KR101043227B1 - Method of centrifugal separation and syringe for centrifugal separation - Google Patents

Abstract

PURPOSE: A centrifugation method and syringe for centrifugation are provided to extract blood by using syringe and to pass centrifugation process immediately inside the syringe without the need do move blood to other reservoir or tube. CONSTITUTION: The centrifugation method includes the steps of: storing an processing object inside the syringe(S10); first centrifuging the processing object of inside of syringe in the state of arranging nozzle to face outside of the center of rotation(S20). Density relatively highs among the component comprising the processing object, task specific component, arranged at nozzle by the first centrifugation, is discharged through the nozzle(S30). The syringe is reversed so the nozzle face inside of the center of rotation of syringe and second centrifuges the processing object of inside of the syringe(S40). Density is relatively low among the remaining component comprising the processing object and the other specific component, arranged at the nozzle by the second centrifugation, is discharged through the nozzle(S50).

Description

Centrifugal Separation Method and Centrifugal Syringe {METHOD OF CENTRIFUGAL SEPARATION AND SYRINGE FOR CENTRIFUGAL SEPARATION}

The present invention relates to a centrifugal separation method and a centrifugal syringe, and more particularly, to a centrifugal separation method and a centrifugal syringe capable of centrifuging a processed object more quickly and simply.

In general, blood is classified into blood cells, which are solid components, and plasma, which is a liquid component. Blood cells are composed of red blood cells, white blood cells and platelets, and the plasma is mainly composed of water, including blood clotting factors, electrolytes, and the like essential for life support.

As described above, the blood is a mixture of various components, and the process of extracting specific components by separating the blood for various medical purposes is widely used. Among them, the blood centrifugation process using a centrifuge and the process using a specific composition are used. It is widely used.

Among these, the centrifugation process of blood refers to a process of performing interlayer separation using the difference in weight of each component constituting the blood by rotating the blood at a constant speed, and when the blood is centrifuged, the heaviest red blood cells are formed in the lower layer ( Outer layer), from which a layer of leukocytes, plasma and serum is formed.

On the other hand, PRP (Platelet Rich Plasma: Platelet Enriched Plasma) in the plasma is relatively located in the lower plasma, and is easily used during surgery because it is involved in blood coagulation or hemostatic action. In addition, PRP contains growth factors such as cytokines, PDCF, TGF-BETA1, and VEGP, which have been shown to have good effects on skin diseases and wound healing, according to the paper.

However, conventionally, the extraction process of extracting a specific component such as platelets from the blood is cumbersome and inconvenient.

In other words, according to the centrifugation process of blood, which is widely used, red blood cells can be centrifuged through a single centrifugation process. Can be extracted by centrifugation again. Therefore, in order to extract platelets, at least two different centrifugation spaces have to be subjected to a centrifugation process, respectively, which is inconvenient and hassle-free. have.

In addition, conventionally, the time required for the separation process of a specific blood component is long, and after collecting blood from a patient, it is difficult to perform a procedure using the specific component immediately after separating a specific component such as platelets.

Accordingly, in recent years, various studies have been made on a centrifugal separation method that enables the centrifugal separation of a treatment object such as blood more quickly and simply.

The present invention provides a centrifugal separation method and a centrifugal syringe which can quickly and simply extract specific components from an object to be treated.

In addition, the present invention provides a centrifugal separation method and a centrifugal syringe that can easily extract a specific component from the treatment object without external exposure or movement of the treatment object, and can prevent deterioration and infection due to external exposure. do.

In addition, the present invention can shorten the time required for the centrifugation process of the treatment object, and provides a centrifugation method and a centrifugal syringe that can directly use a specific component extracted from the treatment object.

In addition, the present invention provides a syringe for centrifugation that can more easily separate a specific component extracted from the object to be treated.

According to a preferred embodiment of the present invention for achieving the above object of the present invention, the centrifugal separation method using a syringe having a nozzle at one end, storing the object to be processed in the syringe, the first object to be treated in the syringe Centrifuging, discharging one specific component disposed on the nozzle side by the first centrifugation through the nozzle, reversing the syringe to separate the object to be treated inside the syringe for the second centrifugation, and second centrifugal separation. Discharging the other specific component disposed on the nozzle side through the nozzle.

For reference, the object to be treated in the present invention means a material to which centrifugation is performed, and the present invention is not limited or limited by the type and characteristic of the object to be treated. For example, blood may be used as the object to be treated, and in some cases, other samples collected from an animal or a human body may be used as the object to be treated instead of blood.

As a syringe, a conventional syringe including a barrel and a plunger may be used, and the present invention is not limited or limited by the type and characteristics of the syringe. One end of the barrel is formed with a nozzle for entering and exiting the treatment object, the nozzle may be blocked during the first and centrifugal separation. In addition, the syringe in the present invention, like a conventional syringe including a barrel and a plunger, a first member having a hole such as a nozzle at one end, and a second member provided to be linearly movable on the first member Other containers, devices, and the like, may be included, and various devices having a similar or identical operating structure to the syringe may be used as the syringe.

In the storing of the object within the barrel, the object may be directly supplied from the body and stored in the barrel. In some cases, the object may be stored in a separate storage container.

The first and second centrifugal separation may be performed using a conventional centrifuge, and the present invention is not limited or limited by the type and characteristics of the centrifuge. In addition, the first centrifugal separation speed and the second centrifugal separation speed of the object to be treated may be set differently.

The syringe may be placed inverted along various directions depending on the conditions required. In one example, the syringe can be reversed by placing the position of the nozzle in the opposite direction relative to the center of rotation of the syringe.

In the first and second centrifugation, the syringe can be placed along various directions depending on the conditions required and the processing environment. As an example, in the first centrifugation step the syringe may be arranged such that the nozzle is facing outward of the rotational center of the syringe, and in the second centrifugation step the syringe may be arranged so that the nozzle is inward of the rotation center of the syringe. have. In some cases, it is also possible to arrange the nozzle to face inward of the rotational center of the syringe in the first centrifugal step and to direct the nozzle outward to the center of rotation of the syringe in the second centrifugal step.

For reference, the rotation center of the syringe in the present invention may be understood as a rotation axis (not shown) of a rotating means such as a rotor of a conventional centrifuge to which the syringe is mounted. In addition, the state in which the nozzle of the syringe is disposed outward (or inward) of the rotational center of the syringe means that the nozzle of the syringe is disposed in a direction completely coincident with the center of rotation, and the nozzle of the syringe rotates. It can be understood to include all of the states that are disposed almost toward the center of rotation even if they are not completely coincident with the center.

If the object to be treated is blood, during the first centrifugation, one of the heaviest components of blood may be disposed on the nozzle side that is the outermost inside the barrel with respect to the center of rotation of the syringe. This particular component may comprise the heaviest red blood cells among the components of the blood.

In addition, during the second centrifugation, an interlayer separation is performed between the components by the difference in the density of the remaining components (for example, plasma and platelets) constituting the blood. The specific component may be disposed on the nozzle side that is the innermost side of the barrel relative to the center of rotation of the syringe, and this other specific component may comprise a relatively light plasma among the remaining components of the blood.

Therefore, after one specific component and the other specific component are separated and discharged from the blood through the first centrifugation and the second centrifugation, the target component remaining in the syringe may include a blood platelet.

In addition, the syringe may be provided including a separation chamber that is selectively detachably connected to the nozzle, at least some of the one specific component in the first centrifugation step may be disposed in the separation chamber, the separation after the first centrifugation The chamber can be separated from the syringe. Since one specific component may be collected through the separation chamber, one specific component that may remain on the inner surface of the barrel may be minimized, and as a result, the purity of the target component may be increased.

According to another embodiment of the present invention, a centrifugal syringe used for extracting a target component from a target material by centrifugation is accommodated in a barrel having a nozzle formed at one end thereof and linearly movable inside the barrel at the other end of the barrel. It includes a plunger, and the plunger head of the plunger is formed with an adhesion prevention portion for reducing the adhesion of the target component.

The anti-adhesion unit may be provided in various structures capable of reducing the adhesion of the target component concentrated on the surface of the plunger head. For example, the adhesion prevention portion may be configured to include an adhesion prevention protrusion protruding from the surface of the plunger head. The anti-adhesion protrusions can be changed in various ways depending on the required conditions and processing environment. For example, the anti-adhesion protrusions can be cones, polygonal pyramids (eg, square pyramids, triangular pyramids, etc.), frustums of cones and polygonal pyramids ( It may be provided in the shape of at least one of a truncated cone, a polygonal truncated cone, etc.), a cylinder, a polyhedron (pentahedron, a hexahedron, etc.) and an ellipsoid. In addition, a plurality of anti-adhesion protrusions may be arranged in a predetermined arrangement (for example, lattice nothing), and the plurality of anti-adhesion protrusions may be provided to have the same size as each other or may have different sizes. Alternatively, the anti-adhesion protrusions may be provided in a band shape that protrudes continuously along a specific direction.

On the other hand, as another example of the adhesion prevention portion, the adhesion prevention portion may include an adhesion prevention net provided apart from the surface of the plunger head. The anti-adhesion net may be formed of a net material having a predetermined mesh, and a spacer may be interposed between the anti-adhesion net and the surface of the plunger head.

According to the centrifugal separation method and the centrifugal syringe according to the present invention, blood can be extracted using a syringe and then subjected to a centrifugation process in a syringe without having to be transferred to another storage container or tube, and a specific component in the syringe. For example, platelet-concentrated plasma (PRP) may be directly separated and injected directly into a syringe without a moving process. Through this process, certain components can be extracted more hygienically, quickly and simply from the object to be treated.

In particular, according to the present invention, in order to extract a characteristic component from a treatment object such as blood, the first object is used by using a single syringe without exposing the treatment object to the outside or moving to another centrifuge space by using a separate moving means. And since the second centrifugation can be performed, it is possible to extract a specific component contained in the object more quickly and simply, and can be injected directly.

In addition, according to the present invention, since a specific component can be extracted from the object without external exposure or movement of the object, deterioration and infection due to external exposure can be prevented in advance.

In addition, according to the present invention can shorten the time required for the centrifugation process, it is possible to immediately use the specific components extracted from the object to be treated. For example, after collecting blood from a patient, specific components such as platelets can be isolated, and then the patient can perform the procedure using the specific components, and more effectively cope with emergencies.

In addition, according to the present invention, since the blood can be collected from the patient using one syringe and the centrifugation process can be performed, infection due to the blood migration process can be prevented, and the blood centrifugation process can be performed. It can be simplified more.

In addition, according to the present invention, by allowing at least some of one specific component to be collected through the separation chamber in the first centrifugal separation step, it is possible to minimize the deterioration of purity of the target component as one specific component remains in the barrel.

Further, according to the present invention, by providing a plunger head adhesion prevention portion, it is possible to reduce the adhesion of the target component extracted by centrifugation to the plunger head, thereby more easily separating the target component extracted by centrifugation from the plunger head. Can be.

1 is a block diagram illustrating a centrifugal separation method according to the present invention.
2 to 4 is a centrifugal separation method according to the present invention, a view for explaining the first centrifugation process and the discharge process of one specific component.
5 to 7 is a view for explaining the second centrifugal separation process and the discharge process of another specific component as a centrifugal separation method according to the present invention.
8 is a view showing an example of using the target component extracted after the second centrifugal separation method according to the present invention.
9 to 14 is a view showing the structure of a centrifugal syringe according to the present invention.
15 and 16 are views for explaining a centrifugal separation method according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, but the present invention is not limited or limited by the embodiments. In describing the present invention, a detailed description of well-known functions or constructions may be omitted for clarity of the present invention.

1 is a block diagram illustrating a centrifugal separation method according to the present invention. In addition, Figures 2 to 4 is a centrifugal separation method according to the present invention, a view for explaining the first centrifugal separation process and the discharge process of one specific component, Figures 5 to 7 as a centrifugal separation method according to the present invention , The second centrifugal separation process and the discharge process of other specific components. On the other hand, Figure 8 is a centrifugal separation method according to the present invention, a diagram showing an example of the use of the target component extracted after the second centrifugal separation.

As shown in FIG. 1, the centrifugal separation method according to the present invention may be performed by using a syringe 100 having a nozzle 112 formed at one end thereof, and storing the processing object in the syringe 100 (S10). ), In the state in which the nozzle 112 is disposed so as to face the direction opposite to the rotational center of the syringe 100, separating the object to be processed within the syringe 100 by first centrifugation (S20), and processing by the first centrifugation. Discharging one specific component separated from the object to be disposed on the nozzle 112 side through the nozzle 112 (S30), the syringe 112 in a state in which the nozzle 112 is disposed to face the rotation center of the syringe 100 ( 100) the second centrifugal separation of the object to be treated (S40), and the step of discharging the other specific component separated from the object to be treated by the second centrifugal and disposed on the nozzle 112 side through the nozzle 112 (S50).

As the syringe 100, a conventional syringe including a barrel 110 and a plunger 120 may be used, and the present invention is not limited or limited by the type and characteristics of the syringe 100.

The barrel 110 may be formed in a hollow cylindrical shape having a predetermined diameter (or capacity). One end of the barrel 110 is formed with a nozzle 112 for entering and exiting the treatment object, the other end of the barrel 110 is opened so that the plunger 120 can enter. In addition, the nozzle 112 is forcibly cut off during the first and second centrifugal separation, which will be described later, and the nozzle 112 may be blocked using a conventional blocking member such as a cap 130.

The plunger 120 enters the other end of the barrel 110 and is accommodated in the barrel 110 so as to be linearly movable, and the object to be processed through the nozzle 112 according to the pressure change caused by the linear movement of the plunger 120. Can be entered or discharged.

For reference, the object to be treated in the present invention means a material to which centrifugation is performed, and the present invention is not limited or limited by the type and characteristic of the object to be treated. Hereinafter, an example in which blood is used as the object to be treated will be described. In some cases, other samples from animals or human bodies may be used for treatment instead of blood.

Hereinafter, a centrifugal separation method using a syringe will be described with reference to FIGS. 2 to 7.

First, blood is stored in the barrel 110. As described above, blood may enter the barrel 110 through the nozzle 112 according to the pressure change caused by the linear movement of the plunger 120. The blood used as the target material may be provided with a separate needle (see 132 of FIG. 8) at the tip of the nozzle 112 and directly supplied from the body using the needle. In some cases, it is also possible to enter the blood stored in a separate reservoir into the barrel through the nozzle.

Next, as shown in Figure 2, by using a conventional centrifuge (not shown) by rotating the syringe 100, the blood stored in the barrel 110 is centrifuged first. At this time, the syringe 100 is disposed so that the nozzle 112 faces in the opposite direction (outside) of the rotation center.

That is, the syringe 100 may be mounted and rotated in a rotor used in a conventional centrifuge. For example, as a rotor to which the syringe 100 may be mounted, a swing rotor or an angle rotor, which is generally used in a centrifuge, may be used, and the rotor may be used in accordance with the type and characteristics of the rotor. The present invention is not limited or limited. In addition, the rotation center of the syringe 100 may be understood as a rotation axis (not shown) of a rotating means such as a rotor on which the syringe 100 is mounted.

As described above, when the syringe 100 is rotated in a state in which the nozzle 112 of the syringe 100 is disposed to face the direction opposite to the rotation center, as shown in FIG. Interlayer separation between components is performed, wherein one specific component (A), which is the heaviest among components of blood, is the outermost side of the nozzle 112 at the inside of the barrel 110 based on the center of rotation of the syringe 100. Is placed on. For reference, the one specific component (A) may include the heaviest red blood cells among the components of the blood.

Next, the specific component (A) separated from the blood by the first centrifugal separation and disposed on the nozzle 112 side is discharged through the nozzle 112. That is, as shown in FIG. 4, the plunger 120 may be pushed out to discharge one specific component A (red blood cells) disposed on the nozzle 112 side to the outside of the barrel 110 through the nozzle 112.

Next, as shown in Figure 5, by rotating the syringe 100 through the centrifuge to separate the second centrifugal blood separated from one specific component. At this time, the syringe 100 is disposed in the opposite direction as the first centrifugal separation. That is, the syringe 100 is rotated with the nozzle 112 disposed to face the center of rotation.

When the syringe 100 is rotated while the nozzle 112 of the syringe 100 is disposed toward the rotation center as described above, as shown in FIG. 6, the remaining components (eg, plasma and platelets) constituting the blood Interlayer separation between the components is achieved by the difference in density, wherein another specific component (B), which is relatively light among the remaining components of blood, is the innermost nozzle inside the barrel 110 with respect to the center of rotation of the syringe 100. It is arrange | positioned at the 112 side. For reference, the other specific component (B) may include a relatively light plasma of the remaining components of the blood.

In addition, the first centrifugal separation rate and the second centrifugal separation rate of the blood are set differently. For example, the first centrifugal separation may be performed under a condition of 2500 to 3500 rpm, and the second centrifugal separation may be performed under a condition of 4000 to 5500 rpm.

Next, the other specific component B which is separated from the blood by the second centrifugal separation and disposed on the nozzle 112 side is discharged through the nozzle 112. As in the specific component described above, as shown in FIG. 7, the specific component B (plasma) disposed on the nozzle 112 side by pushing the plunger 120 out of the barrel 110 through the nozzle 112. Can be discharged.

Therefore, after one specific component (A) and the other specific component (B) are separated and discharged from the blood through the first centrifugal separation and the second centrifugal separation, the target component (C) remaining inside the barrel 110 is platelets. (blood platelet).

As described above, only platelets may be extracted into the syringe 100 through the first centrifugation and the second centrifugation of blood, and various experiments and studies are performed using the extracted platelets, or as shown in FIG. 8, The injection using a platelet may be performed by directly injecting the patient through the needle 132 mounted on the nozzle 112.

Meanwhile, as described above, the platelets may be concentrated on the surface of the plunger head 122 because they are separated from the plasma by centrifugation and extracted. However, when the surface of the plunger head 122 is flat, adhesion of platelets concentrated on the surface of the plunger head 122 may occur. To this end, the centrifugal syringe 100 according to the present invention may be provided with an adhesion prevention unit 140 for reducing adhesion of a target component such as platelets.

On the other hand, Figures 9 to 14 is a view showing the structure of a syringe for centrifugation according to the present invention. In addition, the same or equivalent portions as those in the above-described configuration are denoted by the same or equivalent reference numerals, and a detailed description thereof will be omitted.

Referring to Figure 9, the centrifugal syringe 100 according to the present invention can be used to extract the target component from the object to be treated by centrifugation, the barrel 110, the nozzle 112 is formed at one end, and the At the other end of the barrel 110 includes a plunger 120 accommodated in the barrel 110 to be linearly movable, the plunger head 122 of the plunger 120, the adhesion prevention portion for reducing the adhesion of the target component 140 may be formed.

The adhesion prevention part 140 may be provided in various structures capable of reducing adhesion of a target component concentrated on the surface of the plunger head 122. For example, the adhesion prevention part 140 may include an adhesion prevention protrusion 141 protruding from the surface of the plunger head 122.

Therefore, even if the target component is concentrated on the surface of the plunger head 122 by centrifugation, the target component may be disposed in such a manner that the target component is divided on the surface of the plunger head 122 by the adhesion preventing protrusion 141. Adhesion of the components can be minimized, and the desired components can be more easily separated from the plunger head 122.

The adhesion preventing protrusion 141 may be changed in various ways depending on the required conditions and processing environment. For example, the anti-adhesion protrusion 141 may be a cone, a polygonal pyramid (for example, a square pyramid, a triangular pyramid), a frustum (a cone, a polygonal pyramid, etc.), a cylinder, a polyhedron (pentahedron, a hexahedron, etc.) and an ellipsoid. It may be provided in at least one of the shape.

In addition, the anti-adhesion protrusions 141 may be arranged in plural in a predetermined arrangement (for example, lattice nothing), and the plural anti-adhesion protrusions 141 may be provided to have the same size or have different sizes. Can be. Hereinafter, a plurality of adhesion preventing protrusions 141 having the same size as each other and having a quadrangular pyramid shape will be described with an example uniformly formed on the surface of the plunger head 122.

Alternatively, as shown in FIG. 10, the adhesion preventing protrusion 142 may be provided in a shape that continuously protrudes along a specific direction. For example, the adhesion preventing protrusion 142 may be provided in the form of a circular band having a triangular cross-sectional shape, and a plurality of adhesion preventing protrusions 142 may be provided to have a gradually larger diameter based on the center of the surface of the plunger head 122. In some cases, the band-shaped adhesion preventing protrusion may be configured to have a square or other cross-sectional shape. Alternatively, the anti-adhesion protrusions may be formed in a continuously protruding shape to form a spiral shape.

In addition, as shown in FIG. 11, the anti-adhesion protrusion 143 may be provided in a hemispherical shape in the form of embossing, and the anti-adhesion protrusion 144 may be provided in the form of a square pillar as shown in FIG. 12.

Meanwhile, according to another embodiment of the present invention, the adhesion prevention part may include an adhesion prevention net provided to be spaced apart from the surface of the plunger head. That is, as shown in FIG. 13, the adhesion prevention part 140 ′ may include an adhesion prevention net 147 provided to be spaced apart from the surface of the plunger head 122, and the adhesion prevention net 147 may be a predetermined mesh. It can be formed of a net (net) having a). The mesh size of the anti-adhesion net 147 and the separation distance from the surface of the plunger head 122 may be variously changed according to the required conditions and the processing environment.

In addition, as shown in FIG. 14, a spacer 148 may be interposed between the adhesion preventing net 147 constituting the adhesion preventing portion 140 ′ and the surface of the plunger head 122. For example, a substantially spherical spacer 148 may be used as the spacer 148, and a plurality of spacers 148 may be provided at predetermined intervals.

In addition, the aforementioned anti-adhesion portion may be provided irregularly by roughly processing the surface of the plunger head, and may be provided in other ways besides the above-described method and structure.

15 and 16 are views for explaining a centrifugal separation method according to another embodiment of the present invention. In addition, the same or equivalent portions as those in the above-described configuration are denoted by the same or equivalent reference numerals, and a detailed description thereof will be omitted.

15 and 16, according to another embodiment of the present invention, the syringe 100 may be provided including a separation chamber 150 that is selectively detachably connected to the nozzle, and in the first centrifugation step. At least some of one specific component may be disposed in the separation chamber 150, and after the first centrifugal separation, the separation chamber 150 may be separated from the syringe.

The separation chamber 150 may be formed in a cylindrical shape having a predetermined receiving space therein, and connected to communicate with the barrel. To this end, a connection portion 152 may be formed on the separation chamber 150 to be connected to the nozzle.

The above-described first centrifugal separation may be performed while the separation chamber 150 is connected to the nozzle 112 of the syringe 100, and at least a part of one specific component is disposed in the separation chamber 150 in the first centrifugal separation step. Can be. That is, when the syringe 100 is rotated while the separation chamber 150 is connected to the nozzle 112, the density difference of each component constituting the blood in the internal space of the barrel 110 and the separation chamber 150 in communication with each other Interlayer separation between each component is performed, wherein the heaviest red blood cells among the components of the blood may be disposed in the separation chamber 150 which is the outermost with respect to the rotation center of the syringe 100. After the first centrifugation is completed, the separation chamber 150 in which the red blood cells are collected may be separated from the syringe 100.

Although all the red blood cells separated in the first centrifugation step are preferably arranged in the separation chamber, in this case, since some of the platelets may be disposed in the separation chamber, a small amount of the red blood cells separated in the first centrifugation step may cause It may be arranged inside the nozzle side.

As such, according to another embodiment of the present invention, since the red blood cells separated in the first centrifugal separation step may be collected through the separation chamber 150, the red blood cells remain inside the barrel 110 after the first centrifugation. Lowering the purity of platelets can be prevented.

In general, the inner surface of the barrel is difficult to have a certain degree of surface. Therefore, when the interlayer separation between components by centrifugation is performed only in the inner space of the barrel, even if the red blood cells separated in the inner space of the barrel are pushed out by the plunger and discharged, a small amount of red blood cells may remain on the inner surface of the barrel. Residual erythrocytes are difficult to separate by second centrifugation, and as a result, platelet purity may be reduced. However, in another embodiment of the present invention, since the red blood cells may be collected through the separation chamber 150, the red blood cells that may remain on the inner surface of the barrel 110 may be minimized, and as a result, the purity of platelets may be increased. Can be.

In another exemplary embodiment of the present invention, the upper inner surface 154 of the separation chamber 150 is simply described as an example, but in some cases, a component by centrifugation in the inner space of the barrel and the separation chamber communicating with each other. It is also possible to form the upper inner surface of the separation chamber inclined so that the separation between the layers can be more easily implemented.

As described above, although described with reference to the preferred embodiment of the present invention, those skilled in the art various modifications and variations of the present invention without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

100: syringe 110: barrel
112 nozzle 120 plunger
122: plunger head 130: cap
140: adhesion prevention part

Claims (16)

In the centrifugal separation method using a syringe having a nozzle formed at one end,
Storing an object to be processed in the syringe;
First centrifuging the object within the syringe with the nozzle disposed outwardly toward the center of rotation of the syringe;
Discharging, through the nozzle, a specific component having a relatively high density among the components constituting the object to be treated and disposed on the nozzle side by the first centrifugation;
Reversing the syringe so that the nozzle is inward of the center of rotation of the syringe to second centrifuge the object within the syringe; And
A relatively low density of the remaining components constituting the object to be treated, and the step of discharging the other specific components disposed on the nozzle side by the second centrifugation through the nozzle; Centrifugation method comprising a. delete delete The method of claim 1,
The syringe,
A barrel having a nozzle formed at one end thereof; And
It is provided including a plunger accommodated in a linear movement in the barrel at the other end of the barrel,
And the nozzle is blocked while the first and second centrifugal separations are in progress. The method of claim 1,
When the object to be treated is blood,
The one specific component separated by the first centrifugation comprises red blood cells, the other specific component isolated by the second centrifugation includes plasma,
The target component remaining in the syringe after each specific component is discharged, characterized in that it comprises a platelet (blood platelet). The method of claim 4, wherein
The plunger head of the plunger is provided with an adhesion prevention part,
The target component remaining in the syringe after each specific component is discharged is centrifugal separation method characterized in that the adhesion to the plunger head is reduced by the adhesion prevention portion. The method of claim 1,
The syringe is provided including a separation chamber selectively detachably connected to the nozzle,
At least some of the one specific component in the first centrifugal separation step is disposed in the separation chamber,
And the separation chamber is separated from the syringe after the first centrifugal separation. delete The method of claim 6,
The adhesion prevention part comprises a adhesion prevention protrusion protruding on the surface of the plunger head. 10. The method of claim 9,
The adhesion preventing projection is a centrifugal separation method characterized in that it is provided in at least one of the shape of a cone, a polygonal pyramid, a truncated cone, a polygonal pyramid, a cylinder, a polyhedron and an ellipsoid. 10. The method of claim 9,
The adhesion preventing projections are arranged in a plurality of predetermined arrangement,
A plurality of the anti-adhesion projections are characterized in that the centrifugal separation method is provided to have the same or different sizes. 10. The method of claim 9,
The adhesion preventing projection is a centrifugal separation method characterized in that it is provided in a shape that continuously protrudes along a specific direction. The method of claim 6,
The adhesion prevention part,
Formed from a net (net) material having a predetermined mesh (mesh), the centrifugal separation method comprising a coalescing prevention net provided to be spaced apart from the surface of the plunger head. The method of claim 13,
And a spacer interposed between the anti-adhesion net and the surface of the plunger head. delete delete

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