JPH025965A - Blood purifying device - Google Patents

Abstract

PURPOSE:To shorten the automatic priming time and perfectly prevent the generation of the mixing of gas foams and permit the safe work by installing a discharge line in branching into a separating line for a plasma separator and a removing device and permitting the simultaneous priming for the blood plasma separator and the removing device. CONSTITUTION:A level detector 24 is installed in a chamber in a separating line, and when a prescribed level is achieved, an air valve 22 is closed, and a valve 10 is opened. The priming liquid is discharged through a discharge line 25. Nearly at the same time, a valve 18 is closed, and a valve 8 is opened. The priming liquid is branched from the outlet of a return pipe 9, and discharged from the discharge line 25 through two flow passages. One portion of the priming liquid is discharged from the discharge line, washing a removing device 2. The other portion is sent by a separating pump 23 and washes a heating device 13, chamber 14 in a vein side circuit 28, and the hollow thread film of the blood plasma separator 1 and is discharged from the discharge line, passing through the chamber in a separating line 19.

Description

Detailed Description of the Invention (Field of Industrial Application) The present invention relates to a blood purification device having a plasma separator that separates blood cells and plasma from blood and a remover that removes unnecessary substances from the separated plasma. This invention relates to a device that can simultaneously brim a plasma separator and a remover.

(Prior technology) As a treatment for renal failure, liver failure, autoimmune diseases, etc., a patient's blood is separated into plasma and blood cells using a plasma separator 1111, and the separated plasma is removed using a remover to remove unnecessary substances from the plasma. A blood purification method is employed in which the removed and purified plasma is returned to the body together with blood cells. As this type of blood purification device, a device that can be automatically primed with a circuit, a plasma separator, and a remover built into the device is known (for example, Japanese Patent Laid-Open No. 120854/1983).

The above-mentioned known device is of the type that calculates the amount of priming liquid based on the rotation speed of the pump, and the command-control bag holder and the priming liquid amount calculation device are linked, and a partial circuit is formed in a part of the processing circuit by the control device. Next, briming of the partial circuit is performed, and the device sequentially repeats the combination of forming the partial circuit and briming to complete automatic briming of the entire processing device.

Priming of the blood circuit, plasma separator, etc. is performed using physiological saline. This physiological saline solution is usually contained in a small container and its volume is not constant, so it may sometimes run out during briming, or it may not be possible to accurately determine the amount of briming based only on the number of revolutions of the pump. When priming is insufficient, air enters the blood circuit, etc.
Its removal is a great example. In order to eliminate this problem, an air bubble detector is installed in the middle of the blood circuit. When a calculated predetermined amount is reached, the saline pump is stopped to avoid air intrusion as much as possible.

(Problems to be Solved by the Invention) Although the known device can be automatically primed and the brimming operation is easy, it still requires a considerably long briming time. The present invention provides an apparatus that further shortens the automatic briming time and at the same time completely prevents the occurrence of air bubbles, allowing safe operation.

(Means for Solving the Problems) The blood purification device of the present invention is characterized by introducing blood from the arterial circuit into a plasma separator, separating it into blood cell components and plasma components, and separating the blood cell components into blood cell components and plasma components. A blood circuit returns the blood to the human body from the venous circuit, and the plasma components separated by the plasma separator are introduced into a remover for removing unnecessary substances from the plasma through a separation line and a plasma chamber for purification. It is equipped with a plasma circuit that leads the purified plasma to the blood circuit downstream of the plasma separating S device through the plasma return line, and the blood circuit, the plasma circuit, the plasma separator, and the remover are supplied with physiological saline, etc. In a blood purification device that automatically sends the washing and filling liquid from the branch point of the plasma return line described above, a discharge line is provided with a branch in the separation line between the plasma separator and the remover, and the plasma fraction iwl is The key point is that the container and remover can be brimmed at the same time.

In the blood purification device of the present invention, by having such features, there is a briming passage that reaches from the outside of the hollow fiber of the plasma separator through a part of the separation line to the discharge line, and a part of the separation line from the remover. The briming passageway reaching the discharge line via the brimming passage can be formed and operated at the same time, thereby shortening the briming time. Next, the present invention will be explained by examples.

(Example) The figure shows one example of the blood purification device of the present invention. Next, we will explain the priming, clinical, and collection operations when using this device.

Priming Blood circuit and plasma molecules! and set it on the device.

Remover 2 is not connected yet. The briming liquid bottle 3 is set in the replenisher meter 4 and connected to the replenisher line 5. A heparin disposable syringe is set in the syringe pump and connected to the heparin line 6. Open the clamp 7 by hand.

Fill the plasma circuit (part of the plasma return line) connected to the lower side of the remover with Briminda fluid. Once Briminder's solution is filled, use forceps to close the plasma circuit near the eliminator connection. Connect the eliminator and plasma circuit. At this time, since the eliminator is filled with physiological saline, it must be connected to the plasma circuit to prevent overflow. Connection between remover and plasma circuit? &, press the rPHJ button. This causes valve 8 to open. After opening valve 8, set the plasma circuit. Next, remove the forceps near the connection port of the plasma circuit.

Press the "Start" button. The plasma return pump tube is set by the automatic effusion mechanism of the plasma return pump 9. Next, press the "Wash" button. The plasma return pump 9 rotates clockwise and the valve 10.8 opens. The Briminder liquid is discharged from the discharge line displacing the fill liquid of the eliminator. When a predetermined amount of the priming liquid is discharged, the valve 8 is closed 11-. Next, the valve 11 is opened, and the priming solution passes through the replenisher line, the plasma return line 12, the warmer 13, and the chamber 14 of the venous circuit, and is discharged from the outlet of the venous circuit. Air bubble detector 17 installed in the venous circuit
After a few seconds after sensing the passage of the priming liquid, the valve 11
is closed and valve 18 is opened. After the priming liquid fills the chamber 14 of the venous circuit, it is introduced into the plasma separator 1 and filtered from the inside to the outside of the hollow fiber membrane. The priming liquid is filled into the plasma separator and simultaneously flows out of the -F section outflow [1] of the plasma separator and flows into the separation line 19. When the priming liquid reaches the briming detector 20 installed in the '1tll line, the plasma return pump 9 is stopped, the valve 18 is closed, and the valve 11 is opened. At the same time, the air valve 21 or ;) 1 is activated, and the priming liquid outside the hollow fiber membrane filled in the plasma separator passes through the hollow fiber membrane hole and enters the inside of the hollow fiber membrane into the chamber of the venous circuit. 14 and is discharged from the outlet of the venous circuit. When all the priming liquid on the outside of the hollow fiber membrane of the plasma separator υ1 has been discharged, air cannot pass through the pores of hollow fiber 1, so the priming liquid is filled inside the hollow fiber membrane of the plasma separator. In this state, the discharge of the priming liquid from the outlet of the venous circuit ends. During this time, open the air valve 22 and set the pump tube of the separation pump 23 with the automatic occlusion. When the priming stomach evacuation 11i is completed, the valve 11 and air valve 21 are closed 1F, the valve 18 is opened, and the plasma return pump is rotated again. After a few seconds, the separation pump 23 starts and rotates. The flow rate of the separation pump is adjusted to be lower than the flow rate i1 of the plasma return pump (9>23). The priming liquid is applied again from the inside to the outside of the hollow fiber membrane of the evaporator.
It flows out from the lower outlet of the plasma separator, passes through the separation line 19, and is stored in the chamber 16 of the separation line.

A level detector 24 is provided in the chamber of the separation line, and when a predetermined level is reached, the air valve 22 is closed and the air valve 0 is opened. The priming liquid is discharged through discharge line 25. At about the same time, valve 18 closes and valve 8 opens. Priming liquid is plasma return pump 9
The discharge line 2 is branched from the outlet L and has two flow paths.
It is discharged from 5. - one side is discharged from the discharge line while cleaning the remover 2; On the other side, a warmer 13 is provided by a separation pump 23, a chamber 14 of a venous circuit 28,
The hollow fiber membrane of the plasma separation lining is washed, passes through the chamber of the separation line 19, and is discharged from the discharge line. The amount of cleaning of the remover and plasma separator at this time can be determined by calculating the cumulative flow rate of the replenisher meter 4, the plasma return pump 9, and the separation pump 23.

After the remover and plasma separator have been cleaned by a predetermined amount, turn on the valve l01.
8 is closed and the separation pump 23 is stopped.

Next, the valve 18 is opened, and the priming liquid cleans the inside of the hollow fiber membrane of the plasma separator, passes through the chamber 15 of the arterial circuit 27, and is discharged from the output LI of the arterial circuit. At this time, vibrate the swinger 29 several times to
Remove the air bubbles inside. At the same time, quickly move the syringe pump to replace the air in heparin line 6 with heparin'4
-ru. When the inside of the hollow fiber membrane of the plasma separator reaches a predetermined amount of cleaning, the valve 18 is closed, and the valve 11 is opened to discharge the blood from the outlet of the venous circuit. Once a predetermined amount has been discharged, the valve 11 is closed and the return serum pump is stopped, allowing the operator to finish the briming process. The total amount of priming solution used during briming is monitored by a replenisher meter 4, and if the remaining amount of priming solution becomes small during the priming process, the plasma return pump and separation pump are stopped.
1, valve 18.10.8.11, air valve 21.
Close 22 and notify the operator. Replace the empty priming liquid bottle with a new bottle and press the "Wash" button again. The plasma return pump rotates to open the wash IIt. As the priming progresses, i1T is opened from the state of +if immediately after the bottle is replaced, and the valve, air valve, and separation pump are respectively driven.

Manually set each condition setting value necessary for clinical practice and set monitor-related alarm values. Connect the patient's blood removal needle to the arterial circuit and the blood return needle to the venous circuit. Press the "Clinical" button. Valve 18.8.11 is opened and blood pump 26 is ready to rotate. When the blood pump's flow rate adjustment knob is turned, the blood pump's pump tube is set by the automatic effusion mechanism. The patient's blood is introduced into the arterial circuit 27 by a blood pump, mixed with an anticoagulant injected by a syringe pump, and temporarily stored in the chamber 15 of the arterial circuit. The syringe pump operates when the blood pump is rotating. The syringe pump is equipped with a fast-forward mechanism, and anticoagulant can be injected at any time by pressing the "fast-forward" button. A blood shortage detector 29 is provided upstream of the blood pump, and when it becomes difficult to remove blood from the patient, it detects the positive pressure in the blood flow path and stops the blood pump. The blood pump automatically restarts when the positive pressure in the blood flow path is released. A pressure gauge 30 is provided in the chamber of the arterial circuit to monitor abnormally high pressure caused by clogging in the plasma separator in the blood flow path or other factors. If the pressure gauge 30 exceeds the alarm set value, the blood pump is stopped. The plasma separator is made of hollow fiber membranes made of cellulose diacetate, and the blood introduced from the chamber of the arterial circuit is subjected to positive pressure generated by the blood pump on the blood inlet side and pressure on the plasma outflow side of the plasma separator. (TMP), the blood cells are separated into blood cell components and plasma components via the hollow fiber membrane. The plasma component is temporarily stored in the chamber 16 of the separation line by the separation pump 23 through the lower outlet of the plasma separator. A pressure gauge 31 is provided on the plasma outflow side of the plasma separator, and the pressure (TMP) between the hollow fibers of the plasma volume S device is detected by the pressure gauge 30 provided in the arterial side circuit chamber. If the membrane pores are detected to be clogged with blood cells and the TMP ti setting value is exceeded, the blood pump 26 is automatically stopped. Note that when the blood pump stops, the other separation pumps 23 and plasma return pump 9 are also automatically stopped. In the case of manual operation, each pump can be rotated independently. The plasma flow rate of plasma components through the plasma separator is determined by the rotation speed of the separation pump 23. The rotation speed of the separation pump is controlled by the blood flow rate of the blood pump 26, and the flow rate ratio between the blood pump 26 and the separation pump 23 is controlled in an interlocked manner that can be varied in the range of 100:10 to 40. The remover 2 is made of phenylalanine-immobilized polyvinyl alcohol gel, and harmful substances such as immune complexes and rheumatoid factors in the separated plasma are removed while passing through the remover.

A pressure gauge 32 is located in the chamber of the separation line to monitor clogging of the subsequent remover with harmful substances.

If the pressure gauge 32 exceeds the alarm set value, the separation pump 23
to stop. The plasma from which harmful substances have been removed passes through a filter 33, joins with a replenisher 3 such as fresh frozen plasma injected by a plasma return pump to replace the amount of plasma lost in the remover, and is introduced into the warmer 13. be done. The amount of replenishment fluid injected with the plasma return pump varies depending on the patient's disease name, clinical condition, etc.

Plasma heated to a predetermined temperature by a warmer is combined with blood cell components separated by a plasma separator in a chamber 14 of the venous circuit. There is a pressure gauge 34 in the chamber of the venous circuit to monitor the condition of the blood being returned to the patient. When the pressure gauge 34 exceeds the alarm set value, the blood pump 26 is stopped.

An air bubble detector 17 is installed in the downstream circuit of the chamber 14 in the venous circuit, and when a predetermined amount of air or more passes through the circuit, the clamp 7 immediately works to cut off the blood flow path and stop the blood pump 26 at the same time. let When the blood processing required for treatment reaches a predetermined value, the end of the clinical trial is notified. At this time, the device continues the clinical state without stopping. After the doctor or staff confirms the end of the clinical trial and stops the blood pump, they press the "end" button.

When the collected blood processing is completed, the blood removal needle on the patient's artery side is removed, and the blood inflow [l] of the blood circuit is connected to the blood return liquid bottle. At the end of blood processing, the blood pump 26 and the separation pump 23
, plasma return pump 9 is stopped and valve 18.8.11
is open, and valve 10 is properly closed. Air valve 21.
22 is closed+h, and clamp 7 is open. "collect"
I press the button. The blood pump 26 is started, and the blood remaining in the blood circulation circuit is introduced into the preservative separator 1 without being replaced with blood return fluid. At the same time, the separation pump 23 starts and rotates counterclockwise, the air valve 22 opens, and the plasma is removed! i
The plasma outside the hollow fiber 11i of the plasma separator is introduced into the inside of the hollow fiber membrane of the plasma separator by a separation pump. Blood return fluid and plasma are mixed and returned to the patient via a chamber in the venous circuit. The separation pump 23 is stopped when the set value of the plasma pressure gauge 31 is reached. At this time, the blood return liquid is 50
~100m42 will be used. When the blood return fluid runs out, the blood is returned using air. Air is introduced into the venous circuit 28 by means of a blood pump 26 to return blood remaining in the blood circulation circuit via a +Iu serum separator. An air detector 35 is provided in the chamber 14 of the venous circuit, and when air is detected, the blood pump stops.

Next, the separation pump 23 is started and rotates clockwise. At the same time, air valve 21 opens and air valve 22 closes. Air flows through the air valve 21 to the outside of the hollow fiber membrane of the separator and is introduced into the remover 2 by the separation pump 23. The plasma in the remover is pushed out by air and returned to the patient via the warmer 13 and the venous circuit chamber 14.

When the air reaches the filter 33, the filter has a structure that does not allow air to pass through, so the pressure on the pressure gauge 32 installed in the chamber of the separation line rises by a moment.
When the set value is reached, the separation pump 23 stops. Next, the valve 8 is closed and the plasma return pump 9 is rotated. At this time, if there is any remaining replenishment fluid, it is injected, but normally air is pumped in. Plasma in the return plasma line is replaced by air. The displaced air is introduced by the plasma return pump through the warmer and into the venous circuit chamber. An air detector 35 provided in the venous circuit chamber detects the passage of air and stores it electrically. When air is detected by the air bubble detector 17 provided on the downstream side of the venous circuit chamber, the plasma return pump 9 is stopped, the valve 11 and the clamp 7 are closed, and the collection is completed. In the unlikely event that air is not detected by the air bubble detector 17 located downstream of the venous circuit chamber, it will have a serious effect on the patient. Based on the stored information, the remaining blood prefectural bond in the blood circuit is calculated, and the operation to complete the collection is performed. Furthermore, when the accumulated flow JH of the plasma return pump 9 reaches a predetermined value (b), the collection is completed even if the air bubble detector 17 detects no air.

(Effects of the Invention) The apparatus of the present invention has a briming passageway that reaches from the outside of the hollow fiber of the 11IL serum separator through a part of the separation line to the discharge line, and a briming passageway that reaches the discharge line from the remover through a part of the separation line. can be operated simultaneously, each with a saline flow rate of 20 m Il, 7
It is possible to pass 1000 mft of liquid in 55 minutes.
Briming can be completed in about 0 minutes. Due to such simultaneous briming processing, the time can be reduced by about 25 minutes compared to the known method, and the briming operation does not require a particularly skilled person.

BRIEF DESCRIPTION OF THE DRAWINGS The attached drawing is a schematic diagram showing one example of the blood purification device of the present invention. 1, lf[L serum separator 5. Replenisher line 2, remover 9. Plasma return pump 3, replenishment fluid
25. Discharge line 4 Replenishment liquid meter

Claims (1)

[Claims] A blood circuit that introduces blood from an arterial circuit into a plasma separator, separates it into blood cell components and plasma components, and returns the separated blood cell components to the human body through a venous circuit, and a blood circuit that separates blood by the plasma separator. The components pass through a separation line and a plasma chamber, and are introduced into a remover for removing unnecessary substances in the plasma for purification.The purified plasma is then passed through a return plasma line to the blood circuit downstream of the plasma separator. Equipped with a plasma circuit that leads to
In a blood purification device that automatically sends washing/filling fluid such as physiological saline to the blood circuit, plasma circuit, plasma separator, and remover from the branch point of the plasma return line mentioned above, the plasma separator and remover are A blood purification device characterized in that a separation line between the vessels is provided with a branched discharge line so that a plasma separator and a remover can be primed at the same time.