JPH0247960Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a support for a blood storage container used in an extracorporeal circulation device such as a plasma separation device.

[Prior Art] Conventionally, blood storage containers used in extracorporeal circulation devices have been suspended vertically. Therefore, the state of diffusion of blood components within the blood storage container becomes non-uniform, and blood with a high hematocrit value is selectively stored in the lower layer of the blood storage container. For this reason,
Especially when there is a large amount of blood in the blood storage container, blood with a high hematocrit value stored in the lower part of the blood storage container will preferentially flow out, and as the blood volume in the blood storage container decreases. Gradually, blood with a low hematocrit value begins to flow out.

As a result, it becomes difficult to supply blood of a constant quality from the blood storage container to the blood processing device provided in the extracorporeal circulation device, resulting in the problem that stable blood processing cannot be performed. In addition, in order to solve the above problems, it has become possible to install a shaking device that shakes and stirs the blood in the blood storage container, but in this case, maintenance of the shaking device is required, and The circulation device also had the problem of being large and complicated to handle.

[Problems to be solved by the invention] The purpose of the invention is to solve the problems of the prior art,
There is no need to install equipment that requires maintenance and management, and it is easy to handle. It also allows blood of a constant quality to be supplied to the blood processing device installed in the extracorporeal circulation device, and the stable The present invention provides a support for a blood storage container used in an extracorporeal circulation device capable of blood processing.

[Means for Solving the Problems] What achieves the above object is a soft resin blood for extracorporeal circulation device which has a blood outlet provided at one end and temporarily stores blood inside. A support for a storage container, the support includes a support part that supports the blood storage container, and a support that tilts the blood storage container at a predetermined angle with respect to a horizontal plane so that the blood outflow port side faces downward. This is a support for a blood storage container having an inclined surface for mounting.

The blood storage container has a blood outflow port provided at one end and a slit provided at the other end, and the support portion engages with the slit of the blood storage container, and the blood storage container It is preferable that the other end of the container be supported. Furthermore, it is preferable that the inclined surface is formed by a flat plate-shaped portion inclined at a predetermined angle with respect to a horizontal surface. Also,
It is preferable that the support has a flat plate-shaped part and a fixing part that fixes the flat plate-shaped part in a state inclined at a predetermined angle with respect to a horizontal plane. Furthermore, it is preferable that the support device has a lower support portion that supports the blood outlet side of the blood storage container. Preferably, the support portion is provided on the inclined surface. Furthermore, it is preferable that the inclined surface is formed by a table-shaped member having the inclined surface formed on the upper surface. Furthermore, it is preferable that the predetermined angle is 10 to 60 degrees. Also. It is preferable that the fixing part includes an angle adjustment mechanism that fixes the flat plate part at an arbitrary predetermined angle.

Therefore, the support for the blood storage container used in the extracorporeal circulation apparatus of the present invention will be explained using an embodiment shown in the drawings.

The blood storage container support 1 of the present invention has a blood outflow port 21 provided at one end and supports a soft resin blood storage container 2 for use in an extracorporeal circulation device that temporarily stores blood inside. blood outlet 2
The blood storage container 2 has a support part 4 that supports the blood storage container 2, and an inclined surface for placing the blood storage container 2 at a predetermined angle with respect to a horizontal surface so that the first side faces downward.

Therefore, a specific explanation will be given using an embodiment of the support of the present invention shown in FIGS. 1 and 2.

FIG. 1 shows a support device 1 of the present invention and a blood storage container 2.
FIG. 2 is a side view of the state in which the first
FIG. 2 is a top view of the support device 1 and blood storage container 2 shown in the figure.

The support 1 of this embodiment has a flat plate shape that is inclined at a predetermined angle A with respect to the horizontal plane in order to form an inclined surface on which the blood storage container 2 is placed so as to be inclined at a predetermined angle with respect to the horizontal plane. A portion 3 is provided, and support portions 4 and 5 for supporting the blood storage container 2 are provided on the flat portion 3. Specifically, the support 1 of this embodiment is a platform-like member in which a flat plate-shaped portion 2 is formed on the upper surface, and supporting portions 4 and 5 are provided on the flat plate-shaped portion 3.

In the support device of this embodiment, a slit 20 is provided at the top of the blood storage container 2 made of soft resin (for example, soft vinyl chloride resin).
An upper support 4 is provided which engages with the slit 20, and the engagement between the upper support 4 and the slit 20 prevents the blood storage container 2 from moving downward. moreover,
A lower support part 5 that supports the blood inflow tube 21 and the blood outflow tube 22, which are provided at the lower part of one end of the blood storage container 2 and connected to a blood outflow port communicating with the internal space of the storage container, without constriction.
a, 5b are provided, and this lower support part 5
The engagement of tubes 21 and 22 with a and 5b prevents the blood storage container 2 from moving in the lateral direction. Blood storage container 2 supported by this support 1
The blood 6 inside is stored below the container 2, but compared to when the blood storage container is suspended vertically,
Blood with a high hematocrit value can be prevented from concentrating at the bottom of the container, especially red blood cells near the blood outlet provided at the bottom of the container.
It is possible to prevent the blood from selectively pooling in the lower part of the blood storage container.

Then, the angle of the inclined surface, specifically the flat plate part 2
As for the predetermined angle A of the inclination, it is possible to increase the diffusion state of blood components inside the blood storage container 2 by making it as small as possible. However, if the angle A is made too small, blood may flow into the blood storage container 2 or Since there is a risk of entraining air when flowing out, it is preferable that the angle A is 10 to 60 degrees.
More preferably, it is 10° to 30°.

In addition, in the above description, the lower support parts 5a and 5b
Although it is preferable to provide these support parts, it is not necessary to provide them, and it is also possible to provide one of them. Also, instead of the lower support, a blood storage container 2
It may also be supported on the sides of the moreover,
Although the case where the supporting parts 4, 5a, 5b are provided on the flat plate part 3 has been described, the present invention is not limited to this, and as shown in FIG.
It may also be provided with

Next, a support for a blood storage container according to the embodiment shown in FIG. 4 will be explained.

The support 1 of this embodiment includes a flat plate part 3, a fixing part that fixes the flat part 3 in a state inclined at a predetermined angle with respect to a horizontal plane, and a blood storage container 2 placed on the flat part 3. It consists of supporting parts 4, 5a, and 5b. The fixed part is the stand 7.
and a fixing member 8 for fixing the flat plate part 3 to the stand 7.
It is made up of. The fixing member 8 has an angle adjustment mechanism for fixing the flat plate portion 3 to the stand 7 at an arbitrary predetermined angle. Furthermore, the fixing member 8 can be fixed to the stand 7 at any desired height. A known method can be used for fixing the fixing member 8 and the stand 7.

Further, as mentioned above, it is preferable that the angle of the flat plate portion 3 can be changed arbitrarily, but it may be fixed at a fixed angle.
Further, although it is preferable that the height of the fixing member 8 can be changed arbitrarily, it may be fixed at a constant height.

In addition, the flat plate-shaped part in the above description is sufficient as long as the blood storage container can be placed on the upper surface, and it is sufficient that the flat part is formed on the upper surface of the plate-shaped part. The material is not limited to a net-like material, and may be a net-like material made of metal, synthetic resin, or the like.

Next, a state in which the blood storage container support of the present invention is attached to an extracorporeal circulation apparatus will be described.

FIG. 5 is a schematic diagram of an extracorporeal circulation apparatus in which a single needle plasma separator is used as the extracorporeal circulation apparatus.

In the plasma separation device shown in FIG. 5, a first infusion tube 46 is provided, one end of which communicates with the first blood supply tube 37, and the other end of the first infusion tube 46 is used for priming and cleaning the inside of the device. A liquid container 45 for storing a liquid such as physiological saline is provided in the first infusion tube 46.
7 is provided. Note that the first infusion tube 46 is
It may be communicated not only with the first blood vessel 37 but also with the second blood vessel 39 or even with the third blood vessel 41. , Furthermore, blood sampling means 31 is inserted from this first infusion tube 46.
A second tube, one end of which communicates with the first blood supply tube 37 located on the side.
An infusion tube 49 is provided, and this second infusion tube 4
An anticoagulant container 48 for storing an anticoagulant such as an ACD solution, a CPD solution, and heparin is provided at the other end of the infusion tube 9 , and a liquid feeding means 50 is provided in the second infusion tube 49 . ing.

The blood collection means 31 is connected to a suitable blood donation means such as a biological vein or a blood bag. As the blood collection means 31, a blood collection needle is used when the blood donation means is a biological vein, and a connector connectable to other containers containing blood (for example, blood bags) is used.

The first blood supply tube has a blood sampling means 31 attached to its tip and communicates with the blood storage container 2 at the other end.
The blood storage container 2 is supported by the support 1 so as to be inclined at a predetermined angle with respect to a horizontal plane. The tip of the second feeding tube communicates with the blood storage container 2, and the other end communicates with the blood inlet 34 of the plasma separation device 33.
It communicates with The third feeding tube has a distal end communicating with the blood outflow port 35 of the plasma separation device 33 and a second end communicating with the first feeding tube 37 .

As the first tube 37, the second tube 39, and the third tube 41, tubes made of transparent flexible synthetic resin, such as vinyl chloride resin, can be suitably used.

The first blood vessel 37 includes a first blood vessel 38 .
The second blood feeding tube 39 is provided with a second blood feeding means 40 . First blood feeding means 38
and second blood feeding means 40, further liquid feeding means 47,
As the pump 50, a pump such as a roller pump or a peristaltic pump is suitably used.

Plasma transport pipes 42 are connected to the plasma outlet ports 36a and 36b of the plasma separator 33, which is a blood processing means.
and a plasma storage container 54 communicating with the plasma transport tube 42.
The plasma transport tube 52 is provided with a plasma transport means 43. As the plasma transport tube 42, a transparent flexible synthetic resin tube such as vinyl chloride resin can be suitably used, and as the plasma transport means 43, a pump such as a roller pump or a peristaltic pump is suitably used. The plasma storage container 44 used is made of soft synthetic resin (for example,
A closed storage means made of vinyl chloride resin) or an open storage means, such as a container made of hard synthetic resin (e.g. polycarbonate, hard vinyl chloride resin) with a hydrophobic filter impermeable to bacteria. can be used.

The first blood supply tube 37 communicates between the blood collection means 31 and the blood storage container 2, and the second blood supply tube 39 connects the blood storage container 2 and the blood inlet 3 of the plasma separation device 33.
4, and the third blood supply tube 41 communicates with the blood outlet 35 of the plasma separation device 33 and the first blood supply means 38.
It communicates with a first blood supply tube 37 located closer to the blood collection means 31, thereby forming an extracorporeal circulation device.

With this extracorporeal circulation device, when blood is collected, blood flows into the blood storage container 2 from the first blood supply tube 37, and a part of the blood flows from the blood storage container 2 into the second blood storage container 2.
It passes through the blood supply tube 39 and flows into the plasma separation device 33,
The treated blood passes through the third blood vessel 41, flows into the first blood vessel 37 again, and further flows into the blood storage container 2. Also, when blood is returned, the blood stored in the blood storage container 2 is transferred to the second blood storage container 2.
It passes through the blood supply tube 39 and flows into the plasma separation device 33,
The blood has been processed, and the treated blood passes through the third blood vessel 41 and flows into the first blood vessel 37 again.
A part of the blood that has passed through the blood collection means 31, been returned, and flowed into the first blood supply tube 37 is flowed into the blood storage container 2 again if necessary, and is subjected to blood treatment again.

Blood processing means are not limited to plasma separation devices, but also remove specific parts of blood (e.g., γ-IgG, rheumatoid factor) by chemical, physical, or biological methods (e.g., adsorption removal). Possible devices include blood purification devices and artificial lungs.

[Function] The function of the support device for the blood storage container of the present invention is described in the fifth section.
This will be explained using a diagram.

First, the blood collecting means 31 is connected to the blood donating means 56, such as a blood bag filled with blood. and,
The first blood feeding means 38 is driven to send blood from the blood donating means 56 to the blood storage container 2 via the blood collecting means 31 and the first blood feeding tube 37. At this time, depending on the case, the second liquid feeding means 50 is driven to supply an anticoagulant such as heparin, ACD liquid, CPD liquid, etc. from the anticoagulant container 48 to the first liquid feeding tube 37 via the second liquid feeding tube 49.
sent to the body to suppress blood coagulation. The blood that has flowed into the blood storage container 2 is driven by the second blood feeding means 40, passes through the second blood feeding tube 39, and is transferred to the plasma separation device 33.
The blood is sent to the blood inlet 34 of. Plasma separation device 33
A part of the plasma in the blood is separated, passes through the plasma transport pipe 42 from the plasma outlet ports 36a and 36b, and flows into the plasma storage container 44 by the plasma collection means 43.

Then, the blood storage container 2 is connected to the support device 1 of the present invention.
Since the blood storage container 2 is supported at a predetermined angle with respect to the horizontal plane, blood with a high hematocrit value can flow to the lower part of the blood storage container, compared to when the blood storage container 2 is suspended vertically. Blood storage container 2 can be prevented from selectively pooling.
Therefore, blood having a constant property can be supplied to the blood processing device, and stable blood processing can be performed.
Then, the treated blood flows out from the blood outflow port 35 and passes through the third blood feeding means 41 to the first blood feeding tube 3.
Join 7.

Next, an example in which the blood storage container support of the present invention is used will be described.

[Example] Using stainless steel, as shown in Figs. 1 and 2, it has a flat part of 200 mm in length and 115 mm in width,
A table-shaped support was prepared, with an upper support section provided at the center of the upper part and two lower support sections provided at the bottom. The inclination angle A of the planar portion was approximately 15°.

Next, experiments with and without the support of the above embodiment and their results will be shown.

[Experiment] A schematic diagram of the experimental circuit used in the experiment is shown in FIG. A blood storage container made of vinyl chloride resin with a volume of 200 ml (length when not filled with blood is 170 mm long and 115 mm wide) was used and supported with the support of the above example. Blood is injected into the blood inflow tube 21 of the blood storage container 2 at a rate of 50 ml/min for 1 minute from the blood storage container 60 using the pump 61, and then physiological saline is injected into the saline container 62 using the pump 61. was allowed to flow in from the blood inflow tube 21 at a rate of 50 ml/min. Thirty seconds after the start of the inflow of physiological saline, the blood stored in the blood storage container 2 was drained from the blood outflow tube 22 at a rate of 50 ml/min, and the hematocrit value was measured over time. The results were as shown by the solid line in FIG.

As a comparative example, a similar experiment was conducted in which the blood storage container was not supported by the support of the above example but was suspended vertically. The results were as shown by the broken line in FIG.

From the results shown in Figure 7, the blood flowing out from the blood storage container supported by the support of the present invention is gradually diluted by the influence of physiological saline, and in particular, it is gradually diluted even within 15 seconds. It was found that the hematocrit value decreased. On the other hand, in the comparative example, especially within 15 seconds,
No decrease in hematocrit value was observed, indicating that blood with a high hematocrit value was flowing out at an early stage.

[Effects of the invention] The blood storage container support of the invention is a soft resin blood storage container for an extracorporeal circulation device that has a blood outflow port provided at one end and is used by temporarily storing blood inside. The support includes a support part for supporting the blood storage container, and the blood storage container is placed with the blood storage container tilted at a predetermined angle with respect to a horizontal plane so that the blood outflow port side faces downward. Compared to the case where a soft resin blood storage container is used in a vertically suspended state, blood with a high hematocrit value is stored in the lower part of the blood storage container, especially in the lower part of the blood storage container. It is possible to prevent blood from selectively pooling near the blood outlet of the blood storage container, and therefore blood of a certain quality can be supplied from the blood storage container to the blood processing device installed in the extracorporeal circulation device, resulting in stable blood processing. It can be performed. Furthermore, there is no need to provide the blood storage container with a shaking device that requires maintenance, and it is easy to handle.

[Brief explanation of drawings]

FIG. 1 is a diagram showing an embodiment of the support for the blood storage container of the present invention, FIG. 2 is a top view of the support of FIG. 1, and FIG. FIG. 4 is a diagram showing another embodiment of the support for a blood storage container of the present invention, and FIG. 5 is a diagram showing another embodiment of the support for the blood storage container of the present invention. FIG. 6 is a diagram showing an example of an extracorporeal circulation device; FIG. 6 is a circuit diagram used in an experiment of the support device of the present invention and a comparative example; FIG. 7 is a diagram showing the experimental results of the support device of the present invention and a comparative example. be. DESCRIPTION OF SYMBOLS 1...Blood storage container support, 2...Blood storage container, 3...Planar part, 4...Upper support part, 5
a, 5b... lower support part, 7... stand, 8...
... Fixed part, 21 ... Blood inflow tube, 22 ...
Blood drain tube.

Claims (1)

[Scope of Claim for Utility Model Registration] (1) A support for a soft resin blood storage container for use in an extracorporeal circulation device, which has a blood outflow port provided at one end and is used to temporarily store blood inside. hand,
The support includes a support portion that supports the blood storage container so that the blood outflow port side faces downward;
A support for a blood storage container, comprising an inclined surface for placing the blood storage container at a predetermined angle with respect to a horizontal surface. (2) The blood storage container has a blood outflow port provided at one end and a slit provided at the other end, and the support portion engages with the slit of the blood storage container to allow the blood to flow out. Utility model registration claim 1 which supports the other end side of the storage container
A support device for a blood storage container as described in 2. (3) The support device for a blood storage container according to claim 1, wherein the inclined surface is formed by a flat plate-shaped portion inclined at a predetermined angle with respect to a horizontal surface. (4) The support device has a flat plate-like portion and a fixing portion that fixes the flat plate-like portion in a state inclined at a predetermined angle with respect to a horizontal plane, as set forth in claim 3 of the utility model registration claim. blood storage container support. (5) The support device for a blood storage container according to claim 1 or 2, wherein the support device has a lower support portion that supports the blood outflow port of the blood storage container. (6) The support device for a blood storage container according to claim 1, wherein the support portion is provided on the inclined surface. (7) The support device for a blood storage container according to claim 1, which is a registered utility model, wherein the support device is formed of a table-like member having the sloped surface on the upper surface. (8) The blood storage container support according to claim 1, wherein the predetermined angle is 10 to 60 degrees. (9) The blood storage container support device according to claim 4, wherein the fixing portion includes an angle adjustment mechanism for fixing the flat plate portion at an arbitrary predetermined angle.