JP2012249745A - Blood purification system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a blood purification system capable of performing control by attaining bidirectional communication between a supply means and each blood purifying means at a low cost while securing safety.SOLUTION: The blood purification system includes a plurality of monitoring devices 1 mounted with dialyzers 5 for performing blood purification treatment to patients, and a dialysate supply device 2 capable of supplying a dialysate to each monitoring device 1, wherein the supply means and each blood purifying means can be in bidirectional communication. The dialysate supply device 2 is provided with a control central processor 14 for various control, a monitoring central processor 15 and a communication central processor 13 for communication, and each monitoring device 1 is provided with a control central processor 11, a monitoring central processor 12 and a communication central processor corresponding to the control central processor 14 and the monitoring central processor 15.

Description

  The present invention provides blood comprising a plurality of blood purification means to which a blood purification device for performing blood purification treatment on a patient is attached, and supply means capable of supplying dialysate or dialysate stock solution to each of the blood purification means. It relates to a purification system.

  In general, a blood purification system has a dialysate supply device installed in a machine room at a medical site such as a hospital, and a dialysis monitoring device installed in a dialysis room (treatment room), which is a separate place. The dialysate supply device and the monitoring device for dialysis are connected by a pipe. The dialysis fluid supply device is a device that supplies purified water to produce a predetermined concentration of dialysis fluid, while the dialysis monitoring device corresponds to the number of blood purifiers (dialyzers) for dialysis treatment for patients. A plurality of dialysate prepared by a dialysate supply device are introduced through a pipe and supplied to a blood purifier.

  That is, the dialysis fluid supply device installed in the machine room is distributed to a plurality of dialysis monitoring devices installed in the dialysis chamber, and the dialysis fluid is sent, and the dialysis fluid is supplied to the dialyzer in each. It is. The blood purification system that distributes the dialysate prepared in the machine room to each monitoring device for dialysis is usually referred to as “central system for dialysis treatment”, while each blood purifier (ie, dialysis treatment patient's Those that can produce a dialysate in each case) are usually referred to as “personal dialysers”.

  However, conventionally, the dialysate supply device and each monitoring device for dialysis are electrically connected to each other from the dialysate supply device (supply means) during the dialysis treatment process, the pipe washing process, or the disinfection process. A device that transmits an electrical signal (process signal) to each dialysis monitoring device (blood purification means) has been proposed (for example, see Patent Document 1). Thus, when each dialysis monitoring device receives a predetermined electrical signal (process signal), an operation (such as driving a pump or opening / closing a solenoid valve) according to the signal is performed.

JP 2004-16412 A

However, the conventional blood purification system has the following problems.
In recent medical devices, when performing various controls by transmitting or receiving information, a plurality of central processing devices (specifically, central processing for control) are provided on both the information transmitting side and the receiving side. Even if a failure such as a failure occurs in any of the equipment or parts, the multiple central processing units monitor each other to ensure patient safety. The control to hold | maintain is comprised so that it may be maintained.

  On the other hand, in the blood purification system, the applicant constructs a LAN (local area network: local communication network) between the dialysate supply device (supply means) and each dialysis monitoring device (blood purification means). It has been considered to perform control related to treatment by bi-directional communication between them, but in that case, it is necessary to connect a plurality of central processing units to each other. A plurality of LAN cables corresponding to the respective processing devices are required, and a problem that costs increase is assumed. This problem is the same when the blood purification means is a personal dialyzer.

  The present invention has been made in view of such circumstances, and provides a blood purification system capable of controlling the supply means and the respective blood purification means in two-way communication at low cost while ensuring safety. It is to provide.

  The invention according to claim 1 is a plurality of blood purification means to which a blood purification device for performing blood purification treatment on a patient is attached, and dialysate, dialysate undiluted solution, clean water or disinfectant solution is respectively added to the blood purification means A blood purification system comprising a supply means capable of supply, wherein the supply means and each of the blood purification means are capable of bidirectional communication, wherein the supply means has a plurality of supply-side centers for various controls. A central processing unit for communication and a central processing unit for communication are provided, and each blood purification means is provided with a plurality of central processing units for treatment and a central processing unit for communication corresponding to the central processing unit on the supply side. It is characterized by that.

  According to a second aspect of the present invention, in the blood purification system according to the first aspect, the central processing unit for communication in the supply unit and the central processing unit for communication in each of the blood purification units can identify the corresponding central processing unit In addition, the information is transmitted after being tagged, and the information is transmitted to either the supply-side central processing unit or the treatment-side central processing unit corresponding to the tag attached to the received information.

  According to a third aspect of the present invention, in the blood purification system according to the first or second aspect, the plurality of supply-side central processing units and treatment-side central processing units are a pair of control central processing unit and monitoring central unit, respectively. It consists of a processing device, and the control content of the control central processing device can be monitored by the monitoring central processing device.

  According to a fourth aspect of the present invention, in the blood purification system according to any one of the first to third aspects of the present invention, the supply means can produce dialysis fluid having a predetermined concentration using clean water and a dialysate stock solution. The blood purification means comprises a monitoring device for supplying the blood purification device with the dialysate supplied from the dialysate supply device.

  According to a fifth aspect of the present invention, in the blood purification system according to any one of the first to third aspects, the supply means includes a water treatment device capable of producing clean water, and the blood purification system. The means is characterized by comprising a personal dialyzer that produces a dialysate having a predetermined concentration using clean water supplied from the water treatment device and supplies the dialysate to the blood purifier.

  The invention according to claim 6 is the blood purification system according to any one of claims 1 to 3, wherein the supply means is a water treatment apparatus capable of producing clean water, and the water treatment apparatus. The blood purification means comprises a dialysate undiluted solution and clean water supplied from the dissolver and the water treatment device. It is characterized by comprising a personal dialyzer that produces dialysate of a predetermined concentration and supplies it to the blood purifier.

  According to the invention of claim 1, the supply means is provided with a plurality of supply-side central processing devices for various controls and a communication central processing device for communication, and each blood purification means is provided with the supply-side central processing device. A plurality of treatment-side central processing units and communication central processing units corresponding to the above are provided, so that the supply means and the respective blood purification means can be communicated and controlled bidirectionally at low cost while ensuring safety. Can do.

  According to the invention of claim 2, the central processing unit for communication in the supply means and the central processing unit for communication in each blood purification means transmit information with tagging that can identify the corresponding central processing unit. Since the information is transmitted to either the supply-side central processing unit or the treatment-side central processing unit corresponding to the tag attached to the received information, the correspondence between the central processing units is clarified and information is transmitted and received. Therefore, safety can be improved, and the supply means and the respective blood purification means can be controlled to communicate with each other at low cost.

  According to the invention of claim 3, the plurality of supply-side central processing units and treatment-side central processing units each comprise a pair of control central processing units and monitoring central processing units, and control of the control central processing units. Since the contents can be monitored by the monitoring central processing unit, the safety can be improved more reliably, and the supply means and the respective blood purification means can be controlled to communicate in two directions.

  According to the invention of claim 4, the supply means comprises a dialysate supply device capable of producing a predetermined concentration of dialysate using clean water and dialysate stock solution, and the blood purification means comprises the dialysate Since it consists of a monitoring device that supplies the dialysate supplied from the supply device to the blood purifier, it can be applied to a central system.

  According to the invention of claim 5, the supply means has a water treatment device capable of producing clean water, and the blood purification means uses a clean water supplied from the water treatment device to dialyze with a predetermined concentration. Since it consists of a personal dialysis device that produces a liquid and supplies it to a blood purifier, it can be applied to a blood purification system having the personal dialysis device.

  According to the invention of claim 6, the supply means includes a water treatment device capable of producing clean water, and a dissolution device capable of producing a dialysate stock solution having a predetermined concentration using the clean water produced by the water treatment device. The blood purification means is a personal dialysis apparatus for preparing a dialysate having a predetermined concentration using the dialysate stock solution and clean water supplied from the dissolution apparatus and the water treatment apparatus and supplying the dialysate to the blood purifier. Therefore, it can be applied to a blood purification system having the personal dialysis device.

1 is an overall schematic diagram showing a blood purification system according to an embodiment of the present invention. Schematic diagram showing the configuration of the monitoring device in the blood purification system The block diagram which shows the internal structure and connection state of each apparatus in the blood purification system Overall schematic view showing a blood purification system according to another embodiment of the present invention. Overall schematic view showing a blood purification system 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 system according to the present embodiment is for preparing a dialysate having a predetermined concentration from a dialysate stock solution and supplying the dialysate to a plurality of dialysis monitoring devices, as shown in FIG. A plurality of monitoring devices 1 installed in a dialysis room A (treatment room) in a medical site such as a hospital, and a dialysate supply device 2 installed in a machine room B which is a place different from the dialysis room A in the medical site; It is mainly composed of a dissolving device 3 and a water treatment device 4.

  The monitoring device 1 (blood purification means) is provided with a dialyzer 5 (blood purifier) for performing blood purification treatment (hemodialysis treatment) on the patient, and the dialyzate supplied from the dialysate supply device 2 is used as the dialyzer 5. A plurality of dialysis rooms A are installed. The monitoring device 1 is provided with a touch panel 1a capable of giving instructions and predetermined display of hemodialysis treatment and other control contents (washing or disinfection).

  More specifically, each of the plurality of monitoring devices 1 installed in the dialysis chamber A has a pipe L1 extending from the dialysate supply device 2 as shown in FIG. A pipe L2 connected to the means is provided, and a duplex pump P1 is arranged across the pipes L1 and L2. Among these, the pipe L1 in the monitoring device 1 has a flow rate detection sensor 7 for detecting the flow rate of the liquid flowing through the pipe L1, a hydraulic pressure detection sensor 8 for detecting the supply pressure of the liquid, and the electrical conductivity of the liquid ( A conductivity detection sensor 9 for detecting (concentration) is provided.

  Further, a dialysate introduction line L4 communicated with the pipe L1 and a dialysate discharge line L5 communicated with the pipe L2 are extended from the duplex pump P1, and the distal end of the dialysate introduction line L4 via the coupler C is extended. Can be connected to the dialysate inlet 5a of the dialyzer 5, and the tip of the dialysate discharge line L5 can be connected to the dialysate outlet 5b of the dialyzer 5 via the coupler C. In this way, each monitoring device 1 is provided with a dialyzer 5 corresponding to the patient, and the dialyzer 5 is connected to a blood circuit 6 for circulating the patient's blood extracorporeally. .

  The pump chamber of the duplex pump P1 is divided by a single plunger (not shown) into a liquid-feeding pump chamber connected to the pipe L1 and a discharge-side pump chamber connected to the pipe L2. By reciprocating, the dialysate or the washing solution sent to the liquid feeding side pump chamber is supplied to the dialyzer 5 and the dialysate in the dialyzer 5 is sucked into the discharge side pump chamber. Further, a pipe L3 that connects the pipe L2 and the dialysate discharge line L5 is formed in the monitoring device 1 while bypassing the duplex pump P1, and a water removal pump P2 is disposed in the middle of the pipe L3. ing. By driving the water removal pump P2, the blood of the patient flowing through the dialyzer 5 can be removed.

  In place of the dual pump P1, a so-called chamber type may be used, and sensors such as the flow rate detection sensor 7, the fluid pressure detection sensor 8, or the conductivity detection sensor 9 may be arranged arbitrarily. You may make it add well or another general purpose thing. Furthermore, in the present embodiment, the sensors are arranged in the pipe L1, but may be arranged in another pipe (for example, the pipe L2). For example, sensors such as the flow rate detection sensor 7, the fluid pressure detection sensor 8, or the conductivity detection sensor 9 may be provided on either or both of the pipe L1 and the pipe L2.

  The water treatment device 4 is provided with a module (purification filter) having a filter membrane or the like inside, for purifying raw water to obtain clean water (RO water), and is a dissolving device via a pipe L8. 3 is configured to be able to supply clean water to the dissolving device 3 and to be connected to the dialysate supply device 2 via pipes L6 and L7 so as to be able to supply clean water to the dialysate supply device 2. ing. The clean water obtained by the water treatment device 4 is used when preparing the dialysate in the dialysate supply device 2 or as wash water for cleaning the dialysate supply device 2 and the piping of the monitoring device 1. Is also used. The water treatment device 4 may be connected to a personal dialysis device (not shown), a dissolution device that dissolves a powdered dialysis drug, or the like, and clean water may be supplied thereto.

  In addition, the water treatment apparatus 4 is provided with a touch panel 4a capable of instructing and displaying predetermined control contents regarding water treatment, and an interface unit 16 and a control unit 17 electrically connected to the LAN cable β. It has. When the interface unit 16 receives predetermined information from the dialysate supply device 2 or the like, a predetermined operation (preparation of clean water or the like) by the control unit 17 is performed based on the information.

  For example, a predetermined amount of the dialysis powder drug is introduced into the dissolution apparatus 3, and the dialysis powder drug and clean water supplied from the water treatment device 4 are mixed (mixed) to obtain a dialysis solution having a predetermined concentration. This is for preparing a stock solution. The dissolving device 3 is provided with a touch panel 3a capable of performing an instruction and predetermined display of control contents relating to the preparation of the dialysate stock solution, and an interface unit 18 electrically connected to a LAN cable β described later and the control. Part 19 is provided. When the interface unit 18 receives predetermined information from the dialysate supply device 2 or the like, a predetermined operation (preparation of dialysate stock solution, etc.) is performed by the control unit 19 based on the information. The dissolving device 3 is connected to the dialysate supply device 2 via a pipe L6, and is configured to be able to supply the prepared dialysate stock solution to the dialysate supply device 2.

  Thus, the dialysate supply device 2, the dissolution device 3, and the water treatment device 4 are connected by a LAN (local area network: local communication network), and bidirectional communication of information is possible. Such a LAN is not limited to the one using the LAN cable β (wired) as in the present embodiment, but may be one that can communicate bidirectional information wirelessly (wireless LAN). In addition, it is good also as what can transmit an electrical signal (process signal) unilaterally with respect to the melt | dissolution apparatus 3 and the water treatment apparatus 4 from the dialysate supply apparatus 2 instead of the said LAN.

  The dialysate supply device 2 (supply means) can prepare a dialysate having a predetermined concentration using the clean water obtained by the water treatment device 4 and the dialysate stock solution prepared by the dissolution device 3, and the monitoring device 1 ( The dialysis solution prepared for each of the blood purification means) can be supplied. That is, the dialysate supply device 2 is connected to each of the plurality of monitoring devices 1 via the piping L1, and desired monitoring fluid 1 such as dialysate, washing water, and disinfecting solution is connected to each of the monitoring devices 1 via the piping L1. The liquid can be supplied. In addition, the dialysate supply device 2 is provided with a touch panel 2a capable of giving an instruction and a predetermined display of control contents related to dialysate supply, cleaning, or disinfection.

  Here, in the blood purification system according to the present embodiment, the dialysate supply device 2 (supply means) and each monitoring device 1 (blood purification means) are connected by a LAN (local area network: local communication network). It is possible to communicate bidirectional information. Thereby, in this blood purification system, it is set as the structure which can transmit each predetermined information regarding the several monitoring apparatus 1 with respect to the dialysate supply apparatus 2 from each monitoring apparatus 1. FIG.

  That is, the dialysate supply device 2 and each monitoring device 1 are connected to each other via a LAN cable α, and the dialysate supply device 2 is connected to the LAN cable α as shown in FIG. Single communication central processing unit 10 (communication CPU) for communicating with the monitoring apparatus 1 via the control unit, and a pair of control central processing units 11 (control CPU) constituting a plurality of supply side central processing units And a central processing unit 12 (protection CPU) for monitoring, each of the monitoring devices 1 has a single communication for communicating with the dialysate supply device 2 via the LAN cable α. A central processing unit 13 (communication CPU), a pair of control central processing units 14 (control CPU) and a monitoring central processing unit 15 (protective CPU) constituting a plurality of treatment-side central processing units are provided. Yes. Such a LAN is not limited to the one using the LAN cable α (wired) as in the present embodiment, but may be one that can communicate bidirectional information wirelessly (wireless LAN).

  Furthermore, in the present embodiment, on the premise of the above configuration, the communication central processing unit 13 in the dialysate supply device 2 and each communication central processing unit 10 in each monitoring device 1 can identify the corresponding central processing unit. Information is transmitted with a simple tag attached, and the supply-side central processing unit (control central processing unit 14 or monitoring central processing unit 15) or treatment-side central processing unit (corresponding to the tag attached to the received information) The information is transmitted to either the control central processing unit 11 or the monitoring central processing unit 12). That is, in the present embodiment, the control central processing unit 14 of the dialysate supply device 2 corresponds to the control central processing unit 11 of each monitoring device 1, and the monitoring central processing unit 15 of the dialysate supply device 2. And the monitoring central processing unit 12 of each monitoring device 1 are tagged so as to correspond to each other.

  Specifically, when predetermined information is transmitted from the dialysate supply device 2 to the monitoring device 1, a tag that can identify whether the information is information on the central processing device 14 for control or information on the central processing device 15 for monitoring Is transmitted from the communication central processing unit 13 to each communication central processing unit 10. The communication central processing unit 10 that has received this information refers to the tag to which it is attached, and sends the information to the treatment central processing unit (control central processing unit 11 or monitoring central processing unit 12) corresponding to the tag. Send.

  Similarly, when transmitting predetermined information from the monitoring device 1 to the dialysate supply device 2, a tag that can identify whether the information is information on the central processing unit 11 for control or information on the central processing unit 12 for monitoring is attached. Then, the data is transmitted from each communication central processing unit 10 to the communication central processing unit 13. The communication central processing unit 13 that has received this information refers to the tag attached thereto, and sends the information to the treatment central processing unit (control central processing unit 14 or monitoring central processing unit 15) corresponding to the tag. Send.

  For example, the central processing unit 11 for control performs control in each monitoring device 1. For example, the control central processing unit 11 performs predetermined operations (priming before treatment, hemodialysis treatment, blood return, cleaning / disinfection). Etc.) and predetermined information can be transmitted to the dialysate supply device 2 via the communication central processing unit 10. On the other hand, the monitoring central processing unit 12 monitors the control contents of the control central processing unit 11 and determines that there is an error in the information received due to a failure of a device or a part. Instead of the control, control is performed so that a safe operation for the patient is performed.

  Similarly, the control central processing unit 14 controls the dialysate supply device 2. For example, the control central processing unit 14 performs a predetermined operation (preparation of a dialysate or a dissolving device for preparing the dialysate). 3 or an instruction to the water treatment device 4, etc.) and predetermined information can be transmitted to each monitoring device 1 via the communication central processing device 13. On the other hand, the monitoring central processing unit 15 monitors the control contents of the control central processing unit 14 and determines that there is an error in the received information due to a failure of a device or a part. Instead of the control, control is performed so that a safe operation for the patient is performed.

  As described above, the central processing unit for communication (10, 13) performs interface-related operations such as screen display on a monitor, input detection on a touch panel, and communication control. The control central processing units (11, 14) are assumed to control the control relationship such as dialysate temperature control, dialysate mixing control, and the monitoring central processing units (12, 15) For example, the alarm is monitored and an alarm action is performed.

  In this embodiment, control and monitoring (protection) are separated, and if one is normal, it can be configured so that the patient does not pose a risk even if the other fails. A system that does not pose a risk to the patient can be constructed. As long as such an object can be achieved, the relationship between the central processing unit for control (11, 14) and the central processing unit for monitoring (12, 15) is various in addition to the above embodiment. Can do.

  For example, the central processing unit for control (11, 14) controls the heater until the temperature of the dialysate reaches the target temperature, whereas the central processing unit for monitoring (12, 15) If the control is performed so that the flow of the dialysate is interrupted when the alarm point is exceeded, even if the dialysate is heated in the state where the control central processing unit (11, 14) is out of order, the monitoring center If the control (monitoring) of the processing devices (12, 15) is normal, the hot dialysis fluid will not be supplied to the patient, and danger can be avoided. On the contrary, if the temperature control of the central processing unit for control (11, 14) is normal even if the central processing unit for monitoring (12, 15) cannot shut off the dialysate due to failure, Heating is performed normally and danger can be avoided.

  According to this embodiment, the dialysate supply device 2 has a plurality of supply-side central processing devices (in this embodiment, a pair of control central processing devices 14 and a monitoring central processing device 15) for various controls and communication. A single central processing unit 13 for communication, and a plurality of treatment-side centers corresponding to the supply-side central processing units (control central processing unit 14 and monitoring central processing unit 15) in each monitoring unit 1 Since the processing apparatus (in this embodiment, a pair of central processing unit 11 for control and central processing unit 12 for monitoring) and a single central processing unit 10 for communication are provided, dialysis is performed at low cost while ensuring safety. The liquid supply device 2 and each monitoring device 1 can be controlled by communicating bidirectionally via a LAN.

  Moreover, according to the said embodiment, the central processing unit 13 for communication in the dialysate supply apparatus 2 and the central processing unit 10 for communication in each monitoring apparatus 1 are the corresponding central processing unit (control central processing unit 14 or monitoring). The central processing unit 15 for monitoring, or the central processing unit 11 for control or the central processing unit 12 for monitoring) is attached with a tag that can be identified, and information is transmitted. Either the supply-side central processing unit or the treatment-side central processing unit corresponding to the assigned tag (that is, either the control central processing unit 14 or the monitoring central processing unit 15, or the control central processing unit 11 or The information is transmitted to any one of the monitoring central processing units 12), so that the correspondence between the central processing units is clarified and information is transmitted and received. It is possible to improve safety by, it can be controlled by communication with each of the monitoring device 1 and the dialysate supplying device 2 at a low cost in both directions.

  However, in the present embodiment, the dialysate supply device 2 includes a plurality of supply-side central processing devices (a pair of control central processing devices 14 and a monitoring central processing device 15) for various controls and communication for communication. A central processing unit 13 is provided, and a plurality of treatment-side central processing units (a pair of control units) corresponding to the supply-side central processing units (control central processing unit 14 and monitoring central processing unit 15) are provided in each monitoring device 1. A central processing unit 11, a central processing unit 12 for monitoring, and a central processing unit 10 for communication, and a central processing unit 13 for communication in the dialysate supply device 2 and a central processing unit 10 for communication in each monitoring device 1. Transmits the information with a tag that can identify the corresponding central processing unit, and supplies the central processing unit or supply side corresponding to the tag attached to the received information. Since the information is transmitted to one of the central processing units on the treatment side, control (control by the central processing unit for control (11, 14)) and protection (central processing for monitoring) are performed while sharing the physical communication path (LAN). It is possible to maintain independence from the control by the devices (12, 15).

  Furthermore, according to the present embodiment, the plurality of supply-side central processing units and treatment-side central processing units each comprise a pair of control central processing units (14, 11) and monitoring central processing units (15, 12). In addition, since the control content of the central processing unit (14, 11) can be monitored by the central processing unit (15, 12) for monitoring, the safety of the dialysate supply device 2 can be improved more reliably. Each monitoring apparatus 1 can be controlled by bidirectional communication.

  In particular, according to the present embodiment, communication is performed via the single central processing unit 10 for communication in the dialysate supply device 2 and the single central processing unit 13 for communication in each monitoring device 1. Bidirectional communication can be performed with the system LAN cable α, which can contribute to cost reduction. Thus, single communication central processing units 10 and 13 are formed at both ends of the LAN cable α, respectively, from which information can be selectively transmitted to the control central processing unit and the monitoring central processing unit. Since it is configured, it is not necessary to form a plurality of communication central processing units and LAN cables according to the number of control central processing units and monitoring central processing units.

  However, the supply-side central processing device to be formed in the dialysate supply device 2 and the treatment-side central processing device to be formed in the monitoring device 1 need only be configured by a plurality of central processing devices, respectively, and are similar to each other. A central processing unit having the above function or control program may be provided in each of the dialysate supply device 2 and the monitoring device 1. Even in this case, the control contents of the respective central processing units are monitored or complemented with each other, and if it is determined that there is an error in the information received due to equipment or component failure, the control of one central processing unit Instead, control by the other central processing unit is performed, and control is performed so that a safe operation for the patient is performed.

  In the present embodiment, the individual predetermined information related to the plurality of monitoring devices 1 (blood purification means) can be transmitted from each monitoring device 1 to the dialysate supply device 2 (supply means). The dialysate supply device 2 can be operated while accurately grasping the actual state of the device 1. In particular, since the predetermined information to be transmitted includes information on the temperature, pressure, concentration or flow rate of the liquid sent from the dialysate supply device 2 to the monitoring device 1, the real-time information in the monitoring device 1 is used as the dialysate supply device 2. The monitoring device 1 can be more accurately ascertained.

  Furthermore, according to the present embodiment, the supply means includes the dialysate supply apparatus 2 capable of producing a predetermined concentration of dialysate using clean water and dialysate stock solution, and the blood purification means includes the dialysate supply apparatus. Since it consists of the monitoring apparatus 1 which supplies the dialysate supplied from 2 to the dialyzer 5 (blood purifier), it can be applied to a central system. In addition, since the dialysate supply device 2 and the monitoring device 1 can communicate in both directions, various information can be communicated between the dialysate supply device 2 and the monitoring device 1, which is more appropriate and safe. Blood purification treatment can be performed.

  The blood purification system according to the present embodiment has been described above. However, the present invention is not limited to this, and for example, instead of the central system as described above, as shown in FIG. The blood purification device has a water treatment device 4 capable of producing clean water, and the blood purification means prepares a dialysate having a predetermined concentration using the clean water supplied from the water treatment device 4, and dialyzer 5 (blood purification) You may apply to what consists of the personal dialysis machine 20 supplied to a container. In this case, the personal dialysis machine 20 includes a tank T1 that stores a dialysate stock solution or a disinfectant solution, and is connected to the water treatment device 4 by a pipe L9 and is supplied with clean water sent from the water treatment device 4. The dialysate stock solution in the tank T1 can be used to prepare a dialysate having a predetermined concentration or a diluted disinfectant solution.

  That is, in the embodiment shown in FIG. 1, the supply means is configured by the dialysate supply device 2 (including the dissolving device 3 and the water treatment device 4) capable of supplying dialysate to each of the monitoring devices 1. However, the blood purification means may have a dialyzer 5 (blood purifier) and may be a blood purification system including a personal dialyzer 20 capable of producing dialysate from the dialysate stock solution in the tank T1.

  Further, for example, as shown in FIG. 5, instead of the central system as described above, the supply means supplies the water treatment device 4 capable of producing clean water and the clean water produced by the water treatment device 4. The blood purifying means has a predetermined concentration using the dialysate stock solution and clean water supplied from the dissolution device 3 and the water treatment device 4. You may apply to what consists of the personal dialyzer 21 which produces the dialysate of a density | concentration and supplies to the dialyzer 5 (blood purifier). In this case, the personal dialysis apparatus 21 includes a tank T2 that contains a disinfectant solution, and is connected to the dissolution apparatus 3 and the water treatment apparatus 4 by pipes L10 and L11, respectively. The dialysis fluid having a predetermined concentration can be produced using the dialysis fluid stock solution and the clean water fed from the above, or a diluted disinfectant solution can be produced.

  That is, in the embodiment shown in FIG. 1, the supply means is configured by the dialysate supply device 2 (including the dissolving device 3 and the water treatment device 4) capable of supplying dialysate to each of the monitoring devices 1. However, a blood purification system comprising a personal dialysis device 21 having a dialyzer 5 (blood purifier) as a blood purification means and capable of producing a dialysate from a dialysate stock solution and clean water sent from the supply means side. It's good.

  In the present embodiment, the monitoring device 1 and the dialysate supply device 2 each include a plurality of supply-side central processing devices, treatment-side central processing devices (control central processing devices 11, 14, monitoring central processing devices 12, 15). ) And communication central processing devices 10 and 13 are formed. Similarly, a plurality of central processing devices and communication central processing devices are formed in the dissolution device 3 and the water treatment device 4 to supply dialysate. Information may be transmitted to and received from the device 2. In addition, in this embodiment, although it is set as the system which performs a hemodialysis treatment, you may make it apply to the blood purification system which performs another blood purification treatment.

  The supply means includes a plurality of supply-side central processing devices for various controls and a communication central processing device for communication, and each blood purification means has a plurality of treatment-side central processing corresponding to the supply-side central processing device. As long as it is a blood purification system provided with a device and a central processing unit for communication, the present invention can also be applied to devices to which other functions are added.

1 Monitoring device (blood purification means)
2 Dialysate supply device (supply means)
3 Dissolution device 4 Water treatment device 5 Dialyzer (blood purifier)
6 Blood circuit 7 Flow rate detection sensor 8 Fluid pressure detection sensor 9 Conductivity detection sensor 10 Central processing unit for communication 11 Central processing unit for control (central processing unit on treatment side)
12 Central processing unit for monitoring (Central processing unit on the treatment side)
13 Central processing unit for communication 14 Central processing unit for control (Central processing unit on the supply side)
15 Central processing unit for monitoring (Central processing unit on the supply side)
16 Interface unit 17 Control unit 18 Interface unit 19 Control unit P1 Duplex pump P2 Dewatering pump

Claims (6)

A plurality of blood purification means to which a blood purifier for performing blood purification treatment on a patient is attached;
Supply means capable of supplying dialysate, dialysate stock solution, clean water or disinfectant to each of the blood purification means;
A blood purification system in which the supply means and each blood purification means are capable of bidirectional communication,
The supply means includes a plurality of supply-side central processing devices for various controls and a communication central processing device for communication, and each of the blood purification means has a plurality of treatments corresponding to the supply-side central processing device. A blood purification system comprising a side central processing unit and a communication central processing unit.   The central processing unit for communication in the supply means and the central processing unit for communication in each of the blood purification means transmit information with tagging that identifies the corresponding central processing unit, and are given to the received information. 2. The blood purification system according to claim 1, wherein the information is transmitted to either the supply side central processing unit or the treatment side central processing unit corresponding to the tag.   The plurality of supply-side central processing units and treatment-side central processing units each comprise a pair of control central processing units and monitoring central processing units, and control contents of the control central processing units are indicated by the monitoring central processing units The blood purification system according to claim 1 or 2, wherein the blood purification system can be monitored by the method.   The supply means includes a dialysate supply apparatus capable of producing a dialysate having a predetermined concentration using clean water and a dialysate stock solution, and the blood purification means is a dialysis solution supplied from the dialysate supply apparatus. The blood purification system according to any one of claims 1 to 3, further comprising a monitoring device that supplies liquid to the blood purifier.   The supply means comprises a water treatment device capable of producing clean water, and the blood purification means produces a dialysate having a predetermined concentration using the clean water supplied from the water treatment device, The blood purification system according to any one of claims 1 to 3, wherein the blood purification system comprises a personal dialysis device that supplies the blood purification device.   The supply means includes a water treatment device capable of producing clean water, and a dissolution device capable of producing a dialysate stock solution having a predetermined concentration using the clean water produced by the water treatment device, and the blood The purification means comprises a personal dialysis device that produces a predetermined concentration of dialysate using the dialysate stock solution and clean water supplied from the dissolution device and the water treatment device and supplies the dialysate to the blood purifier. The blood purification system according to any one of claims 1 to 3.

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