JP6961762B2 - Blood purification device - Google Patents

Description

The present invention relates to a blood purification device for purifying a patient's blood while circulating it extracorporeally.

In general, a blood purification device for performing dialysis treatment is used to purify the blood circulating outside the body by the arterial blood circuit and the venous blood circuit that constitute the blood circuit for circulating the patient's blood extracorporeally. It is provided with a blood purifier of the above and a main body of a device provided with various treatment means such as a blood circuit and a blood pump for performing blood purification treatment with the blood purifier. A vascular access catheter or a puncture needle (arterial puncture needle and venous puncture needle) can be attached to the tips of the arterial blood circuit and the venous blood circuit, respectively.

Then, for example, by piercing the patient with an arterial puncture needle and a venous puncture needle and then driving a blood pump, the patient's blood flows through the arterial blood circuit and the venous blood circuit, and in the flow process. Blood is purified by a blood purifier. Further, in dialysis treatment, a dialysate introduction line for introducing dialysate into the blood purifier and a dialysate discharge line for draining drainage from the blood purifier are connected to the blood purifier, respectively. ..

By the way, in the conventional blood purification device, a dialysate storage bag containing the dialysate to be introduced into the blood purifier is connected to the tip of the dialysate introduction line, and blood is connected to the tip of the dialysate discharge line. A drainage storage bag was connected to store the drainage from the purifier. In addition, a dialysate pump and a drainage pump composed of ironing type pumps are arranged in the dialysate introduction line and the dialysate discharge line, respectively, and these dialysate pumps and drainage pumps are rotationally driven during blood purification treatment. By doing so, the dialysate contained in the dialysate bag was introduced into the blood purifier, and the drainage discharged from the blood purifier was contained in the drainage storage bag.

However, the dialysate storage bag and the drainage liquid storage bag are attached to the weight scales (dialysate side weight scale and drainage side weight scale, respectively), and in the process of rotationally driving the dialysate pump and the drainage pump, the weight is increased. It was configured to monitor changes in meter measurements. As a result, it is possible to detect an error (error in the discharge amount) by comparing the weight change (actual measurement value) due to the rotational drive of the replenishment pump and the drainage pump with the theoretical value, and it is determined that an error has occurred. In this case, the rotation speeds of the replenishment pump and the drainage pump were configured to be automatically corrected. Since the prior art does not relate to the invention known in the literature, there is no prior art document information to be described.

In the above-mentioned conventional blood purification device, two weigh scales (dialysate side weigh scale and drain side weigh scale) are required to measure the weight of each of the dialysate pump and the drainage pump. Therefore, the manufacturing cost increases by the number of the weighing scales, and the errors of the two weighing scales may be accumulated, so that the correction cannot be performed accurately.

Therefore, it is conceivable to measure both the dialysate storage bag and the drainage liquid storage bag with a single (common) weighing scale so that the correction can be performed accurately while reducing the cost. However, in this case, although the error during the rotational drive of the dialysate pump or the drainage pump can be detected by comparing the measured value of the weighing scale with the theoretical value, which pump has the error? I can't judge. Further, for example, if it is determined that an error has occurred in either the dialysate pump or the drainage pump based on the measured value of the weighing scale, it is considered that the dialysate pump has no error and the drainage pump is discharged. Although it is possible to make corrections for the liquid pump, if there is an error in the dialysate pump, an error will occur in the flow rate of the dialysate to be introduced into the blood purifier, which will adversely affect the blood purification treatment. There was a risk that it would occur.

The present invention has been made in view of such circumstances, and the dialysate pump and the drainage fluid are reduced while reducing the cost by measuring the weight of the dialysate storage bag and the drainage fluid storage bag with a single weighing scale. It is an object of the present invention to provide a blood purification device capable of accurately correcting the rotation speed of a pump and suppressing an error in the flow rate of a dialysate to be introduced into a blood purification means.

The invention according to claim 1 has an arterial side blood circuit and a venous side blood circuit, and has a blood circuit capable of extracorporeally circulating a patient's blood from the tip of the arterial side blood circuit to the tip of the venous side blood circuit, and the blood. A blood purification means that is interposed between the arterial side blood circuit and the venous side blood circuit of the circuit and can purify the blood flowing through the blood circuit, and a dialysate introduction line for introducing dialysate into the blood purification means. It consists of a dialysate discharge line for draining the drainage liquid from the blood purification means and an ironing type pump arranged in the dialysate introduction line, and the dialysate of the dialysate introduction line flows by rotationally driving. A dialysate pump that can be used, a dialysate storage bag that is connected to the tip of the dialysate introduction line and contains the dialysate to be introduced into the blood purification means, and an ironing pump provided in the dialysate discharge line. A drainage pump capable of flowing the drainage of the dialysate discharge line by rotationally driving, and a drainage pump connected to the tip of the dialysate drainage line, capable of accommodating the drainage discharged from the blood purification means. A single weight scale capable of measuring the total weight of the dialysate storage bag and the drainage storage bag, and the dialysate pump and the drainage pump are controlled based on the measured values of the weight scale. In a blood purification device including a possible control unit, the control unit rotatively drives the dialysate pump to allow the dialysate in the dialysate storage bag to flow without being housed in the drainage storage bag. Based on the change in the measured value of the weighing scale in the process, the correction value of the rotation speed of the dialysate pump or the value related to the rotation speed can be calculated, and the dialysate is based on the calculated correction value. During the correction step of correcting the rotational speed of the pump or a value related to the rotational speed, the dialysate in the dialysate storage bag is made to flow into the blood circuit, and the dialysate is introduced into the dialysate introduction line. A flexible accommodating means capable of accommodating the dialysate flowing in the line is connected, and at the time of the correction step, the accommodating means is configured to be capable of accommodating the dialysate in the dialysate accommodating bag. During the correction step, the control unit secures a capacity for discharging the liquid in the accommodating means before rotationally driving the dialysate pump and accommodating the liquid flowing by the rotational drive of the dialysate pump. It is characterized by obtaining.
The invention according to claim 2 has an arterial blood circuit and a venous blood circuit, and has a blood circuit capable of extracorporeally circulating a patient's blood from the tip of the arterial blood circuit to the tip of the venous blood circuit, and the blood. A blood purification means that is interposed between the arterial side blood circuit and the venous side blood circuit of the circuit and can purify the blood flowing through the blood circuit, and a dialysate introduction line for introducing dialysate into the blood purification means. It consists of a dialysate discharge line for draining drainage from the blood purification means and an ironing type pump arranged in the dialysate introduction line, and the dialysate of the dialysate introduction line flows by rotationally driving. A dialysate pump that can be used, a dialysate storage bag that is connected to the tip of the dialysate introduction line and contains dialysate to be introduced into the blood purification means, and an ironing pump provided in the dialysate discharge line. A drainage pump capable of flowing the drainage of the dialysate discharge line by rotationally driving, and a drainage pump connected to the tip of the dialysate drainage line, capable of accommodating the drainage discharged from the blood purification means. A single weigh scale capable of measuring the total weight of the dialysate storage bag and the drainage storage bag, and the dialysate pump and the drainage pump are controlled based on the measured values of the weigh scale. In a blood purification device including a possible control unit, the control unit rotates and drives the dialysate pump to allow the dialysate in the dialysate storage bag to flow without being stored in the drainage storage bag. Based on the change in the measured value of the weighing scale in the process, the correction value of the rotation speed of the dialysate pump or the value related to the rotation speed can be calculated, and the dialysate is based on the calculated correction value. During the correction step of correcting the rotational speed of the pump or a value related to the rotational speed, the dialysate in the dialysate storage bag is made to flow into the blood circuit, and the dialysate is introduced into the dialysate introduction line. A flexible accommodating means capable of accommodating the dialysate flowing in the line is connected, and at the time of the correction step, the accommodating means is configured to be able to accommodate the dialysate in the dialysate accommodating bag. The accommodating means comprises a heating bag for heating the dialysate flowing through the dialysate introduction line during blood purification treatment.

According to a third aspect of the present invention, in the blood purification apparatus according to the first or second aspect , the control unit simultaneously drives the dialysate pump and the drainage pump after the correction step, and the weigh scale. It is characterized in that the drainage pump is corrected based on the change of the measured value of.

The invention according to claim 4 comprises the blood purifying apparatus according to any one of claims 1 to 3, further comprising a blood pump composed of an ironing pump provided in the arterial blood circuit, and the amendment. It is characterized in that the blood pump is stopped during the process.

The invention according to claim 5 allows the dialysate in the dialysate storage bag to flow to the venous blood circuit via the blood purification means in the blood purification apparatus according to any one of claims 1 to 4. It is characterized by being able to do so.

The invention according to claim 6 has, in the blood purification apparatus according to any one of claims 1 to 4 , a replacement fluid line capable of communicating a predetermined site of the venous blood circuit and a dialysate introduction line. At the time of the correction step, the dialysate in the dialysate storage bag can be flowed to the venous blood circuit via the replacement fluid line.

The invention according to claim 7 is characterized in that, in the blood purification device according to claim 5 or 6 , a storage bag capable of storing a liquid is connected to the tip of the venous blood circuit during the correction step. do.

The invention according to claim 8 is the blood purification apparatus according to any one of claims 1 to 7 , wherein the correction step is performed before the blood purification treatment.

The invention according to claim 9 is the blood purification apparatus according to any one of claims 1 to 7 , wherein the correction step is performed during the blood purification treatment.

The invention according to claim 10 is the blood purification device according to any one of claims 1 to 9 , wherein the control unit is based on an error between a measured value of the weighing scale and a theoretical value during the correction step. It is characterized in that the rotation speed of the dialysate pump is corrected and controlled.

The invention according to claim 11 is the blood purification device according to any one of claims 1 to 10 , wherein the control unit drives the dialysate pump at a plurality of rotation speeds during the correction step, respectively. It is characterized in that a correction value can be set according to the rotation speed of the dialysate pump based on the change in the measured value of the weighing scale acquired at the rotation speed of the dialysate pump.

The invention according to claim 12 stores in advance characteristic data of the flow rate change rate with respect to the total rotation speed of the dialysate pump in the blood purification device according to any one of claims 1 to 10, and also stores the characteristic data of the flow rate change rate with respect to the total rotation speed. Is characterized in that during the correction step, a correction value can be set according to the rotation speed of the dialysate pump based on the characteristic data.

According to the inventions of claims 1 and 2 , the control unit rotationally drives the dialysate pump to allow the dialysate in the dialysate storage bag to flow without being stored in the drainage storage bag, and the weight scale in the process. Based on the change in the measured value, the rotation speed of the dialysate pump or the correction value of the value related to the rotation speed can be calculated. By making the measurement, it is possible to accurately correct the rotational speeds of the dialysate pump and the drainage pump while reducing the cost, and it is possible to suppress an error in the flow rate of the dialysate to be introduced into the blood purification means.
Further, according to the inventions of claims 1 and 2, a flexible accommodating means capable of accommodating the dialysate flowing in the dialysate introduction line is connected to the dialysate introduction line, and at the time of the correction step, Since the dialysate in the dialysate storage bag can be stored in the storage means, it is possible to prevent the liquid that has flowed due to the rotational drive of the dialysate pump from flowing to the blood circuit side. Further, since the accommodating means is flexible, the accommodating means can be expanded according to the flow rate of the liquid flowed by the rotational drive of the dialysate pump, and resistance (flow resistance) is generated when the liquid flows. Can be suppressed, and the rotation speed of the dialysate pump can be corrected more accurately.
According to the invention of claim 1, in the correction step, the control unit discharges the liquid in the accommodating means before rotationally driving the dialysate pump to accommodate the liquid flowing by the rotational drive of the dialysate pump. Since the capacity can be secured, the liquid that has flowed by the rotational drive of the dialysate pump can be more reliably accommodated in the accommodating means. According to the invention of claim 2, since the accommodating means comprises a heating bag for heating the dialysate flowing through the dialysate introduction line during the blood purification treatment, the heating bag required for the blood purification treatment is provided. It can be diverted to accommodate the fluid that has flowed by the rotational drive of the dialysate pump.

According to the invention of claim 5 , since the dialysate in the dialysate storage bag can be flowed to the venous blood circuit via the blood purification means, the dialysate in the dialysate storage bag does not need to be added separately. The dialysate can flow into the venous blood circuit.

According to the invention of claim 6 , it has a replacement fluid line capable of communicating a predetermined site of the blood circuit on the venous side and a dialysate introduction line, and during the correction step, the dialysate in the dialysate storage bag via the replacement fluid line. Can be flowed to the blood circuit on the venous side, so that the dialysate can be flowed to the blood circuit side without going through the blood purification means.

According to the invention of claim 7 , during the correction step, a storage bag capable of storing the liquid is connected to the tip of the venous blood circuit, so that the liquid flowing in the venous blood circuit is driven by the rotation of the dialysate pump. It is possible to prevent spilling from the tip of the venous blood circuit.

According to the invention of claim 8 , since the correction step is performed before the blood purification treatment, the blood purification treatment can be started immediately.

According to the invention of claim 9 , since the correction step is performed during the blood purification treatment, even if the characteristics of the dialysate pump are changed during the blood purification treatment, the rotation speed of the dialysate pump can be corrected. can.

According to the invention of claim 10 , during the correction step, the control unit corrects and controls the rotation speed of the dialysate pump based on the error between the measured value of the weighing scale and the theoretical value, and thus rotates the dialysate pump. The speed can be corrected more accurately, and the flow rate error due to the rotational drive of the dialysate pump can be made smaller.

According to the invention of claim 11 , the control unit drives the dialysate pump at a plurality of rotation speeds during the correction step, and the dialysate is based on the change in the measured value of the weighing scale acquired at each rotation speed. Since the correction value can be set according to the rotation speed of the pump, the flow rate error due to the rotation drive of the dialysate pump can be further reduced.

According to the invention of claim 12 , the characteristic data of the flow rate change rate with respect to the total rotation speed of the dialysate pump is stored in advance, and the control unit sets the rotation speed of the dialysate pump based on the characteristic data at the time of the correction step. Since the correction value can be set according to the rotation speed of the dialysate pump, even if a flow rate error occurs due to a change over time of the dialysate pump, the correction value according to the rotation speed of the dialysate pump can be set more smoothly without driving at multiple rotation speeds. Can be set.

Schematic diagram which shows the blood purification apparatus which concerns on embodiment of this invention Schematic diagram showing a heating bag applied to the blood purification device Perspective view showing the heating means (the lid is open) in the blood purification device. A perspective view showing a state in which a heating bag is attached to the heating means. A perspective view showing a state in which the lid is closed after the heating bag is attached to the heating means. Schematic diagram showing an ironing pump applied to the blood purification device The schematic diagram which shows the state at the time of the correction process in the blood purification apparatus which concerns on 1st Embodiment of this invention. Schematic diagram showing a state at the time of a correction step in a blood purification device (flowing dialysate to a venous blood circuit via a dialyzer) according to another embodiment of the present invention. Flow chart showing the control contents by the control unit in the blood purification device Flow chart showing the control contents by the control unit A flowchart showing the content of control by the control unit of the blood purification device according to another embodiment. Flow chart showing the control contents by the control unit A flowchart showing the content of control by the control unit of the blood purification device according to still another embodiment. Flow chart showing the control contents by the control unit Graph showing characteristic data of dialysate pump referred to by the control unit The schematic diagram which shows the state at the time of the correction process in the blood purification apparatus which concerns on 2nd Embodiment of this invention. Schematic diagram showing the state of the blood purification device during the correction process

Hereinafter, embodiments of the present invention will be specifically described with reference to the drawings.
The blood purification device according to the first embodiment is applied to a blood dialysis device for purifying a patient's blood while circulating it extracorporeally, and as shown in FIG. 1, the arterial blood circuit 1a and the venous blood. A blood circuit 1 having a circuit 1b, a dialyzer 2 (blood purification means) interposed between the arterial blood circuit 1a and the venous blood circuit 1b to purify the blood flowing through the blood circuit 1, and an arterial blood circuit 1a. Blood pump P1 composed of ironing type pumps arranged in, dialysate introduction line L1 and dialysate discharge line L2, and dialysate pump P2 arranged in these dialysate introduction line L1 and dialysate discharge line L2, respectively. And the drainage pump P3, the replenishment line L3, the dialysate storage bag B1 containing the dialysate to be introduced into the dialyzer 2, the drainage storage bag B2 containing the drainage discharged from the dialyzer 2, and the priming liquid. It includes a priming liquid storage bag B3, a weight scale 4, and a control unit 7. In the figure, reference numerals P and Pa indicate pressure detecting means (pressure gauge), and reference numerals T indicate temperature detecting means.

A connector is connected to the tip of each of the arterial blood circuit 1a and the venous blood circuit 1b, and the arterial puncture needle and the venous puncture needle (not shown) can be connected via the connector. .. Then, the blood pump P1 is rotationally driven (forward rotation) with the arterial puncture needle connected to the tip of the arterial blood circuit 1a and the venous puncture needle connected to the tip of the venous blood circuit 1b pierced by the patient. When driven), the patient's blood reaches the dialyzer 2 through the arterial blood circuit 1a, is purified by the dialyzer 2, and then returns to the patient's body through the venous blood circuit 1b. It has become. Instead of puncturing the patient's blood vessel with the arterial and venous puncture needles, a double lumen catheter is inserted into the patient's subclavian vein or femoral vein, or inserted into the patient's arm blood vessel. May be.

Further, an air trap chamber 3 is connected in the middle of the venous blood circuit 1b, and the blood circulating outside the body returns to the patient after the air bubbles are removed in the air trap chamber 3. An air flow path extends from the upper part of the air trap chamber 3, and the pressure detecting means P at the tip thereof can detect the venous pressure. Further, a clamping means 5 that can be opened and closed to open or block the flow path is provided at the tip of the venous blood circuit 1b (between the tip of the venous blood circuit 1b and the air trap chamber 3). ..

The replacement fluid line L3 is composed of a flow path capable of communicating a predetermined site of the venous blood circuit 1b (in this embodiment, the air trap chamber 3) and the dialysate introduction line L1. The fluid can be supplied to the venous blood circuit 1b. In the present embodiment, the priming liquid storage bag B3 containing the priming liquid is connected to the tips of the arterial side blood circuit 1a and the venous side blood circuit 1b, and the blood pump P1 is rotationally driven to drive the priming liquid storage bag B3. The priming liquid in the priming liquid storage bag B3 is supplied to the blood circuit 1 to enable priming.

The dialyzer 2 has a blood inlet 2a (blood inlet port), a blood outlet 2b (blood outlet port), a dialysate inlet 2c (dialysate flow path inlet: dialysate inlet port), and a dialysate in its housing. An outlet 2d (dialysis fluid flow path outlet: dialysate outlet port) is formed, of which the blood inlet 2a has the proximal end of the arterial blood circuit 1a and the blood outlet 2b has the venous blood circuit 1b. The base ends of each are connected. Further, the dialysate introduction port 2c and the dialysate outlet 2d are connected to the dialysate introduction line L1 and the dialysate discharge line L2, respectively.

A plurality of hollow fiber membranes (not shown) are housed in the dialyzer 2, and the hollow fibers form a blood purification membrane for purifying blood. In the dialyzer 2, a blood flow path through which the patient's blood flows (a flow path between the blood inlet 2a and the blood outlet 2b) and a dialysate flow path through which the dialysate flows (dialysate introduction). A flow path between the port 2c and the dialysate outlet 2d) is formed. The hollow fiber membrane constituting the blood purification membrane is formed with a large number of minute holes (pores) penetrating the outer peripheral surface and the inner peripheral surface thereof to form the hollow fiber membrane, and blood is formed through the hollow fiber membrane. It is configured so that impurities and the like inside can permeate into the dialysate.

The dialysate introduction line L1 is composed of a flow path for introducing the dialysate into the dialyzer 2, one end of which is connected to the dialysate introduction port 2c of the dialyzer 2, and also constitutes the flow path of the dialysate introduction line L1. A dialysate pump P2 comprising an ironing pump that handles and feeds a flexible tube is provided. The other end of the dialysate introduction line L1 is connected to a dialysate accommodating bag B1 accommodating a predetermined volume of dialysate, and by driving the dialysate pump P2 (forward rotation drive), the inside of the dialysate accommodating bag B1. The dialysate can be introduced into the dialyzer 2.

Further, a flexible heating bag 6 (accommodating) capable of accommodating the dialysate flowing through the dialysate introduction line L1 between the dialysate pump P2 and the replacement fluid line L3 in the dialysate introduction line L1. Means) are connected. The heating bag 6 is for heating the dialysate flowing through the dialysate introduction line L1 during blood purification treatment, and as shown in FIG. 2, two flexible sheets are laminated and welded. As a result, the flow path 6a is formed, and connecting portions 6b and 6c that can be connected to the dialysate introduction line L1 are provided on one end side and the other end side of the flow path 6a.

The heating bag 6 can be attached to a heating means h including a heater capable of heating the dialysate. As shown in FIG. 3, the heating means h is formed on the housing portion H attached to the main body of the dialysis machine, and is formed on the lid portion M, the housing portion H side, and the lid portion M side, respectively. It is configured to have a heating portion C. The heating portion C is made of a metal plate material so that heat from a heat source (heating wire or the like) (not shown) can be transferred. Then, as shown in FIG. 4, after the heating bag 6 is attached to the heating portion C on the lid portion M side, the housing portion H is closed by closing the lid portion M as shown in FIG. The heating bag 6 is sandwiched between the heating portions C on the side and the lid portion M side, and the dialysate flowing through the flow path 6a can be heated by the heat of the heat source.

As shown in FIG. 1, the dialysate discharge line L2 is composed of a flow path for draining drainage from the dialyzer 2, one end of which is connected to the dialysate outlet 2d of the dialyzer 2, and the dialysate discharge line. A drainage pump P3 composed of an ironing type pump that handles and feeds a flexible tube constituting the flow path of L2 is arranged. The other end of the dialysate discharge line L2 is connected to a drainage storage bag B2 capable of storing a predetermined amount of drainage, and is discharged from the dialyzer 2 by driving the drainage pump P3 (forward rotation drive). The dialysate (drainage) that has been prepared can be introduced into the drainage storage bag B2.

Then, the dialysate of the dialysate storage bag B1 flows toward the dialyzer 2 by the forward rotation drive of the dialysate pump P2, and the dialysate (drainage) of the dialyzer 2 is discharged by the forward rotation drive of the drainage pump P3. It will flow toward the drainage storage bag B2. The weighing scale 4 holds the dialysate storage bag B1 and the drainage storage bag B2 by hooking them on a hook, and also holds the dialysate storage bag B1 and the drainage storage bag B2 (dialyte solution storage bag B1 and drainage storage bag B1). The total weight of the bag B2) can be measured in real time (common to the dialysate storage bag B1 and the drainage storage bag B2). The dialysate storage bag B1 and the drainage storage bag B2 (the same applies to the priming liquid storage bag B3) consist of a flexible storage container, of which the drainage storage bag B2 is before starting the blood purification treatment. In, it is in an empty state where no drainage is contained inside.

By the way, as shown in FIG. 6, the ironing type pumps such as the blood pump P1, the dialysate pump P2 and the drainage pump P3 applied to the present embodiment include the stator 8 and a rotor that can be rotationally driven in the stator 8. It is mainly composed of a 9, a roller 10 (ironing portion) formed on the rotor 9, and a pair of guide pins 11. In the figure, the cover covering the upper part of the stator 8 is omitted.

The stator 8 is formed with a mounting recess 8a to which the ironing tube D is attached, and the ironing tube D is configured to be mounted along the inner peripheral wall surface forming the mounting recess 8a. The ironing tube D has a flexible tube F (arterial blood circuit 1a in the blood pump P1, dialysate introduction line L1 in the dialysate pump P2, dialysate discharge line L2 in the drainage pump P3). Flexible tubes that make up the flow path) are connected. Further, a rotor 9 that can be rotationally driven by a motor is disposed substantially in the center of the mounting recess 8a. A pair of rollers 10 and a guide pin 11 are arranged on the side surface of the rotor 9 (the surface of the mounting recess 8a facing the inner peripheral wall surface).

The roller 10 is rotatable about a rotation shaft L formed on the outer edge side of the rotor 9, and the ironing tube D attached to the attachment recess 8a is compressed in the radial direction to close the flow path. At the same time, the liquid such as blood and dialysate can be flowed by squeezing in the longitudinal direction (flow direction of the liquid) with the rotation of the rotor 9. That is, when the ironing tube D is mounted in the mounting recess 8a and the rotor 9 is rotationally driven, the ironing tube D is compressed between the roller 10 and the inner peripheral wall surface of the mounting recess 8a, and the flow path is closed. At the same time (closed), it can be squeezed in the rotational direction (longitudinal direction) as the rotor 9 is rotationally driven. Due to this ironing action, the liquid in the ironing tube D is discharged in the rotation direction of the rotor 9.

The control unit 7 shown in FIG. 1 is composed of a microcomputer or the like arranged in the blood purification device, and is a blood pump P1, a dialysate pump P2, and a drainage pump P1 based on the weight measured by the scale 4 and a set value stored in advance. The drive of the liquid pump P3 can be controlled. Here, the control unit 7 according to the present embodiment rotates the dialysate pump P2 while stopping the drainage pump P3, without accommodating the dialysate in the dialysate storage bag B1 in the drainage storage bag B2. Based on the change in the measured value of the weight scale 4 in the process of flowing, the rotation speed of the dialysate pump P2 or the correction value of the value related to the rotation speed can be calculated, and the rotation speed of the dialysate pump P2. It is supposed that a correction step for correcting the above can be performed. Specifically, during the correction step, as shown in FIG. 7, the clamp means 5 is opened to open the flow path, and the dialysate pump P2 is rotationally driven (forward rotation driven) while the drainage pump P3 is stopped. Let me. The blood pump P1 is preferably stopped.

As a result, the dialysate in the dialysate storage bag B1 flows through the dialysate introduction line L1 and then flows into the venous blood circuit 1b via the replacement fluid line L3, and does not reach the drainage storage bag B2. No. Therefore, in the process of flowing the dialysate in the dialysate storage bag B1 to the venous blood circuit 1b, the rotation speed of the dialysate pump P2 can be corrected based on the change in the measured value of the weighing scale 4. The correction method will be described later. Further, the liquid (dialysate and priming liquid in the dialysate storage bag B1) that has flowed by driving the dialysate pump P2 is a storage bag connected to the tip of the venous blood circuit 1b (priming in the present embodiment). It will be stored in the liquid storage bag B3).

However, as shown in FIG. 8, when the replacement fluid line L3 is not provided, during the correction step, as shown in the figure, the clamp means 5 is opened to open the flow path, and the dialysate pump P2 is rotationally driven. The drainage pump P3 may be stopped while being driven (forward rotation drive). The blood pump P1 is preferably stopped. In this case, since the dialysate in the dialysate storage bag B1 can be flowed to the venous blood circuit 1b via the dialyzer 2, the dialysate storage bag B1 does not need to add a special flow path such as the replacement fluid line L3. The dialysate inside can be flowed into the venous blood circuit 1b.

According to the present embodiment, the control unit 7 rotationally drives the dialysate pump P2 to flow the dialysate in the dialysate accommodating bag B1 without accommodating it in the drainage accommodating bag B2, and the weight scale 4 in the process. Since a correction step for correcting the rotational speed of the dialysate pump P2 can be performed based on the change in the measured value of the above, the weights of the dialysate storage bag B1 and the drainage liquid storage bag B2 are measured by a single weighing scale 4. By making the measurement, it is possible to accurately correct the rotation speed of the dialysate pump P2 while reducing the cost, and it is possible to suppress an error in the flow rate of the dialysate introduced into the dialyzer 2.

Further, since the control unit 7 according to the present embodiment rotates and drives the dialysate pump P2 while stopping the drainage pump P3 during the correction step, the dialysate flowing from the dialysate storage bag B1 in the correction step is drained. It is possible to surely prevent the storage bag B2 from being stored. Further, it has a replacement fluid line L3 capable of communicating a predetermined site of the venous blood circuit 1b and the dialysate introduction line L1, and during the correction step, the dialysate in the dialysate storage bag B1 is intravenously passed through the replacement fluid line L3. Since it can be flowed to the side blood circuit 1b, the dialysate can be flowed to the blood circuit 1 side without passing through the dialyzer 2.

Further, if the dialysate in the dialysate storage bag B1 can be allowed to flow to the venous blood circuit 1b via the dialyzer 2, dialysis in the dialysate storage bag B1 can be performed without adding a special flow path. The fluid can flow into the venous blood circuit 1b. Furthermore, during the correction step, a storage bag (priming liquid storage bag B3) capable of storing the liquid was connected to the tip of the venous blood circuit 1b, so that the venous blood circuit 1b was driven by the rotation of the dialysate pump P2. It is possible to prevent the flowing liquid from spilling from the tip of the venous blood circuit 1b.

The rotation speed of the drainage pump P3 is controlled to be the same as that of the dialysate pump P2 when water is not removed from the patient as a treatment condition, and when water is removed, the rotation speed is controlled. It is controlled so that the rotation speed is the sum of the flow rate due to water removal. Then, after a lapse of a predetermined time, if there is an error between the weight of the dialysate storage bag B1 and the drainage storage bag B2 detected by the weighing scale 4 and the theoretical weight, the drainage is performed in order to eliminate the error. The rotation speed of the liquid pump P3 can be automatically corrected.

That is, by combining the correction related to the dialysate pump P2 of the present invention and the correction related to the drainage pump P3 of the prior art, the weights of the dialysate storage bag and the drainage liquid storage bag are measured by a single weighing scale. As a result, it is possible to reduce the manufacturing cost, suppress the error in the flow rate of the dialysate to be introduced into the blood purification means, and further suppress the water removal error in the treatment.

Next, the control in the correction step of the control unit 7 according to the present embodiment will be described with reference to the flowcharts of FIGS. 9 and 10.
First, when the measurement step for correction is started, the measured value (m0) of the weighing scale 4 is stored in S1 as shown in FIG. After that, as shown in FIG. 7, the drainage pump P3 is opened while the clamping means 5 is opened and the flow path is opened, and the dialysate pump P2 is rotationally driven (rotational speed n1, forward rotation drive at rotational time t1). Is stopped (S2), and the measured value (m1) of the weighing scale 4 is stored in that state (S3).

Then, using the measured value (m0) stored in S1 and the measured value (m1) stored in S3, V = (m0-m1) / ρ / (n1 · t1) (where ρ is the dialysate of the dialysate. The correction value V (discharge amount per rotation) is obtained based on the calculation formula (density) (S4). The calculation formula used in S4 can obtain a correction value for correcting the rotation speed of the dialysate pump P2 based on the error between the measured value of the weighing scale 4 and the theoretical value.

With the above, the measurement step for correction is completed, and then the correction processing step is started. In such a correction processing step, as shown in FIG. 10, based on the set flow rate Q (S1) input by the operator, the calculation formula is that the rotation speed (n) = the set flow rate (Q) / the correction value (V). Based on this, the rotation speed (n) of the dialysate pump P2 is corrected and controlled (S2). In this way, during the correction process, the control unit 7 corrects and controls the rotation speed of the dialysate pump P2 based on the error between the measured value and the theoretical value of the weighing scale 4, so that the rotation speed of the dialysate pump P2 is controlled. Can be corrected more accurately, and the flow rate error due to the rotational drive of the dialysate pump P2 can be made smaller.

Further, the control of the control unit 7 of the correction process according to the other embodiment can be based on the flowcharts shown in FIGS. 11 and 12.
First, when the measurement step for correction is started, the measured value (m0) of the weighing scale 4 is stored in S1 as shown in FIG. After that, as shown in FIG. 7, the drainage pump P3 is opened while the clamping means 5 is opened and the flow path is opened, and the dialysate pump P2 is rotationally driven (rotational speed n1, forward rotation drive at rotational time t1). Is stopped (S2), and the measured value (m1) of the weighing scale 4 is stored in that state (S3).

Further, the drainage pump P3 is stopped (S4) while the dialysate pump P2 is rotationally driven (normal rotation drive) at a rotation speed n2 and a rotation time t2, and the measured value (m2) of the weighing scale 4 is measured in that state. Remember (S5). Then, using the measured value (m0) stored in S1, the measured value (m1) stored in S3, and the measured value (m2) stored in S5, V1 = (m0-m1) / ρ / (n1). -T1), V2 = (m1-m2) / ρ / (n2 · t2) (where ρ is the density of dialysate), the correction values V1 and V2 are obtained (S6). The calculation formula used in S6 can obtain a correction value for correcting the rotation speed of the dialysate pump P2 based on the error between the measured value of the weighing scale 4 and the theoretical value. Then, using these correction values V1 and V2, the flow rates Q1 and Q2 are obtained by the arithmetic expressions Q1 = n1 · V1 and Q2 = n2 · V2 (S7).

With the above, the measurement step for correction is completed, and then the correction processing step is started. In such a correction processing step, as shown in FIG. 12, when the relationship is 0 ≦ Q <Q1 based on the set flow rate Q (S1) input by the operator, the rotation speed (n) = (n1 / Q1). -The rotation speed (n) of the dialysate pump P2 is corrected and controlled based on the calculation formula Q, and when the relationship Q ≧ Q2, the rotation speed (n) = ((n2-n1) / (Q2-). The rotation speed (n) of the dialysate pump P2 is corrected and controlled based on the calculation formulas Q1)) and Q + (n1-((n2-n1) / (Q2-Q1)) and Q1). In this way, the control unit 7 drives the dialysate pump P2 at a plurality of rotation speeds during the correction step, and based on the change in the measured value of the weighing scale 4 acquired at each rotation speed, the dialysate pump P2 Since the correction value can be set according to the rotation speed of the dialysate pump P2, the flow rate error due to the rotation drive of the dialysate pump P2 can be further reduced.

In addition, the control of the control unit 7 of the correction process according to still another embodiment can be based on the flowcharts shown in FIGS. 13 and 14.
First, when the measurement step for correction is started, the measured value (m0) of the weighing scale 4 is stored in S1 as shown in FIG. After that, as shown in FIG. 7, the drainage pump P3 is opened while the clamping means 5 is opened and the flow path is opened, and the dialysate pump P2 is rotationally driven (rotational speed n1, forward rotation drive at rotational time t1). Is stopped (S2), and the measured value (m1) of the weighing scale 4 is stored in that state (S3).

Then, using the measured value (m0) stored in S1 and the measured value (m1) stored in S3, V0 = (m0-m1) / ρ / (n1 · t1) (where ρ is the dialysate of the dialysate. The correction value V0 (initial value of discharge amount per rotation) is obtained based on the calculation formula (density) (S4). The calculation formula used in S4 can obtain a correction value for correcting the rotation speed of the dialysate pump P2 based on the error between the measured value of the weighing scale 4 and the theoretical value.

With the above, the measurement step for correction is completed, and then the correction processing step is started. In such a correction processing step, as shown in FIG. 15, characteristic data of the flow rate change rate (volume change rate) with respect to the total rotation speed Z in the dialysate pump P2 is stored in advance. Then, when the correction processing step is started, as shown in FIG. 14, the rotation speed (n) = the set flow rate (n) based on the set flow rate Q (S1) input by the operator and the characteristic data stored in advance. Q) / (correction value (V0) / volume change rate (c)) is used to correct and control the rotation speed (n) of the dialysate pump P2 (S2).

In this way, the characteristic data of the flow rate change rate (capacity change rate c) with respect to the total rotation speed Z in the dialysate pump P2 is stored in advance, and the control unit 7 performs the dialysate pump based on the characteristic data at the time of the correction step. Since the correction value can be set according to the rotation speed of P2, even if a flow rate error occurs due to a change over time of the dialysate pump P2, the dialysate pump P2 can be operated more smoothly without being driven at a plurality of rotation speeds. A correction value can be set according to the rotation speed.

Next, the blood purification device according to the second embodiment of the present invention will be described.
Similar to the first embodiment, the blood purification device according to the second embodiment is applied to a blood dialysis device for purifying the patient's blood while circulating it extracorporeally, and as shown in FIG. 1, the arteries A dialyzer 2 (blood purification means) that is interposed between the blood circuit 1 having the side blood circuit 1a and the venous blood circuit 1b and the arterial blood circuit 1a and the venous blood circuit 1b to purify the blood flowing through the blood circuit 1. ), A blood pump P1 composed of an ironing type pump arranged in the arterial blood circuit 1a, a dialysate introduction line L1 and a dialysate discharge line L2, and these dialysate introduction lines L1 and dialysate discharge lines L2, respectively. The arranged dialysate pump P2 and drainage pump P3, the replenishment line L3, the dialysate storage bag B1 containing the dialysate to be introduced into the dialyzer 2, and the drainage liquid containing the drainage discharged from the dialyzer 2. It includes a storage bag B2, a priming liquid storage bag B3 that stores the priming liquid, a weight scale 4, and a control unit 7. The same components as those in the first embodiment are designated by the same reference numerals, and detailed description thereof will be omitted.

Here, the control unit 7 according to the present embodiment rotates the dialysate pump P2 while stopping the drainage pump P3, without accommodating the dialysate in the dialysate storage bag B1 in the drainage storage bag B2. It is possible to perform a correction step of flowing and correcting the rotation speed of the dialysate pump P2 based on the change of the measured value of the weighing scale 4 in the process, and is connected to the dialysate introduction line L1 at the time of the correction step. The heating bag 6 (accommodation means) is configured to accommodate the dialysate in the dialysate accommodating bag B1.

Specifically, as shown in FIG. 16, during the correction step, the drainage pump P3 is driven (forward rotation drive) while the dialysate pump P2 is stopped before the dialysate pump P2 is rotationally driven as described above. (At this time, the clamping means 5 is in the closed state), so that the liquid in the heating bag 6 (accommodating means) is discharged, and the capacity for accommodating the liquid flowing by the rotational drive of the dialysate pump P2. To secure. After driving the drainage pump P3 (forward rotation drive), the drainage pump P3 is provided on condition that the measured value of the pressure detecting means (pressure gauge) attached to the drainage line L2 reaches a predetermined value. It is preferable to stop. As a result, it is possible to prevent the inside of the dialysate introduction line L1 from becoming negative pressure and foaming, or becoming excessive pressure and causing liquid leakage or the like.

After that, as shown in FIG. 17, the clamp means 5 is closed to close the flow path, and the drainage pump P3 is stopped while rotating the dialysate pump P2 (forward rotation drive). At this time, it is preferable to stop the blood pump P1. As a result, the dialysate in the dialysate storage bag B1 is stored in the heating bag 6 and does not reach the drainage liquid storage bag B2. When the dialysate is housed in the heating bag 6, since the heating bag 6 is made of a flexible material, it swells according to the amount of the dialysate flowing in. Therefore, in the process of accommodating the dialysate in the dialysate accommodating bag B1 in the heating bag 6, the rotation speed of the dialysate pump P2 can be corrected based on the change in the measured value of the weighing scale 4. The correction method is the same as that of the first embodiment (including other embodiments and further other embodiments).

According to the present embodiment, the control unit 7 rotationally drives the dialysate pump P2 to flow the dialysate in the dialysate accommodating bag B1 without accommodating it in the drainage accommodating bag B2, and the weight scale 4 in the process. Since a correction step for correcting the rotation speed of the dialysate pump P2 can be performed based on the change in the measured value of the above, the weights of the dialysate storage bag B1 and the drainage liquid storage bag B2 are measured by a single weighing scale 4. By making the measurement, it is possible to accurately correct the rotational speeds of the dialysate pump P2 and the drainage pump P3 while reducing the cost, and it is possible to suppress an error in the flow rate of the dialysate introduced into the dialyzer 2.

Further, since the control unit 7 according to the present embodiment rotates and drives the dialysate pump P2 while stopping the drainage pump P3 during the correction step, the dialysate flowing from the dialysate storage bag B1 in the correction step is drained. It is possible to surely prevent the storage bag B2 from being stored. Further, a heating bag 6 as a flexible accommodating means capable of accommodating the dialysate flowing in the dialysate introduction line L1 is connected to the dialysate introduction line L1, and the heating is performed during the correction step. Since the dialysate in the dialysate accommodating bag B1 can be accommodated in the bag 6, it is possible to prevent the fluid that has flowed due to the rotational drive of the dialysate pump P2 from flowing to the blood circuit 1 side.

In particular, since the heating bag 6 as an accommodating means is flexible, the heating bag 6 can be expanded according to the flow rate of the liquid flowed by the rotational drive of the dialysate pump P2, and resistance when the liquid flows. It is possible to suppress the occurrence of (flow resistance), and it is possible to correct the rotational speed of the dialysate pump P2 more accurately. Further, since the accommodating means includes a heating bag 6 for heating the dialysate flowing through the dialysate introduction line L1 during the blood purification treatment, the heating bag 6 required for the blood purification treatment is used for dialysis. The fluid that has flowed by the rotational drive of the liquid pump P2 can be accommodated. In addition, during the correction step, the control unit 7 discharges the liquid in the heating bag 6 before rotationally driving the dialysate pump P2, and supplies the liquid that flows by the rotational drive (forward rotation drive) of the dialysate pump P2. Since the capacity for accommodating can be secured, the liquid flowed by the rotational drive of the dialysate pump P2 can be more reliably accommodated in the heating bag 6.

After the correction steps according to the first and second embodiments, the dialysate pump P2 and the drainage pump P3 are simultaneously driven, and the rotation speed of the drainage pump P3 is based on the change in the measured value of the weighing scale 4. To correct. That is, since the dialysate pump P2 is in a state where there is no flow error (or the flow error is small) due to its drive, the error detected based on the change in the measured value of the weighing scale 4 is excluded. It can be determined that the error is in the liquid pump P3, and the drainage pump P3 can be corrected.

However, the correction steps according to the first and second embodiments are supposed to be performed before the blood purification treatment (after the completion of priming), so that the blood purification treatment can be started immediately. In addition, the correction step is performed during blood purification treatment (while the patient is pierced with a puncture needle attached to the tip of the arterial blood circuit 1a and the venous blood circuit 1b and the patient's blood is circulated extracorporeally by the blood circuit 1). In this case, even if the characteristics of the dialysate pump P2 change during the blood purification treatment, the rotation speed of the dialysate pump P2 can be corrected.

Although the present embodiment has been described above, the present invention is not limited to these. For example, during the correction step, the dialysate pump P2 is rotationally driven to accommodate the dialysate in the dialysate storage bag B1 in the drainage storage bag B2. If the rotation speed of the dialysate pump P2 can be corrected based on the change in the measured value of the weighing scale 4 in the process, the drainage pump P3 is driven during the correction step. May be.

Further, after the control unit 7 calculates a correction value of the rotation speed of the dialysate pump P2 (including a value related to the rotation speed), the rotation speed of the dialysate pump P2 is manually corrected based on the correction value. You may do so. In addition, it is preferable to notify the correction value or the like (including the rotation speed or the like corrected based on the correction value) by the notification means. Examples of the notification means include a display device that displays a correction value, etc., a voice output device that outputs a correction value, etc. as voice, and when the actual rotation speed of the dialysate pump P2 matches the corrected rotation speed, or Examples include lamps that turn on or off when they do not match. In such an embodiment, it is possible to exert the effect of being able to support (assist) the accurate correction of the dialysate pump P2 manually.

Further, in the first embodiment, a solenoid valve or the like may be connected to the replacement fluid line L3 so that the solenoid valve is opened during the correction step, and in the second embodiment, heating may be performed. Instead of the bag 6, another flexible storage means (that is, a storage container that can be expanded according to the flow rate of the dialysate) may be connected to the dialysate introduction line L1. The blood purification treatment to be applied is not limited to dialysis treatment, and may be another treatment that purifies the patient's blood while circulating it extracorporeally.

The dialysate pump is rotationally driven to allow the dialysate in the dialysate storage bag to flow without being stored in the drainage storage bag, and the rotational speed of the dialysate pump is based on the change in the measured value of the weighing scale in the process. Alternatively, as long as it is a blood purification device provided with a control unit capable of calculating a correction value of a value related to the rotation speed, another function may be added.

1 Blood circuit 1a Arterial blood circuit 1b Venous blood circuit 2 Dializer (blood purification means)
3 Air trap chamber 4 Weighing scale 5 Clamping means 6 Heating bag (accommodating means)
7 Control unit h Heating means L1 dialysate introduction line L2 dialysate discharge line L3 replacement fluid line P1 blood pump P2 dialysate pump P3 drainage pump

Claims (12)

A blood circuit that has an arterial blood circuit and a venous blood circuit and can circulate the patient's blood extracorporeally from the tip of the arterial blood circuit to the tip of the venous blood circuit.
A blood purification means that is interposed between the arterial side blood circuit and the venous side blood circuit of the blood circuit and can purify the blood flowing through the blood circuit.
A dialysate introduction line for introducing dialysate into the blood purification means, a dialysate discharge line for draining drainage from the blood purification means, and the like.
A dialysate pump consisting of an ironing pump arranged on the dialysate introduction line and capable of flowing the dialysate of the dialysate introduction line by rotationally driving the dialysate pump.
A dialysate storage bag connected to the tip of the dialysate introduction line and containing the dialysate to be introduced into the blood purification means.
A drainage pump composed of an ironing type pump arranged in the dialysate discharge line and capable of flowing the drainage of the dialysate discharge line by rotationally driving the dialysate discharge line.
A drainage storage bag that is connected to the tip of the dialysate discharge line and can store the drainage discharged from the blood purification means.
A single weigh scale capable of measuring the total weight of the dialysate storage bag and the drainage storage bag, and
A control unit capable of controlling the dialysate pump and the drainage pump based on the measured values of the weighing scale, and
In a blood purification device equipped with
The control unit rotates the dialysate pump to flow the dialysate in the dialysate accommodating bag without accommodating it in the drainage accommodating bag, and based on the change in the measured value of the weighing scale in the process. Therefore, a correction value of a value related to the rotation speed or rotation speed of the dialysate pump can be calculated, and a value related to the rotation speed or rotation speed of the dialysate pump is corrected based on the calculated correction value. During the correction step, the dialysate in the dialysate storage bag is made to flow into the blood circuit, and the dialysate introduction line is flexible enough to accommodate the dialysate flowing through the dialysate introduction line. The accommodating means is connected, and the accommodating means is configured to accommodate the dialysate in the dialysate accommodating bag during the correction step, and the control unit is configured to accommodate the dialysate during the correction step. A blood purification apparatus characterized in that a capacity for accommodating a liquid flowing by the rotational drive of the dialysate pump can be secured by discharging the liquid in the accommodating means before the pump is rotationally driven. A blood circuit that has an arterial blood circuit and a venous blood circuit and can circulate the patient's blood extracorporeally from the tip of the arterial blood circuit to the tip of the venous blood circuit.
A blood purification means that is interposed between the arterial side blood circuit and the venous side blood circuit of the blood circuit and can purify the blood flowing through the blood circuit.
A dialysate introduction line for introducing dialysate into the blood purification means, a dialysate discharge line for draining drainage from the blood purification means, and the like.
A dialysate pump consisting of an ironing pump arranged on the dialysate introduction line and capable of flowing the dialysate of the dialysate introduction line by rotationally driving the dialysate pump.
A dialysate storage bag connected to the tip of the dialysate introduction line and containing the dialysate to be introduced into the blood purification means.
A drainage pump composed of an ironing type pump arranged in the dialysate discharge line and capable of flowing the drainage of the dialysate discharge line by rotationally driving the dialysate discharge line.
A drainage storage bag that is connected to the tip of the dialysate discharge line and can store the drainage discharged from the blood purification means.
A single weigh scale capable of measuring the total weight of the dialysate storage bag and the drainage storage bag, and
A control unit capable of controlling the dialysate pump and the drainage pump based on the measured values of the weighing scale, and
In a blood purification device equipped with
The control unit rotates the dialysate pump to allow the dialysate in the dialysate storage bag to flow without being stored in the drainage storage bag, and is based on a change in the measured value of the weighing scale in the process. Therefore, a correction value of a value related to the rotation speed or rotation speed of the dialysate pump can be calculated, and a value related to the rotation speed or rotation speed of the dialysate pump is corrected based on the calculated correction value. During the correction step, the dialysate in the dialysate storage bag is made to flow into the blood circuit, and the dialysate introduction line is flexible enough to store the dialysate flowing through the dialysate introduction line. The accommodating means is connected and is configured so that the accommodating means can accommodate the dialysate in the dialysate accommodating bag during the correction step, and the accommodating means is configured to accommodate the dialysate during the blood purification treatment. A blood purification device comprising a heating bag for heating the dialysate flowing through the introduction line. The claim is characterized in that, after the correction step, the control unit simultaneously drives the dialysate pump and the drainage pump, and corrects the drainage pump based on a change in the measured value of the weighing scale. The blood purification device according to claim 1 or 2. The invention according to any one of claims 1 to 3, further comprising a blood pump composed of an ironing type pump disposed in the arterial blood circuit, and stopping the blood pump during the correction step. Blood purification device. The blood purification apparatus according to any one of claims 1 to 4 , wherein the dialysate in the dialysate storage bag can be flowed to the venous blood circuit via the blood purification means. It has a replacement fluid line capable of communicating a predetermined site of the venous blood circuit and a dialysate introduction line, and during the correction step, the dialysate in the dialysate storage bag is passed through the replacement fluid line to the venous blood circuit. The blood purification apparatus according to any one of claims 1 to 4 , wherein the blood purifying device can be flowed into a blood purifying apparatus. The blood purification apparatus according to claim 5 or 6 , wherein a storage bag capable of storing a liquid is connected to the tip of the venous blood circuit during the correction step. The blood purification apparatus according to any one of claims 1 to 7 , wherein the correction step is performed before the blood purification treatment. The blood purification apparatus according to any one of claims 1 to 7 , wherein the correction step is performed during blood purification treatment. Any of claims 1 to 9 , wherein the control unit corrects and controls the rotation speed of the dialysate pump based on an error between the measured value and the theoretical value of the weighing scale during the correction step. The blood purification device according to one. The control unit drives the dialysate pump at a plurality of rotation speeds during the correction step, and based on the change in the measured value of the weighing scale acquired at each rotation speed, the rotation speed of the dialysate pump. The blood purification apparatus according to any one of claims 1 to 10 , wherein a correction value can be set according to the above. The characteristic data of the flow rate change rate with respect to the total rotation speed of the dialysate pump is stored in advance, and the control unit sets a correction value according to the rotation speed of the dialysate pump based on the characteristic data at the time of the correction step. The blood purification apparatus according to any one of claims 1 to 10 , wherein the blood purification apparatus can be used.

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