KR102502401B1 - A transfromed cancer cell cellection device comprising a mock vessel unit and a cancer cell transformation observation system using the same - Google Patents

Abstract

Transformed cancer cell collection device including a simulated blood vessel unit according to the present invention and a system for observing transformation of cancer cells using the same have an inlet and an outlet, and in order to observe the transformation of cancer cells passing through a blood vessel wall, the inlet and the outlet are formed. A simulated vascular unit formed on a part of the path along which the medium and cancer cells move toward the outlet, wherein a plurality of vascular units are disposed along the path so as to be spaced apart from each other to form a spaced gap so that the cancer cells flow out; A replicative vascular unit including a membrane portion in which a plurality of the loop portions are located, formed of a plurality of membranes, secreting an inducer so that the cancer cells flow out through the spaced gap, and serving as a path through which the medium and the cancer cells move. Provided is a transformed cancer cell collection device comprising a and a cancer cell transformation observation system using the same.

Description

Transformed cancer cell collection device including a replicative blood vessel unit and cancer cell transformation observation system using the same

The present invention relates to a transformed cancer cell collection device including a simulated vascular unit and a cancer cell transformation observation system using the same, and more particularly, to a cancer cell transformation through vascular endothelial cells can be observed by collecting various samples. The present invention relates to a transformed cancer cell collection device including a replicative vascular unit and a cancer cell transformation observation system using the same.

Cancer cells can escape from the primary site where they first occurred and move along blood vessels, colonize in another organ, and metastasize to another organ.

As described above, cancer cells that have escaped from the primary site may move along the blood vessels to the organs to which they metastasize, pass through the blood vessel walls, and migrate to the metastasis area.

However, cancer cells that have migrated to the metastasis site through the vascular wall in this way may have similar phenotypes to the cancer cells of the original origin, but some cancer cells are transformed and converted into cancer cells of a different type from the cancer cells of the original origin. Situations may arise in which other treatments may be used.

Various attempts have been made to collect various samples for the transformation of cancer cells passing through the blood vessel wall or moving along the blood vessel, but it is virtually Because it is difficult, it may be somewhat difficult to sample cancer cells from the primary site and the metastasis area respectively.

Accordingly, means for observing the transformation of cancer cells passing through vascular endothelial cells by collecting various samples have been actively devised, and means to solve this problem are needed.

The present invention is intended to solve the above problems, and an object of the present invention is to observe the transformation of cancer cells passing through vascular endothelial cells by collecting various samples.

The tasks of the present invention are not limited to the tasks mentioned above, and other tasks not mentioned will be clearly understood by those skilled in the art from the description below.

In order to solve the above problems, according to one embodiment of the present invention, an inlet and an outlet are formed, and the path through which the medium and cancer cells move from the inlet toward the outlet to observe the transformation of cancer cells passing through the blood vessel wall A simulated vascular unit formed in a part, wherein a plurality of ring parts are disposed along a path so as to be spaced apart from each other to form a spaced gap so that the cancer cells flow out, a plurality of the ring parts are located inside, and a plurality of membranes It is formed to secrete an inducer so that the cancer cells flow out of the spaced gap, and includes a film portion that serves as a path for moving the medium and the cancer cells.

In addition, a portion of the circumference of the ring portion extends through the adjacent ring portion to further include a connecting portion connecting each other.

Here, the connection part is characterized in that the ring part is formed long from the inlet toward the outlet so that the ring part is fixed on the path and connects the plurality of the ring parts inside the film part.

In addition, the connecting portion is characterized in that the distance between the plurality of the ring portion is maintained by connecting the ring portions adjacent to each other in the spaced gap.

At this time, the connecting portion is characterized in that a plurality is formed along the circumference of the ring portion.

On the other hand, the film portion includes a cover member provided to surround the ring portion and the connection portion, and a secretion member formed along the circumference of the cover member and secreting an inducer to move the cancer cells to the outside. do.

Here, the secretion member is characterized in that composed of vascular endothelial cells.

In addition, the film unit is characterized in that it further comprises a moisture holding member provided along the circumference of the secretion member so that the moisture of the secretion member is maintained.

Here, the moisture retaining member is formed along the circumference of the secretion member between the ring parts, characterized in that formed to surround the secretion member.

On the other hand, the ring portion is characterized in that in contact with the inner circumference of the film portion to support the film portion.

An apparatus for collecting transformed cancer cells including a replicative vascular unit according to an embodiment of the present invention having the above-described configuration includes an inlet and an outlet, and at the inlet to observe the transformation of cancer cells passing through the blood vessel wall. A simulated vascular unit formed on a part of the path along which the medium and cancer cells move toward the outlet, a ring part arranged so as to be spaced apart from each other on the path to form a gap to allow the cancer cells to flow out, and a plurality of rings inside the unit. A replicative vascular unit including a membrane portion, formed of a plurality of membranes, secreting an inducer so that the cancer cells flow out through the gap, and forming a path through which the medium and the cancer cells move, and a space inside. Formed, the cancer cells are located, the primary unit through which the medium is circulated through communication with the inlet and the outlet, and the simulated blood vessel unit are disposed penetrating the inside, and the cancer cells moving out of the simulated blood vessel unit are collected contain the receiving unit.

Here, the accommodating unit is characterized in that an inducer is accommodated so as to promote the outward migration of the cancer cells that migrate through the simulated vascular unit.

On the other hand, the primary unit includes a circulation unit connected to the inlet and the outlet to circulate the medium, an outer tube communicating with the circulation unit, and an inner tube spaced apart from the outer tube and having cancer cells positioned therein and having an opening formed toward the top. and an inducing portion formed of a plurality of membranes on one side of the inner cylinder to secrete an inducer so that the cancer cells floating in the inner cylinder are moved toward the simulated vascular unit by circulation of the medium. to be

On the other hand, the induction unit is provided between a first upper skin member formed on one surface of the round portion, a second upper skin member provided to contact the first membrane, and the first membrane and the second membrane to secrete an inducer. It is characterized in that it includes a third upper skin member.

Here, the third epidermal layer is provided with vascular endothelial cells so that the cancer cells are moved toward the simulated vascular unit and is attached to the first epidermal layer and the imitation capsule layer attached to the first epidermal layer and the second epidermal layer. In order to prevent damage to the coating layer, it is characterized in that it includes a hydrogel layer provided between the dummy coating layer and the second upper skin member.

On the other hand, the inner tube is characterized in that it includes a filtering member provided in the opening to prevent the cancer cells from escaping to the outside.

On the other hand, the simulated blood vessel unit is characterized in that it further comprises a connection portion for connecting a portion of the circumference of the ring portion extending through the adjacent ring portion to connect each other.

Here, the connection part is characterized in that the ring part is formed long from the inlet toward the outlet so that the ring part is fixed on the path and connects the plurality of the ring parts inside the film part.

The cancer cell transformation observation system according to an embodiment of the present invention using the transformed cancer cell collection device including the above-described replicative blood vessel unit has an inlet and an outlet, and observes transformation of cancer cells passing through a blood vessel wall. As a simulated blood vessel unit formed on a part of the path along which the medium and cancer cells are moved from the inlet toward the outlet, a plurality of vascular units are arranged to be spaced apart on the path to form a gap so that the cancer cells flow out; A replicative vascular unit including a film portion in which a plurality of the ring portions are positioned, formed of a plurality of membranes, secreting an inducer so that the cancer cells flow out through the gap, and forming a path through which the medium and the cancer cells move; A space is formed therein to position the cancer cells, the primary unit through which the medium is circulated through communication with the inlet and the outlet, and the simulated blood vessel unit are disposed penetrating the inside, and the simulated blood vessel unit is moved to the outside. Transformed cancer cell collection device including a simulated blood vessel unit including a receiving unit for collecting cancer cells, a circulation device communicating with the receiving unit so that an inducer circulates through the receiving unit, and formed on the path of the circulation unit and an extraction device in which the cancer cells moved to the receiving unit are moved and collected according to the flow of the inducer.

Here, the extraction device is characterized in that a space is formed at the bottom so that the inner space is formed stepwise so that the cancer cells settle in the inner space.

In addition, the circulation device is characterized in that it comprises a pump unit for providing power so that the inducer is moved on the moving path of the inducer.

On the other hand, the primary device includes a circulation unit connected to the inlet and the outlet to circulate the medium, an outer tube communicating with the circulation unit, and an inner tube spaced apart from the outer tube and having cancer cells positioned therein and having an opening toward the top. and an inducing portion formed of a plurality of membranes on one side of the inner cylinder to secrete an inducer so that the cancer cells floating in the inner cylinder are moved toward the simulated vascular unit by circulation of the medium. to be

Here, the induction unit includes a first upper skin member formed on one surface of the round portion, a second upper skin member provided to contact the first membrane, and a second membrane provided between the first membrane and the second membrane to secrete an inducer. It is characterized by including 3 upper skin materials.

In addition, the third epidermal layer is provided with vascular endothelial cells so that the cancer cells are moved toward the simulated vascular unit and is attached to the first epidermal layer, the first epidermal layer, and the second epidermal layer. It is characterized in that it includes a hydrogel layer provided between the fake coating layer and the second upper skin member to prevent damage to the fake coating layer.

On the other hand, the simulated blood vessel unit is characterized in that it further comprises a connection portion for connecting a portion of the circumference of the ring portion extending through the adjacent ring portion to connect each other.

Here, the connection part is characterized in that the ring part is formed long from the inlet toward the outlet so that the ring part is fixed on the path and connects the plurality of the ring parts inside the film part.

In order to solve the above problems, according to an embodiment of the present invention, a transformed cancer cell collection device including a replicative vascular unit and a cancer cell transformation observation system using the same are used to measure the transformation of cancer cells passing through vascular endothelial cells in various samples. There is an effect that can be collected and observed.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

The above summary, as well as the detailed description of the preferred embodiments of the present application set forth below, will be better understood when read in conjunction with the accompanying drawings. Preferred embodiments are shown in the drawings for the purpose of illustrating the present invention. However, it should be understood that this application is not limited to the precise arrangements and instrumentalities shown.
1 is a view showing the overall appearance of a transformed cancer cell collection device including a replicative vascular unit and a cancer cell transformation observation system using the same according to an embodiment of the present invention;
FIG. 2 is a view for explaining the replicative vascular unit of the transfected cancer cell collection device including the replicative vascular unit and the cancer cell transformation monitoring system using the same according to an embodiment of the present invention;
FIG. 3 is a diagram illustrating a film portion of a transformed cancer cell collection device including a replicative vascular unit and a cancer cell transformation observation system using the same according to an embodiment of the present invention;
4 is a diagram illustrating a primary unit of a transformed cancer cell collection device including a replicative vascular unit and a cancer cell transformation observation system using the same according to an embodiment of the present invention;
5 is a diagram illustrating an induction unit of a transformed cancer cell collection device including a replicative vascular unit and a cancer cell transformation observation system using the same according to an embodiment of the present invention;
FIG. 6 is a view for explaining an apparatus for collecting transformed cancer cells including a simulated vascular unit and an extraction apparatus for a system for observing transformation of cancer cells using the apparatus according to an embodiment of the present invention;
FIG. 7 is a diagram illustrating the overall flow of a transformed cancer cell collection device including a replicative vascular unit and a system for observing transformation of cancer cells using the same according to an embodiment of the present invention;
FIG. 8 is a view to explain a situation in which cancer cells are leaked through the replicative vascular unit of the transformed cancer cell collection device including the replicative vascular unit and the system for observing transformation of cancer cells using the same according to an embodiment of the present invention. ;
FIG. 9 is a diagram illustrating in detail the escape of cancer cells into the replicative vascular unit of the transformed cancer cell collection device including the replicative vascular unit and the system for observing the transformation of cancer cells using the same according to an embodiment of the present invention. floor plan; and
FIG. 10 is a view showing the formation of reinforcement parts in the replicative vascular unit of the transformed cancer cell collection device including the replicative vascular unit and the cancer cell transformation monitoring system using the same according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention in which the object of the present invention can be realized in detail will be described with reference to the accompanying drawings. In describing the present embodiment, the same name and the same reference numeral are used for the same configuration, and additional description thereof will be omitted.

First, with reference to FIGS. 1 to 6 , configurations of a transformed cancer cell collection device including a replicative vascular unit and a cancer cell transformation observation system using the same according to an embodiment of the present invention will be described.

Specifically, FIG. 1 is a view showing the overall appearance of a transformed cancer cell collection device including a replicative vascular unit and a cancer cell transformation observation system using the same according to an embodiment of the present invention, and FIG. 2 is an embodiment of the present invention. Figure 3 is a diagram showing the replicator unit of the transformed cancer cell collection device including the replicator unit according to the example and the system for observing transformation of cancer cells using the same, and FIG. 3 is the replicator unit according to one embodiment of the present invention. Figure 4 is a view to explain the coating portion of a transformed cancer cell collecting device and a cancer cell transformation observation system using the same, and FIG. FIG. 5 is a diagram illustrating a device and a primary unit of a system for observing transformation of cancer cells using the device, and FIG. 5 is a device for collecting transformed cancer cells including a simulated vascular unit according to an embodiment of the present invention and the transformation of cancer cells using the device. FIG. 6 is a diagram for explaining the induction unit of the conversion observation system, and FIG. 6 describes a transformed cancer cell collection device including a simulated vascular unit and an extraction device of the cancer cell transformation observation system using the same according to an embodiment of the present invention. It is a drawing shown to do.

Here, as shown in FIG. 1 , the transformed cancer cell collecting device including the replicative vascular unit and the system for observing the transformation of cancer cells using the same according to an embodiment of the present invention include the replicative vascular unit 100 and the primary unit 200 , It may be composed of a receiving unit 300, an extraction device 400, and a circulation device 500, and cancer cells (C) may be accommodated in the primary unit 200.

At this time, the replicative vascular unit 100 moves through the inlet I through which the cancer cells C move inside the primary unit 200 and the replicative vascular unit 100, as shown in FIG. 2 . It may be formed on a part of the path of the outlet (O) to be.

In addition, the simulated vascular unit 100 is disposed along the path so that a plurality of them are spaced apart from each other on the movement path of the cancer cells (C) to form a gap 122 spaced apart so that the cancer cells (C) flow out. 120) and a plurality of the ring parts 120 are positioned therein, formed of a plurality of membranes, secreting an inducer so that the cancer cells (C) flow out of the spaced gap 122, and the medium and a connecting portion 160 connecting the encapsulated portion 140 and the ring portion 120, which serve as a path for the cancer cells (C) to move.

Here, a plurality of ring parts 120 may be arranged and spaced apart from each other from the inlet port I toward the outlet port O, and the plurality of ring parts 120 may be spaced apart from each other by a predetermined distance. there is.

In addition, the ring parts 120 may be spaced apart from each other to form the spaced gap 122 so that the cancer cells C moving from the inlet port I to the outlet port O flow out.

In addition, the ring part 120 is in contact with the inside of the film part 140 to prevent the film part 140 formed of a plurality of films from extending downward due to gravity to form the film part 140. can support

On the other hand, the above-described film portion 140 is formed of a plurality of films, may have a plurality of pores formed so that the cancer cells (C) can move to the outside, and as shown in FIG. 3, the cover member ( 142), a secretion member 144, and a moisture holding member 146.

Here, the cover member 142 is provided to surround the ring part 120 and the connection part 160, and may be formed along an outer circumference of the ring part 120.

In addition, as described above, a plurality of pores may be formed so that the cancer cells (C) can migrate to the outside.

On the other hand, the secretion member 144 is an inducer that induces the outflow of the cancer cells (C) so that the cancer cells (C) can flow out of the spaced gap 122 through the film portion 140 to the outside. can secrete

In addition, the secretion member 144 may be formed along the outer circumference of the cover member 142, and is formed of a vascular endothelial cell layer so that the cancer cells (C) can pass through the blood vessel wall and observe the transformation. There may be.

The cover member 142 and the secretion member 144 described above may be formed long from the inlet (I) toward the outlet (O).

On the other hand, the moisture holding member 146 is the secretion member 144 to maintain the moisture of the secretion member 144 to prevent the movement of the cancer cells (C) from being restricted due to evaporation of the moisture of the secretion member 144. It may be formed along the outer circumference of (144).

At this time, the moisture retaining member 146 may be provided only between the above-described spaced gaps 122 and formed along the circumference of the secretion member 144, which is the spaced space through which the cancer cells (C) flow out. It is possible to keep the moisture of the secretion member 144 in the gap 122 so that the movement of the cancer cells (C) is not restricted.

In addition, the water holding member 146 may have a plurality of pores formed therein so that the cancer cells C can move, and may be formed of a hydrogel layer to provide an environment similar to an extracellular matrix existing between blood vessels. .

That is, the water holding member 146 maintains the moisture of the secretion member 144 so that the movement of the cancer cells C in the spaced gap 122 is not restricted, and the spaced gap 122 An environment similar to the extracellular matrix is created to provide an environment similar to that of the human body for the cancer cells (C) flowing out through, and a plurality of pores are formed so that the cancer cells (C) pass through the spaced gap 122. can be allowed to leak.

Meanwhile, the connecting portion 160 may be connected to each other by extending toward the ring portion 120 adjacent to a portion of the circumference of the ring portion 120 .

In addition, the connecting portion 160 connects the adjacent ring portions 120 to maintain a distance between the plurality of ring portions 120, and is formed long from the inlet port I toward the outlet port O to form a plurality of The ring part 120 may be fixed so as to be positioned on the path.

At this time, a plurality of connection parts 160 may be formed along the circumference of the ring part 120, and face each other in order to improve the area of the gap 122 through which the cancer cells C flow out. It may be desirable to have a pair for viewing.

Meanwhile, as shown in FIG. 4 , the primary unit 200 in which the cancer cells C are accommodated has the inlet I and the outlet so that the cancer cells C can move to the simulated vascular unit 100 . (O) in communication with the circulation portion 220 through which the medium is circulated, an outer tube 242 communicating with the circulation unit 220 and an inner tube 244 formed to be spaced apart from the outer tube 242. 240 and an inducer 260 formed on one surface of the inner tube 244 to secrete an inducer so that the cancer cells C can move toward the simulated vascular unit 100.

Here, the circulation unit 220 may be in communication with the inlet (I) and the outlet (O), and is provided with a medium pump capable of supplying the medium to a part of the path or a pump providing power to move the medium. It can be.

Meanwhile, the circular portion 240 may be divided into an outer cylinder 242 and an inner cylinder 244, and the outer cylinder 242 and the inner cylinder 244 may be spaced apart from each other.

Here, the outer cylinder 242 may be in communication with the circulation part 220 so that the medium flows in, and the circulation part 220 communicates with the upper part of the outer cylinder 242 so that the medium flows in naturally. It may be introduced into the inner cylinder 244 .

At this time, the inner cylinder 244 is formed to have a lower height than the outer cylinder 242, and an opening is formed toward the top so that the medium can flow in, and the cancer cells C are accommodated therein and flowed into the inner cylinder 244. The cancer cells (C) can be suspended inside the inner tube 244 by the medium.

In addition, the opening of the inner cylinder 244 is provided to prevent the cancer cells (C) floating inside the inner cylinder 244 from leaking out to the outer cylinder 242 through the opening. (C) may be provided with a manure member 246 to prevent the escape.

Here, the filtering member 246 does not limit the movement of the medium toward the inner tube 244, but only limits the escape of the cancer cells (C) from the inner tube 244, so that the cancer cells (C) It is possible to create an environment that can move toward the hairline vascular unit 100.

On the other hand, the guide part 260 may be formed of a plurality of films as shown in FIG. 5, the first upper skin member 262 coupled to one surface of the inner tube 244, the first upper skin member 262 ) and a third upper skin member 266 provided between the first upper skin member 262 and the second upper skin member 264.

Here, the first upper skin member 262 may have a plurality of pores formed so that the cancer cells C can move toward the simulated vascular unit 100, and may form one surface of the inner tube 244. can

In addition, the second upper skin member 264 may have a plurality of pores formed similarly to the first upper skin member 262 described above, and may be provided so that the circumference comes into contact with the first upper skin member 262 .

At this time, the third epidermal skin member 266 allows the cancer cells C to move toward the simulated vascular unit 100 between the first epidermal skin member 262 and the second epidermal skin member 264. It may be composed of an imitation coating layer (M1) secreting an inducer, and a hydrogel layer (M2) preventing the imitation coating layer (M1) from being damaged by the second upper skin member (264).

Here, the simulated capsular layer (M1) may be composed of vascular endothelial cells, and the cancer cells (C) form the replicative vascular unit (100) so that the cancer cells (C) can mimic the departure from the original origin. When the cancer cells (C) floating in the inner tube 144 are moved to an adjacent position, they can be induced to move toward the simulated vascular unit 100 by the inducer.

In addition, the hydrogel layer (M2) is composed of the imitation film layer (M1) and the first upper skin member (262) and the second upper skin member (264) to prevent damage to the imitation film layer (M1). It may be provided between two upper skin members 264, and a plurality of pores may be formed so that the cancer cells (C) may move toward the simulated vascular unit 100. An environment similar to the extracellular matrix provided between blood vessels may be created.

That is, the hydrogel layer (M2) forms a plurality of pores through which the cancer cells (C) can move while preventing damage to the simulated coating layer (M1), and makes the movement of the cancer cells (C) more similar to that of the human body. It is possible to create an environment similar to the extracellular matrix in order to create

Meanwhile, the receiving unit 300 is configured to accommodate the cancer cells C when the cancer cells C flow out through the spaced gap 122 formed in the simulated vascular unit 100. The replicative vascular unit 100 may be located inside, and the circulation part 220 may be formed to pass through so that the primary unit 200 may communicate with the inlet (I) and the outlet (O). .

In addition, an inducer may be accommodated therein to promote the movement of the cancer cells (C) flowing out into the receiving unit 300 through the simulated vascular unit 100 .

Meanwhile, as shown in FIG. 6 , the extraction device 400 can extract the cancer cells (C) flowing out from the simulated vascular unit 100 while being moved by the inducer accommodated in the receiving unit 300 . It can be divided into a migration region 420 through which the inducer passes and a sedimentation region 440 where the cancer cells (C) are precipitated.

Here, the movement region 420 may be in communication with the accommodation unit 300 through the circulation device 500, and the cancer cells formed in the upper region of the extraction device 400 and moving together with the inducer ( C) may be a region in which the flow rate is slowed down by the flow of the inducer.

This is because the movement area 420 has a wider area than the circulator 500, so the flow rate can be slowed down, and as the flow rate of the inducer slows down, the cancer cells (C) are precipitated into the sedimentation area 440. can

On the other hand, in the sedimentation area 440, the cancer cells C moved through the circulator 500 are relatively heavier than the inducing material due to the inducing material slowing down the flow rate in the moving area 420. ) is precipitated toward the precipitation region 440, and the cancer cells (C) can be extracted.

In addition, the settling area 440 may have a stepped portion communicating with the moving area 420, and through this, the moving area 420 and the settling area 440 may be distinguished.

On the other hand, as described above, the circulation device 500 may be in communication with the extraction device 400, and may be in communication with the upper portion of the extraction device 400 to communicate with the moving area 420. there is.

In addition, the circulation device 500 may be provided with a pump part on a part of the path to provide power to the inducer.

Based on the configuration described above, the overall situation of the transformed cancer cell collection device including the replicative vascular unit and the cancer cell transformation observation system using the same according to an embodiment of the present invention will be described with reference to FIGS. 7 to 10. can

First, as shown in FIG. 7 , the cancer cells (C) accommodated in the inner tube 244 are suspended inside the inner tube 244 by the medium flowing into the inner tube 244 as described above, and the Cancer cells (C) may be moved toward the simulated blood vessel unit 100 by the inducer of the simulated coating layer (M1) at a position adjacent to the induction unit 260 .

Here, the cancer cells (C) can be moved into the receiving unit 300 through the spaced gap 122 of the simulated vascular unit 100 as described above, and the inlet (I) and the outlet ( O) may be passing through the receiving unit 300 to communicate with the primary unit 200.

At this time, when some of the cancer cells (C) flow out through the spaced gap 122, they may be moved to the extraction device 400 together with the inducer by the circulation device 500.

Here, on the lower bottom surface of the accommodation unit 300, an imitation film layer M1 having the same structure as the imitation film layer M1 is provided on the bottom in order to further promote the migration of the cancer cells C into the accommodation unit 300. It may be provided on the surface.

On the other hand, the flow rate of the inducer is slowed down by the moving region 420 inside the extraction unit 400, and accordingly, the relatively heavy cancer cells (C) are precipitated into the sedimentation region 440 and the cancer cells (C) is what can be extracted.

At this time, the cancer cells (C) flowing out of the simulated blood vessel unit 100 can flow out through the spaced gap 122 as shown in FIG. It can pass through the coating part 120.

As described above, the movement can be promoted by an inducer secreted by the secretion member 144 or an inducer accommodated in the accommodation unit 300, and the cover member 142, the secretion member ( 144), it can be moved into the accommodation unit 300 through pores formed in the water holding member 146.

In addition, the moisture retaining member 146 surrounds the secretion member 144 of the spaced gap 122 to maintain moisture in the secretion member 144 so that the movement of the cancer cells C is not restricted. may be formed according to

On the other hand, in order to prevent the replicative blood vessel unit 100 from being formed long and drooping downward due to gravity, the connecting portion 160 facing each other is connected to the spaced gap 122 to prevent the replicative blood vessel unit 100 from drooping downward. A reinforcing part 180 reinforcing the rigidity of may be formed.

Here, the reinforcing part 180 may be formed to cross the spaced gap 122 so as to connect the connecting parts 160 facing each other, and the ring part prevents the spaced gap 122 from being closed. It may be formed to have a radius of curvature along the circumferential curve of (120).

In addition, as shown in FIG. 10, they may be sequentially arranged from the inlet (I) toward the outlet (O) so as to be offset from each other, may be arranged in the same direction, or may be arranged to cross each other. .

However, the spaced gap 122 may be formed to open so that the gap 122 is closed and the outflow of the cancer cells C is not restricted.

Based on the configuration described above, according to an embodiment of the present invention, the transformed cancer cell collection device including the replicative blood vessel unit and the cancer cell transformation observation system using the same are the cancer cells (C) departing from the initial place of origin and following the blood vessels. It is possible to simulate migration through the blood vessel wall and through the transition site, and through this, multiple samples can be taken to observe transformation while leaving the blood vessel wall or the initial place of origin. Accordingly, when injecting a drug, a specific A drug may be injected targeting the cancer cells (C) and the progress thereof may be observed.

Accordingly, according to an embodiment of the present invention, the transformed cancer cell collection device including the simulated vascular unit and the cancer cell transformation observation system using the same collects various samples for the transformation of cancer cells (C) passing through vascular endothelial cells. This may have an observable effect.

On the other hand, according to another embodiment of the present invention, a transformed cancer cell collection device including a replicative vascular unit and a cancer cell transformation observation system using the same can easily collect and transform cancer cells (C) passing through vascular endothelial cells. A sensor may be provided that interworks with the manager's terminal so as to be adjustable.

For example, the cancer cells (C) located in the circular portion 240 may be sensed to determine the cycle and amount of movement of the cancer cells (C) toward the simulated vascular unit 100 by the flow of the medium. A first sensor is provided between the simulated vascular unit 100 and the induction unit 260 to measure the amount of movement of the cancer cells (C) per hour, the movement period, and the amount of movement of the cancer cells (C) over time in the administrator's terminal. can be checked through

Alternatively, the cancer cells (C) moved from the simulated vascular unit 100 to the receiving unit 300 are sensed to confirm that the cancer cells C are moved to the extraction device 400 according to the flow of the fluid. A second sensor that does this can be disposed on the path of the circulator 500.

In addition, a power unit for providing power to circulate the medium to control the transformed cancer cell collection device including the replicative vascular unit of the present invention and the cancer cell transformation observation system using the terminal using the manager's terminal; and It is interlocked to control the intensity and flow rate of the medium flow through the manager's terminal, and the flow rate and flow of the inducer are controlled in conjunction with the pump unit so that the cancer cells (C) are removed from the inside of the extraction device 500. It can be controlled to effectively precipitate into the precipitation region 440.

In addition, a management server for managing data measured through the first sensor and the second sensor is provided, and the management server receives the data measured through the first sensor and the second sensor to receive time, the power unit and It is possible to analyze the amount of movement of the cancer cells (C) according to the strength of the pump unit and the amount of cancer cells (C) accommodated in the Singa primary unit 200, and interlock with the power unit and the pump unit to produce a medium or inducer It may be provided so as to be able to control the supply unit to be supplied.

That is, according to another embodiment of the present invention, the apparatus for collecting transformed cancer cells including an imitation blood vessel unit and the system for observing transformation of cancer cells using the same allows the manager to detect the flow of medium or inducer, cancer cells (C) through the terminal, It may be determined and managed by measuring the amount of movement of .

As described above, the preferred embodiments according to the present invention have been reviewed, and the fact that the present invention can be embodied in other specific forms without departing from the spirit or scope in addition to the above-described embodiments is a matter of ordinary knowledge in the art. It is self-evident to them. Therefore, the embodiments described above are to be regarded as illustrative rather than restrictive, and thus the present invention is not limited to the above description, but may vary within the scope of the appended claims and their equivalents.

100: imitation blood vessel unit
120: ring part 140: coating part 160: connection part
200: primary unit
220: circulation part 240: epicenter part 260: induction part
300: accommodation unit
400: extraction device
500: circulator

Claims (26)

An imitation blood vessel unit formed in a part of a path in which an inlet and an outlet are formed, and a medium and cancer cells are moved from the inlet to the outlet in order to observe the transformation of cancer cells passing through the blood vessel wall,
a plurality of rings arranged along the path so as to be spaced apart from each other to form spaced gaps through which the cancer cells flow out;
a film portion having a plurality of ring parts positioned therein, formed of a plurality of films, secreting an inducer so that the cancer cells flow out through the spaced gap, and serving as a path through which the medium and the cancer cells move; and
A portion of the circumference of the ring portion extends through the adjacent ring portion and includes a connection portion connecting each other,
The ring part,
Characterized in that it is located inside the film part to support the film part and prevent the film part from sagging due to gravity.
imitation blood unit.
delete According to claim 1,
The connection part,
Characterized in that the ring portion is formed long from the inlet toward the discharge port so that the ring portion is fixed on the path and connects a plurality of the ring portions inside the film portion,
imitation blood unit.
According to claim 3,
The connection part,
Characterized in that connecting the adjacent ring parts in the spaced gap and maintaining a distance between the plurality of the ring parts,
imitation blood unit.
According to claim 1,
The connection part,
Characterized in that a plurality is formed along the circumference of the ring portion,
imitation blood unit.
According to claim 3,
The coating part,
a cover member provided to surround the ring portion and the connection portion;
Characterized in that it comprises a secretion member formed along the circumference of the cover member and secreting an inducer to move the cancer cells to the outside.
imitation blood unit.
According to claim 6,
The secretion member,
Characterized in that it is composed of vascular endothelial cells,
imitation blood unit.
According to claim 6,
The coating part,
Characterized in that it further comprises a moisture holding member provided along the circumference of the secretion member so that the moisture of the secretion member is maintained,
imitation blood unit.
According to claim 8,
The moisture retaining member,
Characterized in that it is formed along the circumference of the secretion member between the ring portions to surround the secretion member.
imitation blood unit.
According to claim 1,
The ring part,
Characterized in that it contacts the inner circumference of the film portion and supports the film portion,
imitation blood unit.
An inlet and an outlet are formed, and in order to observe the transformation of cancer cells passing through the blood vessel wall, the simulated blood vessel unit is formed on a part of the path along which the medium and cancer cells are moved from the inlet to the outlet, so that a plurality of units are spaced apart on the path. A ring part disposed to form a gap to allow the cancer cells to flow out, a plurality of the ring parts are located inside, and formed of a plurality of membranes to secrete an inducer so that the cancer cells flow out of the gap, and the medium and a capsular portion in which a path through which the cancer cells move is formed and a connection portion extending through the ring portion adjacent to a portion of the circumference of the ring portion to connect each other;
a primary unit having a space formed therein to position the cancer cells and communicating with the inlet and the outlet to circulate the medium; and
The capillary blood vessel unit is disposed penetrating the inside and includes a receiving unit for collecting the cancer cells moving out of the capillary blood vessel unit,
The ring part,
Characterized in that it is located inside the film part to support the film part and prevent the film part from sagging due to gravity.
Transformed cancer cell collection device comprising an imitation blood vessel unit.
According to claim 11,
The receiving unit,
Characterized in that an inducer is accommodated to promote the migration of the cancer cells migrating through the simulated vascular unit to the outside.
Transformed cancer cell collection device comprising an imitation blood vessel unit.
According to claim 11,
The primary unit,
a circulation unit connected to the inlet and the outlet to circulate the medium;
an oval portion divided into an outer tube communicating with the circulation unit and an inner tube spaced apart from the outer tube and having cancer cells located therein and having an opening toward the top;
characterized in that it comprises an induction unit formed of a plurality of membranes on one side of the inner tube and secreting an inducer so that the cancer cells floating in the inner tube are moved toward the simulated vascular unit by the circulation of the medium.
Transformed cancer cell collection device comprising an imitation blood vessel unit.
According to claim 13,
The inner pain,
Characterized in that it comprises a filtering member provided in the opening to prevent the cancer cells from escaping to the outside.
Transformed cancer cell collection device comprising an imitation blood vessel unit.
According to claim 13,
The induction unit,
a first upper skin member formed on one surface of the oval portion;
a second upper skin member provided to be in contact with the first upper skin member;
Characterized in that it comprises a third upper skin member provided between the first upper skin member and the second upper skin member to secrete an inducer,
Transformed cancer cell collection device comprising an imitation blood vessel unit.
According to claim 15,
The third upper skin member,
a pseudocapsular layer provided with vascular endothelial cells and attached to the first upper skin material so that the cancer cells move toward the replicative vascular unit; and
Characterized in that it comprises a hydrogel layer provided between the imitation film layer and the second upper skin material to prevent damage to the dummy skin layer by the first upper skin member and the second upper skin member,
Transformed cancer cell collection device comprising an imitation blood vessel unit.
delete According to claim 11,
The connection part,
Characterized in that the ring portion is formed long from the inlet toward the discharge port so that the ring portion is fixed on the path and connects a plurality of the ring portions inside the film portion,
Transformed cancer cell collection device comprising an imitation blood vessel unit.
A system for observing transformation of cancer cells using a transformed cancer cell collection device comprising at least one of the simulated vascular units of claims 11 to 16 and 18,
An inlet and an outlet are formed, and in order to observe the transformation of cancer cells passing through the blood vessel wall, the simulated blood vessel unit is formed on a part of the path along which the medium and cancer cells are moved from the inlet to the outlet, so that a plurality of units are spaced apart on the path. A ring part disposed to form a gap to allow the cancer cells to flow out, a plurality of the ring parts are located inside, and formed of a plurality of membranes to secrete an inducer so that the cancer cells flow out of the gap, and the medium and a replicative vascular unit including an encapsulated portion in which a pathway through which the cancer cells move is formed, a primary unit in which a space is formed therein to position the cancer cells, and the medium is circulated through communication with the inlet and the outlet, and the replicative vascular unit. a transformed cancer cell collecting device including a replicative vascular unit disposed penetrating the inside and including a receiving unit for collecting the cancer cells moved out of the replicative vascular unit;
a circulation device communicating with the accommodation unit so that the induction material circulates through the accommodation unit; and
It is formed on the path of the circulation device and includes an extraction device in which the cancer cells moved to the receiving unit are moved and collected according to the flow of the inducer.
Cancer cell transformation observation system.
According to claim 19,
The extraction device,
Characterized in that the inner space is formed stepwise so that a space is formed at the bottom so that the cancer cells settle in the inner space.
Cancer cell transformation observation system.
According to claim 19,
The circulator,
Characterized in that it comprises a pump unit for providing power to move the inducing material on the moving path of the inducing material,
Cancer cell transformation observation system.
According to claim 19,
The primary unit,
a circulation unit connected to the inlet and the outlet to circulate the medium;
an oval portion divided into an outer tube communicating with the circulation unit and an inner tube spaced apart from the outer tube and having cancer cells located therein and having an opening toward the top;
characterized in that it comprises an induction unit formed of a plurality of membranes on one side of the inner tube and secreting an inducer so that the cancer cells floating in the inner tube are moved toward the simulated vascular unit by the circulation of the medium.
Cancer cell transformation observation system.
The method of claim 22,
The induction unit,
a first upper skin member formed on one surface of the oval portion;
a second upper skin member provided to be in contact with the first upper skin member;
Characterized in that it comprises a third upper skin member provided between the first upper skin member and the second upper skin member to secrete an inducer,
Cancer cell transformation observation system.
According to claim 23,
The third upper skin member,
a pseudocapsular layer provided with vascular endothelial cells and attached to the first upper skin material so that the cancer cells move toward the replicative vascular unit; and
Characterized in that it comprises a hydrogel layer provided between the imitation film layer and the second upper skin material to prevent damage to the dummy skin layer by the first upper skin member and the second upper skin member,
Cancer cell transformation observation system.
According to claim 19,
The simulated blood vessel unit,
Characterized in that a portion of the circumference of the ring portion further comprises a connection portion extending through the adjacent ring portion to connect each other,
Cancer cell transformation observation system.
According to claim 25,
The connection part,
Characterized in that the ring portion is formed long from the inlet toward the discharge port so that the ring portion is fixed on the path and connects a plurality of the ring portions inside the film portion,
Cancer cell transformation observation system.

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