JP2023119235A - Blood purification device - Google Patents

Abstract

To improve workability in attaching a conduit line.SOLUTION: In a blood purification device 1, a first valve 1V is provided in a dialysis fluid conduit line 110 and opens/closes the dialysis fluid conduit line 110. A second valve 2V is provided in a drainage conduit line 120 and opens/closes the drainage conduit line 120. A cover 210 covers at least part of the dialysis fluid conduit line 110, at least part of the drainage conduit line 120, the first valve 1V and the second valve 2V in a closed state. A control part 420 brings the first valve 1V and the second valve 2V into an open state when a signal on a change in the cover 210 from a closed state to an open state is input by a detection part 410, and brings the first valve 1V and the second valve 2V into a closed state when a signal on a change in the cover 210 from an open state to a closed state is input by the detection part 410.SELECTED DRAWING: Figure 1

Description

The present invention relates to a blood purification device.

A blood purification apparatus includes a conduit for flowing medical fluids. For example, International Publication No. WO 2013/047185 (Patent Document 1) discloses a device attached with a pipeline for flowing a medical fluid.

WO2013/047185

In a blood purification system, conduits for various liquids are attached to the valves of the blood purification system prior to initiation of treatment. When installing the pipeline, the valve must be in an open state. After the conduit is attached to the valve, the valve is closed, and then a bag containing a predetermined liquid such as physiological saline is attached to the conduit. If the bag is attached to the pipeline while the valve is open, so-called free flow occurs, in which the liquid unintentionally flows into the pipeline. As described above, in the conventional blood purification apparatus, the valve operation performed at the time of attaching the pipeline was complicated.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a blood purification apparatus capable of improving the workability of installing a pipe line.

A blood purification apparatus according to the present invention comprises a blood purifier, a dialysate line, a drain line, a first valve, a second valve, a main body, a cover, a detector, and a controller. It has A dialysate line supplies dialysate to the blood purifier. The drainage line carries drainage discharged from the blood purifier. The first valve is provided in the dialysate line and opens and closes the dialysate line. The second valve is provided in the drainage pipeline and opens and closes the drainage pipeline. The body portion has one side surface, and the first valve and the second valve are attached to the one side surface. The cover is attached to cover at least a portion of one side surface of the main body so as to be openable and closable. The cover covers at least part of the dialysate line, at least part of the drain line, the first valve, and the second valve in the closed state. The detector can detect whether the cover is open or closed. The controller is electrically connected to each of the detector, the first valve, and the second valve. The control unit opens each of the first valve and the second valve when a signal indicating that the cover has changed from the closed state to the open state is input from the detection unit, and the cover is closed from the open state by the detection unit. Each of the first valve and the second valve is closed when a signal regarding the state change is input.

In one aspect of the present invention, the blood purification device further includes an arterial blood circuit, a venous blood circuit, a replacement fluid line, and a third valve. The arterial blood circuit is a circuit that is connected to a blood purifier and allows blood to flow into the blood purifier. The venous blood circuit is a circuit that is connected to a blood purifier and allows blood to flow out from the blood purifier. The replacement fluid line is connected to the arterial blood circuit or the venous blood circuit to supply replacement fluid. The third valve is provided in the replacement fluid channel and opens and closes the replacement fluid channel. A third valve is further attached to one side of the main body. The cover covers at least part of the replacement fluid line and the third valve in the closed state. The controller is further electrically connected to the third valve. The control unit opens the third valve when a signal indicating that the cover has changed from the closed state to the open state is input from the detection unit, and the detection unit indicates that the cover has changed from the open state to the closed state. When the signal is input, the third valve is closed.

In one aspect of the present invention, the blood purification device further comprises a connection line, a weighing bag and a fourth valve. The connection line is connected upstream of the second valve in the drain line. The measuring bag is connected to the end of the connection conduit opposite to the drainage conduit side, and is capable of temporarily storing the drainage. The fourth valve is provided in the connecting pipeline and opens and closes the connecting pipeline. A fourth valve is further attached to one side surface of the main body. The cover covers at least a portion of the connection pipeline and the fourth valve in the closed state. The controller is further electrically connected to the fourth valve. The control unit opens the fourth valve when a signal indicating that the cover has changed from the closed state to the open state is input from the detection unit, and the detection unit indicates that the cover has changed from the open state to the closed state. When the signal is input, the fourth valve is closed.

According to the present invention, it is possible to improve the workability of installing pipelines.

1 is a circuit diagram showing the configuration of a blood purification device according to one embodiment of the present invention; FIG. 1 is a side view of a blood purification device according to one embodiment of the present invention, viewed from one direction; FIG. FIG. 2 is a side view of the blood purification apparatus according to one embodiment of the present invention when the cover is closed, viewed from one direction. FIG. 4 is a perspective view showing a state in which each of the first to fourth valves is in a closed state in one embodiment of the present invention; FIG. 4 is a perspective view showing a state in which each of the first to fourth valves is in an open state in one embodiment of the present invention; 1 is a block diagram showing the electrical relationship of the configuration of a blood purification apparatus according to one embodiment of the present invention; FIG.

A blood purification apparatus according to an embodiment of the present invention will be described below with reference to the drawings. In the following description of the embodiments, the same or corresponding parts in the drawings are denoted by the same reference numerals, and the description thereof will not be repeated.

In the description of the embodiments below, a blood purification device used for continuous renal replacement therapy (CRRT) will be described as a blood purification device. However, blood purification devices include continuous hemodiafiltration (CHDF), continuous hemofiltration (CHF), continuous hemodialysis (CHD), and continuous slow hemodialysis. It may be a blood purifying device used for any of external filtration (Slow Continuous UltraFiltration: SCUF).

First, the circuit of the blood purification apparatus according to this embodiment will be mainly described. FIG. 1 is a circuit diagram showing the configuration of a blood purification device according to one embodiment of the present invention. As shown in FIG. 1, the blood purification apparatus 1 according to this embodiment includes a blood purifier 100, a dialysate line 110, a drain line 120, an arterial blood circuit 130, and a venous blood circuit 140. , a replacement fluid line 150, a (first) connecting line 160, a (first) weighing bag 165, a second connecting line 170, a second weighing bag 175, a scale 180, and a syringe pump 190. , a first valve 1V, a second valve 2V, a third valve 3V and a fourth valve 4V.

Blood purifier 100 contains a semi-permeable membrane made of, for example, a hollow fiber membrane. Blood purifier 100 has dialysate inlet 101 , drain outlet 102 , blood inlet 103 and blood outlet 104 .

Dialysate line 110 is connected to dialysate inlet 101 of blood purifier 100 and supplies dialysate to blood purifier 100 . The upstream end of the dialysate line 110 is connected to a first source 115 that supplies the first liquid 10, which is the replacement fluid and the dialysate. A dialysate pump 111 that pumps out the dialysate is connected to the dialysate line 110 . The dialysate pump 111 is a peristaltic pump, but may be a roller pump. A first heater 112 that heats the dialysate is provided in the dialysate line 110 downstream of the dialysate pump 111 . Note that the first heater 112 may not be provided. The dialysate that has flowed through the dialysate line 110 is supplied into the blood purifier 100 . It should be noted that dialysate line 110 and other lines described below are flexible tubes made of, for example, polyvinyl chloride or polybutadiene.

The drainage pipe line 120 is connected to the drainage outlet 102 of the blood purifier 100 and allows the drainage discharged from the drainage outlet 102 of the blood purifier 100 to flow. Drainage discharged from the blood purifier 100 is discharged from the downstream end of the drainage conduit 120 . A drainage pump 121 is connected to the drainage pipeline 120 to pump out the drainage flowing through the drainage pipeline 120 . The drainage pump 121 is a peristaltic pump, but may be a roller pump. The drainage pipe 120 is provided with a drainage pressure measuring device 122 for measuring the pressure in the drainage pipe 120 on the upstream side of the drainage pump 121 .

Arterial blood circuit 130 is a circuit that is connected to blood inlet 103 of blood purifier 100 and allows blood to flow into blood purifier 100 . The arterial blood circuit 130 is provided with a blood pump 131 that pumps out blood. An arterial air trap chamber 132 is provided between the blood pump 131 and the blood purifier 100 in the arterial blood circuit 130 . The arterial air trap chamber 132 is provided with an arterial pressure measuring device 133 for measuring the pressure inside the arterial air trap chamber 132 . The arterial blood circuit 130 is provided with an arterial opening/closing valve 135 that opens and closes the arterial blood circuit 130 .

Blood collected from the patient's artery flows through the arterial blood circuit 130 and is pressure-measured as it passes through the arterial air trap chamber 132 before flowing into the blood purifier 100 through the blood inlet 103 . The arterial air trap chamber 132 is provided to prevent air from entering the blood in the arterial blood circuit 130 .

A priming fluid line 136 is further connected to the arterial blood circuit 130 . The priming liquid line 136 is connected between the arterial side on-off valve 135 and the blood pump 131 in the arterial blood circuit 130 to supply the priming liquid 20 . A priming liquid valve 137 that opens and closes the priming liquid line 136 is provided in the priming liquid line 136 . The priming liquid 20 is physiological saline or the like.

An airless monitor 138 is further connected to the arterial blood circuit 130 . Specifically, the airless monitor 138 is connected between the blood pump 131 and the connection to the priming liquid line 136 in the arterial blood circuit 130 . A blood pressure measuring device 139 is connected to the airless monitor 138 to measure the patient's blood pressure flowing into the arterial blood circuit 130 .

Venous blood circuit 140 is a circuit that is connected to blood outlet 104 of blood purifier 100 and causes blood to flow out from blood purifier 100 . A venous air trap chamber 141 is provided in the venous blood circuit 140 . The venous air trap chamber 141 is provided with a venous pressure measuring device 142 for measuring the pressure inside the venous air trap chamber 141 . The venous blood circuit 140 is provided with a venous on-off valve 144 for opening and closing the venous blood circuit 140 .

Blood purified by blood purifier 100 is pressure-measured as it flows through venous blood circuit 140 and through venous air trap chamber 141 before being returned to the patient's vein. The venous air trap chamber 141 is provided to prevent air from entering the blood in the venous blood circuit 140 .

The replacement fluid line 150 is connected to the arterial blood circuit 130 or the venous blood circuit 140 to supply replacement fluid. In this embodiment, the replacement fluid line 150 is connected to the venous blood circuit 140 and supplies the venous blood circuit 140 with the first fluid 10 as a replacement fluid. That is, the blood purification apparatus 1 in this embodiment employs a so-called post-dilution method. Specifically, the replacement fluid line 150 is connected to the venous air trap chamber 141 . The replacement fluid that has flowed through the replacement fluid line 150 is supplied into the venous air trap chamber 141 . It should be noted that the blood purification apparatus 1 can also be applied by a so-called predilution method. When the predilution method is employed, the replacement fluid line 150 is connected to the arterial blood circuit 130 .

A replacement fluid pump 151 that pumps out replacement fluid is connected to the replacement fluid line 150 . The replacement fluid pump 151 is a peristaltic pump, but may be a roller pump. A second heater 152 that heats the replacement fluid is provided downstream of the replacement fluid pump 151 in the replacement fluid line 150 . Note that the second heater 152 may not be provided.

The first connection line 160 is connected to the drainage line 120 . Specifically, the first connection pipeline 160 is connected downstream of the drainage pump 121 in the drainage pipeline 120 . The first measuring bag 165 is connected to the end of the first connection pipe 160 opposite to the drainage pipe 120 side, temporarily stores the drainage, and can deliver the stored drainage. be. The first weighing bag 165 is a soft bag that does not have air vent holes.

The second connection line 170 is connected to the replacement fluid line 150 . Specifically, the second connection line 170 is connected to the replacement fluid line 150 upstream of the replacement fluid pump 151 . The second measuring bag 175 is connected to the end of the second connection conduit 170 opposite to the replacement fluid conduit 150 side, and temporarily stores the first liquid 10 (as the replacement fluid). A first fluid 10 (as replacement fluid) can be delivered. The second weighing bag 175 is a soft bag that does not have air vent holes.

The scale 180 has a mounting portion 181 and a measuring portion (not shown). A first weighing bag 165 and a second weighing bag 175 are attached to the attachment portion 181 . The measuring section is connected to the mounting section 181 and measures the weight change of the entire first weighing bag 165 and the second weighing bag 175 attached to the mounting section 181 . In this embodiment, scale 180 is a load cell. However, the scale 180 is not limited to a load cell, and may be a spring scale or the like.

A syringe pump 190 is connected to the arterial blood circuit 130 via a syringe pump line 191 . Specifically, the syringe pump line 191 is connected upstream of the arterial opening/closing valve 135 in the arterial blood circuit 130 . Syringe pump 190 supplies drug solution 30 into arterial blood circuit 130 . The drug solution 30 is, for example, an anticoagulant such as heparin or nafamostat.

The first valve 1V is provided in the dialysate line 110 and opens and closes the dialysate line 110 . Specifically, the first valve 1V is provided in the dialysate line 110 upstream from the connection position with the replacement liquid line 150 .

The second valve 2V is provided in the drainage pipeline 120 and opens and closes the drainage pipeline 120 . Specifically, the second valve 2V is provided downstream of the connection position with the first connecting line 160 in the drain line 120 . That is, the first connection pipe 160 is connected to the drainage pipe 120 upstream of the second valve 2V.

The third valve 3V is provided in the replacement fluid channel 150 and opens and closes the replacement fluid channel 150 . The third valve 3V is provided on the upstream side of the connection position with the second connecting line 170 in the replacement fluid line 150 .

The fourth valve 4V is provided in the first connection pipeline 160 and opens and closes the first connection pipeline 160 . When the fourth valve 4V closes the first connecting line 160, the measuring section of the scale 180 can measure the weight change of the second weighing bag 175. FIG.

Next, the device configuration of the blood purification device 1 will be mainly described. FIG. 2 is a side view of the blood purification device according to one embodiment of the present invention, viewed from one direction. As shown in FIG. 2, the blood purification device 1 according to this embodiment further includes a main body 200 and a cover 210 . The main body part 200 has one side surface 201 to which a first valve 1V, a second valve 2V, a third valve 3V and a fourth valve 4V are attached.

A scale 180 is incorporated in the body portion 200 , and the mounting portion 181 is positioned to face the same side as the one side surface 201 in the body portion 200 . The mounting portion 181 is positioned so as to form substantially the same plane as the one side surface 201 . The mounting portion 181 is located above the first valve 1V, the second valve 2V, the third valve 3V and the fourth valve 4V. Therefore, the first weighing bag 165 and the second weighing bag 175 are also positioned above the first valve 1V, the second valve 2V, the third valve 3V and the fourth valve 4V.

A first housing portion 202 and a second housing portion 203 are further attached to one side surface 201 of the body portion 200 . The dialysate pump 111 , the drainage pump 121 and the replacement fluid pump 151 are housed in the first housing portion 202 . As a result, various pumps can be prevented from coming into contact with other articles or people. The first housing portion 202 is positioned substantially horizontally when viewed from the first valve 1V, the second valve 2V, the third valve 3V, and the fourth valve 4V. The second housing portion 203 houses the first heater 112 and the second heater 152 . As a result, the heat of various heaters can be suppressed from escaping to the outside of the blood purification apparatus 1, and the thermal efficiency of the various heaters can be improved.

FIG. 3 is a side view of the blood purification apparatus according to one embodiment of the present invention when the cover is closed, viewed from one direction. As shown in FIGS. 2 and 3, the cover 210 is attached to cover at least a portion of one side surface 201 of the main body 200 so as to be openable and closable. Cover 210 is attached to body portion 200 by, for example, a hinge. Note that FIG. 2 shows the blood purification apparatus 1 when the cover 210 is open.

When the main body 200 is viewed from the one side 201 side, the cover 210 covers at least part of the dialysate line 110, at least part of the drain line 120, and at least part of the replacement liquid line 150 in the closed state. a portion, at least a portion of the first connection pipeline 160 (specifically, the entire first connection pipeline 160), the first weighing bag 165, and at least a portion of the second connection pipeline 170 (specifically, Specifically, the entire second connection pipe 170), the second weighing bag 175, the mounting portion 181 of the scale 180, the first valve 1V, the second valve 2V, the third valve 3V, the fourth valve It covers the valve 4V and the first container 202 (ie the dialysate pump 111, the drain pump 121 and the replacement fluid pump 151).

By covering the first valve 1V, the second valve 2V, the third valve 3V, and the fourth valve 4V with the cover 210, contact of the operator and the patient with each valve in operation is suppressed. safer for In addition, by covering the entirety of the first connection line 160, the first weighing bag 165, the entirety of the second connection line 170, and the mounting portion 181 of the scale 180 with the cover 210, the blood purification apparatus 1 can be operated. At times, the weight of the first weighing bag 165 and the second weighing bag 175 can be measured more accurately because the operator or patient can be prevented from touching these bags and scales. Covering the first storage unit 202 (that is, the dialysate pump 111, the drainage pump 121, and the replacement fluid pump 151) with the cover 210 makes it safer for the operator or the patient who operates the blood purification apparatus 1 even when the pumps are in operation. is.

It should be noted that the second housing portion 203 is attached to the one side surface 201 at a position where it is not covered by the cover 210 even when the cover 210 is in the closed state. As a result, it is possible to prevent the heat from the first heater 112 and the second heater 152 housed in the second housing portion 203 from remaining excessively in the cover 210 when the cover 210 is in the closed state.

The cover 210 further has a light transmission panel 211 so that the inside of the cover 210 can be visually recognized from the outside of the cover 210 through the light transmission panel 211 even when the cover 210 is closed. When blood purification apparatus 1 is viewed from side 201 with cover 210 closed, light transmission panel 211 is positioned so that at least first weighing bag 165 and second weighing bag 175 are visible from the outside. positioned.

The cover 210 is further formed with a first notch 212 and a second notch 213 . When blood purification apparatus 1 is viewed from side 201 , first notch 212 is located on the side of cover 210 . In the closed state of the cover 210, the portion of the dialysate duct 110 on the downstream side when viewed from the dialysate pump 111 and the portion of the replacement fluid duct 150 on the downstream side when viewed from the replacement fluid pump 151 are formed into the first notch. It is arranged to face the hole formed by the portion 212 and one side surface 201 . As a result, the dialysate line 110 and the replacement liquid line 150 can be easily inserted through the hole formed by the first notch 212 and the one side surface 201 .

Second notch 213 is located below cover 210 when blood purification apparatus 1 is viewed from side 201 . A guide portion 214 is further provided on one side surface 201 , and a portion of the drainage pipe line 120 on the upstream side as viewed from the drainage pump 121 is fixed to the guide portion 214 . In addition, the guide portion 214 allows the portion of the drainage pipe 120 on the upstream side as seen from the drainage pump 121 to be directed downward as the distance from the drainage pump 121 increases. As a result, when the cover 210 is closed, the upstream portion of the drainage pipe 120 from the drainage pump 121 faces the hole formed by the second notch 213 and the one side surface 201 . placed. As a result, the drainage pipe line 120 can be easily inserted into the hole formed by the second notch 213 and the one side surface 201 . In the closed state of the cover 210, the portion of the dialysate duct 110 on the upstream side when viewed from the first valve 1V and the portion of the drain duct 120 on the downstream side when viewed from the second valve 2V are also , facing the hole formed by the second notch 213 and the one side surface 201 .

As described above, for each of the three lines that extend directly from each pump, the dialysate line 110 and the replacement fluid pump 151 extend outward from the first notch 212, and the drain line 120 extends outward from the second notch 213. Take out. As a result, it is possible to prevent workers from mistaking these pipelines.

In addition, among the configurations of the blood purification apparatus 1, those attached to the one side surface 201 are not limited to the configurations described above. In this embodiment, the configuration of the blood purification apparatus 1 other than the configuration described above may be attached to another side surface or upper surface of the main body 200, or may be a component separate from the main body 200. good.

FIG. 4 is a perspective view showing a state in which each of the first to fourth valves is closed in one embodiment of the present invention. FIG. 5 is a perspective view showing a state in which each of the first to fourth valves is open in one embodiment of the present invention. In the following, the detailed structure of the first valve 1V will be explained. Regarding the second valve 2V, the third valve 3V, and the fourth valve 4V, the same reference numerals will be given to the same structures as the first valve 1V, and the explanation will be given. is not repeated.

As shown in FIGS. 4 and 5, the first valve 1V includes an open end portion 310, a plate-like portion 320, a connecting portion 330, and a biasing portion 340. As shown in FIGS.

The open end portion 310 has a substantially rectangular outer shape when the main body portion 200 is viewed from one side surface 201 . The open end portion 310 is provided on the one side surface 201 and forms a substantially rectangular opening 311 on the one side surface 201 .

The plate-like portion 320 has a substantially rectangular outer shape when the body portion 200 is viewed from one side surface 201 . The plate-like portion 320 is positioned to face the opening 311 while being separated from the opening end 310 .

The connection portion 330 connects the open end portion 310 and the plate-like portion 320 . The plate-like portion 320 extends in the vertical direction, and connects only one side of the opening end portion 310 and only one side of the plate-like portion 320 when the main body portion 200 is viewed from the one side surface 201 side. This facilitates attachment of the dialysate line 110 to the first valve 1V.

At least a portion of the biasing portion 340 is positioned inside the opening 311 . The biasing portion 340 is configured to be movable along the facing direction of the opening 311 and the plate-like portion 320 by a drive mechanism such as an air cylinder or an actuator. Also, the dialysate line 110 is arranged between the opening 311 and the plate-like portion 320 . The biasing portion 340 is configured to be able to bias the dialysate conduit 110 arranged at the above position in the direction from the opening 311 toward the plate-like portion 320 . When the urging portion 340 urges the dialysate line 110 against the plate-like portion 320, the first valve 1V is in a closed state in which the dialysate line 110 is closed. Then, the urging portion 340 is relatively moved away from the plate-like portion 320 , thereby releasing the urging of the dialysate line 110 by the urging portion 340 . At this time, the first valve 1V is in an open state to open the dialysate line 110 .

The dialysate line 110 in the first valve 1V corresponds to the drainage line 120, the replacement fluid line 150 and the first connection line 160 in the second valve 2V, the third valve 3V and the fourth valve 4V, respectively. do.

Next, control of the blood purification device 1 will be mainly described. FIG. 6 is a block diagram showing the electrical relationship of the configuration of the blood purification apparatus according to one embodiment of the present invention. As shown in FIG. 6, the blood purification device 1 according to this embodiment further includes a detection section 410 and a control section 420 . As shown in FIGS. 2, 3 and 6, detection unit 410 can detect whether cover 210 is open or closed. In this embodiment, the detector 410 is provided on the main body 200 side, but may be provided on the cover 210 . Moreover, the specific type of the detection unit 410 is not particularly limited. In this embodiment, the detection unit 410 is a magnetic sensor, more specifically, a Hall element. A magnet (not shown) is provided on the cover 210 at a position corresponding to the detection unit 410 . Accordingly, detection unit 410 , which is a magnetic sensor, can detect the open/closed state of cover 210 by detecting the magnet of cover 210 . Note that the detection unit 410 may be, for example, a distance sensor. Examples of distance sensors include reflective photoelectric sensors, capacitance sensors, and ultrasonic sensors.

The control unit 420 is electrically connected to each of the detection unit 410, the first valve 1V, the second valve 2V, the third valve 3V and the fourth valve 4V. In this embodiment, the controller 420 may also be electrically connected to other valves, various pumps, the scale 180, etc. in the blood purification apparatus 1 . Control unit 420 has, for example, a CPU (Central Processing Unit) and a memory (both not shown). Accordingly, a signal for opening or closing the first valve 1V, the second valve 2V, the third valve 3V, and the fourth valve 4V is input. The CPU may be implemented as a CPU of a microcomputer.

Control unit 420 detects that cover 210 has changed from the closed state to the open state by detection unit 410 when blood purification apparatus 1 is not performing blood purification and is in the preparation mode for attaching each duct. When a signal relating to this is input, each of the first valve 1V, the second valve 2V, the third valve 3V, and the fourth valve 4V is opened, and the cover 210 is changed from the open state to the closed state by the detector 410. Each of the first valve 1V, the second valve 2V, the third valve 3V and the fourth valve 4V is closed when a signal relating to the action is input. Specifically, the memory of the control unit 420 stores a program for transmitting an opening/closing signal to each valve based on the input signal from the detection unit 410 as described above.

As described above, in the blood purification apparatus 1 according to this embodiment, the first valve 1V is provided in the dialysate line 110 and opens and closes the dialysate line 110 . The second valve 2V is provided in the drainage pipeline 120 and opens and closes the drainage pipeline 120 . In the closed state, the cover 210 covers at least part of the dialysate line 110, at least part of the drain line 120, the first valve 1V, and the second valve 2V. Then, when a signal indicating that the cover 210 has changed from the closed state to the open state is input from the detection unit 410, the control unit 420 opens each of the first valve 1V and the second valve 2V. When a signal indicating that the cover 210 has changed from the open state to the closed state is input from 410, each of the first valve 1V and the second valve 2V is closed.

According to the above configuration, it is possible to improve the workability of attaching the dialysate line 110 and the drain line 120 . This work will be described below.

First, when the dialysate line 110 is attached to the first valve 1V and the drain line 120 is attached to the second valve 2V, the operator opens the cover 210 from the closed state. When the cover 210 is changed from the closed state to the open state, the control unit 420 opens the first valve 1V and the second valve 2V, so that the valve opening operation by the operator is omitted. After attaching the dialysate line 110 to the first valve 1V and the drain line 120 to the second valve 2V, the operator closes the cover 210 . When the cover 210 is closed, the control unit 420 closes the first valve 1V and the second valve 2V, so that the valve closing operation by the operator is omitted. Further, when a bag containing dialysate is attached to the dialysate line 110 after this, the free flow to the dialysate line 110 and the drain line 120 is suppressed. As described above, in the blood purification apparatus 1 according to the present embodiment, workability in attaching the dialysate line 110 and the drain line 120 is improved.

Further, in the blood purification apparatus 1 according to this embodiment, the third valve 3V is provided in the replacement fluid pipeline 150 and opens and closes the replacement fluid pipeline 150 . The cover 210 covers at least part of the replacement fluid line 150 and the third valve 3V in the closed state. Then, when a signal indicating that the cover 210 has changed from the closed state to the open state is input from the detection unit 410, the third valve 3V is opened, and the detection unit 410 changes the cover 210 from the open state to the closed state. The third valve 3V is closed when a signal is input.

According to the above configuration, it is possible to improve the workability of attaching the replacement fluid line 150 . This work will be described below.

First, when attaching the replacement fluid line 150 to the third valve 3V, the operator opens the cover 210 . When the cover 210 is opened, the control unit 420 opens the third valve 3V, thereby omitting the valve opening operation by the operator. After attaching the replacement fluid line 150 to the third valve 3V and attaching the replacement fluid line 150 to the third valve 3V, the operator closes the cover 210 . When the cover 210 is closed, the control unit 420 closes the third valve 3V, so that the operator's operation to close the valve is omitted. Further, when a bag containing replacement fluid is attached to the replacement fluid channel 150 after this, free flow to the replacement fluid channel 150 is suppressed. Thus, in the blood purification device 1 according to the present embodiment, workability in attaching the replacement fluid line 150 is improved.

Furthermore, in the blood purification apparatus 1 according to this embodiment, the first connection line 160 is connected to the drainage line 120 upstream of the second valve 2V. The first weighing bag 165 is connected to the end of the first connection conduit 160 opposite to the drainage conduit 120 side, and can temporarily store the drainage. The fourth valve 4V is provided in the first connection pipeline 160 and opens and closes the first connection pipeline 160 . The cover 210 covers at least a portion of the first connection line 160 and the fourth valve 4V in the closed state. Then, when a signal indicating that the cover 210 has changed from the closed state to the open state is input from the detection unit 410, the control unit 420 opens the fourth valve 4V, and the detection unit 410 opens the cover 210. The fourth valve 4V is closed when a signal relating to the change from the closed state to the closed state is input.

According to the above configuration, it is possible to improve the workability of attaching the first connection pipeline 160 . This work will be described below.

First, when attaching the first connection pipeline 160 to the fourth valve 4V, the operator opens the cover 210 . When the cover 210 is opened, the controller 420 opens the fourth valve 4V, so that the operator can omit the valve opening/closing operation. After attaching the first connection pipeline 160 to the fourth valve 4V and attaching the first connection pipeline 160 to the fourth valve 4V, the operator closes the cover 210 . When the cover 210 is closed, the controller 420 closes the fourth valve 4V, so that the operator can omit the valve opening/closing operation. Further, when a bag containing dialysate is attached to the dialysate line 110 after this, the free flow to the first connection line 160 is further suppressed. Thus, in the blood purification device 1 according to the present embodiment, workability in attaching the first connecting conduit 160 is improved.

It should be considered that the embodiments disclosed this time are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the scope of the claims rather than the above description, and is intended to include all modifications within the scope and meaning of equivalents of the scope of the claims.

1 blood purification device, 1V first valve, 2V second valve, 3V third valve, 4V fourth valve, 10 first liquid, 20 priming liquid, 30 chemical liquid, 100 blood purifier, 101 dialysate inlet, 102 drainage liquid outlet, 103 blood inlet, 104 blood outlet, 110 dialysate line, 111 dialysate pump, 112 first heater, 115 first source, 120 drain line, 121 drain pump, 122 drain pressure measuring device, 130 arterial blood circuit, 131 blood pump, 132 arterial air trap chamber, 133 arterial pressure measuring device, 135 arterial opening/closing valve, 136 priming fluid line, 137 priming fluid valve, 138 airless monitor, 139 withdrawal blood pressure measuring device , 140 venous blood circuit, 141 venous air trap chamber, 142 venous pressure measuring device, 144 venous opening/closing valve, 150 replacement fluid line, 151 replacement fluid pump, 152 second heater, 160 (first) connection line, 165 (first) weighing bag, 170 second connection line, 175 second weighing bag, 180 scale, 181 mounting part, 190 syringe pump, 191 syringe pump line, 200 body part, 201 one side surface, 202 first accommodation Part 203 Second accommodation part 210 Cover 211 Light transmission panel 212 First notch 213 Second notch 214 Guide part 310 Opening end 311 Opening 320 Plate-like part 330 Connecting part 340 biasing unit 410 detection unit 420 control unit;

Claims (3)

blood purifier and
a dialysate line that supplies dialysate to the blood purifier;
a drainage conduit for flowing the drainage discharged from the blood purifier;
a first valve provided in the dialysate line for opening and closing the dialysate line;
a second valve provided in the drainage pipeline for opening and closing the drainage pipeline;
a body having a side surface to which the first valve and the second valve are attached;
It is attached so as to be openable and closable so as to cover at least part of the one side surface of the main body, and in a closed state, at least part of the dialysate line, at least part of the drainage line, and the second dialysate line. a cover that covers the first valve and the second valve;
a detection unit capable of detecting whether the cover is open or closed;
It is electrically connected to each of the detection unit, the first valve, and the second valve, and when the detection unit inputs a signal indicating that the cover has changed from the closed state to the open state, the Each of the first valve and the second valve is opened, and when a signal indicating that the cover has changed from the open state to the closed state is input from the detection unit, the first valve and the second valve are opened. and a control unit that closes each of them. an arterial blood circuit connected to the blood purifier for allowing blood to flow into the blood purifier;
a venous blood circuit connected to the blood purifier for causing blood to flow out from the blood purifier;
a replacement fluid line connected to the arterial blood circuit or the venous blood circuit and supplying replacement fluid;
a third valve provided in the replacement fluid channel for opening and closing the replacement fluid channel;
The third valve is further attached to the one side surface of the main body,
the cover covers at least part of the replacement fluid line and the third valve in a closed state;
The control section is further electrically connected to the third valve, and opens the third valve when a signal indicating that the cover has changed from the closed state to the open state is input from the detection section. 2. The blood purification apparatus according to claim 1, wherein the third valve is closed when a signal indicating that the cover has changed from the open state to the closed state is input from the detection unit. a connection pipeline connected to the upstream side of the second valve in the drainage pipeline;
a weighing bag that is connected to the end of the connection conduit opposite to the drainage conduit side and that can temporarily store the drainage;
a fourth valve provided in the connection pipeline for opening and closing the connection pipeline;
The fourth valve is further attached to the one side surface of the main body,
the cover covers at least part of the connection pipeline and the fourth valve in a closed state;
The control section is further electrically connected to the fourth valve, and opens the fourth valve when a signal indicating that the cover has changed from the closed state to the open state is input from the detection section. 3. The blood purification according to claim 1, wherein the fourth valve is closed when a signal indicating that the cover has changed from the open state to the closed state is input from the detection unit. Device.

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