KR101279557B1 - Method for reusing dialyzer - Google Patents

Abstract

The present invention relates to a method for reusing a dilizer, wherein the hollow fiber membrane filter inside the dilizer is sterilized with peracetic acid, washed with reverse osmosis purified water, and washed once more with alkaline sterilized water, and then, in the hollow fiber membrane filter. By completely removing the peracetic acid residues, you can reduce the economic burden on the hemodialysis patient by prolonging the reuse time and recovery while avoiding damage to the diiser, while also preventing peracetic acid from entering the patient's body. have.

Description

How to reuse your diliser {METHOD FOR REUSING DIALYZER}

The present invention relates to a method of reusing the dilizer, and more particularly, by disinfecting the dilizer with a disinfectant solution such as peracetic acid, washing with reverse osmosis purified water and washing with alkaline sterilization water, The present invention relates to a method for reusing a dilizer which can prevent peracetic acid from being injected into a patient's body while preventing damage.

In general, as one of the ways in which a patient with chronic renal failure who has lost kidney function due to various diseases can maintain life, a hollow fiber membrane filter 11 (membrane) is installed therein as shown in FIG. There is a hemodialysis method of dialysis of purified blood by removing the waste accumulated in the blood through (10, hemodialysis machine).

In the hemodialysis method, the patient's blood is effectively purified by dialysis about 4 hours at a time and about 12 hours a week for 3 times a week through the diliser 10 after the patient visits the hospital.

At this time, the diiser 10 may reuse about 70 to 100 times, but when the hollow fiber membrane filter 11 is not properly disinfected and cleaned, and the functional degradation and breakage occur, the distiller 10 should be used less than 10 times and then discarded. do.

That is, the effective burden of the dialysis patient is reduced as the number of reuse of the diiser is increased only by disinfecting and washing the dilizer 10 effectively.

As an example, a method of manufacturing a medical device cleaning agent using a conventional peracetic acid to wash and reuse the dilizer 10 is disclosed in Korean Patent Publication No. 2000-0049667.

In the conventional method for preparing a detergent, as shown in FIG. 2, 79-24% reverse osmosis water and 10-30% acetic acid are mixed in an agitator, 5-25% hydrogen peroxide is added and mixed to form peracetic acid. In the step of adding, and mixing 1-20% phosphoric acid for the stabilization of the resulting peracetic acid and the acidity (pH) of the product, 1,1-diphosphone stabilizer to improve the stabilization and cleaning efficiency of the product Adding and mixing 5% to 1% of acid, keeping the mixture at a temperature of 35 to 45 ° C. for 4-7 hours to promote the reaction between hydrogen peroxide and acetic acid, and aging at room temperature for 3 days to increase the content of hydrogen peroxide. It is prepared by lowering to less than%.

That is, in the conventional re-dilator reusing method, after filling the cleaning agent prepared by the cleaning agent manufacturing method using the peracetic acid for about 50-55 hours, which is the time coming to receive the next dialysis, Hemodialysis patients are washed with purified water and reused after one treatment and immediately before the treatment.

Republic of Korea Patent Publication No. 2000-0049667 (Name: medical device cleaning agent using peracetic acid and its manufacturing method, Applicant: Jinseok Lee and one other person, Publication Date: 2000, 08, 05)

However, in the conventional method of reusing the dilizer, since the hollow fiber membrane filter inside the dilizer is exposed to peracetic acid for a long time, the pore size (pore distribution) of the hollow fiber membrane filter (fiber) inside the dilizer is increased. At the same time there is a problem of being damaged.

In addition, in the conventional method of reusing the dilizer, since the peracetic acid washing solution is washed with purified water immediately before the hemodialysis of the patient, the residue test of the peracetic acid is normal (negative) during the initial washing, but the dilizer during treatment Peracetic acid, which has penetrated the internal hollow fiber membrane filter, gradually escapes and enters the body of the hemodialysis patient.

Therefore, the present invention is to solve the above problems, the object is to disinfect the hollow fiber membrane filter inside the dilizer, through a disinfectant such as peracetic acid, washed through reverse osmosis purified water, through alkaline sterilized water By completely removing the peracetic acid residue in the hollow fiber membrane filter, it is possible to prevent the damage of the dilizer while prolonging the reuse time and recovery as well as preventing the peracetic acid from being injected into the patient's body. To provide.

That is, the purpose of the present invention is to fill the peracetic acid inside the dilizer for 11 to 15 hours, and to wash through reverse osmosis purified water, and to maintain the contamination and disinfection of the dilizer for the rest of the time coming to the next dialysis The present invention provides a method for reusing a dilizer which can improve the removal rate of urea, which is a characteristic of the dilizer, by filling a rinsing liquid such as alkaline sterilizing water, which does not affect the deterioration.

In order to achieve the above object, the method of reusing a dilizer according to the present invention includes: (A) the outlet of the dilizer 120, the dialysate line 121 and 122, the blood lines 123 and 124, and the cylinder 160. Discharging through 180 and operating the compressor 170 to vacuum the inside of the cylinder 160 (S210); (B) supplying and disinfecting the disinfectant solution from the disinfectant tank 130 to the dilizer 120 and the dialysate line 121 and 122 and flowing it into the cylinder 160 (S215); (C) supplying and disinfecting the disinfectant solution from the disinfectant tank 130 to the plunger 120 and the blood lines 123 and 124 to flow into the cylinder 160 (S220); (D) disinfecting the hollow fiber membrane filter 125 by filling a disinfectant solution for a predetermined time inside the diiser 120 (S225); (E) supplying the washing liquid from the washing liquid tank 140 to the cylinder 160 via the dilizer 120, the dialysate lines 121 and 122, and the blood lines 123 and 124, and simultaneously Discharging the disinfectant through the outlet 180 (S230); (F) supplying the washing liquid from the washing liquid tank 140 to the dilizer 120 and the dialysate lines 121 and 122 and then discharging in real time through the outlet 180 via the cylinder 160 (S235). ); (G) supplying the washing liquid from the washing liquid tank 140 to the dilizer 120 and the blood lines 123 and 124 and discharging in real time through the outlet 180 through the cylinder 160 (S240). ); (H) filling the washing solution into the inside of the diiser 120 and removing the disinfecting solution absorbed by the hollow fiber membrane filter 125 (S245); (I) the washing liquid in the dilizer 120, the dialysate line 121 and 122, the blood lines 123 and 124, and the cylinder 160 is discharged through the outlet 180, and the compressor 170 is operated to operate the compressor. Making the interior of the cylinder 160 in a vacuum state (S250); (J) supplying the washing liquid from the washing liquid tank 150 to the dilizer 120 and the dialysate lines 121 and 122 and filling it and then flowing it to the cylinder 160 (S255); And (K) supplying the cleaning liquid from the cleaning liquid tank 150 to the dilizer 120 and the blood lines 123 and 124 to fill and then flowing the cylinder 160 into the cylinder 160 through the step S260. Purify and reuse.

Preferably, before the step (A), (a1) the washing liquid from the washing liquid tank 140 is supplied to the dilizer 120, the dialysate line 121 and 122, the blood lines 123 and 124 to fill the cylinder It further includes the step (S205) to flow to 160 to wash.

More preferably, in order to reliably remove the sanitizing solution of the hollow fiber membrane filter 125 in the dilider 120, the washing solution from the washing solution tank 140 of the step (F) is the diluiser 120 and the dialysate line 121 And discharging the washing liquid from the washing liquid tank 140 of the step (G) in step S235 and discharging in real time through the discharge port 180 via the cylinder 160 after supplying to the distillation unit 120. After supplying to the blood lines (123 and 124) through the discharge port 180 via the cylinder 160 is discharged in real time (S240) is repeated a plurality of times.

In addition, in order to reliably remove the washing liquid from the hollow fiber membrane filter 125 in the dilider 120, the washing liquid from the washing liquid tank 150 of the step (J) is removed from the diluiser 120 and the dialysate lines 121 and 122. (S255) and the cleaning liquid from the cleaning liquid tank 150 of the step (K) and the plunger 120 and the blood lines (123 and 124) It is preferable to repeat the step (S260) a plurality of times to supply to fill in the flow to the cylinder 160 in a vacuum state.

In addition, in the step (D), the disinfectant solution is filled in the dilizer 120 for 11 hours to 15 hours to be disinfected.

In addition, only the steps (F) to (K) may be performed separately to perform a rinsing function of washing and cleaning the diiser 120.

According to the method of reusing the dilizer according to the present invention, since the peracetic acid residues in the hollow fiber membrane filter can be completely removed, not only the urea removal rate, which is an inherent characteristic of the dilizer, can be improved, but also the hollow fiber membrane filter inside the It is possible to reduce the pore size and at the same time to prevent damage to the hollow fiber membrane filter, thereby reducing the economic burden on the hemodialysis patient by increasing the reuse time and the number of distillers.

In addition, when the reuse of the dilizer can prevent the penetration of antiseptic solution such as peracetic acid in the patient's body can provide an effective hemodialysis to patients with heart failure.

Other objects and advantages of the present invention will become apparent from the detailed description of the embodiments with reference to the attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a diagram for explaining a general diiser.
Figure 2 is a flow chart showing a method for preparing a cleaning agent for washing the conventional dilizer.
Figure 3 is a block diagram schematically showing the configuration of the re-dilator reuse apparatus applied to the present invention.
Figure 4 is a real picture showing the state in which the dilizer is attached to the reusing device to be applied to the present invention.
Figure 5 is a real picture showing the side of the dilizer reuse apparatus applied to the present invention.
Figure 6 is a real picture showing the internal configuration of the re-dilator reuse apparatus applied to the present invention.
Figure 7 is a flow chart illustrating a die riser reuse method according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings it will be described in detail the method of reusing the diiser according to the present invention.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, the accompanying drawings show an exemplary form of the present invention, which is provided only to describe the present invention in more detail, whereby the technical scope of the present invention is not limited.

First, an example of a reusing device for reusing a device applied to the present invention will be described with reference to FIGS. 3 to 6.

Figure 3 is a block diagram schematically showing the configuration of the re-applied reuse device applied to the present invention, Figure 4 is a real picture showing a state in which the adder is attached to the re-applied re-applied device applied to the present invention, Figure 5 6 is an actual photograph showing a side of a diliser reuse apparatus applied to the present invention, and FIG.

As shown in FIG. 3, the reuse device for applying the present invention includes an operation panel 110, a dilizer 120, a disinfectant tank 130, a cleaning liquid tank 140, a cleaning liquid tank 150, and a cylinder. 160, compressor 170, outlet 180, PH sensor 190, flow sensor 195, a plurality of sololaid valves (V1, V2, V3, V4, V5, V6, V7, V8 and Vd) And microprocessor 200.

Specifically, the operation panel 110 is a panel for checking the operation, stop and operation state of the reuse device, the operation button 111 for inputting an operation signal to the reuse device and the stop for inputting the stop signal. A button 112, a rinse button 113 for inputting an operation signal for cleaning and cleaning, a disinfecting liquid lamp 114 indicating a state of the disinfecting liquid, a disinfecting lamp 115 indicating disinfection through the disinfecting liquid, A washing liquid lamp 116 indicating the state of the washing liquid, a washing liquid lamp 117 indicating the state of the washing liquid, and a display unit 118 displaying the PH index or rotation amount of the disinfecting liquid, the washing liquid and the washing liquid.

As shown in FIG. 4, the dilizer 120 is a hemodialysis machine equipped with a hollow fiber membrane filter 125 and a membrane to purify blood of a patient.

The disinfectant tank 130 stores a disinfectant such as, for example, acidic peracetic acid for disinfecting the diiser 120.

The washing liquid tank 140 stores a washing liquid such as, for example, neutral reverse osmosis purified water (RO water) for cleaning after the disinfection of the dilizer 120 is finished.

The cleaning liquid tank 150 stores a cleaning liquid, for example, alkaline alkaline sterilizing water, for cleaning once again after the washing of the diiser 120.

The cylinder 160 is a tank that temporarily sucks and sterilizes the disinfecting liquid, the cleaning liquid, and the cleaning liquid for purifying the diiser 120 at a negative pressure in a vacuum state.

The compressor 170 is an air compressor that makes the inside of the cylinder 160 in a vacuum (negative pressure) state.

The outlet 180 discharges the solution in the cylinder 160 to the outside.

The PH sensor 190 is a sensor for detecting the hydrogen ion concentration of the disinfectant, cleaning solution and cleaning solution.

The flow rate sensor 195 is a sensor for detecting a flow rate according to the flow of the disinfectant solution, the cleaning solution and the cleaning solution, for example, a rotary sensor for detecting the flow rate according to the rotation of the propeller.

Meanwhile, the sololaid valves V1, V2, V3, V4, V5, V6, V7, V8, and Vd are solenoid valves turned on (open) or off (closed) according to a control signal of a microprocessor. The valve is installed in the dialysate line 121, the hose formed on one side of the diiser 120, the 'V2' valve is between the dialysate line 122 formed on the other side of the diiser 120 and the cylinder 160 Is installed in, the 'V3' valve is installed in the blood line 123 formed at one end of the dimerizer 120, 'V4' valve is the blood line 124 formed at the other end of the diiser 120 and the It is installed between the cylinders 160.

In addition, the 'V5' valve is installed in the disinfectant tank 130 line to supply the disinfectant solution to the diiser 120, and the 'V6' valve is installed in the wash solution tank 140 line to the 120, and the 'V7' valve is installed in the cleaning tank tank 150 line to supply the cleaning solution to the dilizer 120.

In addition, the 'V8' valve is installed in any one of the dialysate lines 121 and 122 and the blood lines 123 and 124 of the diiser 120, and along the dialysate line and the blood line, disinfectant solution, cleaning solution and cleaning solution. This is a valve for injecting air to flow well, the 'Vd' valve is installed on one side of the outlet 180 is used to discharge the solution in the cylinder 160 to the outside.

In this case, although not specifically illustrated in FIG. 3, a pump may be separately provided at one side of the outlet 180 to facilitate the discharge of the washing solution, the disinfecting solution, and the washing solution.

Subsequently, the microprocessor 200 may include the operation panel 110, the compressor 170, the PH sensor 190, the flow sensor 195, and a plurality of sololaid valves V1, V2, V3, V4, V5, By controlling the functions of V6, V7, V8, and Vd), the controller enables the reuse of the diiser 120 through the sanitizing solution, the cleaning solution and the cleaning solution.

For reference, FIGS. 4 to 6 are actual photographs showing the configuration of the re-apply device for applying the present invention, and the configuration is described in detail through the schematic diagram shown in FIG. Is omitted.

Meanwhile, referring to FIG. 3 to FIG. 6 and FIG. 7 described above, the method of reusing a diiser according to an embodiment of the present invention will be described in detail.

7 is a flowchart illustrating a die riser reuse method according to an embodiment of the present invention.

First, according to the operation of the operation button 111, the microprocessor 200, 'V6' valve, 'V1' valve, 'V2' valve, 'V3' valve, 'V4' valve, 'V8' valve and 'Vd' 'After the valve is turned on, the neutral wash liquid from the wash liquid tank 140 is filled and supplied to the dilizer 120, the dialysate lines 121 and 122, and the blood lines 123 and 124 for approximately 30 seconds to 60 seconds. It flows to the cylinder 160, and it wash | cleans (S205).

In this case, the washing solution is a solution having a predetermined pressure, such as reverse osmosis purified water (RO water), it is not necessary to separately maintain the inside of the cylinder 160 in a vacuum (negative pressure) state.

Thereafter, the microprocessor 200 turns on the dilizer 120 and the dialysate line by turning on the valve 'V1', 'V2', 'V3', 'V4', 'V8' and 'Vd'. 121 and 122), and the remaining solution in the blood lines 123 and 124 and the cylinder 160 are discharged through the outlet 180 for about 3 to 5 minutes, and after the valves are turned off, the compressor 170 is approximately The cylinder 160 is operated in a vacuum (negative pressure) state by operating for 30 seconds to 40 seconds (S210).

Next, the microprocessor 200 turns on the 'V5' valve, the 'V1' valve, and the 'V2' valve, and extracts an acidic disinfectant solution such as peracetic acid from the disinfectant tank 130, and the dialysis solution 120 and the dialysate. After supplying and filling the lines 121 and 122 for approximately 20 to 25 seconds, it flows to the cylinder 160 in a vacuum (negative pressure) state (S215).

At this time, the microprocessor 200 reaches a pH value of 1 to 3 through the PH sensor 190, the flow rate of the disinfectant solution is rotated 40 to 50 times through the propeller of the flow sensor 195 is supplied enough disinfectant solution If it detects that the operation is successful, perform the following steps.

At the same time, the microprocessor 200 turns on the 'V5' valve, the 'V3' valve, and the 'V4' valve, and supplies the disinfectant solution from the disinfectant tank 130 to the dilizer 120 and the blood lines 123 and 124. ) Is filled for about 20 seconds to 25 seconds, and then flows to the cylinder 160 in a vacuum (negative pressure) state (S220).

At this time, the microprocessor 200 reaches a pH value of 1 to 3 through the PH sensor 190, the flow rate of the disinfectant solution is rotated 40 to 50 times through the propeller of the flow sensor 195 is supplied enough disinfectant solution If it detects that the operation is successful, perform the following steps.

Next, the disinfectant solution is filled in the interior of the diiser 120 for about 11 hours to 15 hours to sterilize the hollow fiber membrane filter 125 (S225).

Thereafter, the microprocessor 200 turns on the 'V6' valve, the 'V1' valve, the 'V2' valve, the 'V3' valve, the 'V4' valve, the 'V8' valve, and the 'Vd' valve. Neutral washing liquid such as reverse osmosis purified water from 140 is supplied to the dilizer 120, the dialysate lines 121 and 122, the blood lines 123 and 124, and the cylinder 160 for 30 seconds to 60 seconds to be washed. At the same time the disinfecting solution in the step S225 is discharged through the outlet 180 (S230).

Next, the microprocessor 200 turns on the 'V6' valve, the 'V1' valve, the 'V2' valve, the 'V8' valve, and the 'Vd' valve, and turns off the washing liquid from the washing liquid tank 140. After supplying to the 120 and the dialysate lines 121 and 122 for about 15 seconds to 20 seconds, it is discharged in real time through the discharge port 180 via the cylinder 160 (S235).

In this case, the microprocessor 200 reaches a pH value of 5 to 9 of the washing liquid through the PH sensor 190, and a flow rate of the washing liquid is rotated 20 to 30 times through the propeller of the flow sensor 195 to supply sufficient washing liquid. If it detects that the operation is successful, perform the following steps.

At the same time, the microprocessor 200 turns on the 'V6' valve, the 'V3' valve, the 'V4' valve, the 'V8' valve, and the 'Vd' valve, and turns off the washing liquid from the washing liquid tank 140. After supplying to the 120 and the blood lines 123 and 124 for about 15 seconds to 20 seconds, it is discharged in real time through the discharge port 180 via the cylinder 160 (S240).

In this case, the microprocessor 200 reaches a pH value of 5 to 9 of the washing liquid through the PH sensor 190, and a flow rate of the washing liquid is rotated 20 to 30 times through the propeller of the flow sensor 195 to supply sufficient washing liquid. If it detects that the operation is successful, perform the following steps.

Then, the washing solution is filled in the interior of the diliser 120 for about 30 seconds to 60 seconds, and the disinfecting solution absorbed by the hollow fiber membrane filter 125 is washed and removed (S245).

At this time, in order to reliably remove the disinfectant solution from the hollow fiber membrane filter 125 in the diiser 120, it is preferable to perform the steps S235 and S240 repeatedly 13 to 17 times.

On the other hand, after the step S245, the microprocessor 200 by turning on the 'V1' valve, 'V2' valve, 'V3' valve, 'V4' valve, 'V8' valve and 'Vd' valve to the ), The washing solution in the dialysate line 121 and 122, the blood lines 123 and 124, and the cylinder 160 are discharged through the outlet 180, all valves are turned off, and the compressor 170 is operated to operate the cylinder ( 160) to make a vacuum inside (S250).

Next, the microprocessor 200 turns on the 'V7' valve, the 'V1' valve, and the 'V2' valve, and removes an alkaline cleaning liquid such as alkaline sterilizing water from the cleaning liquid tank 150 with the dilizer 120. It is supplied to the dialysate lines 121 and 122 for about 20 seconds to 25 seconds, and then flows to the cylinder 160 in a vacuum (negative pressure) state (S255).

At this time, the microprocessor 200 reaches a pH value of 10 to 13 of the cleaning liquid through the PH sensor 190, the flow rate of the cleaning liquid is rotated 40 to 50 times through the propeller of the flow sensor 195 is supplied sufficiently cleaning liquid If it detects that the operation is successful, perform the following steps.

At the same time, the microprocessor 200 turns on the 'V7' valve, the 'V3' valve, and the 'V4' valve, and supplies the cleaning liquid from the cleaning liquid tank 150 to the dilizer 120 and the blood lines 123 and 124. ) Is filled for about 20 seconds to 25 seconds, and then flows to the cylinder 160 in a vacuum (negative pressure) state (S260).

At this time, the microprocessor 200 reaches a pH value of 10 to 13 of the cleaning liquid through the PH sensor 190, the flow rate of the cleaning liquid is rotated 40 to 50 times through the propeller of the flow sensor 195 is supplied sufficiently cleaning liquid If it is detected that the purification of the diiser 120 is completed.

In this case, in order to reliably remove the washing solution from the hollow fiber membrane filter 125 in the diiser 120, the steps S250 to S260 may be repeatedly performed two to four times more.

In addition, only the washing and cleaning of the diiser 120 may be performed by only the steps S235 to S260 according to the manipulation of the rinse button 113.

Therefore, if the dilizer is purified through the above steps S205 to S260, the hollow fiber membrane filter is not only prevented from being damaged since the dilizer is shortly exposed to a disinfectant such as peracetic acid. Peracetic acid is certainly removed.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Of course.

110: operating panel 120: diliizer
121, 122: dialysate line 123, 124: blood line
125: hollow fiber membrane filter 130: disinfectant tank
140: washing liquid tank 150: washing liquid tank
160: cylinder 170: compressor
180: outlet 190: PH sensor
195: flow sensor 200: microprocessor (MPU)

Claims (5)

As a way to purify and reuse the dilizer,
(A) Dilizer 120, dialysate lines 121 and 122, blood lines 123 and 124 and the solution in the cylinder 160 is discharged through the outlet 180, the compressor 170 is operated to operate the cylinder (160) making the inside of the vacuum state (S210);
(B) supplying and disinfecting the disinfectant solution from the disinfectant tank 130 to the dilizer 120 and the dialysate line 121 and 122 and flowing it into the cylinder 160 (S215);
(C) supplying and disinfecting the disinfectant solution from the disinfectant tank 130 to the plunger 120 and the blood lines 123 and 124 to flow into the cylinder 160 (S220);
(D) disinfecting the hollow fiber membrane filter 125 by filling a disinfectant solution for a predetermined time inside the diiser 120 (S225);
(E) supplying the washing liquid from the washing liquid tank 140 to the cylinder 160 via the dilizer 120, the dialysate lines 121 and 122, and the blood lines 123 and 124, and simultaneously Discharging the disinfectant through the outlet 180 (S230);
(F) supplying the washing liquid from the washing liquid tank 140 to the dilizer 120 and the dialysate lines 121 and 122 and then discharging in real time through the outlet 180 via the cylinder 160 (S235). );
(G) supplying the washing liquid from the washing liquid tank 140 to the dilizer 120 and the blood lines 123 and 124 and discharging in real time through the outlet 180 through the cylinder 160 (S240). );
(H) filling the washing solution into the inside of the diiser 120 and removing the disinfecting solution absorbed by the hollow fiber membrane filter 125 (S245);
(I) the washing liquid in the dilizer 120, the dialysate line 121 and 122, the blood lines 123 and 124, and the cylinder 160 is discharged through the outlet 180, and the compressor 170 is operated to operate the compressor. Making the interior of the cylinder 160 in a vacuum state (S250);
(J) supplying the washing liquid from the washing liquid tank 150 to the dilizer 120 and the dialysate lines 121 and 122 and filling it and then flowing it to the cylinder 160 (S255); And
(K) supplying the cleaning liquid from the cleaning liquid tank 150 to the plunger 120 and the blood lines 123 and 124 to fill and then flowing the cylinder 160 (S260). How to reuse the eliminator. The method of claim 1,
Before step (A),
(a1) supplying the washing liquid from the washing liquid tank 140 to the dilizer 120, the dialysate lines 121 and 122, and the blood lines 123 and 124, filling and then flowing the washing liquid to the cylinder 160 for washing (S205). The method of reusing the dilizer further comprises a). The method of claim 1,
In order to reliably remove the disinfectant solution of the hollow fiber membrane filter 125 in the dilizer 120, the washing solution from the washing solution tank 140 of the step (F) is transferred to the dilizer 120 and the dialysate line 121 and 122. After supplying the discharge liquid in real time through the discharge port 180 via the cylinder 160 (S235), and the washing liquid from the washing liquid tank 140 of the (G) step the dilizer 120 and the blood line ( 123 and 124 after the supply via the cylinder 160 through the outlet 180 in real time through the discharge step (S240) characterized in that repeating the plurality of reusing method. The method of claim 1,
In the step (D), the disinfectant solution is refilled, characterized in that the inside of the dilizer 120 is maintained for 11 to 15 hours. The method of claim 1,
The method of reusing the dilizer, characterized in that to perform the steps (F) to (K) separately to wash and clean the dilizer (120).

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