KR101694422B1 - Filtration vessel for adipose stem cells - Google Patents

Abstract

The present invention relates to an adipose stem cell filtering container. Specifically, the present invention relates to an adipose stem cell filtering container having first and second filtering sieves formed at the top and the bottom thereof to have meshes of different sizes, thereby sequentially filtering adipose stem cells (SVF) separated from fat extracted from a human body through two stages. Thus, a filtering rate and an extracting amount of adipose stem cells (SVF) are improved. The first and the second filtering sieves having meshes of different sizes are respectively formed in a top container and a bottom container coupled with each other to be detached, or are formed therebetween. Adipose stem cells (SVF) fed to the top container are sequentially filtered through the first filtering sieve and the second filtering sieve, and are discharged to the outside through the bottom container. Accordingly, a filtering rate and an extracting amount of adipose stem cells can be improved.

Description

{FILTRATION VESSEL FOR ADIPOSE STEM CELLS}

The present invention relates to an adipose stem cell filter vessel, and more particularly, to an adipose stem cell filter (SVF) separating fat from a human body, comprising a first and a second filter net having meshes of different sizes inside the container, The present invention relates to an adipose stem cell filter vessel capable of improving the filtration rate and the extraction amount of SVF by sequential filtration in two stages.

In general, a stem cell refers to a cell capable of differentiating into all kinds of cells constituting the body, such as nerve, blood, and cartilage, if necessary, without being differentiated into specific cells. There are two major ways to obtain such stem cells. First, there is a method of obtaining stem cells (embryonic stem cells) from embryos generated from embryos. Second, there is a method obtained from stem cells (adult stem cells) which are retained in each part of the adult human body. Although there are functional differences, embryonic stem cells and adult stem cells all have differentiation characteristics into different types of cells.

Embryonic stem cells have excellent ability to differentiate, and although Telomer has long advantages, it has an ethical problem and it is difficult to acquire a large amount of cells. On the other hand, adult stem cells can obtain a large number of cells, but they have a disadvantage in that the risk of infection or the ability of differentiation is relatively low when they are transplanted into other persons. Despite these shortcomings, adult stem cells are characterized by their high safety for medical applications. In addition, there is a site-specific differentiation that differentiates itself according to the characteristics of the surrounding tissues. In addition, since it does not cause cancer even if it is injected under undifferentiated state, There is a self-renewal ability to recreate and store the necessary undifferentiated stem cells.

Although adipose tissue plays an important role in normal growth and physiology in vivo, its importance has been overlooked so far. The most common form of fat is the white adipose tissue located in the subperitoneal (visceral fat) or in the reproductive organs (gonadal fat), located under the skin (subcutaneous fat). A somewhat less common form in adults is brown adipose tissue and plays an important role in generating heat in the neonatal period (Gimble, New Bio1.2 (4): 304-12, (1990)). However, reproductive and maturation processes are closely linked to the storage of adipose tissue. Adolescent puberty in women and men is closely related to the production and secretion of adipose tissue-derived hormones, and also plays an important role in glucose metabolism and energy balance.

As a result, many studies have been conducted on the use of adipose tissue, and it has recently been confirmed that adult stem cells are present in adipose tissue (Zuk PA, et al., Molecular Biology of Cell, Vol 13: 4279-4295 2002): Rodriguez AM, et al., Biochimie, 87: 125-128 (2005)) Several studies have begun on the use of adipose-derived stem cells. In addition, based on the advances in biochemistry and molecular biology, we have found a small amount of signaling substances (growth factors) that exist in the living body, and the theory of biodegradation based on them is being redefined (Stanley Cohen, Nobel Lecture 1986, Dec, 8). In addition, this signaling substance (growth factor) decreases in vivo with increasing age, and it has been shown that this decrease in growth factor is closely related to our aging (Sporn M and Roberts A, Handbook of Experimental Pharmacology , Vol. 1, Vol. 95/1, 1990, Springer-Verlag, DE, Berlin., Pp. 667-698).

However, although studies on the structure of the signal substance, that is, the growth factor, have been conducted, most of the growth factors have a structure of protein, and their structures are three-dimensionally complex, , And the cost for such synthesis is also very expensive. Recently, studies have been conducted on a method for obtaining an active human growth factor at low cost while maintaining activity in the human body, and it has been known that adipose derived adult stem cells secrete growth factors (Rehman, J. et al. et al., Circulation, 109: 1292-1298 (2004)). Recently, studies on obtaining stem cells from adipose tissue have been carried out. Representative methods include the extraction of fat from adipose tissue, enzyme treatment, lipid stem cell washing, separation and filtration, A method of extracting cells is widely used.

As described above, the method for extracting the adipose stem cells comprises the steps of extracting fat from adipose tissue, enzyme treatment using collagenase and the like, separation and washing of adipose stem cells using centrifugation, and culturing of adulthood adipose stem cells And the like. Separation and washing of adipose stem cells using centrifugation is a multiple-step process. Extraction of adipose stem cells from fat extracted with Luracle syringe or centrifugation to wash extracted adipose stem cells with a washing solution .

However, the filtration vessel used in the filtration step during the extraction process of the adipose stem cells has a single filter network (mesh network) installed therein to filter the adipose stem cells, and thus the adhered adipose stem cells are filtered through the filter network Not only the filtration rate of the adipose stem cells is lowered, but also the volume of the adipose stem cells is reduced because the adipose stem cells can not pass through the filter network when the adipose stem cells are separated.

KR 10-0660117 B1, Dec. 14, 2006. KR 10-1019085 B1, 2011. 02. 24.

DISCLOSURE OF THE INVENTION Accordingly, the present invention has been made to solve the problems of the prior art, and it is an object of the present invention to provide a method for producing a stem cell (SVF) separated from fat extracted from a human body, To thereby improve the filtration rate and the extraction amount of SVF (stem cell).

According to an aspect of the present invention, A lower container coupled to a lower portion of the upper container; And sequentially discharging the adipose stem cells injected into the upper part of the upper container, the lower container, or one of the upper and lower containers in the vertical direction sequentially, and then discharging the adipose stem cells into the lower container Wherein the mesh of the first filter network located above the first and second filter networks is larger than the mesh of the second filter network.

Preferably, the lower container includes a first fused portion protruding upward and thermally fused to a lower periphery of the second filter net, wherein the upper container is protruded inwardly inwardly in the lower portion so that the upper periphery of the first filter net is opened A pressing portion formed to protrude downward from the lower portion of the second fused portion and to be in close contact with the upper periphery of the second filtering net, and a second fused portion extending downward from the lower portion of the upper container, Wherein when the upper container is coupled to the lower container, the pressing portion pushes the upper periphery of the second filter net downward to closely contact the second filter net with the first fused portion, .

Preferably, the upper container has an injection hole formed at an upper portion thereof, and the lower container has a discharge hole formed at a lower portion thereof. A syringe is coupled to the injection hole and the discharge hole, And the fat stem cells filtered through the first and second filter nets are discharged to the outside.

Preferably, the apparatus further comprises first and second lids for sealing the injection hole and the discharge hole.

As described above, according to the present invention, it is possible to provide an upper container and a lower container, which are detachably coupled to each other, and which are provided with first and second filter nets having different mesh sizes, The stem cells injected into the upper container may be firstly filtered through the first filter network and then filtered through the second filter network to improve the filtration rate and the extraction volume of the adipose stem cells by providing a stem cell filter container .

In addition, according to the present invention, a first fused portion to which the second filter net is fused is formed on the upper portion of the lower container, a second fused portion to which the first filter net is fused is formed inside the lower portion of the upper container, The first and second filter nets are easily installed on the inner side of the lower portion and the second filter net is fused on the upper portion of the second fused portion in the process of coupling the upper container to the lower container, So that the second filter net can be stably supported.

1 is a perspective view for explaining an adipose stem cell filter container according to an embodiment of the present invention;
FIG. 2 is an exploded perspective view of the adipose stem cell filter container shown in FIG. 1; FIG.
FIG. 3 is a cross-sectional view of the adipose stem cell filter container shown in FIG. 1 cut vertically. FIG.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to accomplish them, will become apparent by reference to the embodiments described in detail below with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described below, but may be embodied in various other forms.

The present embodiments are provided so that the disclosure of the present invention is thoroughly disclosed and that those skilled in the art will fully understand the scope of the present invention. And the present invention is only defined by the scope of the claims. Thus, in some embodiments, well known components, well known operations, and well-known techniques are not specifically described to avoid an undesirable interpretation of the present invention.

In addition, like reference numerals refer to like elements throughout the specification. Moreover, terms used herein (to be referred to) are intended to illustrate the embodiments and are not intended to limit the invention. In the present specification, the singular form includes plural forms unless otherwise specified in the specification. Also, components and acts referred to as " comprising (or comprising) " do not exclude the presence or addition of one or more other components and operations.

Unless defined otherwise, all terms (including technical and scientific terms) used herein may be used in a sense commonly understood by one of ordinary skill in the art to which this invention belongs. Also, commonly used predefined terms are not ideally or excessively interpreted unless they are defined.

Hereinafter, the technical features of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view illustrating an adipose stem cell filter container according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of the adipose stem cell filter container shown in FIG. 1, and FIG. 3 is a cross- Sectional view of an adipose stem cell filter vessel cut vertically.

1 to 3, an adipose stem cell filtration vessel 10 according to an embodiment of the present invention includes an upper container 11, a lower container 12, a first filter network 13 and a second filter network 14, .

2 and 3, the upper part of the upper container 11 is coupled to the lower part of the lower part 12 at the lower part. Preferably, the upper container 11 and the lower container 12 are detachably coupled. For example, the upper container 11 and the lower container 12 may be detachably coupled to each other in an interference fit manner.

2, the upper vessel 11 is provided with an injection hole 11a at an upper portion thereof. Thus, the adipose stem cells are injected through the injection hole 11a using a syringe. The injection hole 11a may be sealed by the first lid 15 coupled to the upper portion of the upper container 11. [

The lower container 12 has a discharge hole 12a for discharging the adipose stem cells sequentially filtered by the first and second filter nets 13 and 14 to the outside through a syringe. For example, after the syringe is connected to the discharge hole 12a, the syringe is filtered through the first and second filtering nets 13 and 14 using a plunger, and then the adipose stem cells collected in the lower vessel 12 are sucked and discharged do. 1 and 3, the discharge hole 12a of the lower container 12 is sealed by the second lid 16 coupled to the lower portion of the lower container 12, like the upper container 11 .

The first and second filtering nets 13 and 14 are sequentially arranged in the vertical direction in any one of the upper container 11 and the lower container 12 or between the upper container 11 and the lower container 12, The stem cells injected into the upper part of the stem 11 are sequentially filtered and discharged to the lower vessel 12.

At this time, the mesh of the first filtering network 13, which is relatively located at the upper portion and is primarily filtered by the adipose stem cells, is formed larger than the mesh of the second filtering mesh 14. For example, the first filter network 13 may be formed of 200 mesh (200 nozzles), and the second filter network 14 may be formed of 150 meshes (150 nozzles).

As described above, the adipose stem cell filtration vessel 10 according to the embodiment of the present invention is provided with an upper and lower vessels 11 and 12, which are detachably coupled to each other, The first and second filtering nets 13 and 14 having a mesh size are formed so that the adipose stem cells injected into the upper container 11 are firstly filtered through the first filtering net 13 and then filtered through the second filtering net 14 The filtration rate and the extraction volume of adipose stem cells can be improved.

Furthermore, by forming the first filter network 13, in which the adipose stem cells are firstly filtered, into a mesh larger than the second filter network 14, a lump having a large particle size among the adipose stem cells is firstly filtered through the first filter network 13 At the same time, by crushing them into small particles and injecting them into the second filter net 14, the filtration rate of the second filter net 14 is improved to improve the filtration rate of the adipose stem cells and minimize the mass of adipose stem cells, .

The first filter net 13 is fused to the inside of the lower portion of the upper container 11 and the second filter net 14 is fused between the upper and lower containers 11 and 12, Fused.

For this purpose, the lower container 12 is formed with a first fused portion 12b, which is raised upward at an upper portion and is thermally fused to the lower periphery of the second filter net 14, as shown in Fig. The upper container 11 includes a second fused portion 11b protruding from the lower inner side and thermally fused to the upper periphery of the first freeness 13 and a second fused portion 11b A pressing portion 11c that presses the upper portion of the second filter net 15 against the lower side of the upper filter 11 by pressing the upper portion of the second filtering net 15, (11d).

Since the upper container 11 has the second fused portion 11b formed inside the lower portion thereof, it is easy to stably install the first filter net 13 inside the upper container 11, and the pressing portion 11c The upper container 11 is coupled to the lower container 12 and at the same time the upper portion of the second filter net 14 fused to the upper portion of the second fused portion 12b of the lower container 12 is pushed, It is possible to prevent the first and second filter nets 13 and 14 from being separated from each other by being brought into close contact with the fused portion 12b.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

10: Adipose stem cell filtration vessel
11: upper container
12: Lower container
13: first filter net
14: second filter net
15: First lid
16: the second lid

Claims (4)

An upper container;
A lower container coupled to a lower portion of the upper container; And
The upper and lower vessels or the upper and lower vessels, sequentially injecting the adipose stem cells injected into the upper portion of the upper vessel, 1 and a second filter network; ≪ / RTI >
The mesh of the first filter net positioned above the mesh of the second filter net is formed larger than the mesh of the second filter net,
Wherein the lower container includes a first fused portion protruded upward and thermally fused to a lower periphery of the second filter net,
The upper container includes a second fused portion protruding inwardly in the lower portion and thermally fusing the upper periphery of the first filter net, and a second fused portion protruding inwardly downwardly from the lower side of the second fused portion, And an engaging portion extending downward from a lower portion of the upper container to be inserted into the outer side of the first fused portion,
Wherein when the upper container is coupled to the lower container, the pressing portion presses the upper periphery of the second filter net downward to bring the second filter net into close contact with the first fused portion,
Lt; RTI ID = 0.0 > 1, < / RTI >
delete The method according to claim 1,
The upper container has an injection hole formed therein, and the lower container has a discharge hole formed at a lower portion thereof. A syringe is coupled to the injection hole and the discharge hole, and the adipose stem cells are injected through the injection hole and the discharge hole , And the adipose stem cells filtered through the first and second filter nets are discharged to the outside.
The method of claim 3,
Further comprising first and second lids for sealing the injection hole and the discharge hole.

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