JPH0548134B2 - - Google Patents

Description

Detailed Description of the Invention (Industrial Application Field) The present invention relates to a plasma collection device for collecting plasma from a blood donor by membrane separation, which is a raw material for plasma preparations used for treatment and nutritional supplementation in the medical field; In particular, it relates to a device that automatically performs a cycle of blood removal and blood return.

(Prior art) Plasma collection has traditionally been carried out mainly using centrifugation devices, but recently a plasma collection method using a separation membrane has been studied (Medical Instruments Vol. 54, No.
11, 1984, P534-P539, etc.). Among them, the single-needle method, in which blood is repeatedly removed and returned with a single puncture needle, is said to be an excellent method that reduces the mental burden on the donor. In this method, it is difficult to automate the switching between blood removal and blood return cycles, so the operator has to manually switch between them while monitoring the amount of blood removed and blood returned.

(Problem to be solved by the invention) However, when attempting to collect plasma in a short time by manually switching cycles, the amount of blood collected at one time increases, the amount of blood circulating in the donor's body decreases, and If the amount of blood to be collected is reduced, it will take a long time to collect the plasma, and the blood in the blood flow path will become concentrated, making it difficult to collect the plasma. Therefore, it is absolutely necessary to switch between blood collection and blood return in an optimal cycle while paying attention to the decrease in blood circulation in the donor's body.

(Means for Solving the Problems) Therefore, an object of the present invention is to solve the above problems and provide a plasma collection device that can automatically switch between blood collection and blood return. .

In order to achieve the above object, the configuration of the present invention is shown in FIG.

The blood flow path 1 includes a membrane module 3 that separates the blood taken out from the blood collection needle H into blood cell components and plasma components.
It is equipped with a bag 6 for storing blood cell components separated by a membrane module, a blood pump 4 that can be rotated in forward and reverse directions, and a first detector 5 that detects the flow rate (amount of blood removed) in the blood flow path 1. The collected blood cell components are stored in a bag 6, and when blood is returned, the blood pump 4 is reversed to return the blood cell components in the bag 6 to the human body through a blood collection needle H.

The plasma flow path 2 includes a bag 7 for storing plasma components separated by the membrane module 3, and a plasma pump 8.
and a second detector 9 that detects the flow rate of the plasma flow path 2.
The plasma component separated by the membrane module 3 is stored in the bag 7.

The membrane module 3 has its blood cell component outlet located at the top. Although it is usually set in the vertical direction, it may be arranged at an angle so that the outlet for blood cell components is at the top and the outlet for plasma components is at the bottom. A branch pipe for discharging the priming liquid is provided between the membrane module 3 of the blood flow path 1 and the blood cell storage bag 6, and a valve 12 is attached to the branch pipe. Furthermore, a detector 14 is provided at the membrane module outlet of the blood flow path 1 to identify the type of fluid in the flow path.

On the other hand, as a control means, plasma collection starting means 15;
A plasma collection means 16 and a pump stop means 17 are provided. The plasma collection starting means 15 receives an external start signal, opens the valve 12, drives the blood pump 4 in normal rotation, supplies blood to the membrane module, and fills the priming liquid in the membrane module with the blood. It is discharged to the outside from the expulsion valve 12. When all of the priming liquid in the membrane module is expelled by blood and the blood flows out from the membrane module into the blood flow path, the valve 12 is closed in response to a detection signal from the detector 14, and the plasma pump 8 is driven to remove the plasma. Start collecting. Additionally, plasma collection means 16
Upon receiving the detection signal from the first detector 5,
When the amount of blood removed reaches a predetermined value, the blood pump 4 is driven in reverse to return blood, and when the detector 14 detects air, the blood pump 4 is driven forward in response to a detection signal from the detector 14. It is driven to collect blood. Next, the pump stop means 17 receives a detection signal from the second detector 9 and when the amount of plasma collected reaches a predetermined value, stops driving all pumps to complete the plasma collection.

(Function) According to the above configuration, the priming liquid in the membrane module is smoothly discharged to the outside from the valve 12 due to the blood flowing from the lower side to the upper side of the membrane module 3, so that the priming liquid flows into the plasma flow path 2 when blood is returned. It does not dilute the plasma by entering the In addition, there is a blood removal amount detector 5 and a blood flow path 1 at the outlet of the membrane module 3.
Switching between blood purging and blood return cycles can be performed automatically based on a signal from the detector 14 that identifies the type of fluid (blood or air) in the blood.

(Example) Next, an example of the present invention will be described with reference to the drawings. First, before explaining the plasma collection operation, the plasma collection device will be explained. Note that FIG. 2 shows an example in which ACD liquid is used as an anticoagulant.

FIG. 2 is a flow diagram during plasma collection (blood removal), where 1 is a blood flow path and 2 is a plasma flow path. The blood taken out from the blood collection needle H enters the first chamber 21 that detects the blood withdrawal pressure, then is pressurized by the blood pump 4, enters the second chamber 23 that detects the inlet pressure of the membrane module 3, and moves upward and downward. The blood is introduced from below into the membrane module 3 set in the same direction, and is separated into blood cell components and plasma components. The membrane module 3 accommodates a membrane for separating plasma and blood cells, such as a plate-shaped, tube-shaped, or hollow fiber-shaped separation membrane made of polyvinyl alcohol, polysulfone, polyethylene, or the like. Usually, a hollow fiber membrane module is used in which a large number of hollow fiber separation membranes are housed in a housing.

The blood cell components separated by the membrane module 3 are supplied to a blood cell storage bag 6 and stored therein.

Further, the blood inlet of the blood circuit 1 is connected via an ACD pump 19 to a flow path 26 for supplying an anticoagulant, such as ACD liquid, to the blood flow path 1 to prevent coagulation of blood during treatment. The ACD liquid supply channel 26 is connected to the ACD liquid container 24. When blood is collected, the ACD liquid is supplied in a fixed amount to the blood flow path 1,
The supply amount is detected by a detector 20.

Further, a sensor 22 for detecting blood withdrawal pressure is connected to the first chamber 21, and all pumps are stopped when this pressure exceeds a predetermined value. An inlet pressure sensor 24 to the membrane module is connected to the second chamber 23 . Furthermore, a sensor 25 for detecting the plasma outlet pressure is connected to the air inlet of the membrane module, and the above two sensors 2
4 and 25, the transmembrane pressure difference (TMP) is detected. The amount of plasma extracted by the plasma pump 8 is controlled so that this transmembrane pressure difference becomes a predetermined value.

The plasma components separated by the membrane module 3 are stored in a plasma storage bag 7 by a plasma pump 8.

When blood components are returned, the blood pump 4 is reversed and the ACD pump 19 is stopped, and the blood cell components in the blood cell storage bag 6 are returned to the human body through the blood collection needle H.

A detector 14 is provided at the outlet of the membrane module 3 of the blood flow path 1 to identify the fluid in the blood flow path. This detector 14 detects blood or air, and irradiates light or sound from one side of the blood flow path.
A type that measures the transmittance is used. Usually phototubes are preferably used.

Further, the blood pump 4 includes a first detector 5 that detects the flow rate (blood removal amount) of the blood flow path 1 based on the rotation speed of the blood pump, and the plasma pump 8 includes a first detector 5 that detects the flow rate (blood removal amount) of the blood flow path 1 based on the rotation speed of the blood pump. A second detector 9 that detects the flow rate (volume of collected plasma) of the plasma flow path 2 based on the flow rate of the plasma flow path 2 is connected to each of the second detectors 9 .

40 is a control device consisting of a microcomputer, and during blood processing, this control device 40 controls the flow rate detection signals from the detectors 5 and 9 and the detector 14.
and the fluid identification signal from each pressure sensor 22, 24,
While checking the pressure detection signal from 25, the rotation speed of the plasma pump 8 is controlled so that each flow rate in the blood flow path 1 and the plasma flow path 2 and the membrane pressure (TMP) of the membrane module 3 are at appropriate values. Then, the blood is processed by repeating blood removal and blood supply. Also, if the blood withdrawal pressure becomes abnormal, all pumps are stopped.

Next, the operation of the plasma collection device having the above configuration will be explained.

In FIG. 3, the blood collection needle H is connected to a blood donor. The control device 40 also includes a blood collection start means 1 for driving and stopping each of the blood pump 4 and plasma pump 8, and for opening and closing each valve 11, 12.
5. A plasma collection means 17 is built-in.

On the other hand, membrane module 3 that has been primed
Since the inside of the hollow fiber and the blood flow path 1 are filled with priming liquid, a branch pipe is provided at the membrane module outlet of the blood flow path 1 to discharge this priming liquid, and a valve 12 is attached to this branch pipe. It will be worn. This valve is closed at the end of priming. This state is shown in step S-1 in FIG.
Shown as

Plasma collection begins at step S-1 in Figure 4.
The process will be explained based on steps S-2 to S-8 in FIGS. 8 to 8 and the flowchart in FIG.

In FIG. 9, abbreviations are used for each part. As shown in FIGS. 4 to 8, the abbreviations are PV for valve 12, BP for blood pump 4, PP for plasma pump 8, and ACDP for ACD pump 19, respectively.

In step S-2 of FIG. 5, all pumps 5, 8, 19 are stopped, and valves 11, 12 are stopped.
With the ACD pump 19 and blood pump 4 closed, the control device 40 is actuated in response to a start signal from the outside, opens the valve 12, and drives the ACD pump 19 and blood pump 4, and blood is taken out from the donor. This blood is supplied to the membrane module 3 while being mixed with ACD fluid. At this time, blood is supplied into the hollow fibers from below the membrane module 3, so the priming liquid in the hollow fibers is driven out by the blood and discharged from the membrane module to the outside through the valve 12 through the branch pipe.

After the priming liquid in the hollow fiber is expelled, when the blood is led out from the membrane module 3 to the blood flow path 1, a blood identification signal is received from the detector 14, and the expulsion of the priming liquid in the membrane module is assumed to have been completed. At step S-3 shown in FIG. 6, the plasma pump 8 is driven by the control device 40 to enter the blood removal process. As a result, blood cell components are stored in bag 6, and plasma components that have passed through the membrane are stored in bag 7.

Further, when a detection signal is received from the blood volume (blood removal amount) detector 5 and the blood removal amount reaches a predetermined value, the blood removal process is deemed to have ended, and step S shown in FIG.
-4, the control device 40 stops driving the ACD pump 19, drives the blood pump 4 in reverse, and enters the blood return process. In this step, the blood cell components stored in the bag 6 are returned to the blood donor. When the detector 14 receives the air identification signal in the blood flow path, it is assumed that the blood cell components in the bag have been returned to the donor, and the controller 40 starts the ACD pump 19 in step 5 shown in FIG. drive,
The blood pump 4 is driven in normal rotation and the process returns to the above-mentioned blood removal process. In the blood return process, it is necessary to introduce air into the blood flow path 1, so for example, an air inlet with a sterilization filter is attached to the top of the bag 6,
Alternatively, a branch pipe may be further provided in the branch pipe provided in the blood circuit 1, and a valve to which a sterilization filter is attached may be provided to this branch pipe, and this valve may be opened during the blood return process. A predetermined amount of plasma components is collected by repeating the cycle of the blood removal step and blood return step. Next, when the flow rate of the plasma flow path 2 (the amount of plasma collected) reaches a predetermined value in response to the detection signal from the detector 9, it is assumed that plasma collection has been completed, and all pumps 4, 8, and 19 are driven. Stop to complete plasma collection.

When the plasma collection is completed, a collection process begins in which the blood remaining in the blood flow path 1 and membrane module 3 is returned to the blood donor. In the collection process, the blood pump 4 is driven in reverse as in the blood return process shown in FIG. During this time, plasma pump 8 and ACD pump 19 remain stopped. When the blood pump 4 is driven in reverse and the first chamber 21 of the blood flow path 1 is emptied, a detector 1 installed at the outlet of this chamber identifies the air.
The blood pump 4 is stopped in response to the detection signal from the blood pump 3. Next, the valve 11 attached to the opening provided in the upper side wall of the membrane module 3 is opened, and at the same time, the plasma pump 8 is driven to send the remaining plasma in the membrane module into the bag 7, and then the plasma pump 8 is stopped. to complete the collection process.

(Effects of the Invention) As described above, the present invention can automatically carry out the cycle of blood removal and blood feeding, so that the plasma collection operation can be carried out safely and efficiently.

[Brief explanation of the drawing]

Fig. 1 is a flow diagram showing the configuration of the present invention, Fig. 2 is a flow chart showing the state during blood collection, Fig. 3 is a flow chart showing an embodiment of the present invention, and Figs. FIG. 9 is a simplified flowchart showing the operation of the apparatus of the invention. FIG. 9 is a flowchart showing a method of controlling the apparatus of the invention. DESCRIPTION OF SYMBOLS 1... Blood flow path, 2... Plasma flow path, 3... Membrane module, 4... Blood pump, 5... First detector, 6... Blood cell storage bag, 7... Plasma storage bag, 8 ...Plasma pump, 9...Second detector, 1
2... Valve, 14... Detector, 15... Plasma collection start means, 16... Plasma collection means, 17... Pump stop means, H... Blood collection needle.

Claims (1)

[Claims] 1 Blood is introduced into the membrane module 3 from the blood collection needle H, separated into blood cell components and plasma components, the separated blood cell components are stored in the bag 6, and when the blood is returned, the blood cell components in the bag are transferred to the collection needle H. A blood flow path 1 that returns the blood to the human body, a plasma flow path 2 that introduces the plasma components separated by the membrane module 3 into the bag 7, and the blood flow path 1.
A blood pump 4 that can be reversibly provided in a first detector 5 for detecting the flow rate of the blood flow path 1, a second detector 9 for detecting the flow rate of the plasma flow path 2, and a membrane module outlet of the blood flow path 1. A detector 14 for identifying the type of fluid, and upon receiving a start signal from the outside, opens the valve 12 and drives the blood pump 4 in normal rotation to supply blood to the membrane module, and the detector 14 In response to the blood detection signal from the first detector 5, the valve 12 is closed, and the blood removal amount reaches a predetermined value in response to the plasma collection start means 15 that drives the plasma pump 8 and the detection signal from the first detector 5. When this happens, the blood pump is driven in the reverse direction to return the blood cell components of the bag 6 to the human body, and upon receiving the air detection signal from the detector 14, the blood pump is driven in the forward direction to collect blood; A plasma collection device comprising a pump stop means 17 that stops driving all pumps when the amount of plasma collection reaches a predetermined value in response to a detection signal from a second detector 9.