JPH0415699B2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention is a method for separating plasma using a membrane plasma separator when blood is collected from donated blood, and returning the blood with a high concentration of blood cells to the donor. Regarding the donor pheresis device, more specifically, a dual roller pump equipped with two tubes having different inner diameters is arranged in a line for supplying blood to a membrane plasma separator and a line for discharging plasma. The present invention relates to a donor pheresis device.

[Conventional technology]

One method for donor pheresis is centrifugation, but this method requires expensive equipment and is therefore uneconomical. Further, although the sedimentation method uses inexpensive equipment, it is not practical because it requires a long time for plasma separation.

The method using a membrane plasma separator is the most practical and widely used method because the separated plasma does not contain formed components such as platelets.

A donor pheresis device that uses such a membrane plasma separator to separate blood into plasma components and blood cell components, and returns blood rich in blood cell components to the donor, is described in Japanese Patent Application Laid-Open No. 58-206758. Roller pumps equipped with plastic tubes such as these are widely used for blood transfer.

However, if a roller pump is used for each blood supply line, the mechanism becomes complicated and the number of pumps increases. Therefore, two blood supply lines are treated with one roller pump, that is, a roller pump with two tubes is used. A donor pheresis device using a certain dual roller pump is disclosed in JP-A-55-38171 and JP-A-57-75657.

[Problem that the invention seeks to solve]

However, these donor pheresis devices using two roller pumps use two roller pumps equipped with supply lines with the same tube inner diameter, so the amount of plasma discharged and the amount of fresh plasma supplied are different. This is convenient if the blood, which is mainly made up of blood cells, is returned to the veins, and physiological saline, glucose,
When adding different amounts of replacement fluid such as plasma, the amount of discharged plasma and the amount of replacement fluid are often not the same. Normally, in such cases, a pump is attached to each line and the discharge amount is adjusted, but this has the disadvantage that the number of pumps increases and the mechanism becomes complicated.

The present invention has been made to solve these problems, and an object of the present invention is to provide a membrane separation type donor pheresis device with a simplified mechanism and excellent economic efficiency.

[Means for solving problems]

The present inventors conducted extensive research to solve the above problems, and as a result, they arrived at the present invention. That is, the present invention provides a blood collection line that collects blood from a vein; an anticoagulant line that supplies an anticoagulant; and an inner diameter of each tube constituting the blood collection line and the anticoagulant line that is equal to the amount of blood to be collected and the anticoagulant. A first two-barrel roller pump comprising tubes of different inner diameters so that the amount of drug is mixed in a prescribed ratio, and a tube of a blood collection line and a tube of an anticoagulant line are attached from different tube inner diameters. , a line that supplies mixed anticoagulant blood to a membrane plasma separator; a membrane plasma separator that separates plasma from the supplied anticoagulant blood; plasma separated by the membrane plasma separator a plasma line that supplies plasma to the plasma storage tank; a blood return line that returns the remaining blood from which plasma has been separated by the membrane plasma separator to the vein; a replacement fluid line that supplies replacement fluid to be added to the blood that is returned to the vein; Each of the tubes constituting the plasma line and the replacement fluid line has a different inner diameter so that a prescribed ratio of replacement fluid is added to the amount of plasma in the plasma line, and the tubes of the plasma line and the replacement fluid line each have different inner diameters. Rotation of a second dual roller pump equipped with a tube increases the pressure in the anticoagulated blood supply line feeding into the membrane plasma separator and the pressure in the plasma line exiting the membrane plasma separator. This is a donor pheresis device comprising: a control section that is controlled so that hemolysis does not occur according to the transmembrane pressure of the membrane plasma separator indicated by the difference.

[Effect]

As described above, the donor pheresis device of the present invention uses two dual roller pumps to separate and collect donor blood as plasma using a membrane plasma separator.
A replacement fluid such as physiological saline is added to the remaining blood, which mainly consists of blood cells, and the blood is returned to the vein.

Since the dual roller pump is constructed by connecting two tubes with different inner diameters, the amounts of liquid passing through the tubes can be adjusted to be in a specified ratio.

The first two-barrel roller pump collects blood from a blood donor, mixes an anticoagulant with the collected blood in a specified ratio, and supplies the anticoagulant-added blood to a membrane plasma separator. It functions to return the remaining blood of the separated plasma to the blood donor.

On the other hand, the second double roller pump controls the rotation of the pump so that plasma separated by the membrane plasma separator does not contain hemolysis, supplies plasma to the container, stores it, and passes the plasma through the blood return line. The function is to control the amount of replacement fluid added to the concentrated blood from the membrane plasma separator to a specified ratio.

〔Example〕

An embodiment of the present invention will be described based on FIG. In the figure, 1 is the blood collection line, 2 is the anticoagulant line, 3 is the plasma line, 4 is the fluid replacement line, and 5 is the first line.
, 6 is a second double roller pump, 7 is a membrane plasma separator, 8 is a blood return line, 9 and 10 are air traps, 11 is an anticoagulant container, 12 is a plasma storage tank, 13 is a replacement fluid container, 14
15 is a heater, 15 is a control unit, and 16 is a small roller pump of a double roller pump. The transmembrane pressure of the membrane plasma separator 7 is controlled by the rotation speed of the second double roller pump.

The main operation of the embodiment of the present invention having such a configuration is that blood collected from a blood donor's vein (not shown) is mixed with an anticoagulant from an anticoagulant container 11 in a first two-channel system. The mixture is mixed to a specified ratio by a roller pump 5, defoamed by an air trap 9, and then supplied to a membrane plasma separator. The separation membrane of the membrane plasma separator 7 permeates the supplied blood and supplies it as plasma to the plasma storage tank 12 for storage. On the other hand, the blood mainly composed of blood cells that has passed through the membrane plasma separator 7 is mixed with a replacement fluid such as physiological saline at a specified ratio by a second double-roller pump 6, and a heater 14
The blood is warmed to near body temperature by the blood donor and then returned to the donor's veins.

As shown in FIG. 1, the first double roller pump 5 connects the tube of the blood collection line 1 and the tube of the anticoagulant line 2 with two small roller pumps 16, and the amount of blood flowing through the lines. and anticoagulant in a specified ratio. The flow rate ratio of blood and anticoagulant can be adjusted by varying the ratio of the inner diameters of each tube. In this case, empirically, the amount of blood flowing through the blood collection line 1 is 20 to 60 ml/min., and the ratio of blood amount to anticoagulant amount is preferably about 9:1. By adjusting the flow path cross-sectional area ratio of each tube to a desired ratio, a desired amount of anticoagulant can be added to the collected blood, and the mixed blood is defoamed with the air trap 9. The membrane plasma separator 7 is supplied.

The membrane plasma separator 7 is a device for separating plasma from blood, and a hollow fiber type device such as cellulose triacetate is preferred because it is small and can separate plasma from blood with high efficiency.

The anticoagulant-containing blood supplied to the membrane plasma separator 7 passes through the separation membrane and is separated into plasma, which is then supplied to the plasma line 3. The pressure of the separation membrane of the membrane plasma separator 7, that is, the transmembrane pressure, is determined by the pressure P ₁ of the blood volume supplied to the membrane plasma separator 7 (measured by the air trap 9) and the plasma line on the outflow side of the membrane plasma separator 7. (ignoring the pressure in the _blood return line 8 passing through the membrane plasma separator 7). The pressures P ₁ and P ₂ are input to the control unit 15, and the rotation speed of the second double roller pump 6 is determined to prevent excessive transmembrane pressure when the blood flowing into the membrane plasma separator 7 permeates through the separation membrane. It is controlled by a signal from the control unit 15 so that hemolysis does not occur due to the hemolysis.

The second double roller pump 6 functions to supply the plasma separated by the membrane plasma separator 7 to the plasma storage tank 12, and also to add physiological saline to the blood mainly composed of blood cells that has passed through the membrane plasma separator 7. It works by mixing a replacement fluid such as water and supplying the amount of replacement fluid when blood is returned to the blood donor's vein at a specified ratio to the amount of plasma collected. The second double roller pump 6 also has two tubes, one for the plasma line 3 and the other for the fluid replacement line 4, in the same way as the first two roller pump 5. By varying the ratio, the flow rate ratio can be adjusted to a desired value. In this case, empirically, it is preferable that the flow rate ratio of plasma to replacement fluid is about 4:1.

The replacement fluid whose supply amount has been adjusted in this way is mixed with the blood that has passed through the membrane plasma separator 7, heated to around body temperature by the heater 14, and then heated to the air trap 10.
The bubbles are removed and the blood is returned to the donor's vein.

[Effects] The donor pheresis device of the present invention is equipped with a dual roller pump in which two tubes with different inner diameters are connected to a blood collection line from a blood donor and a plasma line that has passed through a membrane plasma separator. can be,
The number of pumps can be reduced compared to the case where a dual roller pump with two tubes of the same inner diameter is provided.

Furthermore, since the donor pheresis device of the present invention uses a dual roller pump to set the flow rate to a desired ratio, the control mechanism is also simplified compared to conventional devices.

[Brief explanation of drawings]

FIG. 1 is an explanatory diagram showing one embodiment of the present invention. In the figure, 1 is the blood collection line, 2 is the anticoagulant line,
3 is the plasma line, 4 is the fluid replacement line, and 5 is the first 2
6 is a second double roller pump, 7 is a membrane plasma separator, 8 is a blood return line, 1
5 indicates a control section.

Claims (1)

[Scope of Claims] 1 Blood collection line for collecting blood from a vein; Anticoagulant line for supplying an anticoagulant; The inner diameter of each tube constituting the blood collection line and the anticoagulant line is determined by the amount of blood to be collected and the anticoagulant line. A first double-barrel roller pump comprising a blood collection line tube and an anticoagulant line tube each having a different tube inner diameter so that the amount of coagulant is mixed in a prescribed ratio, and having a different tube inner diameter. a line that supplies the mixed anticoagulant blood to a membrane plasma separator; a membrane plasma separator that separates plasma from the supplied anticoagulant blood; A plasma line that supplies the collected plasma to the plasma storage tank; A blood return line that returns the remaining blood from which plasma has been separated by the membrane plasma separator to the vein; A blood return line that supplies replacement fluid to be added to the blood that is returned to the vein. Replacement fluid line; The plasma line and each tube constituting the replacement fluid line have different inner diameters so that a prescribed ratio of replacement fluid is added to the amount of plasma in the plasma line; Rotation of a second dual roller pump fitted with a fluid replacement line tube increases the pressure in the anticoagulated blood supply line to the membrane plasma separator and the plasma line exiting the membrane plasma separator. A control unit that is controlled so that hemolysis does not occur based on the transmembrane pressure of a membrane plasma separator indicated by the difference between the pressure and the transmembrane pressure. 2. Claim 1, characterized in that each of the two lines attached to the first and second two-barrel roller pumps is composed of elastic tubes with the same wall thickness and inner diameters in a prescribed ratio. donor pheresis device.