JP2018155733A - Chemical light emission analysis device, blood purification device, and blood purification system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a chemical light emission analysis device in which installation is easy in comparison with a convention device.SOLUTION: In a chemical light emission analysis device 100, which comprises: a reactor 111 that makes drainage of fluid of a blood purification device react with a reagent; and an optical detector 112 that measures light emission intensity of chemical light emission generated by the reactor 111, a following configuration is provided. The chemical light emission analysis device comprises: drainage-of-fluid sending means 113 that transports the drainage of fluid from a drainage-of-fluid flow path to the reactor 111; and reagent sending means 114 that transports the reagent to the reactor 111. On top of these means, the chemical light emission analysis device further comprises: a coupling unit 123 that couples a flow path of a mixed fluid of the post-reacted drainage of fluid and reagent after transported to the reactor 111 to the drainage-of-fluid flow path of the blood purification device; and an electric interface part 165.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a chemiluminescence analyzer, a blood purification device, and a blood purification system.

  2. Description of the Related Art Conventionally, a chemiluminescence analyzer that includes a reactor that reacts a drainage solution of a blood purification device with a reagent solution and a photodetector that measures the emission intensity of chemiluminescence generated in the reactor is known.

For example, Patent Document 1 includes a first liquid feeding means (tubing pump) for transporting a drainage liquid (sample solution) to a reactor, and a measurement by a photodetector (photomultiplier tube). The configuration of the chemiluminescence analyzer (urea concentration measuring device) controlled by the above is described.
With this configuration, since the urea concentration in the drainage of the blood purification device (artificial dialysis device) can be measured in real time, the chemiluminescence analyzer of the blood purification device can know the end of the purification (dialysis) time It can be used suitably.

However, many conventional chemiluminescence analyzers are incorporated in advance in the blood purification apparatus.
For this reason, when it is incorporated later into the blood purification apparatus or operated alone, it is difficult to incorporate it into the blood purification apparatus, or a drainage flow path is ensured when operating alone. In some cases, it is difficult to install the chemiluminescence analyzer.

  In order to solve the above-described problem, the invention described in claim 1 is a reactor for reacting a drainage solution of a blood purification device with a reagent solution, and light detection for measuring the emission intensity of chemiluminescence generated in the reactor. A chemiluminescence analyzer comprising: a first liquid feeding means for transporting the drainage liquid from the drainage flow path of the blood purification apparatus to the reactor; and a first transporting means for transporting the reagent solution to the reactor. A second liquid feeding means; a connecting portion for connecting a flow path of the mixed liquid of the drainage liquid and the reagent solution after being transported to the reactor and reacting to the drainage flow path of the blood purification apparatus; And an interface unit.

  ADVANTAGE OF THE INVENTION According to this invention, the chemiluminescence analyzer which can be installed easily compared with the past can be provided.

Schematic of the blood purification system which concerns on this embodiment. Explanatory drawing of the basic composition of the chemiluminescence analyzer which divided the housing | casing into two. Explanatory drawing of the basic composition of a chemiluminescence analyzer with one housing | casing. Explanatory drawing of the improved structure of the chemiluminescence analyzer which divided the housing | casing into two. Explanatory drawing of the improved structure of a chemiluminescence analyzer with one housing | casing. Explanatory drawing of the structural example which controls the liquid sending / reaction part each connected to the several blood purification apparatus with the control part provided in one operation and control part. The perspective cross-section explanatory drawing of the main apparatuses of the chemiluminescence analyzer of improved structure.

  Hereinafter, as an example of a blood purification system including a chemiluminescence analyzer to which the present invention is applied, an embodiment of a blood purification system (hereinafter referred to as a blood purification system 500) including a blood purification device 200 and a chemiluminescence analyzer 100 is described. A form is demonstrated.

First, the problems of the conventional chemiluminescence analyzer will be described in more detail.
As described above, many conventional chemiluminescence analyzers are incorporated in advance in the blood purification apparatus.
For this reason, when it is incorporated later into the blood purification apparatus or operated alone, it is difficult to incorporate it into the blood purification apparatus, or a drainage flow path is ensured when operating alone. In some cases, it is difficult to install the chemiluminescence analyzer.

Specifically, in order to operate each device provided in the chemiluminescence analyzer, each device requires a power line, a signal line, a driver, an amplifier, etc., and a controller (PC or sequencer) for controlling them is required. is there.
As a result, the conventional chemiluminescence analyzer has a large control system, is not easily incorporated into the blood purification device, and takes time and effort to perform the measurement alone.
Therefore, the first object of the chemiluminescence analyzer 100 of the present embodiment is to provide the chemiluminescence analyzer 100 that is easier to install than the conventional one.

In addition, because it is integrated with the blood purification device, there is a difference in the results output for each manufacturer or model of the blood purification device, so the measurement results with the same chemiluminescence analyzer cannot be obtained, or the data format There was also a problem that it was difficult to use because of the difference.
Therefore, the second object is to provide the following chemiluminescence analyzer 100.
Chemiluminescence analysis that enables doctors and patients to make more appropriate decisions regarding lifestyle improvements, for example, by outputting unified measurement result data that does not depend on the manufacturer or model of the blood purification device Device 100.
Also, chemiluminescence that facilitates data transmission to external terminals such as personal computers (PCs) and servers, mobile terminals such as smartphones, or the cloud, and makes it easier to manage the health status and dialysis results for each patient. This is an analyzer 100.
Furthermore, it is the chemiluminescence analyzer 100 capable of optimizing dialysis conditions (speed and time) together with past dialysis result data by interlocking with the blood purification apparatus.

FIG. 1 is a schematic diagram of a blood purification system 500 according to the present embodiment.
As shown in FIG. 1, a blood purification system 500 includes a blood purification device 200 such as a dialysis device, a chemiluminescence analyzer 100 that detects the concentration of urea contained in the liquid, and the like. The chemiluminescence analyzer 100 is a blood purification device. It is connected to a drainage flow path 220 for 200 drainage 201.
Here, the configuration shown in FIG. 1 is merely an example, and the chemiluminescence analyzer 100 can be installed in the purification device interior 210 of the blood purification device 200 as an optional product. Further, depending on the configuration of the chemiluminescence analyzer 100, it can be used as a single device independent of the blood purification device 200.
Here, since a known dialysis apparatus can be used as the blood purification apparatus 200, detailed description thereof is omitted.

The effluent 201 of the blood purification apparatus 200 passes through the analyzer interior 110 of the chemiluminescence analyzer 100 and is then discharged again to the effluent channel 220 and discarded.
A reagent 141 as a luminescent reagent to be reacted with the effluent 201 of the blood purification apparatus 200 is supplied from a reagent container 140 installed outside the chemiluminescence analyzer 100.
The chemiluminescence analyzer 100 can be operated alone, but wired and wirelessly with an external terminal 310 such as a personal computer (hereinafter referred to as a PC) or a server, a portable terminal 320 including a smartphone, or the like. Communication is now possible.

Next, the basic configuration of the chemiluminescence analyzer 100 will be described with reference to the drawings.
FIG. 2 is an explanatory diagram of the basic configuration of the chemiluminescence analyzer 100 divided into two casings.
As shown in FIG. 2, the chemiluminescence analyzer 100 includes a reactor 111 that reacts the drainage 201 of the blood purification device 200 containing urea with the reagent 141, and the chemistry of the drainage 201 and the reagent 141 of the blood purification device 200. A photodetector 112 for detecting chemiluminescence due to the reaction is provided. Further, a drainage liquid feeding means 113 for transporting the drainage liquid 201 of the blood purification apparatus 200 to the reactor 111 and a reagent liquid feeding means 114 for transporting the reagent 141 to the reactor 111 are also provided.
In addition, a control unit 130 for controlling the operation of each device or means (system) provided in the analysis device internal 110, a blood purification device 200, an external terminal 310, a portable terminal 320, a magnetic card, an IC card, etc. A communication unit 160 that communicates with the information recording medium is also provided.

The effluent 201 of the blood purification apparatus 200 and the reagent 141 are transported to the reactor 111, and chemiluminescence is generated by these chemical reactions.
Examples of the configuration of the reactor 111 include the configuration described in Patent Document 2 and the configuration described in Patent Document 3, but are not limited thereto.

The photodetector 112 is disposed so as to be in contact with the reactor 111, and detects the amount of chemiluminescence generated in the reactor 111.
The photodetector 112 includes a photomultiplier tube, a photodiode, a phototransistor, a photo IC, an avalanche photodiode, a multi-pixel photon counter, and the like, and can be arbitrarily selected.

  The drainage liquid feeding means 113 is disposed between the drainage flow path 220 of the drainage 201 discharged from the blood purification apparatus 200 and the reactor 111, and transports the drainage 201 of the blood purification apparatus 200 to the reactor 111. To do.

  The reagent feeding means 114 is disposed between the reagent container 140 or the reagent port 127 and the reactor 111, and transports the reagent 141 from the reagent container 140 to the reactor 111.

The electrical interface unit 165 is operated and controlled with the liquid delivery / reaction unit 101 provided with electrical / electronic components such as the photodetector 112, the liquid delivery unit 113, and the liquid delivery unit 114 and the reagent delivery unit 114. It is provided between the control unit 130 in the unit 102 and exchanges power and signals.
Here, the chemiluminescence analyzer 100 of the present embodiment is separated into two housings, an operation / control unit 102 and an operation / control unit 102 as shown in FIG.

The control unit 130 controls the operation of each device and means provided in the analyzer internal 110 and has the following functions.
The drainage liquid feeding means 113 is operated so that the drainage 201 of the blood purification apparatus 200 is transported to the reactor 111.
The reagent feeding means 114 is operated so as to transport the reagent 141 to the reactor 111.
When the drainage flow rate measuring means 117 is mounted between the drainage liquid feeding means 113 and the reactor 111, the operation of the measured drainage liquid feeding means 113 can be changed using the flow rate measurement result. is there.
The urea concentration in the effluent 201 of the blood purification apparatus 200 is obtained by multiplying the chemiluminescence amount detected by the photodetector 112 by a coefficient recorded in advance.

When the mixed liquid flow rate measuring means 119 which is a flow rate measuring means for measuring the flow rate of the mixed liquid 181 of the drainage liquid 201 and the reagent 141 after reacting in the reactor 111 is mounted, the flow rate measurement result is used to The amount of chemiluminescence detected by the detector 112 may be corrected.
When the reagent liquid temperature measuring means 120 and the tank liquid temperature measuring means 115a for measuring the liquid temperature of the reagent 141 and the drained liquid 201 are mounted, the chemiluminescence amount detected using the liquid temperature measurement result can be corrected. is there.
Then, the control unit 130 displays various information such as the calculated urea concentration value on the display unit 150 (see FIG. 7), or through the communication unit 160, the blood purification device 200, an external terminal 310 such as a PC or a server, And transmitted to a mobile terminal 320 including a smartphone.
In addition, the control unit 130 interprets and responds to a user operation on the operation unit 170 (see FIG. 7) or a command received from the blood purification device 200, the external terminal 310, the portable terminal 320, or the like through the communication unit 160.
For example, the control unit 130 starts or stops measurement, or performs processing such as displaying / notifying an error state of measurement data of the chemiluminescence analyzer 100.

  As described above, by providing the display unit 150 and the operation unit 170, the chemiluminescence analyzer 100 of this embodiment can be operated and operated as an independent chemiluminescence analyzer 100.

The communication unit 160 transmits and receives data and commands (commands) to and from the blood purification device 200, an external terminal 310 such as a PC or server, and a mobile terminal 320 including a smartphone.
The communication unit 160 may include communication software 161, but may be configured only by hardware.
In some cases, a function of reading and writing data from and to an information recording medium such as a magnetic card or an IC card is provided.
The communication unit 160 is provided with a transmission / reception device 162 such as a connector (interface) for communication, an antenna, and a slot of an information recording medium. The transmission / reception device 162 may have the function of the electrical interface unit 165 on the operation / control unit 102 side.

  The display unit 150 and the operation unit 170 are switches for the operator of the chemiluminescence analyzer 100 to instruct the start / end timing of measurement, and to check the measurement result and the state of the chemiluminescence analyzer 100, Indicators such as lamps and displays are provided.

Next, the actual operation will be described below.
The chemiluminescence analyzer 100 includes three capillaries, one of which is a drainage flow path 220 of the blood purification apparatus 200, one is a reagent container 140 which is a reagent supply unit, and the other is discharged from the apparatus. The drainage pipe 222 is a drainage flow path for the drainage to be discharged.
In the example illustrated in FIG. 2, a drainage flow path connected to the drainage processing unit 240 that processes the drainage of the blood purification apparatus 200 is assumed, but a drainage container or the like that stores the drainage of the blood purification apparatus 200 may be used. .
Here, the liquid to be analyzed by the chemiluminescence analyzer 100 is not limited to the drainage of the blood purification apparatus 200, and urine or a liquid obtained by diluting urine can also be used. In addition, the reagent container 140 as the reagent supply unit has various forms such as a reagent tank and a reagent cartridge.

Next, operations related to reaction and light emission will be described.
Inside the reactor 111, the effluent 201 of the transported blood purification apparatus 200 and the reagent 141 are mixed to cause a chemical reaction, and chemiluminescence is generated.
The light is converted into an electrical signal by the photodetector 112 and transmitted to the control unit 130.
Transport of the waste liquid 201 and the reagent 141 to the reactor 111 is performed by the drain liquid feeding means 113 and the reagent liquid feeding means 114 which are the respective liquid feeding means. Further, the liquid mixture 181 of the drainage liquid 201 and the reagent 141 is naturally discharged with the transport of the drainage liquid 201 and the reagent 141.
The discharged mixed liquid 181 is stored in a tank, a cartridge, or the like of the mixed liquid 181 or is transported to the drainage processing unit 240 or the like.

Next, the control unit 130 and the communication unit 160 will be described.
The control unit 130 controls the drainage liquid feeding means 113 and the reagent liquid feeding means 114 which are the above-described liquid feeding means, and transports the drainage liquid 201 and the reagent 141 of the blood purification apparatus 200 to the reactor 111.
Further, the control unit 130 converts the electrical signal output from the photodetector 112 into the urea concentration in the drainage 201.
Information such as a trigger for starting measurement and the converted urea concentration is transmitted / received to / from an external device such as the external terminal 310 or the portable terminal 320 through the communication unit 160.

The communication unit 160 mainly performs the following.
First, an instruction to start or forcibly stop a measurement operation is received from an external device such as the external terminal 310 or the portable terminal 320 and notified to the control unit 130.
Second, at the end of measurement, the measurement result (urea concentration) is transmitted to an external device such as the external terminal 310 or the portable terminal 320.
Third, the error state of the chemiluminescence analyzer 100 is transmitted to an external device such as the external terminal 310 or the portable terminal 320.

By using this chemiluminescence analyzer 100, the urea concentration in the effluent 201 of the blood purification apparatus 200 can be quickly measured during blood purification, so that the state of blood purification can be known in real time. It becomes like this.
Further, by transmitting the measured data to an external device such as the external terminal 310 or the mobile terminal 320, the following can be realized.
An appropriate end timing of blood purification by the blood purification apparatus 200 can be determined from the urea concentration value obtained by measuring the effluent 201 of the blood purification apparatus 200 with the chemiluminescence analyzer 100.

In addition, the PC or server used as the external terminal 310 can grasp the patient's health status from long-term data accumulation and can be used for advice such as life improvement.
Furthermore, the accumulated data can be used to reproduce the same blood purification state even when using a blood purification device or dialysate that is different from usual during disasters or traveling. As a result, the blood purification rate and the blood urea amount at the end of blood purification can be maintained, and the patient's poor physical condition can be prevented.
On the other hand, the portable terminal 320 is similar to the external terminal 310 such as a PC or a server, but this can be used for the health management of the patient himself.
Here, the chemiluminescence analyzer 100 described above can be incorporated into the blood purification apparatus 200 or installed outside.

Here, as described above, it is possible to divide the case of the chemiluminescence analyzer 100 into one instead of dividing the case into two. For example, the following basic configuration examples are given.
FIG. 3 is an explanatory diagram of the basic configuration of the chemiluminescence analyzer 100 with one housing.
When the chemiluminescence analyzer 100 has one housing, the electrical interface unit 165 may be provided inside the housing, as in the case where the housing shown in FIG. As shown in FIG. 3, the control unit 130 and each electrical / electronic component can be directly connected. By configuring in this way, the operation and effect when the case described later is divided into two cannot be achieved, but the configuration of the chemiluminescence analyzer 100 can be simplified.

However, the basic configuration of the two chemiluminescence analyzers 100 described above does not sufficiently solve the problem that it is difficult to easily install or move, and the problem of further increasing the accuracy of measurement. Remain in.
For example, as shown in FIG. 2, in the basic configuration of the chemiluminescence analyzer 100 described above, the drainage 201 is discharged from the drainage flow path 220 of the blood purification apparatus 200 using a connecting portion 123 such as a three-way joint provided outside. Is introduced into the chemiluminescence analyzer 100.
For this reason, when the chemiluminescence analyzer 100 is installed, as shown in FIG. 1, between the drain port 211 of the blood purification apparatus 200 installed on the floor 231 of the installation place 230 and the chemiluminescence analyzer 100, FIG. It is necessary to provide the connection part 123 as shown in FIG. In addition, a drainage processing unit for the blood purification apparatus 200 is formed by joining the liquid mixture 181 discharged from the chemiluminescence analyzer 100 to the drainage pipe 232 provided on the floor 231 of the installation place 230 for the blood purification apparatus 200. When discharging to 240, processing of the receiving part of the drainage pipe 232 is also required.
Therefore, the chemiluminescence analyzer 100 according to the present embodiment is improved as follows.

An improved configuration found by the inventors to solve the above-described problem of the chemiluminescence analyzer 100 will be described with reference to the drawings.
FIG. 4 is an explanatory diagram of an improved configuration of the chemiluminescence analyzer 100 with the housing divided into two.
In addition to the basic configuration described with reference to FIG. 2, the chemiluminescence analyzer 100 includes a tank 115 that stores a predetermined amount of the drainage 201 of the blood purification device 200, various measuring means, and the drainage 201 and the mixture 181. It has a connection port for introducing or discharging. Unlike the basic configuration, the analyzer 123 includes a connecting portion 123 serving as a connecting portion for connecting the flow path of the mixed liquid 181 after transported to the reactor 111 and reacting to the drainage flow path 220 of the blood purification apparatus 200. In addition to being provided in the interior 110, a check valve 124 and the like are also provided.

Specifically, the tank 115 stores a predetermined amount of the drainage 201 of the blood purification apparatus 200 transported to the reactor 111. As various measuring means, there are a tank liquid temperature measuring means 115a for measuring the temperature of the drainage liquid 201 in the tank 115 and a reagent liquid temperature measuring means 120 for measuring the temperature of the reagent 141 that has passed through the reagent liquid supplying means 114. I have. Further, a drainage flow rate measuring means 117 for measuring the flow rate of the drainage liquid 201 transported by the drainage liquid feeding means 113 and a mixed liquid flow rate measuring means 119 for measuring the flow rate of the mixed liquid 181 discharged from the reactor 111 are provided. ing.
Further, the inlet port 125 for introducing the drainage liquid 201, the cleaning liquid / calibration liquid port 126 for introducing the cleaning liquid and the calibration liquid, the reagent port 127 for introducing the reagent 141 into the analyzer 110, and the mixed liquid 181 are discharged out of the apparatus. Outlet port 128 and the like.
Further, the liquid mixture 181 that has been transported to the reactor 111 and reacted is connected to the drainage flow path 220 of the blood purification apparatus 200, and the liquid mixture 181 from the connection part 123 to the tank 115 side. A check valve 124 is also provided to prevent the flow of air.

The tank 115 stores the drainage 201 discharged from the blood purification apparatus 200, and the collected drainage 201 is taken out by the drainage liquid feeding means 113 when the urea concentration is measured and transported to the reactor 111.
The capacity of the tank 115 is preferably determined according to the amount of the drainage 201 necessary for the reaction in the reactor 111.
Further, if the drainage 201 of the blood purification apparatus 200 stays in the tank 115 for a long time, the old drainage 201 and the new drainage 201 are mixed, so that an error occurs in the concentration measurement. Therefore, it is desirable that the flow path in the tank 115 be formed such that the old drainage 201 is pushed out by the new drainage 201.
Here, the flow rate of the drainage fluid 201 of the blood purification device 200 varies depending on the operation of the blood purification device 200, but the provision of the tank 115 stops the drainage fluid discharge when the drainage fluid flow rate decreases. Even in this case, measurement errors due to insufficient drainage can be prevented.

Further, since the tank 115 is provided, the drainage liquid feeding means 113 is disposed between the tank 115 for storing the drainage 201 discharged from the blood purification apparatus 200 and the reactor 111 and is stored in the tank 115. Then, the discharged liquid 201 of the blood purification apparatus 200 is transported to the reactor 111.
Here, the tank 115 that is connected to the drainage flow path 220 of the blood purification apparatus 200 and stores the drainage 201 is upstream of the drainage liquid feeding means 113 that transports the drainage 201 to the reactor 111 in the transport direction. The following effects can be achieved by providing the internal analyzer 110 on the side.
Since the tank 115 is provided in the analysis apparatus interior 110, measurement can be performed without being affected by fluctuations in the flow rate of the drainage 201 of the blood purification apparatus 200.

  The connecting portion 123 is configured to dispose the mixed liquid 181 of the blood purification apparatus 200 discharged from the reactor 111 and the reagent 141 in the drainage flow path 220 of the blood purification apparatus 200 in order to discard the mixed liquid 181. And a three-way joint that connects the drainage flow path of the blood purification apparatus 200.

The inlet port 125 is a joint installed between the blood purification device 200 and the tank 115 so that the blood purification device 200 and the chemiluminescence analyzer 100 can be freely attached and detached. Examples of joints include quick joints and luer fittings.
In other words, the chemiluminescence analyzer 100 has an inlet port 125 that connects the drainage flow path 220 (relay pipe 221) outside the apparatus upstream of the drainage 201 in the flow direction and the drainage flow path 220 in the apparatus. I have.
Thereby, since the connection with the drainage flow path 220 of the blood purification apparatus 200 is enabled by the inlet port 125 provided in the chemiluminescence analyzer 100, the chemiluminescence analyzer 100 can be easily attached and detached. it can.

The outlet port 128 is installed between the drainage pipe 232 provided on the floor 231 and the like of the installation place 230 and the connecting portion 123 so that the blood purification apparatus 200 and the chemiluminescence analyzer 100 can be freely attached and detached. It is a joint.
In other words, the chemiluminescence analyzer 100 includes an outlet port 128 that connects the drainage flow path 220 (discharge pipe 222) outside the apparatus on the downstream side in the flow direction of the drainage 201 and the drainage flow path 220 in the apparatus. I have.
Accordingly, since the outlet port 128 provided in the chemiluminescence analyzer 100 can be connected to the drainage flow path 220 of the blood purification apparatus 200, connection to the flow path leading to the drainage pipe 232 is possible. Therefore, the chemiluminescence analyzer 100 can be easily attached and detached.

The reagent cartridge 140a is a form of the reagent container 140, and is a container in which a reagent 141 that is a luminescent reagent that reacts with the drainage 201 of the blood purification apparatus 200 to generate chemiluminescence is enclosed. To the reagent port 127 connected to the.
Although the form of the container is arbitrary, it can be attached to and detached from the chemiluminescence analyzer 100, and a luminescent reagent capable of performing one or more measurements is enclosed in one container.
Here, the type of the reagent 141 is not limited to one, and for example, the luminescent reagent and the sensitizer can be provided in separate containers. Therefore, the number of reagent liquid feeding means 114 is not limited to one.

The reagent port 127 is a joint installed between the reagent cartridge 140a and the reagent liquid feeding means in order to freely attach and detach the reagent liquid feeding means including the reagent liquid feeding means 114 and the reagent cartridge 140a as a reagent container. is there.
In other words, the chemiluminescence analyzer 100 includes a reagent port 127 between a reagent container such as a reagent container 140 and a reagent cartridge 140a that encloses the reagent 141, and the reagent feeding means 114.
Accordingly, since the reagent port 127 provided in the chemiluminescence analyzer 100 can be connected to a reagent container such as the reagent container 140 and the reagent cartridge 140a, the reagent container can be easily replaced.
If a reagent container such as the reagent cartridge 140a is not used, the reagent 141 is directly supplied from a container such as a tank.

The cleaning liquid / calibration liquid port 126 is connected to the tank 115 and is different from the inlet port 125 so that the cleaning liquid and the standard urea liquid for calibration can be injected into the tank 115 through the cleaning liquid / calibration liquid port 126. It has become.
In other words, the chemiluminescence analyzer 100 includes a tank 115 that is disposed in the drainage flow path 220 on the upstream side in the flow direction of the drainage 201 of the drainage liquid feeding means 113 and stores the drainage 201. A cleaning liquid / calibration liquid port 126 with a thin tube different from the drainage flow path 220 is provided.

Accordingly, since the cleaning solution or the calibration urea solution can be injected into the tank 115 from the cleaning solution / calibration solution port 126 provided in the chemiluminescence analysis device 100, the chemiluminescence analysis device 100 is connected to the blood purification device 200. Cleaning and calibration operations can be performed as is.
In addition, the chemiluminescence analyzer 100 can be cleaned and sensitivity calibrated while the chemiluminescence analyzer 100 is connected to the blood purification device 200.
It should be noted that when the cleaning liquid / calibration liquid port 126 is opened, the liquid in the tank 115 leaks out. Therefore, it is sealed so that it does not open when not in use, or the cleaning liquid / calibration liquid port 126 and the tank are not used. It is necessary to put a check valve between 115. Further, a member (such as a coupling by CPC) incorporating a check valve may be used.

The check valve 124 is provided between the tank 115 and the connecting portion 123 and is installed in a direction that prevents inflow of liquid from the connecting portion 123 toward the tank 115.
When the blood purification apparatus 200 stops discharging the drainage liquid 201, the drainage liquid feeding means 113 that is the first liquid feeding means of the chemiluminescence analyzer 100 operates, and the drainage liquid 201 in the tank 115 is taken out. In this case, a space that is not filled with liquid is generated in the tank. In this space, the mixed solution 181 from the reactor 111 may flow backward toward the tank 115 and mix into the tank 115.
The check valve 124 can prevent the urea concentration measurement error from occurring due to the mixed liquid 181 from the reactor 111 being mixed into the tank 115 through the connecting portion 123.

Next, the actual operation will be described below.
The chemiluminescence analyzer 100 is installed between the blood purification apparatus 200 and the drainage pipe 232 provided on the floor 231 of the installation place 230.
The effluent 201 of the blood purification device 200 is taken into the analyzer interior 110 from the inlet port 125, passes through the tank 115, and is discharged from the outlet port 128. Specifically, the inlet port 125 is connected to the drainage port 211 of the blood purification apparatus 200, and the outlet port 128 is connected to the drainage pipe 232.

  One check valve 124 and one connecting portion 123 are provided between the tank 115 and the outlet port 128. The purpose and function thereof will be described in more detail later. The tank 115 is connected to a drain liquid feeding means 113 which is a liquid feeding means. The drainage liquid feeding means 113 can transport the drainage 201 of the blood purification apparatus 200 passing through the tank 115 to the reactor 111.

Incidentally, the chemiluminescence analyzer 100 is additionally provided with a reagent port 127.
A reagent cartridge 140a as a reagent container 140 is detachably provided in the reagent port 127. The reagent port 127 is connected to a reagent liquid feeding means 114 as a liquid feeding means so that the reagent 141 in the reagent cartridge 140a can be fed to the reactor 111.
Although only one reagent port 127 and reagent solution feeding means 114 are shown in FIG. 4, a plurality of reagent ports 127 and reagent feeding means 114 may be provided.
Furthermore, a cleaning liquid / calibration liquid port 126 which is a utility port for the purpose of calibration and cleaning of the chemiluminescence analyzer 100 can be arbitrarily provided.
Here, calibration and cleaning operations will be described later.

Next, operations related to reaction and light emission will be described.
As described above, the tank 115 is connected to the drainage liquid feeding means 113 which is a liquid feeding means, and transports the drainage 201 of the blood purification apparatus 200 to the reactor 111. In addition, the reagent feeding means 114 as a feeding means is connected to the reagent port 127 described above, and the reagent 141 is drawn from the reagent cartridge 140 a as the reagent container 140 and transported to the reactor 111.
Inside the reactor 111, the transported waste liquid 201 and the reagent 141 are mixed to cause a chemical reaction, and chemiluminescence is generated. The light is converted into an electrical signal by a photodetector 112 connected to the reactor 111 and transmitted to the control unit 130. Further, the mixed liquid 181 of the drained liquid 201 and the reagent 141 after the reaction is discharged from the reactor 111.

  The flow path of the mixed liquid 181 is connected to the drainage flow path 220 of the blood purification apparatus 200 by a connecting portion 123 (three-way joint). Therefore, the mixed liquid 181 is discarded through the drainage flow path 220 together with the drainage 201 of the blood purification apparatus 200.

On the other hand, since the connecting portion 123 is also connected to the tank 115, when the blood purification device 200 stops discharging the drainage liquid 201, the reacted mixed solution 181 passes through the connecting portion 123 to the tank 115. There is a possibility of inflow. If the liquid mixture 181 flows into the tank 115, the waste liquid of the blood purification apparatus 200 and the liquid mixture 181 are mixed in the tank 115. When the drainage liquid feeding means 113 draws it up and transports it to the reactor 111, it causes a significant erroneous detection of the urea concentration.
In order to prevent this, a check valve 124 is provided between the connecting portion 123 and the tank 115 so that the liquid mixture 181 does not flow into the tank 115.

By the way, the flow rate, the flow rate, and the mixing ratio of the drainage 201 of the blood purification apparatus 200 transported to the reactor 111 and the reagent 141 that is a luminescent reagent increase or decrease the amount of luminescence, and cause of erroneous detection of the component concentration in the drainage 201 It becomes. In order to reduce or eliminate this error, it is desirable to provide a flow rate measuring means for measuring the flow rate in any of the drainage flow path 220, the flow path of the reagent 141, and the flow path of the mixed liquid 181 discharged from the reactor 111. .
Similarly, the temperature of the waste liquid 201 and the reagent 141 transported to the reactor 111 is also a factor for increasing or decreasing the amount of luminescence. In order to avoid or reduce this increase / decrease in the amount of emitted light, a liquid temperature measuring means is provided in any of the drainage flow path 220 of the blood purification apparatus 200, the reagent flow path, and the mixed liquid flow path from the reactor 111. Is desirable.

Therefore, in this improved configuration, as shown in FIG. 4, for the drainage 201 of the blood purification apparatus 200, a tank liquid temperature measuring means 115a for measuring the temperature of the drainage 201 in the tank 115, and a drainage liquid feeding means. A drainage flow rate measuring means 117 for measuring the flow rate between the reactor 113 and the reactor 111 is provided. As for the reagent 141, a reagent liquid temperature measuring unit 120 that measures the temperature of the reagent 141 is provided between the reagent feeding unit 114 and the reactor 111. A mixed liquid flow rate measuring means 119 for measuring the flow rate of the mixed liquid 181 is provided between the reactor 111 and the connecting portion 123.
And the value detected by the photodetector 112 or the value of the component concentration in the drainage 201 obtained by the control unit 130 is corrected using the flow rate and temperature values at each location measured by these various measuring means. As a result, it is possible to reduce the error of the component concentration value and to eliminate the cause of erroneous detection.

The drainage liquid feeding means 113 that is the first liquid feeding means, the reagent liquid feeding means 114 that is the second liquid feeding means, the photodetector 112, and various measuring means described so far are connected via the electrical interface unit 165. It is connected to the control unit 130.
The control unit 130 mainly operates the above-described means and devices, and converts the signal received from the photodetector 112 into the urea concentration in the drainage 201 of the blood purification device 200.
More specifically, the following operation is performed.
When the measurement start command is received from the communication unit 160 or the operation unit 170 or when the time stored in the timer in the control unit 130 has elapsed, the control unit 130 operates each liquid feeding means to the reactor 111. The effluent 201 and the reagent 141 of the blood purification apparatus 200 are transported. Then, chemiluminescence is generated inside the reactor 111.
At this time, the output signals of the respective flow rate measuring means are monitored, and in some cases, the operation of the liquid feeding means is adjusted so as to obtain a desired flow rate. In some cases, the output signal is used to correct the photodetector.

Thereafter, the photodetector 112 outputs an electrical signal corresponding to the received light quantity, but is received by the control unit 130 and converted into a urea concentration by the control unit 130. Here, the temperature information detected by each liquid temperature measuring means is used to correct the output signal of the photodetector 112 and the conversion formula to the urea concentration.
When the output signal, flow rate information, and liquid temperature information of the photodetector 112 are obtained, the operation of each liquid feeding means is stopped.
Finally, the measurement result is transmitted to the external device such as the external terminal 310 and the portable terminal 320 through the communication unit 160 and the result is displayed on the display unit 150. At the same time, a timer in the control unit 130 may be set to match the next measurement timing. The time between them is several seconds to 1 minute.

Here, similarly to the basic configuration described above, the case of the chemiluminescence analyzer 100 can be made one instead of being divided into two. For example, examples of the following improved configuration can be given.
FIG. 5 is an explanatory diagram of a basic configuration of the chemiluminescence analyzer 100 having a single housing.
When the case of the chemiluminescence analyzer 100 is one, the electrical interface unit 165 may be provided inside the case as in the case where the case shown in FIG. 4 is divided into two. As shown in FIG. 5, the control unit 130 and each electrical / electronic component can be directly connected. With this configuration, the operation and effect when the case described below is divided into two cannot be achieved, but the configuration of the chemiluminescence analyzer 100 can be simplified. In addition, the chemiluminescence analyzer 100 can be provided that is easier to install than conventional ones.

In the configuration in which the housing is divided into two, it is separated into two housings, the liquid feeding / reaction unit 101 and the operation / control unit 102, and the electric / electronic components provided in the liquid feeding / reaction unit 101 The control unit 130 in the operation / control unit 102 is connected via an electrical interface unit 165.
By connecting in this way, it is also possible to configure a plurality of chemiluminescence analyzers to be controlled by one control unit. For example, you may comprise as shown in FIG.
FIG. 6 is an explanatory diagram of a configuration example in which the liquid feeding / reaction unit 101 connected to each of the plurality of blood purification devices 200 is controlled by the control unit 130 provided in one operation / control unit 102.

As shown in FIG. 6, the electric / electronic components of the liquid feeding / reaction unit 101 (a, b, c) of the chemiluminescence analyzer 100 provided in each of the three blood purification devices 200 (a, b, c), A control unit 130 in one operation / control unit 102 is connected via an electrical interface unit 165.
And by one control part 130, the liquid feeding / reaction part 101 (a, b, c) respectively connected to the three blood purification apparatuses 200 (a, b, c), that is, the three chemiluminescence analyzers 100 ( a, b, c) are controlled.
Here, in the configuration example shown in FIG. 6, between each of the liquid feeding / reaction units 101 (a, b, c) and the electrical interface unit 165 that connects the control unit 130 in the operation / control unit 102, Power is also supplied to the electric / electronic components of the liquid feeding / reaction unit 101 (a, b, c). For this reason, a power source / signal line 168 is used as an electric wire connecting each liquid feeding / reaction unit 101 (a, b, c) and the control unit 130 in the operation / control unit 102.
With this configuration, it is possible to provide the chemiluminescence analyzer 100, the blood purification device 200, and the blood purification system 500 that are easier to install than in the past.

Next, a cleaning method will be described.
The effluent 201 of the blood purification apparatus 200 contains components of dialysis fluid and human wastes, and these adhere to transport tubules, tanks 115, reactors 111, and the like.
When the chemiluminescence analyzer 100 is connected to the blood purification apparatus 200, the cleaning liquid of the blood purification apparatus 200 flows through the analysis apparatus interior 110, and thus is cleaned to some extent.
However, since it is drained after the blood purification apparatus 200 is cleaned, the cleaning effect is reduced. In addition, the cleaning liquid does not naturally flow through the flow channel that is fed by each liquid feeding means such as the reactor 111.
If cleaning is not performed, dirt and scales adhere to and accumulate in the reactor 111 and various measuring means, causing a reduction in sensitivity and measurement accuracy.
For these reasons, it is required to clean the inside 110 of the analyzer.

As for the actual cleaning means, the drainage flow path 220 through which the drainage 201 of the blood purification apparatus 200 passes may be introduced from the inlet port 125 into which the drainage 201 is taken.
Specifically, the following procedure is performed.
1: When blood purification is not performed, the drainage liquid feeding means 113 is driven to remove the liquid remaining in the tank 115 to some extent.
2: The drainage flow path 220 and the inlet port 125 of the blood purification apparatus 200 are disconnected, and the cleaning liquid is injected from the inlet port 125.
3: The drainage liquid feeding means 113 is driven to transport the cleaning liquid from the tank 115 toward the reactor 111.
Here, in the case of the chemiluminescence analyzer that is not provided with the check valve 124 described above, the connection between the outlet port 128 and the discharge pipe 222 is disconnected, and the outlet port 128 is closed, whereby the cleaning liquid circulates inside the analyzer 110. As a result, cleaning efficiency increases.

The method using the inlet port described above is inconvenient because it is necessary to disconnect the chemiluminescence analyzer 100 and the blood purification device 200 each time cleaning is performed.
Therefore, another port connected to the tank 115 is added as a cleaning liquid / calibration liquid port 126.
When the cleaning liquid is injected into the tank 115 from the added cleaning liquid / calibration liquid port 126 and the liquid feeding means is driven in synchronization with the reactor 111 to clean the reactor 111, and the additional cleaning liquid / calibration liquid port 126 is used. In addition, washing can be performed even during blood purification.
Here, it is necessary to consider the installation of a sealing means, a check valve, etc. so that the drainage liquid 201 of the blood purification apparatus 200 does not leak from the added cleaning liquid / calibration liquid port 126.
The flow path on the reagent 141 side may be washed by injecting a washing solution from the reagent port 127.

The cleaning liquid may have the same components as the cleaning liquid of the blood purification apparatus 200, but it is necessary to prevent the reagent 141 and the cleaning liquid from causing a chemical reaction to generate harmful substances.
There are a method of limiting the components of the cleaning liquid and a method of cleaning the reagent 141 once with water or hot water (preferably pure water or purified water) before flowing the cleaning liquid, and then performing cleaning.
There are two types of stains, one from human waste and one from calcium contained in dialysate (scale). It is desirable to use different washing solutions for each, so the latter is more suitable for the actual situation. It can be said that.

Next, calibration will be described.
The calibration is performed to prevent erroneous detection of the urea concentration due to sensitivity fluctuations due to deterioration of the photodetector 112 in addition to the contamination of the reactor 111 described above.
Basically, the measurement operation may be performed while injecting an aqueous solution having a known urea concentration into the tank 115 of the chemiluminescence analyzer 100.
As the injection path of the calibration urea solution, either the inlet port 125 or the added cleaning liquid / calibration liquid port 126 can be used as in the cleaning.

Next, operations other than measurement will be described.
First, as described above, the communication unit 160 transmits and receives measurement start commands and measurement data. In addition, the communication unit 160 mainly performs the following operations.
The first is an operation for notifying the external device of the state of the chemiluminescence analyzer.
The second is an operation for communicating a command such as an emergency stop of measurement.
Here, the two operations described above are merely examples, and the communication unit 160 may be configured to perform other operations.

The operation unit 170 includes operations related to measurement, cleaning and calibration, stopping them, and operations related to communication and display, and buttons and switches are provided so that they can be performed appropriately.
In addition to the result display, the display unit 150 performs various displays linked with various operations. Therefore, it is desirable that the display unit 150 includes a lamp and a display capable of displaying characters. Here, a display unit 150 and an operation unit 170 that are integrated, such as a touch panel display, may be used.

Unlike the chemiluminescence analyzer of the basic configuration described above, the chemiluminescence analyzer 100 of this improved configuration is assumed to be installed outside the blood purification device 200, and the operation unit 170 and the display unit are always installed. Provided and configured as a device that can operate stand-alone.
For this reason, it can be operated as an independent chemiluminescence analyzer 100 as necessary. When operating in this way, the type of inspection object is not limited to urea.

Here, the example of arrangement | positioning of the main apparatuses of the chemiluminescence analyzer 100 of an improved structure is demonstrated using figures.
FIG. 7 is an explanatory perspective cross-sectional view of the main apparatus of the chemiluminescence analyzer 100 having an improved configuration, and is an example in the case of a single housing.
As shown in FIG. 7, the chemiluminescence analyzer 100 having an improved configuration is provided with the operation unit 170 and the display unit 150 on the front slope on the upper left side in FIG. ) To the inlet port 125, the cleaning liquid / calibration liquid port 126, and the reagent port 127. On the other hand, an outlet port 128 for discharging the mixed liquid 181 after the reaction is provided on the side surface on the lower right side in FIG.

Further, in the analysis apparatus interior 110, a substrate on which the control unit 130 and the communication unit 160 are arranged at the top is arranged behind the slope provided with the operation unit 170 and the display unit 150 in FIG. A reactor 111 and a photodetector 112 are disposed below. Further below, a drainage liquid feeding means 113, a reagent liquid feeding means 114, a mixed liquid flow rate measuring means 119, a drainage flow rate measuring means 117, a connecting portion 123, and the like are disposed, and a tank 115 is disposed below these. Has been placed.
Here, since the main apparatus is shown as a perspective sectional view in FIG. 7, each temperature measuring means of the tank liquid temperature measuring means 115a, the reagent liquid temperature measuring means 120, and the check valve 124 are shown in FIG. It is arranged in the middle, invisible position or omitted position.
The temperature measurement means arranged at these invisible positions and omitted positions and the arrangement position of the check valve 124 are arranged as shown in FIGS. 4 and 5 in the vicinity of the connected device.

  As described above, the chemiluminescence analyzer 100 according to this embodiment includes the reactor 111 that causes the drainage 201 of the blood purification device 200 and the reagent 141 to react, and the light that measures the emission intensity of chemiluminescence generated in the reactor 111. And a detector 112. Then, a drainage liquid feeding means 113 for transporting the drainage liquid 201 from the drainage flow path 220 of the blood purification apparatus 200 to the reactor 111 and a reagent liquid feeding means 114 for transporting the reagent 141 to the reactor 111 are provided. In addition, a connection part 123 that connects the flow path of the mixed liquid 181 of the drainage liquid 201 and the reagent 141 after being transported to the reactor 111 to the drainage flow path 220 of the blood purification apparatus 200, and an electrical interface A portion 165 is also provided.

With this configuration, the chemiluminescence analyzer 100 of the present embodiment can achieve the following effects.
Since the electrical interface unit 165 is provided, the control unit 130 can be separated as shown in FIGS. Since separation is possible in this way, the case of the liquid feeding / reaction unit 101 provided with the photodetector 112 and the like and the case of the operation / control unit 102 provided with the control unit 130 are separated from each other. The degree of freedom of installation (arrangement) is improved.
Further, a single control unit 130 can control a plurality of chemiluminescence analyzers 100 (a, b, c). For example, centralized management of the plurality of chemiluminescence analyzers 100 (a, b, c) It is also possible to create a measuring instrument that measures the component concentrations of a plurality of specimens.
In addition, since the analyzer 110 includes the connecting portion 123 of the drainage 201, the mixed solution 181 discharged from the reactor 111 can be discarded into the drainage flow path 220 of the blood purification device 200 and discharged. It is easy to secure the flow path.
Therefore, it is possible to provide the chemiluminescence analyzer 100 that is easier to install than conventional ones.

  In addition, the chemiluminescence analyzer 100 of the present embodiment includes a reactor 111 that reacts the drainage 201 of the blood purification device 200 and the reagent 141, and a photodetector 112 that measures the emission intensity of chemiluminescence generated in the reactor 111. With. And the drainage liquid feeding means 113 which transports the waste liquid 201 from the drainage flow path 220 of the blood purification apparatus 200 to the reactor 111, the reagent liquid feeding means 114 which transports the reagent 141 to the reactor 111, and the photodetector 112, a controller 130 for controlling the drainage liquid feeding means 113 and the reagent liquid feeding means 114. In addition, the communication unit 160 that communicates with the external terminal 310, the portable terminal 320, and the like, and the flow path of the mixed solution 181 of the drained liquid 201 and the reagent 141 after being transported and reacted to the reactor 111 are connected to the blood purification apparatus 200. The connection part 123 connected to the drainage flow path 220 is also provided.

With this configuration, the chemiluminescence analyzer 100 of the present embodiment can achieve the following effects.
Since the control unit 130 and the communication unit 160 are provided, it is possible to provide the chemiluminescence analyzer 100 that operates by receiving commands from the external terminal 310, the portable terminal 320, and the like alone. On the other hand, even when incorporated into the blood purification apparatus 200, the electrical wiring between the blood purification apparatus 200 and the chemiluminescence analyzer 100 can be reduced, and the instructions for the operation of the chemiluminescence analyzer 100 can be simplified. Can be.
In addition, since the analyzer 110 includes the connecting portion 123 of the drainage 201, the mixed solution 181 discharged from the reactor 111 can be discarded into the drainage flow path 220 of the blood purification device 200 and discharged. It is easy to secure the flow path.
Therefore, it is possible to provide the chemiluminescence analyzer 100 that is easier to install than conventional ones.

Further, the chemiluminescence analyzer 100 of the present embodiment is configured such that the liquid temperature of the tank liquid temperature measuring means 115a or the reagent liquid temperature measuring means 120 that measures at least one liquid temperature of the drainage liquid 201, the reagent 141, and the mixed liquid 181. Measuring means are provided.
With this configuration, the chemiluminescence analyzer 100 of the present embodiment can achieve the following effects.
By obtaining liquid temperature information of at least one of the drainage liquid 201, the reagent 141, and the mixed liquid 181 of the blood purification device 200 by the liquid temperature detection means, and correcting the output signal of the photodetector 112 by the control unit 130. Further, it is possible to reduce the influence of the emission intensity fluctuation of chemiluminescence due to the liquid temperature.

In addition, the chemiluminescence analyzer 100 according to the present embodiment includes a flow rate measuring unit such as a drainage flow rate measuring unit 117 or a mixed solution flow rate measuring unit 119 that measures at least one flow rate of the drainage solution 201, the reagent 141, and the mixed solution 181. It has.
With this configuration, the chemiluminescence analyzer 100 of the present embodiment can achieve the following effects.
The control unit 130 that also functions as a flow rate adjusting unit acquires flow rate information of at least one of the drainage 201, the reagent 141, and the mixed solution 181 of the blood purification device 200 by the flow rate detection unit and outputs the flow rate information to the output signal of the photodetector 112. By adding correction, it is possible to reduce the influence of the emission intensity fluctuation of chemiluminescence due to the flow rate and the mixing ratio.

Further, the chemiluminescence analyzer 100 of the present embodiment includes a check valve 124 at the following position.
When the tank 115 for storing the drainage 201 is provided in the drainage flow path 220 on the upstream side in the flow direction of the drainage 201 of the drainage liquid feeding means 113, the liquid mixture 181 is mixed into the tank 115. A check valve 124 is provided at a position such as between the tank 115 and the connecting portion 123 that is not allowed. On the other hand, when the tank 115 is not provided, a check valve 124 is provided at a position where the mixed liquid 181 is not mixed into the flow path for flowing the drained liquid 201 to the drained liquid feeding means 113.
With this configuration, the chemiluminescence analyzer 100 of the present embodiment can achieve the following effects.
Since the check valve 124 prevents the mixed solution 181 discharged from the reactor 111 from flowing into the tank 115 and the drainage liquid feeding means 113, the mixed liquid 181 is mixed into the tank 115 and the drainage liquid feeding means 113. Occurrence of urea concentration measurement errors can be prevented.

In addition, the blood purification apparatus 200 according to the present embodiment includes the chemiluminescence analyzer 100 having any one of the above-described configurations as a measurement unit that measures the urea concentration contained in the drainage 201 discharged when purifying blood. Can do.
With this configuration, the blood purification apparatus 200 of the present embodiment can achieve the same effects as the chemiluminescence analyzer 100 having any one of the above-described configurations.

In addition, the blood purification system 500 of the present embodiment has a chemistry having any one of the above-described configurations as a blood purification device 200 that purifies blood and a measurement unit that measures the urea concentration contained in the effluent 201 of the blood purification device 200. An emission analyzer 100 can be provided.
With this configuration, the blood purification system 500 of the present embodiment can achieve the same effects as the chemiluminescence analyzer 100 having any one of the configurations described above.

  As described above, the present embodiment has been described with reference to the drawings. However, the specific configuration is not limited to the configuration including the chemiluminescence analyzer 100 of the present embodiment described above, and the scope does not depart from the gist. The design may be changed.

What was demonstrated above is an example, and there exists an effect peculiar for every following aspect.
(Aspect A)
A reactor such as a reactor 111 that reacts a drain solution such as the drainage 201 of a blood purification device such as the blood purification device 200 and a reagent solution such as a reagent 141, and the emission intensity of chemiluminescence generated in the reactor is measured. In a chemiluminescence analyzer such as the chemiluminescence analyzer 100 having a photodetector such as the photodetector 112, the drainage channel such as the drainage channel 220 of the blood purification device is discharged to the reactor. A first liquid feeding means such as a drain liquid feeding means 113 for transporting the liquid, a second liquid feeding means such as a reagent liquid feeding means 114 for transporting the reagent solution to the reactor, and a transported to the reactor. A connection part such as a connection part 123 for connecting a flow path of the mixed liquid such as the mixed liquid 181 of the drainage liquid and the reagent solution after the reaction to the drainage flow path of the blood purification apparatus; and an electrical interface part 165 etc. Characterized in that it comprises a face portion, a.

According to this, as described in the present embodiment, the following effects can be achieved.
Since the electrical interface unit is provided, the control unit such as the control unit 130 can be separated, and the operation / control unit provided with a control unit such as a liquid feeding / reaction unit 101 provided with a photodetector and the like. The degree of freedom of installation (arrangement) is improved by making the housing such as 102 a separate housing.
In addition, a plurality of chemiluminescence analyzers can be controlled by a single control unit. For example, centralized management of a plurality of chemiluminescence analyzers or a measuring instrument for measuring the component concentrations of a plurality of specimens can be created. realizable.
In addition, since the drainage connecting portion is provided inside the apparatus such as the analyzer interior 110, the liquid mixture discharged from the reactor can be discarded in the drainage flow path of the blood purification apparatus. Is easy to secure.
Therefore, it is possible to provide a chemiluminescence analyzer that is easier to install than conventional ones.

(Aspect B)
A reactor such as a reactor 111 that reacts a drain solution such as the drainage 201 of a blood purification device such as the blood purification device 200 and a reagent solution such as a reagent 141, and the emission intensity of chemiluminescence generated in the reactor is measured. In a chemiluminescence analyzer such as the chemiluminescence analyzer 100 having a photodetector such as the photodetector 112, the drainage channel such as the drainage channel 220 of the blood purification device is discharged to the reactor. A first liquid feeding means such as a drain liquid feeding means 113 for transporting the liquid; a second liquid feeding means such as a reagent liquid feeding means 114 for transporting the reagent solution to the reactor; the photodetector; A control unit such as a control unit 130 that controls the first liquid feeding unit, the second liquid feeding unit, a communication unit such as a communication unit 160 that communicates with an external device such as the external terminal 310 or the portable terminal 320, and the reactor. After being transported to the reaction The mixture flow path, such as a mixture 181 of the the liquid reagent solution, characterized in that it comprises a connecting portion such as a connecting portion 123 which connects to the drainage flow path of the blood purification apparatus.

According to this, as described in the present embodiment, the following effects can be achieved.
Since the control unit and the communication unit are provided, it is possible to provide a chemiluminescence analyzer that operates by receiving a command from an external device by communication alone. On the other hand, even when incorporated in the blood purification apparatus, the electrical wiring between the blood purification apparatus and the chemiluminescence analyzer can be reduced, and the instructions for the operation of the chemiluminescence analyzer can be simplified. it can.
In addition, since the drainage connecting portion is provided inside the apparatus such as the analyzer interior 110, the liquid mixture discharged from the reactor can be discarded in the drainage flow path of the blood purification apparatus. Is easy to secure.
Therefore, it is possible to provide a chemiluminescence analyzer that is easier to install than conventional ones.

(Aspect C)
(Aspect B) includes an operation unit such as the operation unit 170 and a display unit such as the display unit 150.
According to this, as described in the present embodiment, since the control unit, the operation unit, and the display unit are provided, it is easy to operate and operate as an independent chemiluminescence analyzer.

(Aspect D)
In any one of (Aspect A) to (Aspect C), a tank 115 that is disposed in the drainage flow path on the upstream side in the flow direction of the drainage of the first liquid feeding unit and stores the drainage, etc. A tank is provided.
According to this, as described in the present embodiment, since the tank is provided inside the analyzer 110 or the like, the measurement can be performed without being affected by the fluctuation of the flow rate of the drainage of the blood purification device. Can do.

(Aspect E)
In any one of (Aspect A) to (Aspect D), the tank liquid temperature measuring means 115a and the reagent liquid temperature measuring means 120 for measuring at least one liquid temperature of the drainage liquid, the reagent solution, and the mixed liquid are used. A liquid temperature measuring means is provided.
According to this, as described in the present embodiment, the following effects can be achieved.
By acquiring liquid temperature information of at least one of the drainage liquid, reagent solution, and mixed liquid of the blood purification device by the liquid temperature detection means, and correcting the output signal of the photodetector by the correction means such as the control unit 130 Further, it is possible to reduce the influence of the emission intensity fluctuation of chemiluminescence due to the liquid temperature.

(Aspect F)
In any one of (Aspect A) to (Aspect E), the flow rate of the drainage flow rate measurement unit 117, the mixed solution flow rate measurement unit 119, or the like that measures at least one flow rate among the drainage solution, the reagent solution, and the mixed solution A measuring means is provided.
According to this, as described in the present embodiment, the following effects can be achieved.
By acquiring flow rate information of at least one of the drainage solution, reagent solution, and mixed solution of the blood purification device by the flow rate detection means and correcting the output signal of the photodetector by the flow rate adjustment means such as the control unit 130, It is possible to reduce the influence of chemiluminescence emission intensity fluctuation due to the flow rate and the mixing ratio.

(Aspect G)
In any one of (Aspect A) to (Aspect F), the drainage flow path such as the drainage flow path 220 (relay pipe 221) outside the apparatus upstream in the drainage flow direction, and the drainage in the apparatus. A connection portion such as an inlet port 125 for connecting the liquid flow path is provided.
According to this, as described in the present embodiment, since the connection with the drainage flow path of the blood purification device is made possible by the connecting portion provided in the chemiluminescence analyzer, the attachment / detachment operation of the chemiluminescence analyzer is possible. Can be easily performed.

(Aspect H)
In any one of (Aspect A) to (Aspect G), the drainage flow path such as the drainage flow path 220 (discharge pipe 222) outside the apparatus on the downstream side in the drainage flow direction, and the drainage in the apparatus. A connection portion such as an outlet port 128 for connecting the liquid flow path is provided.
According to this, as described in the present embodiment, the connection portion provided in the chemiluminescence analyzer enables connection with a flow path to the drainage pipe such as the drainage pipe 232, so that the chemical The emission analyzer can be easily attached and detached.

(Aspect I)
In any one of (Aspect A) to (Aspect H), a connecting portion such as a reagent port 127 is provided between a reagent container such as a reagent container 140 or a reagent cartridge 140a that encloses the reagent solution and the second liquid feeding means. It is characterized by providing.
According to this, as described in the present embodiment, since the connection with the reagent container is made possible by the connecting portion provided in the chemiluminescence analyzer, the reagent container can be easily replaced.

(Aspect J)
In any one of (Aspect A) to (Aspect I), a tank 115 that is disposed in the drainage flow path on the upstream side in the flow direction of the drainage of the first liquid feeding unit and stores the drainage, etc. A tank is provided, and the tank includes a connecting portion such as a cleaning liquid / calibration liquid port 126 with a thin tube different from the drainage flow path.
According to this, as explained in the present embodiment, since the cleaning liquid and the urea solution for calibration can be injected into the tank from the connecting portion provided in the chemiluminescence analyzer, the chemiluminescence analyzer can be used as a blood purification device. Cleaning and calibration operations can be performed while connected to.

(Aspect K)
In any one of (Aspect A) to (Aspect J), a tank 115 that is disposed in the drainage flow path on the upstream side in the flow direction of the drainage of the first liquid feeding unit and stores the drainage, etc. In the case where a tank is provided, a check valve such as a check valve 124 is provided at a position such as between the tank 115 and the connecting portion 123 where the mixed liquid is not mixed into the tank, and the tank is not provided. Is characterized in that the check valve is provided at a position where the mixed liquid is not mixed into the flow path for flowing the drainage liquid to the first liquid feeding means.
According to this, as described in the present embodiment, the check valve prevents the mixed liquid discharged from the reactor from flowing into the tank and the first liquid feeding means. Occurrence of a urea concentration measurement error due to mixing in the liquid means can be prevented.

(Aspect L)
In a blood purification apparatus such as a blood purification apparatus 200 provided with a measurement means for measuring a concentration of a component to be detected such as a urea concentration contained in a drainage fluid such as the drainage fluid 201 discharged when purifying blood, as the measurement means, A chemiluminescence analyzer, such as the chemiluminescence analyzer 100 of any one of (Aspect A) to (Aspect K), is provided.
According to this, as described in the present embodiment, it is possible to provide a blood purification device that can achieve the same effects as any of the chemiluminescence analyzers of (Aspect A) to (Aspect K).

(Aspect M)
A blood purification device comprising: a blood purification device such as a blood purification device 200 for purifying blood; and a measuring means for measuring a concentration of a component to be detected such as a urea concentration contained in a drainage fluid such as a drainage fluid 201 of the blood purification device. A blood purification system such as the system 500 is characterized by including a chemiluminescence analyzer such as the chemiluminescence analyzer 100 of any one of (Aspect A) to (Aspect K) as the measuring means.
According to this, as described in the present embodiment, it is possible to provide a blood purification system that can achieve the same effects as any of the chemiluminescence analyzers of (Aspect A) to (Aspect K).

DESCRIPTION OF SYMBOLS 100 Chemiluminescence analyzer 101 Liquid supply / reaction part 102 Operation / control part 110 Inside of analysis apparatus 111 Reactor 112 Photodetector 113 Waste liquid supply means 114 Reagent supply means 115 Tank 123 Connection part 130 Control part 140 Reagent container 141 Reagent 165 Electrical interface unit 181 Mixed liquid 200 Blood purification apparatus 201 Drainage 220 Drainage flow path 310 External terminal 320 Portable terminal 500 Blood purification system

JP 2008-233005 A Japanese Patent No. 4855854 Japanese Patent No. 5637300

Claims (13)

In a chemiluminescence analyzer comprising: a reactor for reacting the effluent of the blood purification device and a reagent solution; and a photodetector for measuring the emission intensity of chemiluminescence generated in the reactor,
First liquid feeding means for transporting the drainage liquid from the drainage flow path of the blood purification apparatus to the reactor; and second liquid feeding means for transporting the reagent solution to the reactor;
A connecting portion for connecting a flow path of the mixed liquid of the drainage liquid and the reagent solution after being transported to the reactor and reacting with the drainage flow path of the blood purification device;
And a chemiluminescence analyzer comprising an electrical interface unit. In a chemiluminescence analyzer comprising: a reactor for reacting the effluent of the blood purification device and a reagent solution; and a photodetector for measuring the emission intensity of chemiluminescence generated in the reactor,
First liquid feeding means for transporting the drainage liquid from the drainage flow path of the blood purification apparatus to the reactor; and second liquid feeding means for transporting the reagent solution to the reactor;
A control unit for controlling the photodetector, the first liquid feeding means, and the second liquid feeding means;
A communication unit that communicates with an external device;
And a connecting portion that connects the flow path of the mixed solution of the drainage solution and the reagent solution after being transported to the reactor and connected to the drainage flow path of the blood purification device. Chemiluminescence analyzer. The chemiluminescence analyzer according to claim 2,
A chemiluminescence analyzer comprising an operation unit and a display unit. The chemiluminescence analyzer according to any one of claims 1 to 3,
A chemiluminescence analyzer, comprising a tank that is disposed in the drainage flow path upstream of the first liquid feeding unit in the flow direction of the drainage and stores the drainage. The chemiluminescence analyzer according to any one of claims 1 to 4,
A chemiluminescence analyzer comprising a liquid temperature measuring means for measuring at least one liquid temperature of the drainage liquid, the reagent solution, and the mixed liquid. The chemiluminescence analyzer according to any one of claims 1 to 5,
A chemiluminescence analyzer comprising flow rate measuring means for measuring a flow rate of at least one of the drainage solution, the reagent solution, and the mixed solution. The chemiluminescence analyzer according to any one of claims 1 to 6,
A chemiluminescence analyzer comprising: a connecting portion that connects the drainage flow channel outside the device upstream of the drainage flow direction and the drainage flow channel inside the device. The chemiluminescence analyzer according to any one of claims 1 to 7,
A chemiluminescence analyzer comprising: a connecting portion that connects the drainage flow channel outside the device downstream in the drainage flow direction and the drainage flow channel inside the device. The chemiluminescence analyzer according to any one of claims 1 to 8,
A chemiluminescence analyzer comprising a connecting portion between a reagent container enclosing the reagent solution and the second liquid feeding means. The chemiluminescence analyzer according to any one of claims 1 to 9,
A tank for storing the drainage, disposed in the drainage flow path upstream of the drainage flow direction of the first liquid feeding means;
2. The chemiluminescence analyzer according to claim 1, wherein the tank includes a connecting portion with a narrow tube different from the drainage channel. The chemiluminescence analyzer according to any one of claims 1 to 10,
In the case where a tank for storing the drainage is provided in the drainage flow path on the upstream side in the flow direction of the drainage of the first liquid feeding means, the mixed liquid is not mixed into the tank. With a check valve in position,
In the case where the tank is not provided, the chemiluminescence analyzer is provided with the check valve at a position where the mixed liquid is not mixed into the flow path for flowing the drainage to the first liquid feeding means. In a blood purification apparatus comprising a measuring means for measuring a concentration of a detection target component contained in a drainage discharged when purifying blood,
A blood purification apparatus comprising the chemiluminescence analyzer according to any one of claims 1 to 11 as the measuring means. In a blood purification system comprising: a blood purification device for purifying blood; and a measuring means for measuring the concentration of a component to be detected contained in the drainage of the blood purification device,
A blood purification system comprising the chemiluminescence analyzer according to any one of claims 1 to 11 as the measuring means.

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