KR20230013494A - Apparatus for manufacturing acellular dermal matrix and method of operating the same - Google Patents

Abstract

Disclosed are a manufacturing apparatus for the acellular dermis and a method of operating the same. The manufacturing apparatus for the acellular dermis of the present disclosure comprises: a plurality of treatment liquid containers; hoppers configured to be in fluid communication with each of the treatment liquid containers or to disconnect the flow of a fluid; a plurality of work containers configured to be fluidly connected to the hoppers or to disconnect the flow of the fluid; and recovery containers configured to be fluidly connected to each of the working containers or to disconnect the flow of the fluid. The manufacturing apparatus for the acellular dermis can improve productivity and simplify the manufacturing process.

Description

Apparatus for manufacturing acellular dermal matrix and method of operating the same}

An acellular dermal manufacturing apparatus and an operating method thereof are disclosed. More specifically, an acellular dermal manufacturing apparatus and an operating method thereof capable of improving productivity, simplifying the manufacturing process, and reducing manufacturing cost are disclosed.

Conventionally, by manually manufacturing the dermis for implantation or implantation in a living body, the manufacturing process is complicated, the productivity is low, and the manufacturing cost is excessive.

Specifically, conventionally, human tissue thawing, thickness adjustment of human tissue by manual processing, human tissue rinsing, epidermal removal reagent treatment, epidermal and hair removal manual processing, human tissue rinsing, cell removal reagent treatment, human tissue rinsing, blood removal Reagent treatment, human tissue rinsing, DNA removal reagent treatment, enzyme stop reagent treatment, human tissue rinsing, cryoprotection (selectively used as needed), and cutting and packaging processes are all performed manually and sequentially for living body transplantation or insertion The dermis was prepared.

One embodiment of the present invention provides an acellular dermal manufacturing apparatus capable of improving productivity and simplifying the manufacturing process as well as reducing manufacturing costs.

Another embodiment of the present invention provides a method for operating the acellular dermis manufacturing apparatus.

One aspect of the present invention is,

a plurality of treatment liquid containers;

a hopper configured to be in fluid communication with each of the treatment liquid containers or to be disconnected from the flow of the fluid;

A plurality of work vessels configured to be fluidly connected to the hopper or to disconnect the fluid flow; and

Provides an acellular dermal manufacturing device comprising a recovery container configured to be fluidly connected to each of the working containers or to cut off fluid flow

The acellular dermal manufacturing apparatus may further include a vacuum pump configured to lower the internal pressure of the recovery container below atmospheric pressure.

The acellular dermis manufacturing apparatus may further include an air compressor configured to supply compressed air to each of the treatment liquid containers and the hopper.

The acellular dermal preparation apparatus may further include a first precision regulator disposed between each of the treatment liquid containers and the air compressor and configured to adjust the pressure of compressed air supplied to each of the treatment liquid containers.

The acellular dermis manufacturing apparatus may further include a first on/off valve disposed between each treatment liquid container and a corresponding first precision regulator configured to pass or block compressed air supplied to each treatment liquid container. can

The acellular dermal manufacturing apparatus may further include a first air filter disposed between each of the treatment liquid containers and a corresponding first on/off valve configured to filter compressed air supplied to each of the treatment liquid containers. .

The acellular dermis manufacturing apparatus may further include a first flow control device disposed between each of the treatment liquid containers and the hopper and configured to adjust the flow rate of the treatment liquid supplied from each of the treatment liquid containers to the hopper. there is.

The acellular dermis manufacturing apparatus may further include a second on/off valve disposed between the first flow rate controller and the hopper and configured to pass or block the treatment liquid supplied from each of the treatment liquid containers to the hopper. can

The acellular dermal manufacturing apparatus may further include a tertiary water supply means configured to supply tertiary water to the hopper.

The tertiary water supply means may include a tertiary water production device, a third on/off valve, a second flow rate control device, and a fourth on/off valve in this order.

The acellular dermis manufacturing apparatus may further include a second precision regulator disposed between the hopper and the air compressor and configured to adjust the pressure of the compressed air supplied to the hopper.

The acellular dermal manufacturing apparatus may further include a fifth on/off valve disposed between the hopper and the second precision regulator and configured to pass or block compressed air supplied to the hopper.

The acellular dermal manufacturing apparatus may further include a second air filter configured to filter compressed air supplied to the hopper and disposed between the hopper and the fifth on/off valve.

The acellular dermis manufacturing apparatus may further include a sixth on/off valve disposed between the hopper and each working container.

The acellular dermal manufacturing apparatus is disposed between the hopper and the recovery container, and further comprises a plurality of seventh on/off valves disposed as many as the number of the working containers.

The acellular dermis manufacturing apparatus may further include a shaking and heating device configured to heat each of the working containers while shaking them.

The acellular dermis manufacturing apparatus may further include a vent filter configured to discharge gas generated inside each of the working vessels to the outside after filtering.

The acellular dermis manufacturing apparatus has a third air filter configured to filter gas generated inside the recovery vessel and disposed at a rear end of the third air filter so that the gas generated inside the recovery vessel exceeds a reference pressure. In the case of doing so, a vent valve configured to be discharged to the outside may be further included.

The acellular dermal manufacturing apparatus may further include a mist filter disposed between the collection container and the vacuum pump to remove mist discharged from the collection container.

Another aspect of the present invention is

As an operating method of the acellular dermis manufacturing apparatus, the operating method comprises:

filling n working containers with n dermis one by one and filling n treatment liquid containers with n treatment liquids one by one;

supplying the treatment liquid in the first treatment liquid container among the n treatment liquid containers to the hopper using air from an air compressor, but supplying only a predetermined amount using a first flow control device (SSS);

supplying the treatment solution No. 1 in the hopper or the dilution thereof to the No. 1 work container among the m number of work containers using compressed air from an air compressor;

Shaking and heating the working vessel No. 1;

discharging the treatment liquid in the first working container into a recovery container using a vacuum;

sequentially repeating the above steps for each of the treatment liquid containers number 2 to n instead of the treatment liquid container number 1; and

Provided is an operating method of an acellular dermal manufacturing apparatus comprising the step of sequentially repeating the above steps for each of the working containers No. 2 to No. m instead of the No. 1 working container.

The method of operating the cell dermal manufacturing apparatus may further include supplying the tertiary water to the hopper simultaneously or sequentially with the step (SSS), but supplying only a predetermined amount using a second flow control device.

An acellular dermal manufacturing apparatus according to an embodiment of the present invention can improve productivity and simplify the manufacturing process, as well as reduce manufacturing cost.

1 is a view schematically showing an acellular dermal manufacturing apparatus according to an embodiment of the present invention.
FIG. 2 is an enlarged view of a hopper provided in the acellular dermis manufacturing apparatus of FIG. 1 .
3a to 3c are enlarged views of a working container provided in the acellular dermal manufacturing apparatus of FIG. 1 .

Hereinafter, the acellular dermal manufacturing apparatus of the present invention will be described in detail with reference to the drawings.

1 is a diagram schematically showing an acellular dermis manufacturing apparatus 100 according to an embodiment of the present invention, and FIG. 2 is an enlarged view of a hopper 120 provided in the acellular dermal manufacturing apparatus 100 of FIG. 3A to 3C are enlarged views of the work vessel 130 provided in the acellular dermis manufacturing apparatus 100 of FIG. 1 .

Referring to FIG. 1, an acellular dermal manufacturing apparatus 100 according to an embodiment of the present invention includes a plurality of treatment liquid containers 110: 110a to 110f, a hopper 120, and a plurality of working containers 130: 130a to 130f) and a recovery container 150.

Different types of treatment liquids may be filled in the plurality of treatment liquid containers 110 ( 110a to 110f ).

For example, a high-concentration washing solution may be filled in the treatment liquid container 110a, a cell removal solution may be filled in the treatment liquid container 110b, and a blood removal solution may be filled in the treatment liquid container 110c. The treatment solution container 110d may be filled with a DNA removal solution, the treatment solution container 110e may be filled with a high-concentration enzyme stop solution, and the treatment solution container 110f may be filled with a cryoprotectant solution. .

The high-concentration washing solution discharged from the treatment liquid container 110a and the high-concentration enzyme stop solution discharged from the treatment liquid container 110e may be diluted inside the hopper 120. When the predetermined amount is injected into the hopper 120, the third water may be simultaneously or sequentially introduced into the hopper 120 by a predetermined amount according to the dilution ratio and mixed inside the hopper 120. In the case of the high-concentration washing solution and the high-concentration enzyme-stopping solution, the amount of use is large, and there is a spatial problem such as an increase in the volume occupied by the reagent tank during automation. Later, it was designed in a way that it is mixed with tertiary water and used, so that the production amount of the treatment liquid was reduced by about 80% and the size of the device was also reduced.

The high-concentration washing solution, the cell removal solution, the blood removal solution, the DNA removal solution, the high-concentration enzyme stopping solution, and the cryoprotection solution may be solutions well known in the art.

The hopper 120 may be in fluid communication with each of the treatment liquid containers 110a to 110f or may be configured such that fluid flow is disconnected. To this end, as will be described later, second on/off valves V21 to V26 may be installed in pipes between the hopper 120 and the treatment liquid containers 110a to 110f.

In addition, the hopper 120 may include an agitator (not shown) mounted therein. The agitator is for increasing the degree of mixing of the high-concentration treatment liquid and the tertiary water.

Referring to FIG. 2 , as many nozzles N1 to N7 as the number of treatment liquid containers 110 may be installed at the upper end of the hopper 120 . The nozzles N1 to N7 may be designed so that the supply of the treatment liquid to the hopper 120 can be stopped immediately when the supply of the treatment liquid is stopped while smoothly passing the treatment liquid. That is, when the integrated flow rate calculated by the first flow control devices FM1 to FM7 reaches the reference value, the second on/off valves V21 to V26 are immediately closed to stop supplying the treatment liquid to the hopper 120. The structures of the nozzles N1 to N7 may be specially designed so that the treatment liquid remaining between the second on/off valves V21 to V26 and the hopper 120 does not fall freely and flow into the hopper 120. . For example, the inner diameter d of the tips of the nozzles N1 to N7 may be 2 to 3.5 mm. A plurality of working containers ( 130: It is possible to control the amount of treatment liquid injected by 130a to 130f) within ±1% of the set value or target value.

A plurality of working vessels (130: 130a ~ 130f) is a component for producing acellular dermis by processing the skin (skin).

These plurality of work vessels (130: 130a ~ 130f) may be configured to be fluidly connected to the hopper 120 or disconnected from the fluid flow. To this end, sixth on/off valves V42 to V92 may be installed in the pipe between the hopper 120 and each of the work vessels 130a to 130f, as described below.

In addition, the plurality of working vessels (130: 130a ~ 130f) may have a variable capacity of 100 ~ 4,500ml.

The recovery vessel 150 may be fluidly connected to each of the working vessels 130a to 130f or may be configured such that the fluid flow is disconnected. To this end, seventh on/off valves V41 to V91 may be installed in pipes between the recovery container 150 and each of the work containers 130a to 130f, as will be described later.

In addition, the acellular dermis manufacturing apparatus 100 may further include a vacuum pump 160 configured to lower the internal pressure of the collection container 150 below atmospheric pressure. In this way, when the vacuum pump 160 is operated to apply a vacuum to the inside of the recovery container 150, the treatment liquid can be removed without opening each of the working containers 130a to 130f containing the dermis. However, there is a problem such as the dermis blocking the drain hole of each of the working vessels 130a to 130f when the treatment liquid is sucked out by vacuum, as shown in FIGS. 3A to 3C, each of the working vessels 130a to 130f ) may be installed at the bottom of the drain hole 133 and the separator plate 134 separating the dermis, and the separator plate 134 is disposed at an angle inclined toward the drain hole 133 to help drain. 3A to 3C, unexplained reference numeral 131 denotes a body, and 132 denotes a treatment liquid inlet.

In addition, the acellular dermis manufacturing apparatus 100 may further include an air compressor (AC).

The air compressor (AC) may be configured to supply compressed air to each of the treatment liquid containers 110a to 110f and the hopper 120 .

In addition, the acellular dermal manufacturing apparatus 100 may further include first precision regulators PR1 to PR6.

The first precision regulators PR1 to PR6 are disposed between the respective treatment liquid containers 110a to 110f and the air compressor AC to precisely control the pressure of the compressed air supplied to each of the treatment liquid containers 110a to 110f. can be configured to control

In addition, the acellular dermal manufacturing apparatus 100 may further include a pressure gauge disposed adjacent to each of the first precision regulators PR1 to PR6.

In addition, the acellular dermal manufacturing apparatus 100 may further include first on/off valves V11 to V16.

The first on/off valves V11 to V16 are disposed between each of the treatment liquid containers 110a to 110f and the corresponding first precision regulators PR1 to PR6 to compress the pressure supplied to each of the treatment liquid containers 110a to 110f. It can be configured to pass or block air.

In addition, the acellular dermal manufacturing apparatus 100 may further include first air filters AF1 to AF6.

The first air filters AF1 to AF6 are disposed between the respective treatment liquid containers 110a to 110f and the corresponding first on/off valves V11 to V16 to compress and supply the respective treatment liquid containers AF1 to AF6. It can be configured to filter the air (ie, remove impurities).

In addition, the acellular dermis manufacturing apparatus 100 may further include first flow control devices FM1 to FM6.

The first flow control devices FM1 to FM6 are disposed between each of the treatment liquid containers 110a to 110f and the hopper 120, and the treatment liquid is supplied to the hopper 120 from each of the treatment liquid containers 110a to 110f. It can be configured to regulate the flow rate of.

In addition, the first flow control devices FM1 to FM6 may be ultrasonic flow sensors, and may be configured to measure the accumulated flow rate of the treatment liquid supplied to the hopper 120 and fill the hopper 120 only by a predetermined amount. . Specifically, the acellular dermal manufacturing apparatus 100 closes the second on/off valves V21 to V26 to be described later when the integrated flow rate calculated by the first flow rate control devices FM1 to FM6 matches a predetermined amount. It may be configured to stop supplying the treatment liquid.

In addition, the first flow control devices FM1 to FM6 may be non-contact, and in this case, cleaning and maintenance are unnecessary.

In addition, the acellular dermal manufacturing apparatus 100 may further include second on/off valves V21 to V26.

The second on/off valves V21 to V26 are disposed between the first flow control devices FM1 to FM6 and the hopper 120 to supply the treatment liquid from the treatment liquid containers 110a to 110f to the hopper 120. It can be configured to pass or block.

In addition, the acellular dermis manufacturing apparatus 100 may further include a tertiary water supply means configured to supply tertiary water to the hopper 120 . In this specification, "tertiary water" means ultrapure water.

The tertiary water supply unit may include a tertiary water production device (not shown), a third on/off valve V31, a second flow rate control device FM7, and a fourth on/off valve V32 in this order.

The configuration and function of the second flow control device FM7 is similar to that of the above-described first flow control devices FM1 to FM6, and the third on-off valve V31 and the fourth on-off valve V32 The configuration and function of may be similar to those of the aforementioned second on/off valves V21 to V26. However, while the first flow control devices FM1 to FM6 and the second on/off valves V21 to V26 are for gas, the second flow control device FM7, the third on/off valve V31 and the fourth on/off valve V21 to V26 are for gases. The difference is that the off valve V32 is for liquid.

In addition, the acellular dermal manufacturing apparatus 100 may further include a second precision regulator PR7.

The second precision regulator PR7 may be disposed between the hopper 120 and the air compressor AC to adjust the pressure of compressed air supplied to the hopper 120 .

The configuration and function of the second precision regulator PR7 may be the same as those of the first precision regulators PR1 to PR6.

In addition, the acellular dermal manufacturing apparatus 100 may further include a pressure gauge disposed adjacent to the second precision regulator PR7.

In addition, the acellular dermal manufacturing apparatus 100 may further include a fifth on/off valve V4.

The fifth on/off valve V4 may be disposed between the hopper 120 and the second precision regulator PR7 to pass or block compressed air supplied to the hopper 120 .

In addition, the acellular dermal manufacturing apparatus 100 may further include a second air filter AF7.

The second air filter AF7 may be disposed between the hopper 120 and the fifth on/off valve V4 to filter compressed air supplied to the hopper 120 (ie, remove impurities).

In addition, the acellular dermis manufacturing apparatus 100 may further include sixth on/off valves V42 to V92.

The sixth on/off valves V42 to V92 may be disposed between the hopper 120 and the respective work vessels 130a to 130f.

In addition, the acellular dermal manufacturing apparatus 100 may further include seventh on/off valves V41 to V91.

The seventh on/off valves V41 to V91 are disposed between the hopper 120 and the recovery vessel 150, and may be disposed as many as the number of working vessels 130a to 130f.

For example, when the treatment liquid is supplied from the hopper 120 to each of the working vessels 130a to 130f, the sixth on/off valves V42 to V92 corresponding to the working vessels 130a to 130f to which the treatment liquid is supplied. ) is opened and the others are closed, and the seventh on-off valves V41 to V91 corresponding to or disposed after the opened sixth on-off valves V42 to V92 are closed and the seventh on-off valves V41 to V91 disposed at the front end thereof. The on/off valves V41 to V91 may be opened.

Dead volumes between the sixth on/off valves V42 to V92 and the seventh on/off valves V41 to V91 may be minimized.

In addition, the acellular dermal manufacturing apparatus 100 may further include shaking and heating devices 140a to 140f.

The shaking and heating devices 140a to 140f may be configured to heat the respective work containers 130a to 130f while shaking them. In this way, when the shaking and heating devices 140a to 140f shake each of the working containers 130a to 130f, the dermis collides with the separator 134, and the water accumulated in the middle of the dermis escapes to promote dehydration.

In addition, the acellular dermal manufacturing apparatus 100 may further include vent filters VF1 to VF6.

Vent filters (VF1 to VF6) may be configured to discharge the gas generated inside each of the working containers (130a to 130f) to the outside after filtering. These vent filters (VF1 to VF6) can prevent the flow of the liquid supplied from the hopper 120 to the respective work vessels 130a to 130f from being deteriorated due to gas filling in the pipes of the treatment liquid.

In addition, the acellular dermal manufacturing apparatus 100 may further include a third air filter AF8 and a vent valve VV.

The third air filter AF8 may be configured to filter gas generated inside the recovery container 150 .

The vent valve VV may be disposed at a rear end of the third air filter AF8 to discharge the gas generated inside the recovery vessel 150 to the outside when the pressure exceeds a reference pressure.

In addition, the acellular dermal manufacturing apparatus 100 may further include a mist filter (MF).

The mist filter MF may be disposed between the recovery vessel 150 and the vacuum pump 160 to remove mist discharged from the recovery vessel 150 .

In addition, the acellular dermis manufacturing apparatus 100 may further include a drain valve DV configured to discharge the liquid in the recovery container 150 to the outside.

Hereinafter, a method of operating the acellular dermis manufacturing apparatus 100 according to an embodiment of the present invention will be described in detail with reference to FIG. 1 .

First, n working containers 130a to 130f are filled with n dermis one by one, and n treatment liquid containers 110a to 110f are filled with n types of treatment liquids one by one. The n may be 6, but the present invention is not limited thereto.

<First washing step>

(1-1) First, the treatment liquid (for example, high-concentration washing liquid) in the first treatment liquid container (110a) is supplied to the hopper 120 using compressed air from an air compressor (AC), but the first flow control device (FM1) is used to supply only a predetermined amount. At the same time or sequentially, the tertiary water is supplied to the hopper 120, but only a predetermined amount is supplied using the second flow control device FM7 according to the dilution ratio of the treatment liquid. At this time, in the hopper 120, the treatment liquid discharged from the first treatment liquid container 110a is mixed with the tertiary water to prepare a diluted solution.

(1-2) Next, the diluted solution in the hopper 120 is supplied to the No. 1 work container 130a using compressed air from the air compressor AC. Specifically, the compressed air of the air compressor (AC) is supplied to the hopper 120 as the fifth on-off valve (V4) is opened after the flow rate is adjusted by the second precision regulator (PR7), whereby the compressed air is The dilution solution may be pushed out of the hopper 120 and supplied to the first working vessel 130a.

(1-3) Next, the working vessel 130a is shaken and heated.

(1-4) Next, the treatment liquid in the No. 1 working container 130a is discharged to the recovery container 150 using a vacuum.

Through the above steps, the dermis in the No. 1 working vessel 130a is washed.

(1-5) Repeat the above (1-1) to (1-4) with respect to the 2nd to nth working containers 130b to 130f. For example, immediately after completing (1-1) and (1-2) for the first working vessel 130a, in a manner of starting the above (1-1) for the second working vessel 130b. Repeat the above (1-1) to (1-4) while changing the working vessel. Through the above steps, the dermis in the second to n working vessels 130b to 130f is washed.

<Cell removal step>

(2-1) First, the treatment solution (for example, cell removal solution) in the treatment solution container 110b 110b is supplied to the hopper 120 using compressed air from an air compressor AC, and the first flow rate is adjusted. Only a predetermined amount is supplied using the device FM2.

(2-2) Next, the processing liquid in the hopper 120 is supplied to the No. 1 working vessel 130a using compressed air from the air compressor AC.

(2-3) Next, the working container 130a is shaken and heated.

(2-4) Next, the treatment liquid in the No. 1 working vessel 130a is discharged to the recovery vessel 150 by using a vacuum.

Through the above steps, cells are removed from the dermis in the No. 1 working container 130a.

(2-5) The above (2-1) to (2-4) are repeated for the 2nd to nth working containers 130b to 130f. For example, immediately after completing (2-1) and (2-2) for the first working vessel 130a, start the above (2-1) for the second working vessel 130b. Repeat the above (2-1) to (2-4) while changing the working container. Through the above steps, cells are removed from the dermis in the second to n working containers 130b to 130f.

<Second washing step>

(3) Next, a second washing step is performed in the same manner as the first washing step for the dermis in the 1st to nth work vessels 130a to 130f.

<Blood removal step>

(4-1) First, the treatment liquid (eg, blood removal solution) in the treatment liquid container 110c is supplied to the hopper 120 using compressed air from the air compressor (AC), and the first flow rate is adjusted. A predetermined amount is supplied using the device FM3.

(4-2) Next, the processing liquid in the hopper 120 is supplied to the No. 1 work container 130a using compressed air from the air compressor AC.

(4-3) Next, the working vessel 130a is shaken and heated.

(4-4) Next, the treatment liquid in the No. 1 working container 130a is discharged to the recovery container 150 using a vacuum.

Through the above steps, blood is removed from the dermis in the No. 1 working vessel 130a.

(4-5) The above (4-1) to (4-4) are repeated for the second to n working vessels 130b to 130f. For example, immediately after completing (4-1) and (4-2) for the first working container 130a, start the above (4-1) for the second working container 130b. Repeat the above (4-1) to (4-4) while changing the working vessel. Through the above steps, blood is removed from the dermis in the second to n working containers 130b to 130f.

<Third washing step>

(5) Next, a third washing step is performed in the same manner as the first washing step for the dermis in the first to n working vessels 130a to 130f.

<DNA removal step>

(6-1) The treatment solution (eg, DNA removal solution) in the treatment solution container 110d 4 is supplied to the hopper 120 using compressed air from an air compressor (AC), and the first flow control device ( FM4) is used to supply only a predetermined amount.

(6-2) Next, the treatment liquid in the hopper 120 is supplied to the No. 1 working container 130a using compressed air from the air compressor AC.

(6-3) Next, the working vessel 130a is shaken and heated.

(6-4) Next, the treatment liquid in the No. 1 working vessel 130a is discharged to the recovery vessel 150 by using a vacuum.

Through the above steps, DNA is removed from the dermis in the No. 1 working container 130a.

(6-5) The above (6-1) to (6-4) are repeated for the second to n working containers 130b to 130f. For example, immediately after completing (6-1) and (6-2) with respect to the first working container (130a), in such a manner as to start the above (6-1) with respect to the second working container (130b). Repeat the above (6-1) to (6-4) while changing the working vessel. Through the above steps, DNA is removed from the dermis in the second to n working containers 130b to 130f.

<Enzyme stop processing step>

(7-1) First, the treatment solution (for example, high-concentration enzyme-stopping solution) in the No. 5 treatment solution container (110e) is supplied to the hopper 120 using compressed air from an air compressor (AC), and the first flow rate is Supply only a predetermined amount by using the control device (FM5). At the same time or sequentially, the tertiary water is supplied to the hopper 120, but only a predetermined amount is supplied using the second flow control device FM7 according to the dilution ratio of the treatment liquid. At this time, in the hopper 120, the treatment liquid discharged from the fifth treatment liquid container 110e and the tertiary water are mixed to prepare a diluted liquid.

(7-2) Next, the diluted solution in the hopper 120 is supplied to the No. 1 working container 130a using compressed air from the air compressor AC.

(7-3) Next, the working vessel 130a is shaken and heated.

(7-4) Next, the treatment liquid in the No. 1 working container 130a is discharged to the recovery container 150 using a vacuum.

Through the above steps, the dermis in the No. 1 working vessel 130a is subjected to enzyme-stopping treatment.

(7-5) The above (7-1) to (7-4) are repeated for the second to n working vessels 130b to 130f. For example, immediately after completing (7-1) and (7-2) for the first working vessel 130a, start the above (7-1) for the second working vessel 130b. Repeat the above (7-1) to (7-4) while changing the working vessel. Through the above steps, the dermis in Nos. 2 to n working vessels 130b to 130f is subjected to enzyme-stopping treatment.

<Fourth washing step>

(8) Next, a fourth washing step is performed in the same manner as the first washing step for the dermis in the 1st to nth working vessels 130a to 130f.

<Freeze protection treatment step>

The cryoprotection treatment step is not an essential step and may optionally be included if necessary.

(9-1) First, the treatment solution (for example, cryoprotection solution) in the No. 6 treatment solution container (110f) is supplied to the hopper 120 using compressed air from the air compressor (AC), but the first flow rate is adjusted. Only a predetermined amount is supplied using device FM6.

(9-2) Next, the processing liquid in the hopper 120 is supplied to the No. 1 working container 130a using compressed air from the air compressor AC.

(9-3) Next, the working vessel 130a is shaken and heated.

(9-4) Next, the treatment liquid in the No. 1 working container 130a is discharged to the recovery container 150 using a vacuum.

Through the above steps, the dermis in the No. 1 working container 130a is treated with cryoprotection.

(9-5) The above (9-1) to (9-4) are repeated for the second to n working containers 130b to 130f. For example, immediately after completing (9-1) and (9-2) with respect to the first working container (130a), in such a manner as to start the above (9-1) with respect to the second working container (130b). Repeat the above (9-1) to (9-4) while changing the working container. Through the above steps, the dermis in the second to n working vessels 130b to 130f is cryopreserved.

<Recovery container drain step>

In the process of performing the above steps, the recovery container 150 is emptied by opening the drain valve DV at appropriate times.

The present invention has been described with reference to the drawings, but these are merely exemplary, and those skilled in the art will understand that various modifications and equivalent other implementations are possible therefrom. Therefore, the true technical scope of protection of the present invention should be determined by the technical spirit of the appended claims.

100: acellular dermal manufacturing device 110: treatment liquid container
120: hopper 130: working container
140: shaking and heating device 150: recovery container
160: vacuum pump

Claims (21)

a plurality of treatment liquid containers;
a hopper configured to be in fluid communication with each of the treatment liquid containers or to be disconnected from the flow of the fluid;
A plurality of work vessels configured to be fluidly connected to the hopper or to disconnect the fluid flow; and
A cell-free dermal manufacturing apparatus comprising a recovery vessel configured to be fluidly connected to each of the working vessels or to disconnect the fluid flow. According to claim 1,
An acellular dermal manufacturing apparatus further comprising a vacuum pump configured to lower the internal pressure of the recovery container below atmospheric pressure. According to claim 1,
An acellular dermis manufacturing apparatus further comprising an air compressor configured to supply compressed air to each of the treatment liquid containers and the hopper. According to claim 3,
The acellular dermal manufacturing apparatus further comprises a first precision regulator disposed between each of the treatment liquid containers and the air compressor and configured to adjust the pressure of the compressed air supplied to each of the treatment liquid containers. According to claim 4,
A cell-free dermal manufacturing apparatus further comprising a first on-off valve disposed between each of the treatment liquid containers and the corresponding first precision regulator and configured to pass or block compressed air supplied to each of the treatment liquid containers. According to claim 5,
The acellular dermal manufacturing apparatus further comprises a first air filter disposed between each treatment liquid container and a corresponding first on/off valve configured to filter compressed air supplied to each treatment liquid container. According to claim 6,
A cell-free dermal manufacturing apparatus further comprising a first flow control device disposed between each of the treatment liquid containers and the hopper and configured to adjust the flow rate of the treatment liquid supplied from each of the treatment liquid containers to the hopper. According to claim 7,
A cell-free dermal manufacturing apparatus further comprising a second on-off valve disposed between the first flow control device and the hopper and configured to pass or block the treatment liquid supplied from each of the treatment liquid containers to the hopper. According to claim 1,
Acellular dermis manufacturing apparatus further comprising a tertiary water supply means configured to supply tertiary water to the hopper. According to claim 9,
The tertiary water supply means comprises a tertiary water manufacturing device, a third on-off valve, a second flow rate control device, and a fourth on-off valve in this order. According to claim 3,
A cell-free dermal manufacturing apparatus further comprising a second precision regulator disposed between the hopper and the air compressor and configured to adjust the pressure of the compressed air supplied to the hopper. According to claim 11,
A cell-free dermal manufacturing apparatus further comprising a fifth on-off valve disposed between the hopper and the second precision regulator and configured to pass or block compressed air supplied to the hopper. According to claim 12,
The acellular dermal manufacturing apparatus further comprises a second air filter disposed between the hopper and the fifth on/off valve and configured to filter compressed air supplied to the hopper. According to claim 1,
A cell-free dermis manufacturing apparatus further comprising a sixth on-off valve disposed between the hopper and each of the working vessels. According to claim 1,
A cell-free dermal manufacturing apparatus further comprising a plurality of seventh on-off valves disposed between the hopper and the recovery container and disposed as many as the number of the working containers. According to claim 1,
A cell-free dermis manufacturing apparatus further comprising a shaking and heating device configured to heat while shaking each of the working containers. According to claim 1,
A cell-free dermal manufacturing apparatus further comprising a vent filter configured to discharge gas generated inside each of the working vessels to the outside after filtering. According to claim 1,
A third air filter configured to filter the gas generated inside the recovery vessel and disposed at a rear end of the third air filter to discharge the gas generated inside the recovery vessel to the outside when the gas generated inside the recovery vessel exceeds a reference pressure. An acellular dermal manufacturing apparatus further comprising a configured vent valve. According to claim 1,
A cell-free dermal manufacturing apparatus further comprising a mist filter disposed between the recovery vessel and the vacuum pump and configured to remove mist discharged from the recovery vessel. A method of operating the acellular dermis manufacturing apparatus according to any one of claims 1 to 19, the operating method comprising:
filling n working containers with n dermis one by one and filling n treatment liquid containers with n treatment liquids one by one;
supplying the treatment liquid in the treatment liquid container 1 of the n treatment liquid containers to the hopper using air from an air compressor, but supplying only a predetermined amount using a first flow control device (SSS);
supplying the treatment solution No. 1 in the hopper or the dilution thereof to the No. 1 work container among the m number of work containers using compressed air from an air compressor;
Shaking and heating the working vessel No. 1;
discharging the treatment liquid in the first working container into a recovery container using a vacuum;
sequentially repeating the above steps for each of the treatment liquid containers number 2 to n instead of the treatment liquid container number 1; and
A method of operating an acellular dermal manufacturing apparatus comprising the step of sequentially repeating the above steps for each of the working containers No. 2 to No. m instead of the No. 1 working container. According to claim 20,
The operation method of the acellular dermis manufacturing apparatus further comprising the step of supplying the tertiary water to the hopper simultaneously or sequentially with the step (SSS), but only by a predetermined amount using a second flow control device.

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