JP2735770B2 - Dialysis device water removal control monitoring device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dialysis apparatus, and more particularly to a monitoring apparatus for water removal control in a dialysis apparatus having an ultrafiltration control device.

[0002]

2. Description of the Related Art Today, dialysis devices are widely used as devices for performing dialysis therapy for patients with chronic renal failure. This dialysis therapy is a necessary means for maintaining the life of removing the consumed water (generally called water removal), especially for patients who do not produce urine, and the presence of a dialysis device is extremely important.

Recently, a high-performance dialyzer (dialyzer) has been developed, and a large amount of water can be removed. However, if water removal control is mistaken, water is removed more than necessary or a sufficient amount of water is removed. Dialysis equipment may not be able to be removed, which may be dangerous to the patient's life. For this reason, dialysis machines are required to have a function that enables proper and safe water removal management. Was.

[0004] From such a viewpoint, as means for equalizing the flow rate of the dialysate flowing into the dialyzer and the flow rate of the dialysate flowing out of the dialyzer , supply and discharge of the same volume are used.
Using a flow control means for performing (eg duplex pump),
Ultrafiltration equipped with a dehydration pump that constitutes an equal flow rate circuit for dialysate and removes a predetermined amount of fluid from the equal flow rate circuit to remove an equivalent amount of water from the blood side of the dialyzer A dialysis device having a water removal control mechanism as a control device has been developed.

Therefore, in this type of dialysis apparatus, when an arbitrary water removal amount is set, a liquid corresponding to the water removal amount is removed via a water removal pump in accordance with the set value, so that the performance of the dialyzer varies. The water removal error can be ignored and accurate water removal can be achieved. But,
Even with this type of dialysis machine, if it is operated for a long time, dust
Dust or carbonate deposits may be caught or pump parts may be worn.
Liquid and air leaks easily from the pump and back pressure valve.
And each of them alone or together
Water removal control becomes difficult, and there is a risk of causing poor water removal. For this reason, a conventional dialysis apparatus employs a monitoring method for detecting a phenomenon causing poor water removal by a change in dialysate pressure.

FIG. 8 is a schematic system diagram showing an example of the configuration of a dialysis apparatus having a water removal control mechanism currently in practical use. In FIG. 8, reference numeral 10 denotes a dialyzer. On the dialysate side of the dialyzer 10 defined through the dialysis membrane 10a, a dialysate supply system 14 forming an equal flow rate circuit through a dual pump 12 is provided. And the dialysate drainage system 16 are connected. In this case, the double pump 12 is constituted by a reciprocating pump having a single plunger and two pump units 18a and 18b having the same volume and alternately performing suction and discharge operations.

In addition, the inlet and the outlet of the dialyzer 10 are short-circuited to the dialysate supply system 14 and the dialysate drainage system 16 by a bypass pipe 20 via electromagnetic switching valves in proximity to the dialyzer 10. . In the dialysate drainage system 16, a pressurizing pump 22 is provided between a connection point between the bypass pipe 20 and the compound pump 12, and a dewatering pump 26 is provided downstream of the pressurizing pump 22 via a deaeration chamber 24. Is connected in a branch.

Further, a back pressure valve is provided on the discharge side of each of the dual pump 12 and the water removal pump 26 so that the back pressure of each pump is set to a predetermined value.
The discharge flow rate of each pump can be kept constant. In this case, the degassing chamber 24 connects the degassing pipe 30 led out via the electromagnetic on-off valve to the dialysate drainage system 16 downstream of the dual pump 12. On the other hand, dialyzer 10
A blood system 34 connected to the patient K via a blood pump 32 is connected to the blood side defined via the dialysis membrane 10a.

In the dialysis apparatus thus constructed, a dialysate pressure sensor 36 for measuring dialysate pressure is provided upstream of the pressurizing pump 22 with respect to the dialysate drainage system 16 and a blood system 34 is provided. A venous pressure sensor 38 is attached to the vein connection side of the diaper, and is used as a monitoring mechanism at the time of dialysis treatment described later.

However, in the dialysis apparatus having the above structure, the dialysate supply system 14 and the dialysate drainage system 16 are communicated with the dialyzer 10 by shutting off the bypass pipe 20, and the dual pump 12, the pressurizing pump 22 And the water removal pump 26 are driven to supply the dialysate, and the blood pump 3
By driving the dialyzer 2 to supply the blood of the patient K to the dialyzer 10, dialysis treatment is performed.

In this case, the flow rate of the dialysate in the dialysate supply system 14 and the flow rate of the dialysate drainage system 16 become equal, and these dialysate systems constitute an equal flow rate circuit. Therefore, water removal pump 2
When the predetermined amount of water is removed from the dialysate drainage system 16 to the water removal system 28 by the drive of the dial 6, the dialysis membrane 1 of the dialyzer 10 is removed.
The same amount of water as the water removal amount can be removed from the blood side to the dialysate side through Oa. The water removal system 28 including the water removal pump 26 can be provided in the dialysate supply system 14.

[0012] As a dialysis device having an ultrafiltration control device currently in practical use, as shown in FIG.
Flow rate to supply and discharge the same volume to form a constant flow circuit
As a control means, the dialysate system 14, 1 connected to one compartment separated by the dialysis membrane 10a of the dialyzer 10 is connected.
No. 6 discloses a configuration in which a pair of diaphragm chambers 40 and 42 are connected and arranged (Japanese Patent Publication No. 56-82). Furthermore, as shown in FIG. 11, constituting an equal flow circuit
Flow control means to supply and discharge the same volume for
There is also known a configuration in which a pair of viscous chambers 44 and 46 are connected and arranged to dialysate systems 14 and 16 which are connected to one compartment separated by a dialysis membrane 10a of a dialyzer 10 (Japanese Patent Application Laid-Open No. HEI 1-1990). -280468).

[0013]

In the above-mentioned conventional dialysis apparatus, an ultrafiltration rate (UFR) is used as a criterion for evaluating the performance. Generally, the ultrafiltration rate (UFR) is expressed by the following approximate expression from the relationship between the ultrafiltration pressure (TMP) and the water removal rate (v).

[0014]

(Equation 3)

Therefore, conventionally, the output difference between the dialysate pressure sensor 36 and the venous pressure sensor 38 provided in the dialyzer shown in FIG. 8 is determined as an ultrafiltration pressure (TMP).
By the this determining the ultrafiltration rate (UFR) Les has implemented safety management abnormality in dialyzer ultrafiltration rate (UFR).

However, the time-dependent change of the ultrafiltration pressure (TMP) in a normal dialysis machine shows a gentle rising curve with the passage of time, as shown in FIG. Therefore, in this case, the dialysis start time t ₁ to the dialysis end time t ₃
Set domain a ₁ ~a ₂ to allow change of TMP to and TMP to be measured to generate an alarm when exceeding the variable region can be notified of the water removal abnormality. Therefore, in the dialysis device shown in FIG. 8, for example, the permissible limit value of the dialysate pressure is set in the dialysate pressure sensor 36 in consideration of the above-mentioned range, and the measured values of the dialysate pressure sensor 36 are respectively set. A water removal control / monitoring device (A) that generates an alarm when a set allowable limit value is exceeded is employed.

In addition, the venous pressure is detected from a blood system connected to the blood side of the dialyzer, and the dialysate pressure is detected from a part of an equal flow rate circuit connected to the dialysate side. The ultrafiltration pressure (TMP) of the dialysis membrane of the dialyzer is continuously calculated from the pressure and the dialysate pressure, and when the ultrafiltration pressure at a certain point falls outside the allowable variation range with respect to the reference point set in advance. A water removal control / monitoring device (B) for generating an alarm has been proposed (Japanese Patent Laid-Open No. 3-133559).

Further, the ultrafiltration rate (UFR) is continuously calculated from the ultrafiltration pressure (TMP) of the dialyzer with respect to the dialysis membrane and the water removal rate (v), and the change in the ultrafiltration rate at a certain point in time is calculated. There is also proposed a water removal control monitoring device (C) which compares the ultrafiltration rate with the amount of change in the ultrafiltration rate before that time, and issues an alarm when the comparison value matches the set alarm condition (particularly). JP-A-5-68710).

Further, a self-diagnosis water removal control / monitoring device (D) for interrupting the dialysis treatment and performing a self-diagnosis of the water removal control device has also been proposed.

However, in today's dialysis treatment, the water removal rate is changed during the dialysis treatment at the discretion of the doctor according to the physiological conditions of the patient (generally, the water removal rate is increased).
Is done.

[0021] In this case, the in the water-removal control and monitoring apparatus (A), as shown by the broken line in FIG. 9, ultrafiltration pressure change time t ₂ of the water removal speed (TMP) is the variance range a ₂ ( (Upper limit alarm level). In order to avoid such a situation, it is necessary to widen the range of the ultrafiltration pressure (TMP).
In this case, for example, if the water removal control mechanism breaks down, a relatively large excess or deficiency in the amount of water removal is allowed, and there is a problem that the effect on the patient becomes extremely large. In particular, despite the normal operation of the water removal control mechanism, the dialysis membrane of the dialyzer is clogged, a change in the plasma osmotic pressure or a change in the water removal rate causes a false alarm as described above. There is.

In the water removal control / monitoring device (B) or (C), the tendency of the ultrafiltration pressure (TMP) or the ultrafiltration rate (UFR) at the present time and the previous time is measured.
Since the tendency of the amount of change is compared, the prediction intervenes in the determination of the alarm, and therefore, there is a problem that the appropriate alarm determination cannot be performed.

Further, the water removal control and monitoring device (D) has a disadvantage that the treatment time is delayed because the treatment is interrupted.

Therefore, an object of the present invention is to provide a dialysis device having an ultrafiltration control device, which is not affected by a change in the water removal rate during the dialysis treatment, and furthermore, the dialysis membrane of the dialyzer is clogged and the plasma permeation is prevented. It is an object of the present invention to provide a water removal control and monitoring device for a dialysis device capable of detecting a change in pressure and the like, and performing a smooth and safe dialysis treatment without being constantly affected by these changes.

[0025]

According to the present invention, there is provided a water removal control monitoring apparatus for a dialysis apparatus, comprising: an ultrafiltration control monitoring apparatus for a dialysis apparatus having an ultrafiltration control apparatus.
Measurement or calculation means and before and after change of water removal speed (v)
To calculate the ratio of ultrafiltration pressure and the ratio of water removal speed in a basin
Means, comparing the ratio of the ultrafiltration pressure and the ratio of the water removal rate
Comparison operation means for obtaining the ratio, and the comparison operation means
The resulting ratio is within the tolerance of the preset function
And a monitoring means for determining whether or not the condition is satisfied . In this case, the monitoring means changes the water removal rate (v).
, Ultrafiltration at the water removal rate (v _n-1 ) before the change
Overpressure (TMP _n-1 ) and water removal rate after change (v _n )
Before changing the ultrafiltration pressure (TMP _n )
The ratio of the ultrafiltration pressure and the ratio of the water removal rate after
In the range of α _xa <1, 0 <α _xb <1, the relationship of the following equation (1) is satisfied.
Can be configured to perform arithmetic control so that
You .

Also, the water removal control supervisor of the dialysis device according to the present invention.
A dialysis device equipped with an ultrafiltration control device
Measurement of ultrafiltration rate (UFR) in water control monitoring equipment
Or the calculation means and the limit before and after the change of the water removal speed (v)
By comparing the filtration rates, the ratio is set to a predetermined function tolerance.
A configuration comprising monitoring means for determining whether or not it is within the enclosure; and
You can also . In this case, the monitoring means is configured to control the water removal speed.
When the degree (v) is changed, the water removal rate before the change
(V _n-1 ) and the ultrafiltration rate (UFR _n-1 )
Ultrafiltration rate in water removal speed (v _n) of the post (UFR _n)
And the ultrafiltration rate before and after the change of the water removal rate.
In the range of 0 <α _xa <1, 0 <α _xb <1, the following equation (2)
It can be configured to perform arithmetic control so that the relationship is established.
I can .

[0027]

(Equation 4)

[0028]

(Equation 5)

[0029]

According to the water removal control / monitoring device for a dialysis device according to the present invention, by changing the water removal rate (v) during the dialysis treatment, the ratio of the ultrafiltration pressure (TMP) before and after the change is reduced.
The ratio of the water removal rate (v) is calculated by the calculating means,
By comparing the ratio of the external filtration pressure (TMP) and the ratio of the water removal rate,
Find the ratio and make sure that this ratio is within the tolerance of the preset function.
To determine whether or not there is
The ultrafiltration rate (UFR) is compared and the ratio is determined in advance.
Judge whether the function is within the allowable range .
With this configuration, it is possible to easily and reliably determine whether or not the water removal control is being performed properly.

[0030]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, a preferred embodiment of a water removal control and monitoring apparatus for a dialysis apparatus according to the present invention will be described in detail with reference to the accompanying drawings. That is, the water removal control in the present invention
The monitoring device basically has the configuration shown in FIG. 8 described above.
Dialysis device with water removal control mechanism as ultrafiltration control device
It can be carried out using a device.

First, the water removal rate (v) and the ultrafiltration pressure (T
MP) and the ultrafiltration rate (UFR) can be expressed by the following equation (4) from the above equation (3). This
In the case of, the dialysate system shown in FIG.
Dialysate pressure sensor 36 provided in the blood system and vein provided in the blood system
The pressure sensor 38 limits the output difference between these sensors.
Determined as the external filtration pressure (TMP) and then the ultrafiltration rate
(UFR).

[0032]

(Equation 6)

In this case, the ultrafiltration rate (UFR) is a value unique to the dialyzer and is a variable that changes during treatment due to clogging of the dialysis membrane. However, the ultrafiltration rate (UFR) can be treated as an unchanging constant (U = 1 / UFR) for a short time immediately before and immediately after the change in the water removal rate. In this case, the ultrafiltration pressure (TMP) and the water removal rate (v)
Is proportional to the following equation (5) and FIGS. 1 and 2
The relationship with the characteristic shown in FIG.

[0034]

(Equation 7)

The relationship between the characteristics shown in FIGS. 1 and 2 is as follows.

[1] The ultrafiltration pressure (TMP) changes at the same rate as the rate of change of the water removal rate (v) (see FIG. 1).

[2] The ultrafiltration rate (UFR) does not change even if the water removal rate (v) changes (see FIG. 2).

Accordingly, in the present invention, FIG.
Dialysate pressure sensor in a dialysis machine
Using the vein pressure sensor 38 and the vein pressure sensor 38 ,
When, whether the relationship between the characteristics shown in FIGS. 1 and 2 are satisfied, so determined with a tolerance range set in advance in the
By providing the monitoring means including the configured arithmetic and control unit , proper monitoring of the water removal control device can be achieved.

Therefore, for example, the conditions for determining the establishment of the relationship in the characteristics shown in FIGS. 1 and 2 can be obtained as follows.

That is, from the above equation (4), when changing the water removal rate, the relationship immediately after the change (represented by n) and immediately before the change (represented by n-1) is as follows.

[0041]

(Equation 8)

[0042]

(Equation 9)

The following equation is obtained from the relationship between the characteristics shown in FIG.

[0044]

(Equation 10)

Therefore, the equation (6) is replaced by the equation (6).
By substituting (7), the following equation is established.

[0046]

[Equation 11]

However, a certain allowable range of the ultrafiltration pressure (TMP) before and after the change of the water removal rate (v) is set.
Assuming α _xa and α _xb , the condition for establishing the relationship of the characteristic shown in FIG. 1 is expressed by the following equation from the equation (9).

[0048]

(Equation 12)

A certain allowable range for the ultrafiltration rate (UFR) before and after the change of the water removal rate (v) is set.
Assuming α _xa and α _xb , from the above equation (8), the condition for establishing the relationship of the characteristic shown in FIG. 2 is expressed by the following equation.

[0050]

(Equation 13)

Therefore, the ultrafiltration pressure (TMP) and / or the ultrafiltration rate (U) before and after the change of the water removal rate (v) are changed.
When FR) satisfies the relationship between the expressions (10) and (11), it is determined that proper water removal control is maintained, and the relationship between the expressions (10) and (11) is not established. In this case, it is determined that the state is abnormal, and an alarm or the like is set.

Next, a method and means for changing the water removal speed (v) for the above-described water removal control monitoring will be described.

A. The water removal rate (v) is automatically and periodically or irregularly changed at a predetermined change rate and monitored (see FIG. 3).

B. Change the water removal rate (v) to multiple stages,
Monitor (see FIG. 4).

C. When the operator of the dialysis device operates for monitoring purposes, the water removal rate (v) is changed and monitored (see FIG. 5).

D. Monitoring is performed when the operator of the dialysis device changes the water removal rate (v) for the purpose of treatment (see FIG. 6).

E. The water removal rate at the time of monitoring is changed so that the average water removal rate (v) during the treatment becomes a preset water removal rate (see FIG. 7).

By changing the water removal rate as described above, it is possible to determine the appropriateness of the water removal control based on the relationship between the above equations (10) and (11).

[0059]

As is clear from the above-described embodiment, according to the water removal control and monitoring apparatus for a dialysis apparatus according to the present invention, the water removal rate (v) is changed during the dialysis treatment, so that the water removal rate before and after the change is changed. Ultrafiltration pressure (TMP) ratio and water removal rate
The ratio of (v) is calculated by the calculating means, and these ultrafiltration pressures are calculated.
(TMP) ratio and the ratio of the water removal rate to determine the ratio.
Therefore, it is determined whether or not this ratio is within an allowable range of a preset function , or the ratio before and after the change of the water removal speed is determined.
The ultrafiltration rate (UFR) is compared and the ratio is preset.
Configured to determine whether it is within the allowable range of functions
This makes it possible to easily and reliably determine whether or not proper water removal control is being performed.

In this case, the relationship between the predetermined allowable range can be set as an arithmetic expression such as a function, and the ultrafiltration pressure and / or the ultrafiltration pressure before and after the change of the water removal rate are changed.
Or by Rukoto determined by measuring or calculating the ultrafiltration rate, it can be easily determined using the monitoring means comprising a calculation control unit such as a computer based on the obtained value.

Thus, in the present invention, the ultrafiltration rate (UF) due to clogging of the dialysis membrane of the dialyzer
R), it is possible to effectively monitor the water removal control corresponding to the time-dependent change of the plasma, the time-dependent change of the plasma osmotic pressure, and the change of the water removal rate, and to improve the performance of the dialysis device to be applied. The safety of water removal control can be further improved.

In particular, according to the present invention, it is not necessary to make predictions about the criterion at the time of monitoring the water removal control device, and it is possible to monitor the water removal control device without interruption during the dialysis treatment. Many excellent advantages can be obtained, for example, the water removal control device can be monitored when the water removal speed has been changed.

Although the preferred embodiment of the present invention has been described above, the present invention is not limited to the above-described embodiment, and various design changes can be made without departing from the spirit of the present invention. Of course. For example, in the above-described embodiment, a dialysis device having an ultrafiltration control device to which the water removal control monitoring device of the present invention is applied is shown in FIG.
In the same way, supply and discharge of the same volume to constitute the equal flow circuit
As a flow control means for, although the case of using the duplex pump the dialysate side of the dialyzer is not limited to this example, or use a diaphragm chamber as shown in FIG. 10, for example, FIG. 11 The water removal control and monitoring device of the present invention can be applied to a dialysis device using a viscous chamber as shown in FIG.

[Brief description of the drawings]

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a diagram showing the monitoring contents in a water removal control monitoring device of a dialysis device according to the present invention, and is a characteristic diagram of an ultrafiltration pressure with respect to a water removal speed.

FIG. 2 is a characteristic diagram of the ultrafiltration rate with respect to the water removal rate, showing the monitoring contents in the water removal control monitoring device of the dialysis device according to the present invention.

FIG. 3 shows a dialysis device water removal control monitoring device according to the present invention.
FIG. 7 is a characteristic diagram of a water removal rate with respect to a dialysis time, showing an embodiment of a method of changing a water removal rate when performing water removal control monitoring .

The water-removal control and monitoring apparatus of the dialysis apparatus according to the present invention; FIG Contact
FIG. 10 is a characteristic diagram of a water removal rate with respect to a dialysis time, showing another embodiment of a method of changing the water removal rate when performing water removal control monitoring .

The water-removal control and monitoring apparatus of the dialysis apparatus according to the present invention; FIG Contact
FIG. 10 is a characteristic diagram of the water removal rate with respect to the dialysis time, showing still another embodiment of a method of changing the water removal rate when performing water removal control monitoring .

The water-removal control and monitoring apparatus of the dialysis apparatus according to the present invention; FIG Contact
FIG. 10 is a characteristic diagram of the water removal rate with respect to the dialysis time, showing another embodiment of a method of changing the water removal rate when performing water removal control monitoring .

The water-removal control and monitoring apparatus of the dialysis apparatus according to the present invention; FIG Contact
FIG. 13 is a characteristic diagram of the water removal rate with respect to the dialysis time, showing still another embodiment of a method of changing the water removal rate when performing water removal control monitoring .

FIG. 8 is provided with a water removal control mechanism as an ultrafiltration control device .
1 is a system diagram illustrating a schematic configuration of a dialysis device according to an embodiment.

FIG. 9 is a water removal control characteristic diagram of a dialyzer according to a conventional water removal control monitoring method in a dialysis device.

FIG. 10 shows a configuration of an equal flow rate circuit in the dialysis device shown in FIG .
FIG. 11 is a main part system diagram showing another configuration example of the flow rate control means for supplying and discharging the same volume for the formation .

FIG. 11 shows a configuration of an equal flow rate circuit in the dialysis device shown in FIG . 8;
Flow control means to supply and discharge the same volume for
It is a main part flow diagram showing another configuration example.

[Explanation of symbols]

 Reference Signs List 10 dialyzer 10a dialysis membrane 12 double pump 14 dialysate supply system 16 dialysate drainage system 18a, 18b pump unit 20 bypass pipe 22 pressurization pump 24 deaeration chamber 26 dewatering pump 28 dewatering system 30 deaeration pipe 32 blood pump 34 blood system 36 dialysate pressure sensor 38 venous pressure sensor 40, 42 diaphragm chamber 44, 46 viscous chamber

Claims (4)

(57) [Claims] An ultrafiltration control monitoring device for a dialysis device equipped with an ultrafiltration control device, which measures an ultrafiltration pressure (TMP).
Alternatively, before and after the change of the water removal speed (v) with the calculation means
Calculating means for calculating the ratio of ultrafiltration pressure to the ratio of water removal speed
And comparing the ratio of the ultrafiltration pressure and the ratio of the water removal rate,
Comparison operation means for obtaining a ratio;
Whether the specified ratio is within the tolerance of the preset function
Monitoring means for judging whether the water removal control of the dialysis device is performed. 2. The monitoring means changes the water removal rate (v).
In the case, the limit in the water removal rate (v _n-1 ) before the change
External filtration pressure (TMP _n-1 ) and water removal rate after change (v _n )
Of the ultrafiltration pressure (TMP _n ) at
The ratio of ultrafiltration pressure before and after renewal and the ratio of water removal rate
In the range of 0 <α _xa <1, 0 <α _xb <1, the relation of the following equation (1) is obtained.
Claim that is configured to perform arithmetic control so that the engagement is established
Item 2. A water removal control and monitoring device for a dialysis device according to Item 1 . (Equation 1) 3. Removal of a dialysis device having an ultrafiltration control device.
Measurement of ultrafiltration rate (UFR) in water control monitoring equipment
Or the calculation means and the limit before and after the change of the water removal speed (v)
By comparing the filtration rates, the ratio is set to a predetermined function tolerance.
Monitoring means for determining whether or not the device is within the enclosure.
Characteristic water removal control monitoring device for dialysis equipment . 4. The monitoring means changes a water removal rate (v).
In the case, the limit in the water removal rate (v _n-1 ) before the change
Outer filtration rate (UFR _n-1 ) and water removal rate after change (v _n )
Of the ultrafiltration rate (UFR _n ) at
Ultrafiltration rate before and after _renewal 0 <α _xa <1,0 <
In the range of α _xb <1, the following equation (2) is satisfied.
4. The dialysis device according to claim 3, wherein the dialysis device is configured to perform arithmetic control.
Water removal control monitoring equipment . (Equation 2)