JPH0667404B2 - Single needle plasma separator - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a plasma separator used for collecting plasma from blood, and more particularly to a single-needle plasma separator.

[Prior Art] A conventional single-needle plasma separator is shown in FIG. In FIG. 9, 50 is a blood collecting needle, 51a and 51b are blood feeding means, 52 is a clamp, 5
3 is a plasma separator, 54 is a blood storage container, 55 is a plasma collection container, and 56 is a liquid feeding means.

As shown in the figure, this device has at least one or more special blood supply means 51a, 51b such as a roller pump for performing plasma separation operation. Further, the one shown in FIG. 9 has a complicated circuit configuration for improving the plasma separation efficiency, and the clamps 52 for switching each line are an indispensable constituent element, and the complicated operation is also required. In addition, in order to smoothly perform complicated operations, supervisory controllers having various sensors are required, and in many cases, these supervisory controllers automatically control based on information from various sensors. Has been done.

Also, for example, two blood storage containers 6 as shown in FIG.
A two-needle type plasma separation device in which 5,66 positions are alternately moved up and down to continuously separate plasma using gravity (Japanese Patent Laid-Open No. 59-20934).
No. 7) is proposed.

Also, for example, one blood storage container 75 as shown in FIG.
There is also proposed a single-needle plasma separation device (Japanese Patent Laid-Open No. 60-7852) in which plasma is intermittently separated by moving gravity up and down.

[Problems to be Solved by the Invention] However, in the conventional single-needle plasma separator (for example, the one shown in FIG. 9), a special blood pump such as a roller pump is used to send blood to the plasma separator. At least one means is required, therefore, it is necessary to manage and control the blood-sending means, and the plasma separation efficiency is improved. Therefore, the circuit configuration is complicated, and the complex circuit configuration can be operated smoothly. Requires a special monitoring and control device, and the entire device becomes large,
It had a problem that it became complicated.

Further, in the two-needle plasma separation apparatus in which two blood storage containers 66 and 65 are alternately moved up and down as shown in FIG. 10 and the plasma separation operation is continuously performed using gravity, the blood is collected by the donor. Needle 61
And the blood return needle 68 must be punctured, and
In this device, the blood collected from the vein of the donor must be perfused by the drop between the donor and the plasma separator 63, and the plasma separator 63 further collects the plasma collection container 60 and the concentrated red blood cell storage container 66. , 65 will be located at the bottom to collect plasma, the operation position will be considerably low, plasma collection operation will be difficult, and it will be difficult to secure the drop between the donor and the plasma separator 63. There is a problem.

In addition, even in the single-needle plasma separation apparatus in which one blood storage container 75 is moved up and down as shown in FIG. 11 and the plasma separation operation is intermittently performed by using gravity, blood collected from the donor's vein is not collected. Perfusion must be performed due to the drop between the blood donor and the plasma separator 73, and plasma is collected with the plasma collection container 79 and the concentrated red blood cell storage container 75 positioned below the plasma separator 73. In addition, the position where the operation is performed becomes considerably low, which makes it difficult to perform the plasma collection operation, and it is also difficult to secure a head between the blood donor and the plasma separator 73.

Therefore, an object of the present invention is to reduce the size of the entire apparatus without requiring a special blood feeding means for feeding blood to the plasma separator, with a simple circuit configuration, and without using a special monitor control device. The present invention provides a single-needle plasma separation apparatus that can be used for blood collection and plasma collection operations, and that can easily secure a head for perfusion of blood and can perform plasma collection safely.

[Means for Solving the Problems] In the single-needle plasma separation apparatus of the present invention, a certain amount of blood is collected in a blood storage container placed below a blood collection needle, and then the blood storage container is replaced with the blood collection needle. A single-needle plasma separator for performing blood return and plasma collection using a head located higher, wherein the single-needle plasma separator separates a blood collection needle and blood flowing from the blood collection needle. A first blood supply container for storing the blood, the blood collection needle and the blood storage container in communication with each other, and a first blood supply for sending blood flowing from the blood collection needle to the blood storage container without using a blood supply means. A blood vessel, a plasma separator, a second blood supply vessel that connects the blood storage container and a blood inlet of the plasma separator, a blood outlet of the plasma separator and the first blood vessel, A third blood feeding vessel for feeding the red blood cell concentrate separated by the plasma separator, and a plasma collection A collection container; a plasma transport pipe that communicates the plasma outlet of the plasma separator with the plasma collection container; a communication part between the third blood vessel and the first blood vessel; and the blood storage container. First circuit opening / closing means provided in the first blood supply vessel at a position between them, second circuit opening / closing means provided in the plasma transportation tube, and provided in the second blood supply vessel or the third blood supply vessel The third blood vessel opening / closing means is provided, and the first blood vessel, the second blood vessel, and the third blood vessel are formed of a flexible synthetic resin tube, and It is a single-needle plasma separation apparatus capable of arbitrarily changing the positional relationship of the plasma separator and the blood storage container with respect to the position.

And, it is preferable that an anticoagulant solution is contained in the blood storage container. Furthermore, the anticoagulant solution is preferably a physiological isotonic solution containing an anticoagulant. Further, it is preferable that the plasma transportation tube is provided with a liquid feeding means. Furthermore, it is preferable that the plasma transportation tube is capable of arbitrarily changing the positional relationship of the plasma collection container with respect to the position of the blood collecting needle. Further, it is preferable that the single-needle plasma separator has an anticoagulant container and an anticoagulant transport pipe that connects the anticoagulant container and the blood storage container. Further, it is preferable that the anticoagulant transport pipe is provided with circuit opening / closing means. It is preferable that circuit opening / closing means is provided in both the second blood supply vessel and the third blood supply vessel. Each of the circuit opening / closing means is a clamp that opens / closes by electromagnetic action, and the single-needle plasma separator has a switching means that outputs an opening / closing signal to each of the circuit opening / closing means. preferable.

Therefore, the single needle plasma separator of the present invention will be described with reference to the embodiment shown in FIG.

The single-needle plasma separation apparatus 1 of the present invention comprises a blood collection needle 10, a blood storage container 3, a first blood supply tube 2 that connects the blood collection needle 10 and the blood storage container 3, a plasma separator 4, and a blood storage container. 3 and plasma separator 4
Second blood vessel 7 that communicates with the blood inlet 23 of the blood vessel, a third blood vessel 8 that communicates with the blood outlet 24 of the plasma separator 4 and the first blood vessel 2, a plasma collection container 6, and plasma. The plasma outlet 26 of the separator 4 has a plasma transport tube 9 that connects the plasma collection container 6 to each other, and the plasma separator 4 and the blood storage container 3 are placed in a high-low positional relationship with respect to the position of the blood collection needle 10. It is configured so that it can be changed arbitrarily.

The feature of the single-needle plasma separator of the present invention is that the position of the plasma separator 4 and the blood storage container 3 can be arbitrarily changed with respect to the position of the blood collection needle 10. With this configuration, it is possible to separate and collect plasma without using a blood feeding means.

As the blood collection needle 10 used in the plasma separation apparatus 1 of the present invention, a known metal blood collection needle or a resin blood collection needle is used.

The blood collection needle 10 is attached to the tip of the first blood supply tube 2,
The other end communicates with the blood storage container 3. Further, two or more blood storage containers may be attached to the other end of the first blood supply vessel 2. The second blood supply vessel 7 has one end communicating with the blood storage container 3 and the other end communicating with the blood inlet 23 of the plasma separator 4. Third
One end of the blood supply vessel 8 is in communication with the blood outlet 24 of the plasma separator 4, and the other end is in communication with the first blood supply vessel 2 at the communication portion 25.
The plasma transport tube 9 has one end communicating with the plasma outlet 26 of the plasma separator 4 and the other end communicating with the plasma collection container 6.

The first blood supply vessel 2 is provided with a circuit opening / closing means 11 at a position between the blood storage container 3 and the communication portion 25 of the third blood supply vessel 8. Further, the second blood supply vessel 7 has a circuit opening / closing means 14
Is provided. In addition, this third
A circuit opening / closing means 12 for opening / closing only the blood supply vessel 8 (without affecting the first blood supply vessel 2) is provided.

As long as either of the circuit opening / closing means 12 and 14 is provided, both of them may not be provided. When only one is provided, it is preferable that the circuit opening / closing means 12 is provided. More preferably, both are provided. Further, the plasma transportation tube 9 is provided with a circuit opening / closing means 13.

Then, the first blood vessel 2, the second blood vessel 7, the third blood vessel 8,
As the plasma transport tube 9, for example, a transparent flexible synthetic resin tube such as vinyl chloride resin or silicone rubber can be preferably used, and the first blood vessel 2, the second blood vessel 7, and the third blood vessel 7 can be used. The blood vessel 8 has sufficient length and flexibility so that the height of the plasma separator 4 and the blood storage containers 3 and 5 attached thereto can be changed with respect to the blood collection needle 10. In particular, the first blood supply vessel preferably has a length of 1 m or more, although it varies depending on the pressure loss of the plasma separator 4. Further, the second blood supply vessel 7 has a drop between the blood inlet 23 of the plasma separator 4 and the blood storage container 3 when the blood storage container 3 and the plasma separator 4 are raised above the position of the blood collection needle 10. To form. The preferable length of the second blood supply vessel 7 is not constant because it depends on the pressure loss of the plasma separator and the like, but since the above-mentioned drop is preferably 50 cm or more, the length of the second blood supply vessel 7 is also 50 cm. The above is preferable. Further, the plasma transport tube 9 is also a blood collection needle of the plasma collection container 6.
It is preferable to have sufficient length and flexibility so that the height with respect to 10 can be changed. By doing so, the plasma collection container 6 at the time of plasma separation
Can be changed, the liquid feeding means for transporting the plasma to the plasma collection container 6 can be omitted, and further, by selecting the position of the plasma collection container 6, the TMP of the plasma separator 4 at the time of plasma separation. Can be changed.

The blood storage container 3 and the plasma collection container 6 are made of a soft synthetic resin (for example, vinyl chloride resin),
Hermetically-sealed blood storage container or open-type blood storage container, for example, a hard synthetic resin having a bacteria-impermeable hydrophobic filter (eg, polycarbonate, hard vinyl chloride resin)
A container or the like can be preferably used. Furthermore, the blood storage container 3
An anticoagulant solution such as an ACD solution, a CPD solution, sodium citrate, or heparin is stored in the inside of the, and preferably, the anticoagulant solution is a physiological isotonic solution. This is because the red blood cell concentrated liquid collected in this blood storage container 3 and having plasma separated by the plasma separator 4 is directly returned to the blood donor. Therefore, by storing the anticoagulant solution, which is a physiologically isotonic solution, inside the blood storage container 3 in advance, the anticoagulant injection line can be omitted, and the plasma separation apparatus can be made smaller. Can be converted. Further, in the plasma separation apparatus 1 of the embodiment shown in FIG. 1, the second blood supply vessel 7 that connects the blood storage container 3 and the plasma separation apparatus 4 to each other.
Does not communicate with the first blood sending vessel 2, blood does not flow into the inside of the second blood sending vessel 7 at the time of blood collection, and therefore, there is no need to remove the blood and the second blood sending vessel 7 It is preferable because blood does not coagulate inside the. Further, the first blood supply vessel 2 and the second blood supply vessel 7 near the blood storage container 3 are
It may be formed of a single blood supply vessel that can be used for both.

The plasma separator 4 includes a blood inlet 23, a blood outlet 24 for letting out a red blood cell concentrate, a blood separating function for separating blood into a plasma component and a blood cell component, and an outlet 26 for the separated plasma component. have. As the structure of the blood component separator,
Hollow fiber membrane type, flat membrane type and the like are used.

Then, forceps or the like may be used as the circuit opening / closing means 11, 12, 13, 14. Alternatively, a clamp that opens and closes by electromagnetic action may be used.

Further, as shown in FIG. 2, circuit opening / closing means 11, 12, 13, 14
On the other hand, a switching means 32 for outputting an opening / closing signal is provided, and the four circuit opening / closing means 11, 12, 13, 14 are electrically connected to the switching means 32 (of the blood storage container 3 and the plasma separator 4). The four circuit opening / closing means 11, 12, 13 are selected by selecting the mode (blood collection mode, blood return and plasma separation mode) changeover switch provided in the switching means 32 so as not to hinder the position change. , 14 may be switched to the open / closed state that matches the intended mode.

In the blood sampling mode, the circuit opening / closing means 11 is opened and the circuit opening / closing means 12, 13, 14 are closed as an output signal when the above-mentioned two-mode selector switch of the switching means 32 is selected. In the blood-returning and plasma separation modes, the circuit opening / closing means 11 is closed and the circuit opening / closing means 12 is used. , 13, 14 are opened.

When only one of the circuit opening / closing means 12 and 14 is provided, the circuit opening / closing means which is not provided in each of the above modes is omitted.

Further, the plasma transport tube 9 may be provided with a liquid feeding means 27 as shown in FIG. In this case, the plasma transport tube 9
The circuit opening / closing means may not be provided. Even if the plasma transfer tube 9 is provided with the liquid feeding means 27, it is necessary to change the positions of the plasma transfer tube 9 and the plasma collection container 6 up and down with respect to the blood collection needle 10 even during use, as will be described later. Even if the liquid feeding means is attached and fixed, it does not hinder the use of the plasma separation device.

A pump such as a roller pump or a peristaltic pump is preferably used as the liquid feeding means 27.

Next, an embodiment of the single needle plasma separator 1 of the present invention shown in FIG. 3 will be described.

The difference between this embodiment and the embodiment shown in FIG. 1 is that in the embodiment shown in FIG. 3, two blood storage containers 3 and 5 are provided.

In this embodiment, the first blood sending vessel 2 communicates with the third blood sending vessel 8 at the communicating portion 25, and is branched into two, one of which is the first blood sending vessel 2a. The first blood supply vessel 2b communicates with the blood storage container 3, and also communicates with the second blood storage container 5. Further, one end of the second blood supply vessel 7 communicates with the blood inlet 23 of the plasma separator 4 and is branched into two in the middle. The second blood supply vessel 7a communicates with the first blood storage container 3 and the second blood supply vessel 7b communicates with the second blood storage container 5. The circuit opening / closing means 12 is provided in the third blood supply vessel 8.
The first blood vessel 2a, 2b is provided with circuit opening / closing means 11a, 11b, and the second blood vessel 7a, 7b is provided with circuit opening / closing means 14a, 14b. The plasma transport tube 9 is also provided with circuit opening / closing means 13.

As the circuit opening / closing means 11a, 11b, 12, 13, 14a, 14b, forceps or the like may be used. Alternatively, a clamp that opens and closes by electromagnetic action may be used.

Further, as shown in FIG. 4, circuit opening / closing means 11a, 11b, 12, 1
Switching means 32 for outputting an opening / closing signal is provided for 3,14a, 14b, and the above-mentioned six circuit opening / closing means are electrically connected to this switching means 32 (of the blood storage containers 3, 5 and the plasma separator 4). The modes (first blood collection mode, first blood return and plasma separation mode, second blood collection mode, second blood return and plasma separation mode) provided in the switching means 32 so as not to hinder the change of position. ) The six circuit opening / closing means 11a, 11b, 12, 13, 14a, 14b may be switched to the open / closed state matching the intended mode by selecting the changeover switch.

In the first blood sampling mode, the circuit opening / closing means 11a is in the open state and the circuit opening / closing means 12, 13, 14a are output signals when the above-mentioned four mode changeover switches of the switching means 32 are selected. , 14b, 11b are occluded, and in the first blood return and plasma separation mode,
The circuit opening / closing means 11a, 11b, 14b are closed, and the circuit opening / closing means 12, 13, 14a are opened.

Furthermore, in the second blood sampling mode, the circuit opening / closing means 11b
Open circuit and circuit opening / closing means 12, 13, 14a, 14b, 11a
In the second blood return and plasma separation mode, the circuit opening / closing means 11a, 11b, 14a are closed and the circuit opening / closing means 12, 13, 14b are opened. .

When only one of the circuit opening / closing means 12 and [14a, 14b] is provided, the circuit opening / closing means which is not provided in each of the above modes is omitted.

Further, the plasma transport tube 9 may be provided with a liquid feeding means.
In this case, the plasma transport tube 9 may not be provided with circuit opening / closing means. Even if the plasma transport tube 9 is provided with a liquid feeding means, as will be described later, the positions of the plasma transport tube 9 and the plasma collection container 6 are not always in relation to the blood collection needle 1 during use.
There is no need to change it up and down, and even if the liquid feeding means is attached and fixed, it does not hinder the use of the plasma separation device.

As the first blood vessel, the second blood vessel, the third blood vessel, the plasma transport tube, the blood storage container, the plasma collection container, the plasma separator, and the liquid delivery means, those described above can be preferably used.

Next, an embodiment of the single needle plasma separator 1 of the present invention shown in FIG. 6 will be described.

The difference between this embodiment and the embodiment shown in FIG. 1 is that in FIG. 6, the anticoagulant transport pipe 16 communicating with the blood storage container 3 and the anticoagulant communicating with this transport pipe 16 are provided. Agent storage container 17
Also, the circuit opening / closing means 15 is provided. By providing the anticoagulant transport pipe 16 and the anticoagulant storage container 17 communicating with the transport pipe 16, it is possible to perform blood collection and plasma separation a plurality of times in one blood storage container.

More specifically, the first blood collection and plasma separation are performed with the circuit opening / closing means 15 provided in the anticoagulant transport tube 16 in the closed state. Then, after that, the circuit opening / closing means 11 provided in the first blood supply vessel 2 and the circuit opening / closing means 14 provided in the second blood supply vessel 7 are closed, and the circuit opening / closing means 15 is opened to store blood. The inside of the container 3 is filled with an anticoagulant solution. Then, the circuit opening / closing means 15 is closed again, the circuit opening / closing means 11 is opened, and blood is sampled twice. In this way, multiple blood collections and plasma separations can be performed continuously in a closed manner.

[Operation] The operation of the single-needle plasma separator of the present invention is
The case of individual pieces will be described with reference to FIGS. 1, 7, and 8.

FIG. 1 shows the single-needle plasma separator in the state of blood collection.

First, the plasma separation device 1 of the present invention is fixed at a position lower than the blood collecting needle 10, the circuit opening / closing means 11 is opened, and the circuit opening / closing means 12, 13, 14 are closed, and the blood collecting needle 10 is used by a donor. Puncture into a vein. The blood that has flowed out of the vein is stored in the blood storage container 3 via the first blood supply tube 2 and is mixed with the anticoagulant filled in the blood storage container 3. And
After a certain amount of blood is stored in the blood storage container 3, blood returning and plasma separation operations are performed.

The blood return and plasma separation operations are performed after moving the plasma separator 4 to a position higher than the blood collection needle 10 and further positioning the blood storage container 3 above it, as shown in FIG. Further, the plasma collection container 6 is in a state of being positioned below the plasma separator 4. Then, the circuit opening / closing means 12, 13, 14 is opened,
The circuit opening / closing means 11 is closed. The blood stored in the blood storage container 3 is returned to the blood donor's vein through the second blood supply vessel 7, the plasma separator 4, the third blood supply vessel 8, and the blood collection needle 10 due to the drop. At this time, the plasma separated by the plasma separator 4 flows into the plasma collection container 6 via the plasma transport tube 9.
As described above, in this plasma separation device 1, since the plasma separation operation can be performed at the time of blood return, the position for performing the plasma separation operation can be performed at a position higher than the position of the blood collection needle 10, Plasma collection work can be easily performed.
Further, it becomes easy to secure a head for perfusing blood into the plasma separator 4. Furthermore, in this plasma separation device 1, the first
Since the blood sending vessel 2 is not in communication with the second blood sending vessel 7, blood does not flow into the second blood sending vessel 7 during blood collection,
Therefore, there is no need to remove it. Further, in the plasma separation apparatus 1 of the present invention, since blood is first collected in the blood storage container 3 and then plasma separation can be performed when the blood is returned, the blood storage container 3 is previously stored. The anticoagulant injection line can be omitted by storing the anticoagulant solution which is a physiological isotonic solution.

FIG. 7 is a diagram showing a priming method performed before using the single-needle plasma separator 1 of the present invention. With the blood storage container 3 containing the anticoagulant inside and the blood collection needle 10 fixed at the same height, and the plasma separator 4 and the plasma collection container 6 fixed at positions lower than that, the circuit opening / closing means 11 The anticoagulant in the blood storage container 3 is filled by filling the first blood supply vessel 2, the second blood supply vessel 7, the third blood supply vessel 8, and the plasma separator 4 by opening the blood vessels 12, 12, and 14 by a drop. To be done. When the blood level of the anticoagulant inside the blood collection needle 10 and the blood storage container 3 reaches the same level, equilibrium is reached, the outflow of the anticoagulant from the blood storage container 3 is stopped, and the priming operation ends. Become.

EXAMPLES Examples of the present invention will be specifically described below with reference to the drawings.

An embodiment of the present invention will be described with reference to FIG. An in vitro experiment for plasma separation was performed using the single-needle plasma separator of the present invention, using bovine blood adjusted to a hematocrit value of 40%.

Of the circuit opening / closing means, 11 is opened and 12, 13, 14 are closed, and the drop is used to draw the blood collection needle 10 and the first blood supply tube 2
After that, 400 ml of blood was stored in the blood storage container 3.

Subsequently, the single-needle plasma separator was installed under the conditions shown in FIG. That is, the height difference from the opening of the blood storage container 3 to the plasma separator 4 is 1000 mm, the height difference from the plasma separator 4 to the blood collection needle 10 is 100 mm, from the plasma separator 4 to the opening of the plasma collection container 6. The height difference was set to 470 mm. Circuit opening / closing means 12,1
3, 14 were opened and 11 were closed. The blood stored in the blood storage container 3 passes through the second blood supply vessel 7, the plasma separator 4, the third blood supply vessel 8, and the first blood supply vessel 2 due to the drop, and then the blood collection needle 10
It was made to flow into the blood collection bag (not shown) connected to the.

A 17 G (gauge) needle was used as the blood collection needle 10.

Table 1 shows an example of changes in the collected plasma volume and pressure per minute [TMP, (inlet pressure + outlet pressure) / 2-plasma pressure] for one of the examples.

As a result of performing plasma separation on 3 cases, the average required time for separating 152 g of plasma was 12 minutes 18 seconds. The TMP during plasma separation was 86 mmHg on average.
Plasma protein recovery rate (plasma protein recovery rate (%) = (1-protein concentration in blood recovery bag / protein concentration in blood storage container) x 10
0) was 88.6%.

[Effect of the Invention] The single-needle plasma separation device of the present invention collects a certain amount of blood in a blood storage container placed below a blood collection needle, and then positions the blood storage container above the blood collection needle. A single-needle plasma separation apparatus for returning blood and collecting plasma by using a drop, wherein the single-needle plasma separation apparatus includes a blood collection needle and a blood reservoir for storing blood flowing in from the blood collection needle. Blood vessel, the blood collection needle and the blood storage container are communicated with each other, a first blood vessel for feeding blood flowing from the blood collection needle to the blood storage container without using a blood feeding means, and plasma separation Device, a second blood vessel for communicating the blood storage container and the blood inlet of the plasma separator, a blood outlet of the plasma separator and the first blood vessel for communication, and to the plasma separator. A third blood supply vessel for sending the separated red blood cell concentrate, a container for collecting plasma, and A plasma transport pipe that connects the plasma outlet of the plasma separator and the plasma collection container, the first portion of the position between the communication portion of the third blood vessel and the first blood vessel, and the blood storage container. No. 1 first circuit opening / closing means provided in the blood vessel, second circuit opening / closing means provided in the plasma transport tube, and third circuit provided in the second blood vessel or the third blood vessel. And a first synthetic blood vessel, a second synthetic blood vessel, and a third synthetic blood vessel, each of which is formed of a flexible synthetic resin tube. Since the positional relationship between the separator and the blood storage container can be arbitrarily changed, plasma can be easily collected by simply changing the positional relationship between the plasma separator and the blood storage container with respect to the blood collection needle during blood collection and blood return. It is possible to perform a separation operation,
It is not necessary to use a special liquid feeding means such as a pump for sending blood to the plasma separator, and without using a dedicated device equipped with a pump, a sensor, etc., which is required in the conventional plasma separation device, The separation operation can be performed, and the device can be downsized.

Further, in the device of the present invention, since the plasma separation operation can be performed at the time of blood return, the position for performing the plasma separation operation can be performed at a position higher than the position of the blood collection needle, and the plasma collection operation is easy. Can be done. Further, it becomes easy to secure a head for perfusing blood into the plasma separator.

Furthermore, the priming operation can be easily performed by changing the height relationship of each component.
Further, since the second blood sending vessel is configured not to communicate with the first blood sending vessel, blood does not flow into the second blood sending vessel at the time of blood collection, and therefore the removal operation thereof is not necessary. Further, in the plasma separation apparatus of the present invention, the blood is first collected in the blood storage container, and the plasma can be separated when the blood is returned. By containing the liquid, the anticoagulant injection line can be omitted.

On the contrary, by providing the blood storage container with the anticoagulant transport pipe and the anticoagulant storage container communicating with this transport pipe, blood collection and plasma separation can be performed multiple times with one blood storage container. It can be carried out.

[Brief description of drawings]

FIG. 1 is a diagram showing an embodiment of the single-needle plasma separator of the present invention, and FIGS. 2, 3, 4, 5, and 6 are single-needle plasma of the present invention. FIG. 7 is a diagram showing another embodiment of the separation device, FIG. 7 is an explanatory view of a priming method of the single-needle plasma separation device of the present invention, and FIG. 8 is an embodiment of the single-needle plasma separation device of the present invention. Explanatory drawing, FIG. 9, FIG. 10 and FIG. 11 are explanatory drawings of the conventional plasma separation device. 1 ... Single needle type plasma separation device, 2 ... First blood supply vessel 3 ... Blood storage container, 4 ... Plasma separator 5 ... Blood storage container, 6 ... Plasma collection container 7 ... Second delivery Blood vessel, 8 ... Third blood supply tube 9 ... Plasma transport tube, 10 ... Blood collection needle 11,11a, 11b, 12,14,14a, 14b, 15 ... Blood circuit opening / closing means 16 ... Anticoagulant transport tube , 17 …… anticoagulant container 21,25 …… communication part, 23 …… blood inlet 24 …… blood outlet, 26 …… plasma outlet 27 …… liquid transfer means, 32 …… switching means

 ─────────────────────────────────────────────────── ─── Continuation of the front page (56) Reference JP-A 59-141953 (JP, A) JP-A 60-7852 (JP, A) JP-A 60-156469 (JP, A) JP-A 62- 79063 (JP, A)

Claims (9)

[Claims] 1. A certain amount of blood is collected in a blood storage container placed below a blood collection needle, and the blood storage container is positioned above the blood collection needle to perform blood return and plasma collection using a drop. A single-needle plasma separator for performing, comprising a blood collecting needle, a blood storage container for storing blood flowing in from the blood collecting needle, the blood collecting needle, and the blood storing container. A first blood vessel for communicating blood with a container and for feeding blood flowing from the blood collecting needle to the blood storage container without using a blood supply means, a plasma separator, the blood storage container, and the plasma separation A second blood supply line communicating with the blood inlet of the blood vessel, a blood flow outlet of the plasma separator and the first blood supply line are communicated with each other, and the red blood cell concentrated liquid separated by the blood plasma separator is supplied with blood. For supplying blood, a container for collecting plasma, a plasma outlet of the plasma separator, and the plasma collection And plasma transport tube communicating the use container,
A first provided on the first blood sending vessel at a position between the communication portion between the third blood sending vessel and the first blood sending vessel and the blood storage container.
Circuit opening / closing means, a second circuit opening / closing means provided in the plasma transport tube, and a third circuit opening / closing means provided in the second blood vessel or the third blood vessel.
The first blood vessel, the second blood vessel, and the third blood vessel are formed of flexible synthetic resin tubes, and the plasma separator and the blood storage container are positioned relative to the position of the blood collection needle. A single-needle plasma separation device characterized by being able to arbitrarily change the high and low positional relationship. 2. The single-needle plasma separator according to claim 1, wherein an anticoagulant solution is stored in the blood storage container. 3. The single-needle plasma separation apparatus according to claim 2, wherein the anticoagulant solution is a physiological isotonic solution containing an anticoagulant. 4. The single-needle plasma separation apparatus according to claim 1, wherein the plasma transport pipe is provided with a liquid feeding means. 5. The plasma transportation tube according to claim 1, wherein the plasma collecting tube can arbitrarily change the positional relationship of the height of the blood plasma collecting container with respect to the position of the blood collecting needle. Single needle plasma separator. 6. The single-needle plasma separator has an anticoagulant storage container and an anticoagulant transport pipe communicating the anticoagulant storage container with the blood storage container. The single-needle plasma separator according to any one of claims. 7. The single-needle plasma separator according to claim 6, wherein the anticoagulant transport pipe is provided with circuit opening / closing means. 8. A circuit opening / closing means is provided in both the second blood vessel and the third blood vessel.
The single-needle plasma separator according to any one of 1. 9. The circuit opening / closing means is a clamp that opens / closes by electromagnetic action, and the single-needle plasma separator has a switching means for outputting an opening / closing signal to the circuit opening / closing means. The single-needle plasma separator according to any one of claims 1 to 8.