body.

As the pore diameter of the sponge-like porous body, a thick porous body may be used if it is a large porous body, and even a thin one may be laminated. And if it is a porous body with a small hole diameter, a thin thing will be used. However, the pore diameter and thickness of the porous body can be appropriately selected depending on the blood component to be separated and removed from the blood. In particular, when the blood component to be separated / removed from blood is white blood cells, a sponge-like porous body having an average pore diameter of 3 to 20 μm is preferable. When a nonwoven fabric is used instead of the sponge-like porous body, the diameter of the fiber but about ordinarily from 0.3 to 20 m, basis weight per thickness 0.1mm is preferably about 10 to 60 g / ^{m 2,} about 20 to 50 g / ^{m 2} is more preferable. Furthermore, in order to improve the permeability of platelets or to improve the effect of removing leukocytes, the surface of the sponge-like porous body or nonwoven fabric is coated with a hydrophilic polymer or coated with an antithrombotic material. You can also In addition, a prefilter part that separates and removes aggregates and the like from blood can be provided. If pre-filter portion of the nonwoven fabric is about the diameter of the fibers is 5 to 30 [mu] m, basis weight per thickness 0.1mm is preferably about 10 to 40 g / ^{m 2,} about 15 to 35 g / ^{m 2} is more preferable.

(Blood inflow port 30)
As shown in FIGS. 1 and 2, the blood inflow port 30 is a member for allowing blood to be processed to flow into the housing 10, and is made of a soft resin such as polyvinyl chloride. The blood inflow port 30 is sandwiched between the sheet-like frame 21 and the blood inflow chamber side resin sheet 12 and welded so that the tip of the blood inflow port 30 communicates with the blood inflow chamber 14. In addition, as shown in FIG. 2, the blood inflow port 30 extends into the housing 10 up to the peripheral edge 23A of the filtration membrane 23 welded to the sheet-like frame 21, whereby the blood inflow chamber side resin sheet is formed. The blood inflow port 30 is interposed between the membrane 12 and the filtration membrane 23, and the blood inflow chamber side resin sheet 12 and the filtration membrane 23 can be prevented from coming into close contact with each other. The other end of the blood inflow port 30 is connected to a tube 106 communicating with the first bag 102 of the blood collection device 101 as shown in FIG.

(Blood outflow port 31)
As shown in FIGS. 1 and 2, the blood outflow port 31 is a member for outflowing blood that has undergone blood treatment and stays in the blood outflow chamber 15, and is made of a soft resin such as polyvinyl chloride.
Further, the blood outflow port 31 is sandwiched between the sheet-like frame 21 and the blood outflow chamber side resin sheet 13 and is welded so as to communicate with the blood outflow chamber 15.
As shown in FIGS. 1 and 2, the blood outflow port 31 in the embodiment extends to the inner edge 21 </ b> A of the sheet frame 21, but extends to at least the peripheral edge 23 </ b> A of the filtration membrane 23. preferable. This is because if the blood outflow port 31 extends to the peripheral portion 23A of the filtration membrane 23, the filtration membrane 23 and the blood outflow chamber side resin sheet 13 can be separated by the diameter of the blood outflow port 31.

Next, the usage method of the blood collection instrument 101 provided with the blood processing instrument 1 in the embodiment will be described with reference to FIGS. Here, the case where the filtration membrane 23 in the blood processing apparatus 1 removes leukocytes and platelets from whole blood will be described. FIG. 5 is an overall view of a blood collection device including the blood processing device according to the present invention.
The blood collection device 101 shown in FIG. 5 includes a metal blood collection needle 104, a first bag 102 (blood collection bag), a second bag 103 (erythrocyte storage bag), a first bag made of a soft resin such as polyvinyl chloride. The three members (plasma collection bag) 104a, the fourth bag (bag containing red blood cell preservation solution) 104b, the blood processing device 1 disposed between the first bag 102 and the second bag 103, and the above-mentioned members are connected. It consists of tubes 105-107.

First, a blood collection needle 104 of the blood collection device 101 is punctured into a donor (blood donor) blood vessel to collect blood. The collected blood is stored in the first bag 102 via the tube 105. At this time, it is preferable to seal the tube 106 with a fracture communicating member or the like because blood outflow from the first bag 102 to the tube 106 is prevented.
Then, after blood collection is completed, the vicinity of the first bag 102 of the tube 105 is sealed by fusion with a tube sealer or the like, the sealed portion is cut, and the blood collection needle 104 is separated.

  Next, the sealing of the tube 106 by the breaking communication member or the like is released, and the blood in the first bag 102 is discharged to the tube 106. The discharged blood flows from the blood inflow port 30 into the blood inflow chamber 14 in the blood processing instrument 1 through the tube 106. In this case, for example, the first bag 102 is suspended by a stand or the like and placed at a high place, and blood is transferred using a drop (gravity).

The blood that has flowed into the blood inflow chamber 14 then moves to the blood outflow chamber 15. Since a plurality of filtration membranes 23 are interposed in the blood flow path, white blood cells and platelets in the blood are It will be removed.
Here, since the blood outflow chamber side resin sheet 13 in the embodiment has a dome shape and does not come into contact with the blood processing filter member 20, a blood flow path in the filtration membrane 23 can be secured. Therefore, the blood in the blood inflow chamber 14 moves smoothly to the blood outflow chamber 15.

  The blood from which white blood cells and platelets have been removed (white blood removal) flows out from the blood outflow port 31 and is introduced into the second bag 103, which is a blood collection device, through the tube 107. After the white blood removal is stored in the second bag 103, the vicinity of the second bag 103 of the tube 107 is sealed by fusion with a tube sealer or the like, the sealed portion is cut, and the first bag 102 and The blood processing device 1 is separated from the second bag 103.

  Then, the second bag 103 is centrifuged together with the third bag 104a and the fourth bag 104b, and the white blood removal in the second bag 103 is separated into an erythrocyte layer and a plasma layer. The separated plasma layer is moved and stored in the third bag 104a, and the remaining red blood cell layer is stored by adding the red blood cell storage solution stored in the fourth bag 104b.

  As mentioned above, although the blood processing instrument in embodiment was demonstrated, according to this invention, it can prevent that the resin sheet of the blood outflow chamber side which comprises a housing closely_contact | adheres to the filter member for blood processing, It is possible to provide a blood processing instrument that secures a blood flow path in the filter member and does not cause filtration clogging, poor filtration, hemolysis, or the like.

  Further, the present invention is not limited to the above-described embodiment. For example, although not shown in the figure, the filter member for blood treatment is composed of only a filtration membrane without using a sheet-like frame, and is produced by welding the entire periphery of the filtration membrane directly between a pair of resins. It may be.

  Moreover, the filter member for blood treatment may be composed of a plurality of filter bodies, and the filter body may be composed of a sheet-like frame and a filter membrane whose peripheral edge is welded to the sheet-like frame. If it is the said structure, since it has a some sheet-like frame, a some filtration membrane can be divided | segmented into the some sheet-like frame, and it becomes easy to weld a filtration membrane to a sheet-like frame. Further, when a large number of filtration membranes are used, the filtration membrane can be welded to the sheet-like frame in a uniform state, so that an effective area of the filtration membrane can be ensured.

Further, as shown in FIG. 4 in the shape of the blood inflow port, it may be a blood inflow port 30a that is connected to the blood inflow chamber and has three outlets through which blood flows out. According to this configuration, since blood flows out in multiple directions in the blood inflow chamber, the entire surface of the filtration membrane for performing blood treatment can be used effectively.
Further, as shown in FIG. 4, a blood inflow port 31a in which the blood outflow port communicating with the blood outflow chamber is radially opened is provided so that blood staying in the blood inflow chamber can easily flow into the blood inflow port. Also good. According to the said structure, it can prevent reliably that the blood outflow side resin sheet 13 adheres to the filtration membrane 23. FIG. In addition, although not shown, a hole, a slit, or the like may be provided on the side surface of the blood inflow port so that blood flows from the side surface of the blood inflow port.

DESCRIPTION OF SYMBOLS 1 Blood processing instrument 10 Housing 11 Resin sheet 12 Blood inflow chamber side resin sheet 13 Blood outflow chamber side resin sheet 14 Blood inflow chamber 15 Blood outflow chamber 20 Blood processing filter member 21 Sheet-like frame 23 Filtration membrane 30 Blood inflow port 30a Blood Inflow port 31 Blood outflow port 31a Blood inflow port

Claims (5)

A housing made of a pair of resin sheets;
A blood processing filter member that is interposed between the pair of resin sheets and divides the inside of the housing into a blood inflow chamber and a blood outflow chamber;
A blood inflow port provided between the blood inflow chamber side resin sheet constituting the blood inflow chamber of the pair of resin sheets and the blood processing filter member, and communicating with the blood inflow chamber;
A blood treatment comprising a blood outflow port provided between the blood outflow chamber side resin sheet constituting the blood outflow chamber of the pair of resin sheets and the blood processing filter member, and communicating with the blood outflow chamber. An instrument,
Surface area of the blood outflow chamber side resin sheet is large Kuna' compared to the surface area of the blood inlet chamber side resin sheet,
The blood outflow chamber side resin sheet and the blood inflow chamber side resin sheet are welded with their peripheral edges overlapped, and the blood outflow chamber side resin sheet rises on the back side of the surface facing the blood inflow chamber side resin sheet A blood processing instrument characterized by.   The blood processing instrument according to claim 1, wherein the blood outflow port extends into the housing. The filter member for blood treatment comprises a sheet-like frame and a plurality of filtration membranes whose peripheral edges are welded to the sheet-like frame,
The blood outflow port is welded between the sheet-like frame and the blood outflow chamber side resin sheet, and extends into the housing to at least a peripheral edge of the filtration membrane. The blood processing apparatus according to item 1.   The blood processing instrument according to claim 1, wherein the blood inflow port extends into the housing. The blood processing filter member comprises a plurality of filter bodies,
The blood according to any one of claims 1 to 4, wherein the filter body includes a sheet-like frame and a filtration membrane whose periphery is welded to the sheet-like frame. Processing equipment.

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