Patent Application
20230211057
The present disclosure relates to monitoring of a manner of extracorporeal blood circulation.
Conventionally, there have been proposed various techniques for extracorporeal blood circulation in dialysis treatment or the like. For the extracorporeal blood circulation, Domestic Re-publication of PCT International Publication No. 2015-141621 (PTL 1) discloses a method for calibrating a blood concentration measurement value including an offset amount resulting from a difference between resin tubes, for example.
PTL 1: Domestic Re-publication of PCT International Publication No. 2015-141621
In dialysis treatment, water removal is performed using a closed system; however, in the closed system, the water removal may be excessive or insufficient due to leakage at an electromagnetic valve or the like. It is considered that by providing a dialysis device with a mechanism for detecting leakage at each electromagnetic valve, the above-described excessive water removal and insufficient water removal can be detected. However, addition of such a mechanism may lead to increased cost in the dialysis device. Further, leakage occurring at a portion other than the electromagnetic valve, such as leakage at a water removal pump, is not detected by the mechanism.
The present disclosure has been conceived in view of such an actual circumstance and has an object to provide a technique for detecting leakage in extracorporeal blood circulation while suppressing increased cost in a dialysis device.
According to a certain aspect of the present disclosure, there is provided a computer-implemented method of monitoring blood circulation, the method including: obtaining a physical quantity in an artery-side blood circuit that allows blood to flow into a blood purifier; obtaining a physical quantity in a vein-side blood circuit that allows the blood to flow out of the blood purifier; obtaining, by using at least one of the physical quantity obtained in the artery-side blood circuit and the physical quantity obtained in the vein-side blood circuit, a theoretical value of the physical quantity in the artery-side blood circuit or the vein-side blood circuit to determine an abnormality of a mechanism that supplies a dialysis fluid to the blood purifier; determining occurrence of the abnormality based on the theoretical value, the physical quantity in the artery-side blood circuit or the vein-side blood circuit, and a given threshold value; and performing an operation abnormality process when it is determined that the abnormality has occurred.
The obtaining of the theoretical value may include calculating a theoretical value of an indicator of a blood concentration in the vein-side blood circuit based on an indicator of a blood concentration obtained in the artery-side blood circuit. The determining of the occurrence of the abnormality may include determining that the abnormality has occurred when a difference between the theoretical value and an indicator of a blood concentration obtained in the vein-side blood circuit is more than or equal to the given threshold value.
The obtaining of the theoretical value may include finding a theoretical value of a blood flow rate in the vein-side blood circuit based on a blood flow rate obtained in the artery-side blood circuit. The determining of the occurrence of the abnormality may include determining that the abnormality has occurred when a difference between the theoretical value and a blood flow rate obtained in the vein-side blood circuit is more than or equal to the given threshold value.
A flow rate of a blood pump provided to send the blood in the artery-side blood circuit may be used as the blood flow rate obtained in the artery-side blood circuit.
The theoretical value may be further based on a water removal rate in the blood purifier.
The obtaining of the theoretical value may include storing, into a storage device as the theoretical value, an indicator of a blood concentration obtained in the artery-side blood circuit or the vein-side blood circuit at a first timing at which a dialysis fluid pump that promotes discharging of the dialysis fluid from the blood purifier is not operated.
The determining of the occurrence of the abnormality may include determining that the abnormality has occurred when a difference between the theoretical value and the indicator obtained at a second timing at which the dialysis fluid pump is not operated is more than or equal to the given threshold value.
The determining of the abnormality may be performed before starting dialysis treatment using the blood purifier.
The obtaining of the theoretical value may include obtaining a first difference that is a difference between an indicator of a blood concentration obtained in the artery-side blood circuit at a first timing and an indicator of a blood concentration obtained in the vein-side blood circuit at the first timing. The determining of the occurrence of the abnormality may include obtaining a second difference that is a difference between an indicator of a blood concentration obtained in the artery-side blood circuit at a second timing and an indicator of a blood concentration obtained in the vein-side blood circuit at the second timing, and determining that the abnormality has occurred when a difference between the first difference and the second difference is more than or equal to the given threshold value.
A water removal rate in the blood purifier at the first timing may be equal to a water removal rate in the blood purifier at the second timing.
Each of the indicators of the blood concentrations may include hematocrit.
According to another aspect of the present disclosure, there is provided a dialysis device including: a blood purifier; an artery-side blood circuit that allows blood to flow into the blood purifier; a vein-side blood circuit that allows the blood to flow out of the blood purifier; a blood pump provided to send the blood in the artery-side blood circuit; and a controller that controls an operation of the blood pump, wherein the controller performs the above-described method of monitoring the blood circulation.
According to still another aspect of the present disclosure, there is provided a program for causing, when executed by a computer, the computer to perform the above-described method of monitoring the blood circulation.
According to the present disclosure, occurrence of an abnormality such as leakage in extracorporeal blood circulation is detected using a physical quantity in an artery-side blood circuit and/or a physical quantity in a vein-side blood circuit.
Hereinafter, one embodiment of a dialysis device will be described with reference to figures. In the description below, the same parts and components are denoted by the same reference characters. Their names and functions are also the same. Therefore, these will not be described repeatedly.
[1. Configuration of Dialysis Device]
(Dialysis Unit 100)
Dialysis unit 100 includes: a dialyzer 103; an artery-side blood circuit 110 that connects a patient's artery to dialyzer 103; and a vein-side blood circuit 120 that connects the patient's vein to dialyzer 103. Dialyzer 103 is an exemplary blood purifier. Dialysis device 1 further includes: a blood pump 102 that sends blood to dialyzer 103 in artery-side blood circuit 110; a concentration measurement device 101 that measures a blood concentration in artery-side blood circuit 110; and a concentration measurement device 104 that measures a blood concentration in vein-side blood circuit 120.
Dialysis device 1 further includes a water removal mechanism 150, which is a mechanism that supplies a dialysis fluid to dialyzer 103. In water removal mechanism 150, the dialysis fluid is supplied to dialyzer 103 via an upstream-side dialysis fluid line 151, and the dialysis fluid is discharged from dialyzer 103 via a downstream-side dialysis fluid line 152. Water removal mechanism 150 includes a dialysis fluid pump 155 that promotes discharging of the dialysis fluid from dialyzer 103. As a method of supplying the dialysis fluid by water removal mechanism 150, various types of supply methods can be employed.
(Controller 200)
Controller 200 includes a processor 201, a storage device 202, an input device 203, an output device 204, and an input/output interface 205.
Processor 201 executes a program stored in storage device 202. Storage device 202 is constituted of a hard disk drive, a solid state drive, or the like. Storage device 202 may store various data to be used to execute a program.
Input device 203 is used by a user to input information to dialysis device 1, and is implemented by, for example, a keyboard, a mouse, a hardware button, and/or a touch sensor.
Output device 204 is used to output information from dialysis device 1, and is implemented by, for example, a display, an LED (Light Emitting Diode) lamp, and/or a speaker.
Input/output interface 205 is an interface for outputting data from each element in dialysis unit 100 to controller 200 and outputting data from controller 200 to each element in dialysis unit 100. In one example, controller 200 outputs a control instruction to blood pump 102 via input/output interface 205. In another example, controller 200 obtains respective measurement results from concentration measurement devices 101, 104 via input/output interface 205.
In the present embodiment, controller 200 controls dialysis unit 100 and can detect an abnormality associated with leakage in water removal mechanism 150. That is, controller 200 can detect abnormalities when leakages occur at various locations including an electromagnetic valve and dialysis fluid pump 155 of water removal mechanism 150.
[2. Water Removal in Dialysis Device]
Next, water removal from blood in dialysis device 1 will be described. In the description below, the names of physical quantities associated with dialysis device 1 are defined as follows.
“BP” represents a flow rate of blood pump 102.
“Ht(A)” represents a blood concentration on the artery side (A side). In the present embodiment, hematocrit is used as an exemplary indicator of the blood concentration. It should be noted that any other type of indicator may be employed as the indicator of the blood concentration.
“Ht(V)” represents a blood concentration on the vein side (V side).
“QB(A)” represents a blood flow rate on the artery side (A side).
“QB(V)” represents a blood flow rate on the vein side (V side).
“QD” represents a flow rate of a dialysis fluid sent from water removal mechanism 150 to dialyzer 103.
“UF” represents a water removal rate (water removal amount per unit) from the blood in dialyzer 103.
In dialysis device 1, water removal mechanism 150 sends the dialysis fluid at the flow rate “QD” to dialyzer 103, and discharges a solution (the dialysis fluid and a solution including the blood of the patient) at a flow rate “QD+UF” from dialyzer 103. In this way, an amount of the solution corresponding to the flow rate “UF” is removed from the blood of the patient.
More specifically, in dialysis device 1, blood pump 102 sends the blood at a flow rate Q per unit time from the artery of the patient's arm to dialyzer 103 via artery-side blood circuit 110. On the other hand, the dialysis fluid at flow rate QD per unit time is supplied to an inflow port of upstream-side dialysis fluid line 151 of dialyzer 103. Due to a concentration difference therebetween, an amount of water corresponding to flow rate UF per unit time is removed from the blood flowing in a hollow fiber of dialyzer 103 to the dialysis fluid flowing around the hollow fiber of dialyzer 103. Then, the blood which has flow rate Q per unit time and from which the amount of water corresponding to flow rate UF has been removed is returned to the vein of the patient's arm via vein-side blood circuit 120. The removed amount of water corresponding to flow rate UF is discharged together with the dialysis fluid from dialyzer 103 via downstream-side dialysis fluid line 152.
[3. Overview of First Method]
A first method for detecting an abnormality associated with leakage will be described. In the first method, dialysis device 1 detects an abnormality based on a difference between theoretical value and measured value of a blood concentration in vein-side blood circuit 120. The theoretical value of the blood concentration in vein-side blood circuit 120 is specified based on the blood concentration and blood flow rate in artery-side blood circuit 110 and the water removal rate in dialyzer 103.
In dialysis device 1, each of UF and QB(A) is input from a user (for example, a medical worker such as a doctor) or registered in advance as a setting value. Controller 200 controls blood pump 102 in accordance with the setting value of QB(A) and controls dialysis fluid pump 155 in accordance with the setting value of UF.
Controller 200 obtains a measured value of Ht(A) and the setting values of UF and QB(A) from concentration measurement device 101, thereby calculating a theoretical value of Ht(V) in accordance with the formula (1). Then, controller 200 obtains a measured value of Ht(V) from concentration measurement device 104, compares the measured value of Ht(V) with the theoretical value, and determines that an abnormality has occurred in water removal mechanism 150 when a difference of the theoretical value from the measured value of Ht(V) is more than or equal to a given threshold value.
The threshold value can be set for each situation to which the technique according to the present embodiment is applied. In one implementation, the threshold value is a value determined in advance and registered in dialysis device 1. In another implementation, the threshold value can be defined based on the theoretical value calculated on that occasion (for example, as a value of 10% of the theoretical value). That is, for example, when the difference between the measured value and the theoretical value is 10% or more of the theoretical value, controller 200 can determine that an abnormality has occurred in water removal mechanism 150.
[4. Flow of First Method]
Dialysis device 1 may start the process of
Referring to
In a step S102, dialysis device 1 obtains a measured value of Ht(V) from concentration measurement device 104.
In a step S104, dialysis device 1 calculates a theoretical value of Ht(V) in accordance with the formula (1) using the measured value of Ht(A) obtained in step S100 and the setting values of QB(A) and UF.
In a step S106, dialysis device 1 determines whether or not a difference between the theoretical value of Ht(V) calculated in step S106 and the measured value of Ht(V) obtained in step S102 is more than or equal to a predetermined threshold value. When dialysis device 1 determines that the difference is less than the threshold value (NO in step S106), dialysis device 1 returns the control to step S100. Thus, for example, whenever a certain period of time has elapsed since the previous execution of step S100, dialysis device 1 executes the control of step S100 again. When dialysis device 1 determines that the difference is more than or equal to the threshold value (YES in step S106), dialysis device 1 proceeds the control to a step S108.
In step S108, dialysis device 1 stops blood pump 102.
In a step S110, dialysis device 1 stops dialysis fluid pump 155.
In a step S112, dialysis device 1 informs the abnormality and ends the process of
In the first method described above, each of the stop of blood pump 102 (step S108), the stop of dialysis fluid pump 155 (step S110), and the informing of the abnormality (step S112) is an exemplary operation abnormality process.
[5. Overview of Second Method]
Flow meter 190 is implemented by, for example, an ultrasonic flow meter, but may be a device that measures the flow rate of the blood in a different manner. Controller 200 obtains a measured value of QB(V) from flow meter 190.
In dialysis device 1, a relation between the blood flow rate in artery-side blood circuit 110 and the blood flow rate in vein-side blood circuit 120 can be expressed by the following formula (2):
QB(V)=QB(A)−UF (2)
In the second method, dialysis device 1 obtains respective setting values of blood pump 102 and dialysis fluid pump 155 as respective values of QB(A) and UF, thereby calculating a theoretical value of QB(V) in accordance with the formula (2). When a difference between the measured value of QB(V) and the theoretical value of QB(V) is more than or equal to a given threshold value, dialysis device 1 determines that an abnormality has occurred in water removal mechanism 150.
In one implementation, the threshold value is a value determined in advance and registered in dialysis device 1. In another implementation, the threshold value can be defined based on the theoretical value calculated on that occasion (for example, as a value of 10% of the theoretical value). That is, for example, when the difference between the measured value and the theoretical value is 10% or more of the theoretical value, controller 200 can determine that an abnormality has occurred in water removal mechanism 150.
[6. Flow of Second Method]
Dialysis device 1 may start the process of
Referring to
In a step S202, dialysis device 1 reads out a setting value of UF.
In a step S204, dialysis device 1 calculates a theoretical value of QB(V) in accordance with the formula (2) using BP and UF read out in step S200 and step S202. On this occasion, dialysis device 1 uses BP as a measured value of QB(A).
In a step S206, dialysis device 1 obtains a measured value of QB(V) from flow meter 190, and compares the measured value of QB(V) with the theoretical value of QB(V) calculated in step S204. Dialysis device 1 then determines whether or not a difference between the measured value and the theoretical value is more than or equal to a given threshold value.
When dialysis device 1 determines that the difference is less than the threshold value (NO in step S206), dialysis device 1 returns the control to step S200. Thus, for example, whenever a certain period of time has elapsed since the previous execution of step S200, dialysis device 1 executes the control of step S200 again. When dialysis device 1 determines that the difference is more than or equal to the threshold value (YES in step S206), dialysis device 1 proceeds the control to a step S208.
In step S208, dialysis device 1 stops blood pump 102.
In a step S210, dialysis device 1 stops dialysis fluid pump 155.
In a step S212, dialysis device 1 informs the abnormality and ends the process of
In the second method described above, each of the stop of blood pump 102 (step S208), the stop of dialysis fluid pump 155 (step S210), and the informing of the abnormality (step S212) is an exemplary operation abnormality process.
[7. Overview of Third Method]
Next, a third method will be described. In the third method, dialysis device 1 detects an abnormality based on a change in a difference between measured value and theoretical value of blood concentration.
For example, in dialysis device 1, artery-side blood circuit 110 is connected to the artery of the patient, vein-side blood circuit 120 is connected to the vein of the patient, and water removal mechanism 150 and dialyzer 103 are connected to each other. In this state, blood pump 102 and dialysis fluid pump 155 have not been driven yet. That is, this state is an exemplary state before starting the dialysis treatment, i.e., when blood pump 102 and dialysis fluid pump 155 are started to be driven, the dialysis treatment is started.
In this state, it is considered that there is substantially no flow of blood and an amount of body fluid of the patient is not changed in the blood in each of artery-side blood circuit 110 and vein-side blood circuit 120. Therefore, when the blood concentration in artery-side blood circuit 110 or vein-side blood circuit 120 is changed in this state, an abnormality such as leakage is highly likely to have occurred in water removal mechanism 150.
In the third method, the blood concentration in artery-side blood circuit 110 is measured at each of a first timing and a second timing while keeping dialysis device 1 in the above-described state (state in which at least dialysis fluid pump 155 is not driven). When a difference between the blood concentration measured at the first timing and the blood concentration measured at the second timing is more than or equal to a given threshold value, dialysis device 1 determines that an abnormality such as leakage has occurred in water removal mechanism 150. On this occasion, the blood concentration measured at the first timing is used as an ideal value for the blood concentration measured at the second timing.
In one implementation, the threshold value is a value determined in advance and registered in dialysis device 1. In another implementation, the threshold value may be defined based on the theoretical value calculated on that occasion (for example, as a value of 10% of the theoretical value). That is, for example, when a difference between the measured value and the theoretical value is 10% or more of the theoretical value, controller 200 can determine that an abnormality has occurred in water removal mechanism 150.
[8. Flow of Third Method]
Referring to
In a step S302, dialysis device 1 stores, into storage device 202, Ht(A) obtained in step S300.
In a step S304, dialysis device 1 obtains a value (Ht(A)) measured by concentration measurement device 101 at time T2.
In the third method, each of time T1 and time T2 can be set for each situation to which the third method is applied. In one implementation, time T1 and time T2 are in a period of time before starting dialysis treatment, and time T2 can be set as a timing at which a significant difference between the measured values at times T1, T2 is obtained when leakage has occurred in water removal mechanism 150.
In a step S306, dialysis device 1 determines whether or not a difference between Ht(A) at time T1 as stored in step S302 and Ht(A) obtained in step S304 is more than or equal to a given threshold value. When dialysis device 1 determines that the difference is less than the given threshold value (NO in step S306), dialysis device 1 starts the dialysis treatment in a step S308 and ends the process of
In step S310, dialysis device 1 informs the abnormality through presentation, sound, and/or notification to an external device, and ends the process of
As the process of
In the above description, the blood concentration in artery-side blood circuit 110 is used to detect an abnormality; however, the blood concentration in vein-side blood circuit 120 may be used. That is, dialysis device 1 may obtain a measured value from concentration measurement device 104 at each of times T1 and T2. When a difference between these measured values is less than a predetermined threshold value, dialysis device 1 may start the dialysis treatment assuming that there is no abnormality, whereas when the difference is more than or equal to the threshold value, dialysis device 1 may inform the abnormality.
In the above description, dialysis device 1 performs the process of
[9. Overview of Fourth Method]
Next, a fourth method will be described. In the fourth method, dialysis device 1 detects an abnormality based on a change in difference between a blood concentration on the artery side and a blood concentration on the vein side.
More specifically, theoretically, when water removal rate UF is unchanged, the blood concentration on the artery side and the blood concentration on the vein side are unchanged in dialysis device 1. However, when leakage has occurred in water removal mechanism 150, an extra amount of water corresponding to an amount of leakage from the blood in dialyzer 103 is removed to increase the blood concentration on the downstream side with respect to dialyzer 103, i.e., on the vein side more than expected, with the result that the difference between the blood concentration on the artery side and the blood concentration on the vein side becomes larger than the theoretical one. Dialysis device 1 informs an abnormality when an amount of change in the difference between the blood concentration on the artery side and the blood concentration on the vein side is more than or equal to a given threshold value.
In one implementation, the threshold value is a value determined in advance and registered in dialysis device 1. In another implementation, the threshold value may be defined based on the difference on a given occasion (for example, as a value of 10% of the difference just before the start of the dialysis treatment or upon the start of the dialysis treatment). That is, for example, when the difference between the blood concentration on the artery side and the blood concentration on the vein side is changed by 10% or more with respect to the difference therebetween upon the start of the dialysis treatment, controller 200 can determine that an abnormality has occurred in water removal mechanism 150.
[10. Flow of Fourth Method]
Dialysis device 1 starts the process of
Referring to
In a step S402, dialysis device 1 obtains a measured value (Ht(V)) from concentration measurement device 104.
In a step S404, dialysis device 1 calculates a difference D1 between Ht(A) obtained in step S400 and Ht(V) obtained in step S402. Then, after passage of a predetermined time (for example, 10 seconds), dialysis device 1 proceeds the control to a step S406.
In step S406, dialysis device 1 obtains a measured value (Ht(A)) from concentration measurement device 101.
In a step S408, dialysis device 1 obtains a measured value (Ht(V)) from concentration measurement device 104.
In a step S410, dialysis device 1 calculates a difference D2 between Ht(A) obtained in step S406 and Ht(V) obtained in step S408.
In a step S412, dialysis device 1 determines whether a difference between D1 and D2 is more than or equal to a given threshold value. When dialysis device 1 determines that the difference is less than a given value (NO in step S412), dialysis device 1 proceeds the control to a step S414, whereas when dialysis device 1 determines that the difference is more than or equal to the given value (YES in step S412), dialysis device 1 proceeds the control to a step S416.
In step S414, dialysis device 1 stores, into storage device 202 as D1, the value calculated as difference D2 in step S410, and dialysis device 1 returns the control to step S406. Thus, after this, in step S412, D1 stored in storage device 202 in step S414 is compared with D2 calculated in step S410.
In step S416, dialysis device 1 stops blood pump 102.
In a step S418, dialysis device 1 stops dialysis fluid pump 155.
In a step S420, dialysis device 1 informs the abnormality and ends the process of
In the fourth method described above, each of the stop of blood pump 102 (step S416), the stop of dialysis fluid pump 155 (step S418), and the informing of the abnormality (step S420) is an exemplary operation abnormality process.
In the fourth method, the difference between the blood concentration on the artery side (Ht(A)) and the blood concentration on the vein side (Ht(V)) is calculated for every predetermined time, and when the calculated difference is changed by a given threshold value or more with respect to the difference calculated previously, it is determined that an abnormality has occurred and an operation abnormality process is performed.
It should be noted that in the fourth method, step S414 may be omitted. In this case, in step S412, D2 calculated in step S410 is compared with D1 calculated in step S404. That is, D2 calculated for every predetermined time is compared with D1 calculated at the start of the process of
[11. Controller]
In the present embodiment, each of the processes described with reference to
The embodiments disclosed herein are illustrative and non-restrictive in any respect. The scope of the present invention is defined by the terms of the claims, rather than the embodiments described above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims. The inventions described in the embodiments and the modifications are intended to be implemented solely or in combination wherever possible.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2020-088045 | May 2020 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2021/018800 | 5/18/2021 | WO |
