JP6933439B2 - 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 purification means of the above and a main body of an apparatus provided with various treatment means such as a blood circuit and a blood pump for performing blood purification treatment by the blood purification means. 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 puncturing the patient with the arterial puncture needle and the venous puncture needle and then driving the 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 blood purification means. Further, in dialysis treatment, a dialysate introduction line for introducing dialysate into the blood purification means and a dialysate discharge line for discharging drainage from the blood purification means are connected to the blood purification means, respectively. ..

In the blood purification device as described above, it is necessary to prime the blood circuit and the blood purification means before the blood purification treatment. Such priming is usually performed by supplying a priming solution such as a physiological saline solution to the blood circuit by driving a blood pump, and is performed in a flow path through which blood circulates outside the body in the blood circuit and in a blood purification means. This is performed by filling the flow path (blood flow path) through which blood flows and the flow path (dialysis solution flow path) through which dialysate flows with a priming solution. Since the prior art does not relate to the invention known in the literature, there is no prior art document information to be described.

The conventional blood purification device has the following problems.
The blood purification means is set so that the flow direction of the dialysate in the dialysate channel faces the blood flow direction in the blood flow path for the reason of dialysis efficiency. In addition, when air bubbles remaining in the arterial blood circuit before blood purification treatment enter the blood purification means, the outlet (blood outlet port) of the blood flow path is moved upward so that the air bubbles can easily pass upward. Blood purification treatment was being performed while holding the blood purification means.

On the other hand, when the blood outlet port is directed upward as described above, the dialysate outlet (dialysate outlet port) is located below the dialysate inlet (dialysis fluid introduction port), and the dialysate is dialyzed during priming. It becomes difficult to satisfactorily remove the air bubbles remaining in the flow path. Therefore, at the time of priming, it is necessary to make the blood outlet port face downward, and at the start of blood purification treatment, it is necessary to turn the blood purification means upside down so that the blood outlet port faces upward. , There was a problem that reversal work by medical staff was required.

The present invention has been made in view of such circumstances, and can reliably fill the blood flow path and dialysate flow path of the blood purification means with a priming solution, and is engaged in medical treatment at the start of blood purification treatment. It is an object of the present invention to provide a blood purification device capable of eliminating the need for a person to reverse the blood purification means.

The invention according to claim 1 is a blood introduction port capable of introducing blood, a blood extraction port capable of deriving blood, and a blood flow extending over the blood introduction port and the blood extraction port to allow blood to flow. A passage, a dialysate introduction port capable of introducing dialysate, a dialysate outlet port capable of deriving dialysate, a dialysate introduction port and a dialysate outlet port extending over the blood flow path. Blood purification that can purify the blood flowing through the blood flow path by interposing between the dialysate flow path capable of flowing dialysate in the direction facing the flowing blood and the blood flow path and the dialysate flow path. It has a blood purification means having a membrane, an arterial blood circuit connected to the blood introduction port of the blood purification means, and a venous blood circuit connected to the blood outlet port, and the arterial blood circuit. A blood circuit that can circulate the patient's blood extracorporeally from the tip of the blood purification means to the tip of the venous blood circuit, and a dialysate introduction line that is connected to the dialysate introduction port of the blood purification means and can introduce dialysate into the blood purification means. , And a dialysate discharge line that is connected to the dialysate outlet port of the blood purification means and can drain the drainage from the blood purification means, and the veins that are arranged in the arterial blood circuit and are arranged in the arterial blood circuit. In a blood purification device provided with a blood pump capable of circulating a patient's blood extracorporeally toward a side blood circuit, and by driving the blood pump, a priming solution is supplied to the blood circuit to enable priming. , during the filling of the priming liquid in the priming, the blood the with blood purification means is held in a derived state that the port was directed upward, said priming introduced into the blood flow path of the blood purification means from said blood inlet port The liquid is filtered through the blood purification membrane into the dialysate flow path, led out from the dialysate introduction port, and the gas replaced by the priming liquid led out from the dialysate introduction port is discharged from the dialysate introduction line. Then, the control for priming the dialysate flow path is executed.

According to the second aspect of the present invention, in the blood purification apparatus according to the first aspect, at least the tip of the arterial blood circuit among the arterial blood circuit and the venous blood circuit contains a priming solution containing the priming solution. The bag is connectable, and when the priming liquid is filled in priming, the priming liquid of the priming liquid storage bag can be supplied to the blood circuit.

The invention according to claim 3 has the replacement fluid line capable of communicating a predetermined site of the venous blood circuit and a dialysate introduction line in the blood purification apparatus according to claim 1 or 2, and the priming in priming. At the time of filling the liquid, the gas discharged from the dialysate introduction port of the blood purification means can be discharged to the venous blood circuit via the replacement fluid line.

The invention according to claim 4 has the replenishment pump according to claim 3, which is arranged in the replenishment line and can send dialysate from the dialysate introduction line to the venous blood circuit. By setting the flow rate by the replenishment pump to be equal to or lower than the flow rate by the blood pump at the time of filling the priming solution in priming, the gas discharged from the dialysate introduction port of the blood purification means is said to pass through the replenishment line. It is characterized in that it can be discharged into the blood circuit on the venous side.

The invention according to claim 5 is disposed in the blood purification apparatus according to claim 3 between the blood purification means in the venous blood circuit and the connection portion of the replacement fluid line, and arbitrarily opens and closes the flow path thereof. It has a possible opening / closing means, and when the priming liquid is filled in priming, the opening / closing means is closed and the flow path is closed, so that the gas discharged from the dialysate introduction port of the blood purification means is taken into the replacement line. It is characterized in that it can be discharged to the venous blood circuit via.

The invention according to claim 6 is the blood purification apparatus according to any one of claims 3 to 5, wherein the gas discharged into the venous blood circuit at the time of filling the priming solution in priming is the venous blood. It is characterized in that it can be collected in a collection container connected to the tip of the circuit.

The invention according to claim 7 is the blood purification apparatus according to any one of claims 3 to 5, wherein a blood circuit-side air trap chamber disposed at a connection portion with the replenishment line in the venous-side blood circuit. And an air discharge line extending from the upper part of the blood circuit side air trap chamber and capable of discharging the air in the blood circuit side air trap chamber, and the air discharge line in the blood circuit side air trap chamber. It has an air discharging means that can be discharged to the outside through the blood circuit side, and at the time of filling the priming liquid in priming, the gas discharged to the venous side blood circuit is collected by the blood circuit side air trap chamber and described as described above. It is characterized in that the air discharge means is operated so that the air can be discharged to the outside through the air discharge line.

The invention according to claim 8 includes the liquid level detecting means capable of detecting the liquid level of the air trap chamber on the blood circuit side in the blood purification device according to claim 7, and the liquid level detecting means has a predetermined height. It is characterized in that the discharge of gas by the air discharge means is stopped on condition that the liquid level is detected.

The invention according to claim 9 is the blood purification apparatus according to any one of claims 1 to 8, which is connected to the tip of the dialysate introduction line and contains the dialysate to be introduced into the blood purification means. The dialysate storage bag, the drainage storage bag connected to the tip of the dialysate discharge line and capable of storing the drainage discharged from the blood purification means, and the dialysate introduction line arranged in the dialysate. A dialysate pump that sends the dialysate from the liquid storage bag to the blood purification means and a drainage liquid that is arranged in the dialysate discharge line and discharged from the blood purification means is sent to the drainage storage bag. It is characterized by being equipped with a drainage pump.

The invention according to claim 10 reverses the dialysate pump so that the flow rate of the dialysate pump is equal to or less than the flow rate of the blood pump when the priming solution is filled in priming in the blood purification apparatus according to claim 9. By driving, the priming liquid introduced from the blood introduction port into the blood flow path of the blood purification means is filtered into the dialysate flow path through the blood purification membrane and derived from the dialysate introduction port. It is characterized in that the dialysate flow path can be primed.

The invention according to claim 11 is the dialysate-side air trap chamber disposed between the dialysate pump and the blood purification means in the dialysate introduction line in the blood purification apparatus according to claim 9 or 10. And an air discharge line extending from the upper part of the dialysate side air trap chamber and capable of discharging the air in the dialysate side air trap chamber, and the air discharge line in the dialysate side air trap chamber. It has an air discharge means that can be discharged to the outside through the dialysate, and when the priming solution is filled in priming, the gas discharged from the dialysate introduction port is collected by the dialysate side air trap chamber, and the above-mentioned It is characterized in that the air discharge means is operated so that the air can be discharged to the outside through the air discharge line.

The invention according to claim 12 includes the liquid level detecting means capable of detecting the liquid level of the dialysate side air trap chamber in the blood purification apparatus according to claim 11, and the liquid level detecting means has a predetermined height. It is characterized in that the discharge of gas by the air discharge means is stopped on condition that the liquid level is detected.

According to the invention of claim 1, when the priming liquid is filled in priming, the blood purification means is held with the blood outlet port facing upward, and the blood purification means is introduced from the blood introduction port into the blood flow path of the blood purification means. Since the priming solution was filtered into the dialysate flow path via the blood purification membrane and led out from the dialysate introduction port to enable priming of the dialysate flow path, the blood flow path and the dialysate flow path of the blood purification means were made possible. It is possible to surely fill the priming solution with the blood, and it is possible to eliminate the need for the reversing work of the blood purification means by the medical worker at the start of the blood purification treatment.

According to the invention of claim 2, a priming liquid storage bag containing a priming liquid can be connected to at least the tip of the arterial blood circuit among the arterial blood circuit and the venous blood circuit, and the priming liquid in priming Since the priming liquid of the priming liquid storage bag can be supplied to the blood circuit at the time of filling, the priming liquid on the blood circuit side can be filled more reliably and smoothly.

According to the invention of claim 3, it has a replacement fluid line capable of communicating a predetermined site of the venous blood circuit and the dialysate introduction line, and discharges the priming fluid from the dialysate introduction port of the blood purification means when the priming fluid is filled in priming. Since the generated gas can be discharged to the venous blood circuit via the replacement fluid line, more efficient priming can be performed.

According to the invention of claim 4, the fluid replacement pump is provided in the fluid replacement line and can send the dialysate from the dialysate introduction line to the blood circuit on the venous side. By setting the flow rate to be less than or equal to the flow rate of the blood pump, the gas discharged from the dialysate introduction port of the blood purification means can be discharged to the venous blood circuit via the replacement fluid line. More efficient priming can be performed.

According to the invention of claim 5, the priming liquid in priming is provided between the blood purification means in the venous blood circuit and the connection portion of the replacement fluid line, and has an opening / closing means capable of arbitrarily opening and closing the flow path. By closing the flow path with the opening / closing means closed at the time of filling, the gas discharged from the dialysate introduction port of the blood purification means can be discharged to the venous blood circuit via the replacement fluid line. The gas discharged through the line can be more reliably performed, and more efficient priming can be performed.

According to the invention of claim 6, when the priming liquid is filled in priming, the gas discharged to the venous blood circuit can be collected in the collection container connected to the tip of the venous blood circuit. When the priming liquid is filled, the gas replaced with the priming liquid can be recovered more reliably.

According to the invention of claim 7, when the priming liquid is filled in priming, the gas discharged to the blood circuit on the venous side is collected by the air trap chamber on the blood circuit side, the air discharge means is operated, and the air discharge line is operated. Since the gas can be discharged to the outside through the priming liquid, the gas replaced with the priming liquid can be reliably discharged to the outside when the priming liquid is filled by diverting the air trap chamber on the blood circuit side and the air discharging means.

According to the invention of claim 8, it is a condition that the liquid level detecting means capable of detecting the liquid level of the air trap chamber on the blood circuit side is provided and the liquid level at a predetermined height is detected by the liquid level detecting means. As a result, since the gas discharge by the air discharge means is stopped, it is possible to detect that all the priming liquid has been replaced with the gas by diverting the liquid level detection means and end the filling operation of the priming liquid. Efficient priming can be performed.

According to the invention of claim 9, it is connected to the tip of the dialysate introduction line and is connected to the dialysate storage bag containing the dialysate to be introduced into the blood purification means and the tip of the dialysate discharge line to purify the blood. A drainage storage bag capable of storing the drainage discharged from the means, a dialysate pump arranged on the dialysate introduction line and sending the dialysate of the dialysate storage bag to the blood purification means, and a dialysate discharge line. Since it is equipped with a drainage pump that sends the drainage liquid discharged from the blood purification means to the drainage storage bag, the dialysate pump or the drainage pump can be diverted to perform more efficient priming. Can be made.

According to the invention of claim 10, when the priming solution is filled in priming, the dialysate pump is reversely driven so that the flow rate of the dialysate pump is equal to or less than the flow rate of the blood pump, thereby performing blood purification means from the blood introduction port. The priming solution introduced into the blood flow path of the above was filtered into the dialysate flow path through the blood purification membrane, and was drawn out from the dialysate introduction port to enable priming of the dialysate flow path. By cooperating with a blood pump, more efficient priming can be performed.

According to the invention of claim 11, when the priming liquid is filled in priming, the gas discharged from the dialysate introduction port is collected by the dialysate side air trap chamber, the air discharge means is operated, and the air discharge line is operated. Since the gas can be discharged to the outside through the priming liquid, the gas replaced with the priming liquid can be reliably discharged to the outside when the priming liquid is filled by diverting the dialysate side air trap chamber and the air discharging means.

According to the invention of claim 12, it is a condition that the liquid level detecting means capable of detecting the liquid level of the dialysate side air trap chamber is provided and the liquid level at a predetermined height is detected by the liquid level detecting means. As a result, since the gas discharge by the air discharge means is stopped, it is possible to detect that all the priming liquid has been replaced with the gas by diverting the liquid level detection means and end the filling operation of the priming liquid. Efficient priming can be performed.

Schematic diagram which shows the blood purification apparatus which concerns on embodiment of this invention Schematic diagram showing blood purification means applied to the blood purification device Flow chart showing the process performed during priming in the blood purification device Schematic diagram showing the blood purification device (when filling with priming liquid) Schematic diagram showing the blood purification device (when filling with priming liquid) Schematic diagram showing the blood purification device (when filling with priming liquid) Schematic diagram showing the blood purification device (when filling with priming liquid) Schematic diagram showing the blood purification device (equipped with opening / closing means) Schematic diagram showing a blood purification apparatus according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be specifically described with reference to the drawings.
The blood purification device according to the present 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 circuit 1b A dialyzer 2 (blood purification means) that is interposed between the arterial blood circuit 1a and the venous blood circuit 1b to purify the blood flowing through the blood circuit 1 and the arterial blood circuit 1a. A blood pump P1 composed of an ironing type pump, a dialysate introduction line L1 and a dialysate discharge line L2, and dialysate pumps P2 and drainage arranged in these dialysate introduction lines L1 and dialysate discharge lines L2, respectively. It includes a liquid pump P3, a replenishment line L3, a replenishment pump P4 arranged on the replenishment line L3, and a control means 11. Reference numeral P in the drawing indicates a pressure 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 driven (forward rotation drive) 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 piercing the patient. ), 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. ing. Instead of puncturing the patient's blood vessel with the arterial puncture needle and venous puncture needle, a double lumen catheter is inserted into the patient's subclavian vein or femoral vein, or inserted into the patient's arm blood vessel. It may be.

Further, an air trap chamber 3 on the blood circuit side is connected in the middle of the blood circuit 1b on the venous side, and the blood circulating outside the body returns to the patient after the air bubbles are removed in the air trap chamber 3. Become. Further, a clamp means 5 is provided at the tip of the venous blood circuit 1b, and the flow path at that position can be opened or closed by arbitrarily opening and closing the clamp means 5.

Furthermore, the venous blood circuit 1b according to the present embodiment extends from the blood circuit side air trap chamber 3 arranged at the connection portion with the replacement fluid line L3 and the upper part of the blood circuit side air trap chamber 3. An air discharge line La capable of discharging the air in the blood circuit side air trap chamber 3 and an air discharge means 9 capable of discharging the air in the blood circuit side air trap chamber 3 to the outside via the air discharge line La. And is formed, and the blood circuit side air trap chamber 3 is provided with a liquid level detecting means 6 capable of detecting the liquid level of the blood circuit side air trap chamber 3.

The air discharge means 9 has a flow path communicating with the air discharge line La, the tip of the flow path is open to the atmosphere through a filter, and a solenoid valve Va and an ironing type pump are provided in the middle of the flow path. Pa is attached. Then, by driving the ironing pump Pa in the forward rotation with the solenoid valve Va in the open state, the air in the blood circuit side air trap chamber 3 is discharged to the outside to raise the liquid level of the blood circuit side air trap chamber 3. In addition, by driving the ironing type pump Pa in the reverse rotation, air can be introduced into the blood circuit side air trap chamber 3 to lower the liquid level of the blood circuit side air trap chamber 3. ing.

As shown in FIG. 2, the dialyzer 2 extends over a blood introduction port 2a capable of introducing blood, a blood extraction port 2b capable of deriving blood, and the blood introduction port 2a and the blood extraction port 2b. To the blood flow path 2e through which blood can flow, the dialysate introduction port 2c into which dialysate can be introduced, the dialysate out-out port 2d from which dialysate can be taken out, and the dialysate introduction port 2c and dialysate out-out port 2d. A dialysate flow path 2f extending over the blood flow path 2e and capable of flowing dialysate in a direction facing the blood flowing through the blood flow path 2e is interposed between the blood flow path 2e and the dialysate flow path 2f. It has 2 g of a blood purification film capable of purifying the blood flowing through the blood flow path 2e.

More specifically, the dialyzer 2 has a blood introduction port 2a, a blood outlet port 2b, a dialysate introduction port 2c, and a dialysate outlet port 2d projecting from the housing portion of the dialyzer 2, of which the blood introduction port 2a is formed. The arterial blood circuit 1a is connected to the blood outlet port 2b, the intravenous blood circuit 1b is connected to the blood outlet port 2b, the dialysate introduction line L1 is connected to the dialysate introduction port 2c, and the dialysate is connected to the dialysate outlet port 2d. The discharge lines L2 are connected to each other. Further, in order to perform efficient dialysis treatment, the vertical positional relationship between the blood introduction port 2a, which is the entrance of blood, and the dialysate introduction port 2c, which is the entrance of dialysate, is reversed, and the blood flow path. The dialysate is configured to flow in the direction opposite to the blood flowing in 2e.

Further, a plurality of hollow fiber membranes are housed in the dialyzer 2, and the hollow fibers constitute 2 g of a blood purification membrane for purifying blood. That is, the inside of the blood purification membrane 2g constituting the hollow fiber is the blood flow path 2e, and the space between the housing and the hollow fiber is the dialysate flow path 2f. The blood purification membrane 2g forms a hollow fiber membrane, and a large number of minute holes (pores) penetrating the outer peripheral surface and the inner peripheral surface thereof are formed, and the blood flow path 2e flows through the membrane. It is configured so that impurities and the like in the blood can permeate (filter) into the dialysate flowing through the dialysate flow path 2f.

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 the dialysate pump P2 is arranged in the flow path in the middle. Has been done. Like the blood pump P1, the dialysate pump P2 includes a squeeze-type pump that squeezes and feeds a flexible tube constituting the dialysate introduction line L1. A dialysate accommodating bag B1 accommodating a predetermined volume of dialysate is connected to the other end of the dialysate introduction line L1. By driving the dialysate pump P2 (forward rotation drive), the dialysate accommodating bag B1 The dialysate in the dialyser 2 can be introduced into the dialyzer 2.

The dialysate discharge line L2 is composed of a flow path for discharging drainage from the dialyzer 2, one end of which is connected to the dialysate outlet port 2d of the dialyzer 2, and a drainage pump P3 is arranged in the flow path in the middle. Has been done. Like the blood pump P1, the drainage pump P3 includes a squeeze-type pump that squeezes a flexible tube constituting the dialysate discharge line L2 to send the liquid. A drainage storage bag B2 capable of storing a predetermined amount of drainage is connected to the other end of the dialysate discharge line L2, and the drainage pump P3 is driven (forward rotation drive) from the dialyzer 2. The discharged dialysate (drainage) can be introduced into the drainage storage bag B2.

Then, the dialysate of the dialysate storage bag B1 flows and is supplied to the dialyzer 2 by the forward rotation drive of the dialysate pump P2, and the dialysate of the dialyzer 2 is supplied by the forward rotation drive of the drainage pump P3. The drainage) flows toward the drainage storage bag B2 and is discharged. The weight scales 4a and 4b are configured so that the dialysate storage bag B1 and the drainage liquid storage bag B2 can be hooked and held by hooks, respectively, and the weights of the dialysate storage bag B1 and the drainage liquid storage bag B2 can be measured in real time. Has been done. The dialysate storage bag B1 and the drainage storage bag B2 are composed of a flexible storage container, of which the drainage storage bag B2 stores the drainage inside before starting the blood purification treatment. It is said to be empty.

Further, the drive of the blood pump P1, the dialysate pump P2, the drainage pump P3 (and the replacement fluid pump P4) is controlled based on the weight measured by the scales 4a and 4b and the set value stored in advance. ing. The drive 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 drive speed is controlled. It is controlled so that the drive speed is the sum of the flow rates according to. Then, after a lapse of a predetermined time, if there is a difference between the respective weights of the dialysate storage bag B1 and the drainage storage bag B2 detected by the weigh scales 4a and 4b and the theoretical weight, the difference is calculated. The drive speed of the drainage pump P3 can be automatically fine-tuned in order to make a correction to eliminate it.

The replacement fluid line L3 is a flow path capable of communicating a predetermined site of the venous side blood circuit 1b (in this embodiment, the blood circuit side air trap chamber 3 connected to the venous side blood circuit 1b) and the dialysate introduction line L1. Consists of. A replacement fluid pump P4 is provided in the replacement fluid line L3, and by driving the replacement fluid pump P4 (forward rotation drive), dialysate is sent from the dialysate introduction line L1 to the venous blood circuit 1b. It is possible to replenish fluid (post-replenishment fluid). The replacement fluid pump P4, like the blood pump P1, is composed of a squeeze-type pump that squeezes a flexible tube constituting the replacement fluid line L3 to send liquid.

Further, in the dialysate introduction line L1 according to the present embodiment, the dialysate side air trap chamber 7 arranged between the dialysate pump P2 and the dialyzer 2 and the upper portion of the dialysate side air trap chamber 7 An air discharge line Lb that can discharge the air in the dialysate side air trap chamber 7 and an air that can discharge the air in the dialysate side air trap chamber 7 to the outside through the air discharge line Lb. A discharge means 10 is formed, and a liquid level detecting means 8 capable of detecting the liquid level of the dialysate side air trap chamber 7 is attached to the dialysate side air trap chamber 7.

The air discharge means 10 has a flow path communicating with the air discharge line Lb, the tip of the flow path is open to the atmosphere through a filter, and an ironing pump Pb is attached in the middle of the flow path. ing. Then, by driving the ironing type pump Pb in the forward rotation, the air in the dialysate side air trap chamber 7 can be discharged to the outside to raise the liquid level of the dialysate side air trap chamber 7, and the ironing type By driving the pump Pb in the reverse direction, air can be introduced into the dialysate side air trap chamber 7 to lower the liquid level of the dialysate side air trap chamber 7.

The control means 11 is composed of a microcomputer or the like arranged in the blood purification device, and includes actuators (blood pump P1, dialysate pump P2, drainage pump P3, replacement liquid pump P4, etc.) and various sensors (liquid level detection means 6, 8). Etc.) and valve means (clamping means 5 etc.) are electrically connected to perform various controls. In the present embodiment, the priming before the blood purification treatment can be automatically performed by the control of the control means 11.

The priming is a step performed by supplying the priming solution to the blood circuit 1 (arterial side blood circuit 1a and venous side blood circuit 1b) by driving the blood pump P1. As shown in FIG. 3, the priming solution is performed. The filling step S1, the cleaning step S2, and the bubble removing step S3 are included. The priming liquid filling step S1 is a step of filling the flow path of the blood circuit 1, the blood flow path 2e and the dialysate flow path 2f of the dialyzer 2 with the priming liquid to replace the gas (air), and the washing step S2 is In the step of discharging the priming liquid filled in the priming liquid filling step S1 to the outside and cleaning while supplying the priming liquid, and the bubble removing step S3, the priming liquid is circulated in the flow path filled and washed with the priming liquid. This is a step of capturing the remaining air bubbles and discharging them to the outside.

Further, a priming liquid storage bag B3 containing a priming liquid (physiological saline) can be connected to the tips of the arterial side blood circuit 1a and the venous side blood circuit 1b according to the present embodiment, and the priming liquid in priming can be connected. At the time of filling, the priming liquid of the priming liquid storage bag B3 can be supplied to the blood circuit 1. In the present embodiment, the priming fluid storage bag B3 is connected to the tips of both the arterial blood circuit 1a and the venous blood circuit 1b, but at least the priming fluid is stored at the tip of the arterial blood circuit 1a. It suffices if the bag B3 is connected.

Here, in the blood purification apparatus according to the present embodiment, when the priming solution is filled in priming (priming solution filling step S1), as shown in FIG. 2, the blood outlet port 2b is directed upward (dialysate solution). The dialyzer 2 (blood purification means) is held in the introduction port 2c located above the dialysate outlet port 2d), and the priming solution introduced from the blood introduction port 2a into the blood flow path 2e of the dialyzer 2 is purified. The dialysate flow path 2f is filtered through the membrane 2g and led out from the dialysate introduction port 2c so that the dialysate flow path 2f can be primed.

For example, when filling of the priming liquid in priming (priming liquid filling step S1) is started, as shown in FIG. 4, the dialysate pump P2 and the drainage pump P3 have the same flow rate while the clamping means 5 is closed. While driving in the forward rotation so as to be, other pumps such as the blood pump P1 and the replenishment pump P4 are stopped. As a result, the dialysate in the dialysate storage bag B1 can be circulated and filled up to the connection portion with the replacement fluid line L3 in the dialysate introduction line L1.

After the above operation is completed, as shown in FIG. 5, the blood pump P1 is driven in the forward rotation and the replacement fluid pump P4 is driven in the forward rotation while maintaining the closed state of the clamp means 5. At this time, the solenoid valve Va in the air discharge means 9 is opened to drive the ironing type pump Pa in the forward rotation, and other ironing type pumps such as the dialysate pump P2 and the drainage pump P3 are stopped. Further, the flow rate by the replacement fluid pump P4 is set to be equal to or lower than the flow rate by the blood pump P1, and the driving speed of the ironing type pump Pa is controlled by the control means 11.

Then, the priming solution (physiological saline solution) in the priming solution storage bag B3 flows through the blood circuit 1a on the arterial side to reach the blood flow path 2e of the dialyzer 2, is filtered by the blood purification membrane 2g, and is a dialysate flow path. After reaching 2f and being discharged from the dialysate introduction port 2c, it is circulated and filled to the venous blood circuit 1b via the replenishment line L3, and is replaced with the gas (air) in the flow path. .. In the filling process of the priming liquid, the gas discharged to the venous side blood circuit 1b (that is, the air replaced with the priming liquid) is collected in the blood circuit side air trap chamber 3, and the air discharge means 9 is operated. It is designed to be discharged to the outside through the air discharge line La.

Then, on condition that the liquid level of the liquid level is detected by the liquid level detecting means 6, the blood pump P1 and the replacement fluid pump P4 are stopped, and the solenoid valve Va in the air discharging means 9 is closed and the ironing type pump. Stop Pa. However, instead of the priming operation as described above, as shown in FIG. 8, it is arranged between the dialyzer 2 and the connection portion of the replacement fluid line L3 in the venous blood circuit 1b, and the flow path thereof can be opened and closed arbitrarily. It is assumed that the opening / closing means 12 is provided, and when the priming liquid is filled in priming, the opening / closing means 12 is closed to block the flow path, so that the gas discharged from the dialysate introduction port 2c of the dialyzer 2 (replaced air). May be made available to the venous blood circuit 1b via the replacement fluid line L3.

In this way, at the time of filling the priming liquid in priming (priming liquid filling step S1), the gas discharged from the dialysate introduction port 2c of the dialyzer 2 (that is, the air replaced with the priming liquid) is passed through the replacement fluid line L3. It is possible to drain the blood into the venous blood circuit 1b. Further, at the time of filling the priming liquid in priming (priming liquid filling step S1), the gas discharged from the dialysate introduction port 2c of the dialyzer 2 is set by setting the flow rate by the replenishment pump P4 to be equal to or lower than the flow rate by the blood pump P1. That is, the air replaced with the priming liquid) can be discharged to the venous blood circuit 1b via the replenishment line L3.

Further, instead of the gas discharged from the dialysate introduction port 2c of the dialyzer 2 (air replaced with the priming liquid) flowing to the venous blood circuit 1b via the replenishment line L3 as described above, the dialyzer 2 The gas discharged from the dialysate introduction port 2c (air replaced with the priming liquid) is collected in the dialysate side air trap chamber 7 in the dialysate introduction line L1, and the air discharge means 10 is operated to discharge the air. It may be configured to discharge to the outside via the line Lb.

In this case, the priming liquid introduced from the blood introduction port 2a into the blood flow path 2e of the dialyzer 2 by reversely driving the dialysate pump P2 so that the flow rate of the dialysate pump P2 is equal to or less than the flow rate of the blood pump P1. Can be filtered into the dialysate flow path 2f via the blood purification membrane 2g and taken out from the dialysate introduction port 2c to prime the dialysate flow path 2f. As a result, the air replaced with the priming liquid is collected in the dialysate side air trap chamber 7, so that the air is discharged on condition that the liquid level detecting means 8 detects the liquid level at a predetermined height. The discharge of gas by means 10 can be stopped.

After the above operation, as shown in FIG. 6, the blood pump P1 is driven in the forward rotation while maintaining the closed state of the clamping means 5, and the solenoid valve Va in the air discharging means 9 is opened to open the ironing type pump Pa. By driving in the forward rotation, the air in the blood flow path 2e of the dialyzer 2 and the flow path from the connection portion of the dialyzer 2 in the vein side blood circuit 1b to the blood circuit side air trap chamber 3 is replaced with the priming liquid. At this time, the driving speed of the ironing type pump Pa is controlled so that the liquid level detected by the liquid level detecting means 6 becomes constant.

Then, while maintaining the forward rotation drive of the blood pump P1, the clamp means 5 is opened, the electromagnetic valve Va in the air discharge means 9 is closed, and the ironing pump Pa is stopped, so that the blood pump P1 is discharged to the venous blood circuit 1b. The gas can be collected in a collection container (in this embodiment, the priming liquid storage bag B3) connected to the tip of the venous blood circuit 1b. As a result, the space between the tip of the venous blood circuit 1b and the blood circuit side air trap chamber 3 can be filled with the priming liquid.

Further, as shown in FIG. 7, when the priming liquid storage bag B3 is connected to the tip of the venous blood circuit 1b, the solenoid valve Va in the air discharging means 9 is opened while the clamping means 5 is opened. By driving the ironing pump Pa in the forward rotation as a state, the air in the flow path from the tip of the vein side blood circuit 1b to the blood circuit side air trap chamber 3 may be replaced with the priming liquid. Since the priming liquid filling step S1 is completed by the above, a series of priming is completed by sequentially performing the cleaning step S2 and the bubble removing step S3.

If the priming liquid supplied to the blood circuit 1 is discharged via the dialysate discharge line L2 in the washing step S2, the priming liquid collection bag connected only at the time of priming can be eliminated. , The cost for priming can be reduced. In particular, in the present embodiment, since the replacement fluid line L3 capable of communicating the predetermined site of the venous blood circuit 1b and the dialysate introduction line L1 is provided, the priming fluid is discharged during priming (cleaning step S2). If the priming solution supplied to the blood circuit 1 is allowed to flow to the dialysate discharge line L2 via the replacement fluid line L3 and discharged, the replacement fluid line L3 can be diverted to perform efficient priming. Then, after the priming is completed, when performing the blood purification treatment, the priming liquid storage bag B3 is removed from the tips of the arterial blood circuit 1a and the venous blood circuit 1b, and the puncture needle is connected.

According to the above embodiment, when the priming solution is filled in priming, the dialyzer 2 is held with the blood outlet port 2b facing upward, and the priming introduced from the blood introduction port 2a into the blood flow path 2e of the dialyzer 2 is performed. The liquid (physiological saline solution in the priming liquid storage bag B3) is filtered into the dialysate flow path 2f via the blood purification membrane 2g, and is led out from the dialysate introduction port 2c so that the dialysate flow path 2f can be primed. Therefore, it is possible to reliably fill the blood flow path 2e and dialysate flow path 2f of the dialyzer 2 with the priming solution, and it is not necessary for a medical worker to reverse the dialyzer 2 at the start of blood purification treatment. Can be done. In the present embodiment, at the start of the blood purification treatment, it is possible to eliminate the need for reconnecting the storage bags such as the dialysate bag B1 and the drainage bag B2, and the workability can be further improved.

Further, a priming solution storage bag B3 containing a priming solution (physiological saline) can be connected to at least the tip of the arterial side blood circuit 1a of the arterial side blood circuit 1a and the venous side blood circuit 1b, in priming. At the time of filling the priming liquid, the priming liquid of the priming liquid storage bag B3 can be supplied to the blood circuit 1, so that the priming liquid on the blood circuit 1 side can be filled more reliably and smoothly.

Further, it has a replenishment line L3 capable of communicating a predetermined site of the venous blood circuit 1b and the dialysate introduction line L1, and when the priming solution is filled in priming, the gas discharged from the dialysate introduction port 2c of the dialyzer 2 is discharged. Since the blood can be discharged to the venous blood circuit 1b via the replenishment line L3, more efficient priming can be performed. In particular, in the present embodiment, there is a replacement fluid pump P4 which is arranged in the replacement fluid line L3 and can send the dialysate from the dialysate introduction line L1 to the venous blood circuit 1b, and when the priming solution is filled in priming, By setting the flow rate by the replacement fluid pump P4 to be equal to or lower than the flow rate by the blood pump P1, the gas discharged from the dialysate introduction port 2c of the dialyzer 2 can be discharged to the venous blood circuit 1b via the replacement fluid line L3. , The replacement fluid pump P4 can be diverted to perform more efficient priming.

Furthermore, it has an opening / closing means 12 (see FIG. 8) that is disposed between the dialyzer 2 in the venous blood circuit 1b and the connection portion of the replacement fluid line L3 and can arbitrarily open and close the flow path, and priming in priming. By closing the flow path with the opening / closing means 12 closed when the liquid is filled, the gas discharged from the dialysate introduction port 2c of the dialyzer 2 can be discharged to the venous blood circuit 1b via the replacement fluid line L3. For example, the gas can be discharged more reliably through the replacement fluid line L3, and more efficient priming can be performed.

Further, at the time of filling the priming liquid in priming, the gas discharged to the venous side blood circuit 1b is put into a collection container (priming liquid storage bag B3 in the present embodiment) connected to the tip of the venous side blood circuit 1b. Since the recovery is possible, the gas replaced with the priming liquid can be recovered more reliably when the priming liquid is filled. A dedicated collection container for collecting gas may be connected to the tip of the venous blood circuit 1b.

Further, when the priming liquid is filled in the priming, the gas discharged to the vein side blood circuit 1b is collected by the blood circuit side air trap chamber 3, the air discharge means 9 is operated, and the gas is discharged via the air discharge line La. Since the gas can be discharged to the outside, the air trap chamber 3 on the blood circuit side and the air discharge means 9 can be diverted to reliably discharge the gas replaced with the priming liquid to the outside when the priming liquid is filled. In particular, the air is discharged on condition that the liquid level detecting means 6 capable of detecting the liquid level of the air trap chamber 3 on the blood circuit side is provided and the liquid level at a predetermined height is detected by the liquid level detecting means 6. Since the discharge of gas by the means 9 is stopped, by diverting the liquid level detecting means 6, it is possible to detect that all the priming liquid has been replaced with gas and end the filling operation of the priming liquid, which is more efficient. Can be primed.

Furthermore, it was connected to the tip of the dialysate introduction line L1 and was connected to the dialysate storage bag B1 containing the dialysate to be introduced into the dialyzer 2 and the tip of the dialysate discharge line L2, and was discharged from the dialyzer 2. A drainage storage bag B2 capable of storing drainage, a dialysate pump P2 arranged in the dialysate introduction line L1 and sending the dialysate of the dialysate storage bag B1 to the dialyzer 2, and a dialysate discharge line L2. Since the drainage pump P3 which is arranged and sends the drainage liquid discharged from the dialyzer 2 to the drainage storage bag B2 is provided, the dialysate pump P2 or the drainage pump P3 can be diverted for more efficient priming. Can be done.

Further, when the priming solution is filled in priming, the dialysate pump P2 is reversely driven so that the flow rate of the dialysate pump P2 is equal to or less than the flow rate of the blood pump P1, so that the blood flow path of the dialyzer 2 is driven from the blood introduction port 2a. The priming solution introduced into 2e was filtered into the dialysate flow path 2f via the blood purification membrane 2g and led out from the dialysate introduction port 2c so that the dialysate flow path 2f could be primed. By the cooperation of P2 and the blood pump P1, more efficient priming can be performed.

Furthermore, when the priming liquid is filled in priming, the gas discharged from the dialysate introduction port 2c is collected by the dialysate side air trap chamber 7, the air discharge means 10 is operated, and the gas is discharged via the air discharge line Lb. If the gas can be discharged to the outside, the dialysate side air trap chamber 7 and the air discharge means 10 can be diverted to reliably discharge the gas replaced with the priming liquid to the outside when the priming liquid is filled. In particular, the air is discharged on the condition that the liquid level detecting means 8 capable of detecting the liquid level of the dialysate side air trap chamber 7 is provided and the liquid level at a predetermined height is detected by the liquid level detecting means 8. If the discharge of the gas by the means 10 is stopped, it is possible to detect that all the priming liquid has been replaced with the gas by diverting the liquid level detecting means 8 and end the filling operation of the priming liquid. More efficient priming can be performed.

Although the present embodiment has been described above, the present invention is not limited thereto, and for example, as shown in FIG. 9, a double pump 13 arranged across the dialysate introduction line L1 and the dialysate discharge line L2. It may be applied to a blood purification device including a bypass line L4 connected to a dialysate discharge line L2 to bypass the dual pump 13 and a water removal pump 14 connected to the bypass line L4. In such a blood purification device, the dialysate introduction line L1 is connected to a water supply means (not shown), and is also connected to a storage tank T1 containing the A stock solution and a storage tank T2 containing the B stock solution, and the pump 15 , 16 is driven to supply the A stock solution and the B stock solution to the dialysate introduction line L1 to prepare a dialysate having a predetermined concentration and to introduce the dialysate into the dialyzer 2.

Even in this case, when the priming liquid is filled in the priming, the dialyzer 2 (blood purification means) is held with the blood outlet port 2b facing upward, and the blood flow path 2e of the dialyzer 2 is held from the blood introduction port 2a. The priming solution introduced into the above can be filtered into the dialysate flow path 2f via the blood purification membrane 2g and led out from the dialysate introduction port 2c to prime the dialysate flow path 2f.

Further, it is applied to a blood purification device that does not have the blood circuit side air trap chamber 3, the dialysate side air trap chamber 7, and the air discharge means 9 and 10, or a blood purification device that does not have the replacement fluid line L3 and the replacement fluid pump P4. May be good. The blood purification means is not limited to the one provided with 2 g of the blood purification membrane made of a hollow thread membrane, and may be another form capable of purifying and treating blood, and the applied blood purification treatment is dialysis. The treatment is not limited to the treatment, and other treatments that purify the patient's blood while circulating it extracorporeally may be used.

When filling the priming solution in priming, the blood purification means is held with the blood outlet port facing upward, and the priming solution introduced from the blood introduction port into the blood flow path of the blood purification means is passed through the blood purification membrane. As long as the blood purification device is filtered through the dialysate flow path and led out from the dialysate introduction port so that the dialysate flow path can be primed, it may have other functions added.

1 Blood circuit 1a Arterial blood circuit 1b Venous blood circuit 2 Dializer (blood purification means)
3 Blood circuit side air trap chamber 4a, 4b Weigh scale 5 Clamping means 6 Liquid level detecting means 7 Dialysate side air trap chamber 8 Liquid level detecting means 9, 10 Air discharging means 11 Control means 12 Opening and closing means L1 Dialysate introduction line L2 Dialysate discharge line L3 Replenishment line P1 Blood pump P2 Dialysis fluid pump P3 Drainage pump P4 Replenishment pump

Claims (12)

A blood introduction port capable of introducing blood, a blood extraction port capable of deriving blood, a blood flow path extending over the blood introduction port and the blood extraction port to allow blood to flow, and a dialysate can be introduced. A dialysate introduction port, a dialysate lead-out port capable of leading out dialysate, and a direction facing the blood flowing in the blood flow path extending over the dialysate introduction port and the dialysate lead-out port. A blood purification means having a dialysate flow path capable of flowing dialysate and a blood purification film capable of purifying the blood flowing through the blood flow path, which is interposed between the blood flow path and the dialysate flow path. When,
It has an arterial blood circuit connected to the blood introduction port of the blood purification means and a venous blood circuit connected to the blood outlet port, and from the tip of the arterial blood circuit to the tip of the venous blood circuit. A blood circuit that can circulate the patient's blood outside the body,
A dialysate introduction line that is connected to the dialysate introduction port of the blood purification means and can introduce dialysate into the blood purification means, and a dialysate outlet that is connected to the dialysate outlet of the blood purification means to drain water from the blood purification means. With a dialysate discharge line that can discharge
A blood pump that is arranged in the arterial blood circuit and can circulate the patient's blood extracorporeally from the arterial blood circuit to the venous blood circuit.
In a blood purification device capable of supplying a priming liquid to the blood circuit and enabling priming by driving the blood pump.
During the filling of the priming liquid in the priming, the with blood purification means is held in the state in which the blood outlet port directed upward, said priming liquid introduced into the blood flow path of the blood purification means from said blood inlet port Is filtered through the blood purification membrane into the dialysate flow path, led out from the dialysate introduction port, and the gas replaced by the priming solution led out from the dialysate introduction port is discharged from the dialysate introduction line. A blood purification apparatus characterized in that control for priming the dialysate flow path is executed. A priming liquid storage bag containing the priming liquid can be connected to at least the tip of the arterial blood circuit among the arterial blood circuit and the venous blood circuit, and the priming is performed when the priming liquid is filled in the priming. The blood purification apparatus according to claim 1, wherein the priming liquid of the liquid storage bag can be supplied to the blood circuit. It has a replacement fluid line capable of communicating a predetermined site of the venous blood circuit and a dialysate introduction line, and when the priming fluid is filled in priming, the gas discharged from the dialysate introduction port of the blood purification means is used as the replacement fluid. The blood purification apparatus according to claim 1 or 2, wherein the blood can be discharged into the venous blood circuit via a line. It has a replenishment pump which is arranged in the replenishment line and can send dialysate from the dialysate introduction line to the venous blood circuit, and when the priming solution is filled in priming, the flow rate by the replenishment pump is changed to the blood. 3. The third aspect of the present invention is that the gas discharged from the dialysate introduction port of the blood purification means can be discharged to the venous blood circuit via the replenishment line by setting the flow rate to be equal to or lower than the flow rate by the pump. The described blood purification device. It is disposed between the blood purification means in the venous blood circuit and the connection portion of the replacement fluid line, and has an opening / closing means capable of arbitrarily opening and closing the flow path, and when the priming liquid is filled in priming, the said By closing the flow path with the opening / closing means closed, the gas discharged from the dialysate introduction port of the blood purification means can be discharged to the venous blood circuit via the replacement fluid line. The blood purification device according to claim 3. 3. The blood purification device according to any one of 5. An air trap chamber on the blood circuit side arranged at a connection portion with the replacement fluid line in the blood circuit on the venous side,
An air discharge line extending from the upper part of the blood circuit side air trap chamber and capable of discharging air in the blood circuit side air trap chamber,
An air discharge means capable of discharging the air in the air trap chamber on the blood circuit side to the outside through the air discharge line, and an air discharge means.
At the time of filling the priming liquid in priming, the gas discharged to the vein side blood circuit is collected by the blood circuit side air trap chamber, the air discharge means is operated, and the air discharge line is operated. The blood purification apparatus according to any one of claims 3 to 5, wherein the blood can be discharged to the outside through the blood purifying apparatus. A gas produced by the air discharging means, provided that the liquid level detecting means capable of detecting the liquid level of the air trap chamber on the blood circuit side is provided and the liquid level at a predetermined height is detected by the liquid level detecting means. The blood purification apparatus according to claim 7, wherein the discharge of the blood is stopped. 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 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 dialysate pump arranged on the dialysate introduction line and sending the dialysate from the dialysate storage bag to the blood purification means.
A drainage pump arranged in the dialysate drainage line and sending the drainage liquid discharged from the blood purification means to the drainage storage bag, and a drainage pump.
The blood purification device according to any one of claims 1 to 8, wherein the blood purification device is provided. When the priming solution is filled in priming, the dialysate pump is reversely driven so that the flow rate of the dialysate pump is equal to or lower than the flow rate of the blood pump, so that the blood flow path of the blood purification means is driven from the blood introduction port. The priming solution introduced into the above is filtered through the blood purification membrane into the dialysate flow path and led out from the dialysate introduction port so that the dialysate flow path can be primed. 9. The blood purification device according to 9. A dialysate-side air trap chamber disposed between the dialysate pump and the blood purification means in the dialysate introduction line.
An air discharge line extending from the upper part of the dialysate side air trap chamber and capable of discharging air in the dialysate side air trap chamber.
An air discharge means capable of discharging the air in the dialysate side air trap chamber to the outside through the air discharge line, and an air discharge means.
At the time of filling the priming liquid in priming, the gas discharged from the dialysate introduction port is collected in the dialysate side air trap chamber, the air discharge means is operated, and the air discharge line is operated. The blood purification device according to claim 9 or 10, wherein the blood purification device can be discharged to the outside through the device. A gas produced by the air discharging means, provided that the liquid level detecting means capable of detecting the liquid level of the dialysate side air trap chamber is provided and the liquid level at a predetermined height is detected by the liquid level detecting means. The blood purification apparatus according to claim 11, wherein the discharge of the blood is stopped.

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