KR102687356B1 - Blood separation device for extracting platelet-rich plasma - Google Patents

Abstract

The present invention relates to a blood separation device for extracting platelet-rich plasma. Pure platelet-rich plasma (PRP) can be extracted through a single centrifugation, and the platelet-rich plasma (PRP) can be stored in a sealed container. Located inside the extraction tube, the pellet-shaped buffy coat can be recovered in a sufficiently loosened state by repeating the suction and discharge of the syringe, and its structure allows anyone, even non-skilled experts, to easily extract platelet-rich plasma (PRP). It relates to an improved blood separation device.

Description

Blood separation device for extracting platelet-rich plasma {BLOOD SEPARATION DEVICE FOR EXTRACTING PLATELET-RICH PLASMA}

The present invention relates to a blood separation device for extracting platelet-rich plasma. Pure platelet-rich plasma (PRP) can be extracted with a single centrifugation, and anyone, even non-experts, can easily extract platelet-rich plasma (PRP). This relates to a blood separation device with an improved structure so that PRP can be extracted.

Blood is composed of plasma, platelets, and blood cells, of which platelets contain components necessary for the regeneration and activation of human tissues. When blood is centrifuged, it is separated into plasma, platelets, and blood cells according to their specific gravity. The separated plasma is divided into platelet rich plasma (PRP) and platelet poor plasma (PPP). It consists of PRP removes red blood cells by centrifuging the subject's blood, and uses blood components containing buffycoat, which is rich in platelets and various growth factors, to promote proliferation of surrounding cells and stimulate them to synthesize abundant components such as collagen. It is reported that it is effective. Accordingly, PRP has recently been used in various fields, including pain treatment such as back pain, hair loss treatment, and skin diseases such as skin regeneration and burn treatment.

Traditionally, to separate PRP containing buffy coat, Ficoll-Hypaque, 3% gelatin, and 6% hydroxyethyl starch, which facilitate layer separation, were added to the blood, then centrifuged, and a skilled It is recovered through manual work by qualified experts. The recovered buffy coat must be additionally washed several times to remove additives whose safety has not been proven, and there is a risk of monocyte loss or bacterial, fungal, and mycoplasma infection occurring during this complex process.

Various blood component separation kits that can easily recover PRP without using additives to blood have been known in the past, and Korean Patent Publication No. 10-2010-0105282 describes a method of separating PRP using two tube-type test tubes. It has been announced. More specifically, blood collected from the human body is injected into a tube-shaped test tube, the injected test tube is first centrifuged using a centrifuge, and then a syringe needle is inserted into the tube to extract only the plasma located in the top layer. Afterwards, to obtain highly concentrated PRP, the extracted plasma is placed in another tube-type test tube and subjected to a second centrifugation. The plasma in the upper layer of the tube-type test tube that underwent secondary centrifugation is extracted with a syringe, and the remaining PRP is extracted.

However, in this process, red blood cells may be aspirated together in the plasma extraction step after the first centrifugation, and the buffy coat layer is created on the red blood cells in a very small amount, so there is a problem in that they cannot be extracted accurately, and the process of transferring them to a new tube There is a problem that can be exposed to the atmosphere.

In addition, Korean Patent No. 10-2323471 can extract the desired PRP through two or more centrifugations, but a small amount of red blood cells are mixed in the lower part of the separated PRP layer during the second centrifugation, so when PRP is extracted with a syringe, There was a problem that pure PRP could not be extracted.

Therefore, in order to solve the above problems, there is a need to develop a dedicated kit that can accurately and easily automatically separate PRP.

Patent Document 1: Korean Patent Publication No. 2010-0105282 (published on September 29, 2010) Patent Document 2: Korean Patent Publication No. 10-2323471 (published on May 12, 2021)

The present invention was created in consideration of the above problems and to solve them. It allows extracting and collecting platelet-rich plasma through a single centrifugation process, thereby simplifying the work process and increasing the convenience of work. The aim is to provide a blood separation device for extracting platelet-rich plasma with an improved structure.

The present invention according to one aspect for achieving the above object is a lower container portion in which a lower inner space in which blood to be centrifuged can be accommodated is formed, and a lower cap that adjusts the volume of the lower inner space is coupled to the lower portion. ; An extraction tube connected in a communication form to the upper side of the lower container unit and allowing blood to penetrate the internal space; A valve cock located at the bottom of the extraction tube and opening or blocking blood passing through the extraction tube; and an upper container portion connected to the lower container portion through a screw thread and forming an upper inner space therein. Provided is a blood separation device for extracting platelet-rich plasma, comprising:

In addition, the inner lower part of the outer circumferential surface of the upper container part includes an upper lower screw thread, and is screwed with the lower upper screw thread located on the outer upper part of the outer circumferential surface of the lower container part, so that the upper container part is raised and lowered by a rotating operation. .

In addition, the lower outer side of the outer peripheral surface of the lower container portion may include lower lower threads, and may be screwed to the threads of the lower cap so as to be raised and lowered through a rotational motion to adjust the volume of the lower inner space.

In addition, the upper internal space may be characterized in that the internal volume of the upper internal space is larger than that of the lower internal space.

Additionally, the extraction pipe may be formed to have a smaller diameter than the upper and lower container portions.

In addition, the lower portion of the upper inner space may include an upper boundary portion having a shape that narrows in width downward, and the upper portion of the lower inner space may include a lower boundary portion that has a shape that narrows in width upward. there is.

In addition, it may further include an upper passage below the upper border, and the diameter of the upper passage may be larger than the diameter of the extraction pipe.

In addition, the upper inner peripheral surface of the upper passage includes an upper passage sealing member that seals the contact surface with the extraction pipe, and the outer peripheral surface of the lower end of the lower container portion includes a lower sealing member that seals the contact surface with the lower cap. You can do this.

In addition, the extraction tube includes a reduced diameter portion and an enlarged diameter portion at the bottom so that the diameter of the extraction tube is formed to be small, and the valve cock is located between the reduced diameter portion and the expanded diameter portion to open the blood penetrating the extraction tube. Alternatively, it may be characterized as blocking.

Additionally, the upper container may include a blood inlet on one side of the upper surface.

Additionally, it may be characterized by including a platelet-rich plasma recovery port in the center of the upper surface of the upper container portion.

In addition, the platelet-rich plasma recovery port may include an extraction tube sealing portion that seals the top of the extraction tube on both sides of the bottom of the platelet-rich plasma recovery port.

In addition, after centrifugation, red blood cells (RBC) and platelet rich plasma (PRP) are accommodated in the lower inner space, and platelet rich plasma (PRP) is accommodated in the extraction tube. It may be characterized in that platelet poor plasma (PPP) is accommodated in the upper internal space.

According to another aspect for achieving the above object, the present invention provides a method for extracting platelet-rich plasma, comprising: (a) injecting blood into a blood inlet; (b) centrifuging the input blood; (c) adjusting the interface between red blood cells and platelet rich plasma (PRP) using a lower cap after centrifugation; (d) rotating the upper container unit downward after the above adjustment; and (e) extracting platelet-rich plasma (PRP) by injecting a needle into the platelet-rich plasma recovery port; It provides a method for extracting platelet-rich plasma, comprising:

In addition, in step (c), the lower cap is rotated upward to place the platelet-rich plasma (PRP) contained in the lower container into the extraction tube, and the valve cock is rotated to prevent the platelet-rich plasma from mixing in the lower container. It can be characterized as preventing this.

In addition, step (d) may be characterized in that the upper container portion is rotated so that the top of the extraction tube containing platelet-rich plasma (PRP) is positioned higher than the platelet poor plasma (PPP) accommodated in the upper container portion. You can.

In addition, in step (d), the upper container part is rotated downward until the upper part of the extraction tube comes into contact with the lower end of the extraction tube sealing part, thereby sealing the platelet-rich plasma (PRP) contained within the extraction tube. You can do this.

The blood separation device according to the present invention is capable of extracting pure platelet-rich plasma that does not contain impurities with a single centrifugation rather than two or more centrifugations, and the platelet-rich plasma is located inside a sealed extraction tube. By repeating the suction and discharge of the syringe, the pellet-shaped buffy coat can be recovered in a sufficiently loosened state, and anyone, even if not a skilled expert, can easily use it, increasing the convenience of work.

The attached drawings are intended to explain the present invention in more detail to those skilled in the art, and the technical idea of the present invention is not limited thereto.
Figure 1 is a cross-sectional view showing blood components separated after centrifuging blood in a blood separation device with an open valve cock according to the present invention.
Figure 2 is a cross-sectional view showing blood components separated before extracting platelet-rich plasma in a blood separation device with a closed valve cock according to the present invention.
Figure 3 is a cross-sectional view showing the lower container portion of the blood separation device with the valve cock open according to the present invention.
Figure 4 is a cross-sectional view showing the upper container portion of the blood separation device with the valve cock closed according to the present invention.
Figure 5 is a cross-sectional view of the upper container portion of the blood separation device with the valve cock closed according to the present invention moved downward.
Figure 6 is a cross-sectional view before the lower cap of the blood separation device with the valve cock opened according to the present invention is rotated upward.
Figure 7 is a cross-sectional view of the blood separation device according to the present invention with the lower cap rotated upward and the valve cock closed.
Figure 8 is a cross-sectional perspective view of the blood separation device with the valve cock open according to the present invention.

Hereinafter, an embodiment according to the present invention will be described in detail with reference to the attached drawings. In this process, the size or shape of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. Additionally, terms specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator. Definitions of these terms should be made based on the content throughout this specification.

In addition, the idea of the present invention is not limited to the presented embodiments, and a person skilled in the art who understands the idea of the present invention will be able to easily implement other embodiments within the scope of the same idea, but this also falls within the scope of the present invention. Of course.

Figure 1 is a cross-sectional view of blood components separated after centrifuging blood in the blood separation device 1 with the valve cock 150 open according to the present invention, and Figure 2 is a cross-sectional view of blood with the valve cock 150 closed according to the present invention. It is a cross-sectional view of the blood components separated before extracting the platelet-rich plasma (12) in the separation device (1), and Figure 3 shows the lower container portion (140) of the blood separation device (1) with the valve cock (150) according to the present invention opened. ), and Figure 4 is a cross-sectional view showing the upper container portion 110 of the blood separation device 1 with the valve cock 150 according to the present invention closed, and Figure 5 is a cross-sectional view showing the valve cock 150 according to the present invention. This is a cross-sectional view in which the upper container portion 110 of the closed blood separation device 1 is moved downward, and Figure 6 shows the lower cap 130 of the blood separation device 1 with the valve cock 150 according to the present invention opened. It is a cross-sectional view before rotating upward, and Figure 7 is a cross-sectional view of the blood separation device 1 with the valve cock 150 closed after rotating the lower cap 130 according to the present invention upward, and Figure 8 is a cross-sectional view of the blood separation device 1 according to the present invention. This is a cross-sectional perspective view of the blood separation device (1) with the valve cock (150) open. Hereinafter, the blood separation device 1 of the present invention will be described in detail through FIGS. 1 to 8 and examples.

As shown in Figures 1 to 8, the blood separation device 1 according to the present invention is formed with a lower internal space that can accommodate blood to be centrifuged, and a lower part that adjusts the volume of the lower internal space at the lower part. A lower container portion 140 to which the cap 130 is coupled; An extraction tube (120) connected in a communication form to the upper side of the lower container part (140) and allowing blood to penetrate the internal space; A valve cock 150 capable of opening or blocking blood penetrating the extraction tube 120, located at the bottom of the extraction tube 120, and opening or blocking blood penetrating the extraction tube 120; and an upper container portion (110) connected to the lower container portion (140) through a screw thread and forming an upper inner space therein. Includes.

The blood separation device (1) according to the present invention is a device used to extract only specific components from a mixture of components of various concentrations, and uses the centrifugal force of a centrifuge to separate each component by specific gravity and then extract the specific components. It is a device that allows you to do this. More specifically, the blood separation device 1 according to the present invention is a device that rotates the mixed substances injected inside at high speed through a centrifuge and separates each component using the centrifugal force, rather than separating the mixed substances injected therein.

The centrifugation container according to the present invention is suitable for extracting platelet-rich plasma (PRP) (12) from collected blood, but is not limited to use for specific substances. In addition to platelet-rich plasma (PRP) (12), the present invention can also be used to extract bone marrow, body fluids, or cells, but is not limited to this.

The blood separation device (1) according to the present invention allows collected blood to be injected into the inside, and through centrifugation, each component of blood, such as red blood cells (13), platelets, and plasma, is separated into layers according to specific gravity, Accordingly, a space in which the blood is stored is provided, and the upper container portion 110, the extraction tube 120, and the lower container portion 140 of the present invention correspond to this. In addition, the blood separation device 1 according to the present invention is formed to have a generally cylindrical shape to be suitable for a centrifuge. In addition, the upper container portion 110, the extraction tube 120, and the lower container portion 140 according to the present invention may be made of a transparent plastic material so that the internal condition can be confirmed from the outside, but the present invention is not limited thereto.

Referring to Figures 1 and 2, the upper container portion 110 is located above the lower container portion 140, and the collected blood can be accommodated in the upper inner space. The blood that is first injected into the container has each component mixed uniformly, so the blood that is first injected into the upper internal space of the upper container portion 110 may also be in a homogeneous state.

The lower container portion 140 is located below the upper container portion 110, and red blood cells 13 may be located in the lower inner space of the lower container portion 140 from blood that has undergone centrifugation.

In addition, an extraction tube 120 is connected to the upper side of the lower container part 140 in a communication form and allows blood to penetrate into the internal space. More specifically, the extraction pipe 120 is integrally connected to the lower boundary portion 141, which has a shape that narrows upward from the upper end of the lower inner space, and the diameter of the extraction pipe 120 is the upper end. It may be formed smaller than the container portion 110 and the lower container portion 140.

Additionally, a lower cap 130 that adjusts the volume of the lower inner space may be coupled to the lower part of the lower container portion 140. More specifically, referring to Figures 6 and 7, the lower outer peripheral surface of the lower container portion 140 includes a lower lower thread, and a lower cap that can engage with the lower lower threaded inside the lower cap 130. A screw thread 131 may be included. Therefore, when the lower cap 130 is raised by rotating the lower cap 130, the volume of the lower inner space becomes smaller, and when the lower cap 130 is rotated to lower the lower cap 130, The volume of the lower internal space may be increased.

The upper lower thread 113, lower lower thread 142, and lower lower thread can be formed in any number as long as they can raise and lower the upper container portion 110 and the lower cap, which is known in the art. Includes the number of threads that can be easily used.

Additionally, referring to FIG. 3, the outer peripheral surface of the lower end of the lower container portion 140 may include a sealing means for sealing the contact surface with the lower cap 130. The sealing means may be a sealing member 122 or 145 commonly used in the industry, and more specifically may be a silicone ring, but is not limited thereto. In addition, there may be more than one sealing member (122, 145), and one or more sealing members (122, 145) can be used without limitation as long as it is a means to prevent blood from flowing.

In addition, the upper lower inner surface of the outer circumferential surface of the upper container part 110 may include a lower upper screw thread 113, and the upper lower outer peripheral surface of the lower container part 140 may include a lower upper screw thread 142. Therefore, the upper container portion 110 can be screwed to the lower container portion 140, and by rotating the upper container portion 110, the upper container portion 110 is raised and lowered through the lower upper screw thread 142. It can be operated as Means for lifting and lowering through screw threads are commonly used in the industry, and any means that can be used for lifting and lowering can be used without limitation.

In addition, when blood is generally centrifuged, red blood cells 13 are separated into 35 to 45% and plasma is separated into 55 to 65%, so the upper internal space can be formed to have a larger internal volume than the lower internal space. .

Referring to FIGS. 3 and 4, the blood separation device 1 of the present invention is located at the bottom of the extraction tube 120 and includes a valve cock capable of opening or blocking blood penetrating the extraction tube 120. 150) may be included. More specifically, the valve cock 150 may be located at the lower end of the extraction pipe 120 where the diameter is narrowed, for example, the reduced diameter portion 121 whose diameter is narrowed in the extraction pipe 120 and It may be located between the enlarged diameter portion 144.

The valve cock 150 includes a valve handle 151 that can open or block the flow of blood by adjusting the through hole 153, a through hole 153 through which flowing blood passes, and a valve cock 150 connected to the extraction pipe. It may be composed of a fixing part 152 that is fixed to (120). The through hole 153 may be smaller than or equal to the diameter of the narrowing extraction pipe 120 between the reduced diameter portion 121 and the expanded diameter portion 144.

More specifically, when the through hole 153 is opened to allow blood to pass through and the blood is centrifuged, red blood cells 13 and platelet-rich plasma 12 will be contained in the lower inner space of the lower container portion 140 of the present invention. You can. Platelet-rich plasma (12) has a smaller specific gravity than red blood cells (13), so it can be located on top of the red blood cell (13) layer, and the interface between the red blood cell (13) layer and the platelet-rich plasma (12) layer can be located in the lower internal space. . The platelet-rich plasma 12 may be located between the upper end of the lower border 141, which has a shape that narrows upward, and the expanded diameter 144 located at the lower end of the valve cock 150. . At this time, when the lower cap 130 is rotated and raised, the volume of the lower container portion 140 decreases, and the platelet-rich plasma 12 located at the bottom of the valve cock 150 passes through the through hole 153. It can be positioned at the top of the valve cock 150 by passing through it. Then, when the valve handle 151 located on one side of the valve cock 150 is turned to block the through hole 153, the red blood cells 13 located in the lower inner space are separated and the extraction tube 120 is rich in platelets. It can be adjusted to position only the plasma (12).

Here, in order to turn the valve handle 151, an adjustment tool 154 may be included between the lower lower thread and the upper lower thread 142 of the lower container portion 140. More preferably, the valve cock 150 may include an adjuster 154 on the outer surface of the lower container portion 140 located in the horizontal direction. A cross- or straight-shaped groove can be formed in the center of the valve handle 151, and a valve handle 151 adjustment tool, for example, a cross or flat-head screwdriver, can be inserted into the adjusting hole 154 to control the valve cock 150. ) can be rotated to open or block the blood penetrating the extraction tube 120.

Figures 4 and 5 are diagrams showing the principle of lowering the upper container portion 110 by rotating the upper container portion 110. The upper container portion 110 includes an upper boundary portion 111 whose width narrows downward at the lower end of the upper inner space, and an upper passage 112 integrally connected to the lower end of the upper boundary portion 111. can do.

More specifically, when the upper container portion 110 is moved up and down by rotating the upper container portion 110, the upper passage 112 can be moved up and down along the outer surface of the extraction pipe 120. . The diameter of the upper passage 112 is larger than the diameter of the extraction pipe 120, and the inner surface of the upper passage 112 and the outer surface of the extraction pipe 120 have an empty space to prevent blood from flowing. It may be a closed space, and the upper inner peripheral surface of the upper passage 112 may include a sealing means. The sealing means may be a sealing member 122 or 145 commonly used in the industry, and more specifically may be a silicone ring, but is not limited thereto. Additionally, there may be more than one sealing member (122, 145), and as long as it is a means to prevent blood from flowing, one or more sealing members (122, 145) can be used without limitation in number.

In addition, one side of the upper surface of the upper container part 110 may include a blood inlet for injecting blood, and the center of the upper surface of the upper container part 110 can be used to recover plasma using a needle. It may include phrase 115. Here, the blood inlet may be a hole through which blood is injected into the container through a needle, and the platelet-rich plasma recovery port 115 may be a hole used to extract the result through a needle. The blood inlet and platelet-rich plasma recovery port 115 may include a control means for controlling the inflow and outflow of blood, and the control means may be a silicone rubber stopper, but is not limited thereto.

In addition, when lowering the upper container portion 110 downward, the rubber stopper of the blood inlet is opened so that the upper container portion 110 can descend without being restricted by the pressure of the upper internal space, which is known in the art. It is possible to prevent contamination of the upper internal space by additionally including a commonly used hole, or by adding a sterilized filter or membrane to the hole.

In addition, the platelet-rich plasma recovery port 115 located at the center of the upper surface of the upper container portion 110 may include an extraction pipe sealing portion 116 that seals the upper end of the extraction pipe 120 on both sides of the bottom. This is done by rotating the upper container part 110 downward until the upper part of the extraction tube 120 abuts the lower end of the extraction tube sealing part 116, thereby receiving platelet-rich plasma (platelet-rich plasma) received inside the extraction tube 120. 12) can be sealed.

In addition, when centrifuging blood, the blood is divided into red blood cells (13), platelet-rich plasma (12), and platelet-poor plasma (11). Depending on the difference in specific gravity, from the bottom, red blood cells (13), platelet-rich plasma (12), Platelet-poor plasma can be separated in that order (11). At this time, red blood cells 13 and platelet-rich plasma 12 are accommodated in the lower inner space, platelet-rich plasma 12 is accommodated in the extraction tube 120, and platelet-poor plasma 11 is accommodated in the upper inner space. It can be accepted.

A method for extracting platelet-rich plasma using the blood separation device (1) of the present invention includes the steps of (a) injecting blood into a blood inlet; (b) centrifuging the input blood; (c) adjusting the interface between red blood cells 13 and platelet-rich plasma 12 using the lower cap 130 after centrifugation; (d) rotating the upper container portion 110 downward after the above adjustment; and (e) extracting platelet-rich plasma (12) by injecting a needle into the platelet-rich plasma recovery port (115); may include.

Here, in step (c), the lower cap 130 is rotated upward to position the platelet-rich plasma 12 contained in the lower container 140 into the extraction tube 120, and the valve cock 150 is rotated upward. By rotating it, it can be adjusted so that the platelet-rich plasma 12 is not mixed in the lower container part 140.

In addition, in step (d), the upper container portion 110 is positioned so that the top of the extraction tube 120, where the platelet-rich plasma 12 is accommodated, is positioned higher than the platelet-poor plasma 11 accommodated in the upper container portion 110. Rotate it. More preferably, the upper container portion 110 is rotated downward until the upper portion of the extraction tube 120 abuts the lower end of the extraction tube sealing portion 116, thereby increasing the platelet abundance contained within the extraction tube 120. Plasma (PRP) (12) can be sealed.

Afterwards, the platelet-rich plasma 12 can be extracted to the outside from the extraction tube 120 containing the platelet-rich plasma 12 by passing the needle through the platelet-rich plasma recovery port 115.

The operation of the present invention having this configuration is explained as follows.

Blood from the subject is collected, the blood is injected through the blood inlet 114 of the upper container unit 110, and centrifuged using a centrifuge.

The amount of blood injected may be 40 to 60 ml, and the centrifugation is operated at 200 to 2,000 G for 5 to 30 minutes. During centrifugation, the penetration portion of the valve cock 150 must be opened to allow blood to pass through.

After centrifugation is completed, the blood is divided into red blood cells (13), platelet-rich plasma (12), and platelet-poor plasma (11), and from the bottom, according to the difference in specific gravity, red blood cells (13), platelet-rich plasma (12), and platelet-poor plasma. The plasma 11 is separated in that order, and the red blood cell layer 13 is located at the bottom of the lower container portion 140, and the platelet-rich plasma layer 12 is located on top of it, forming an interface between them.

In order to accurately separate the red blood cells 13 and platelet-rich plasma 12 accommodated in the lower container 140, the platelet-rich plasma 12 can be placed on the upper part of the valve cock 150 by turning the lower cap 130. After adjusting, turn the valve cock 150 to block the through hole 153.

Afterwards, the upper container part 110 is rotated so that the upper passage 112 can descend along the extraction tube 120, and the upper end of the extraction tube 120 is moved to the platelet-poor plasma (11) accommodated in the upper container part 110. ), and more preferably, the upper container portion 110 is lowered until the upper portion of the extraction pipe 120 abuts the lower end of the extraction pipe sealing portion 116.

Next, the platelet-rich plasma 12 contained in the extraction tube 120 is extracted to the outside by passing the needle through the platelet-rich plasma recovery port 115.

Due to this, the blood separation device (1) of the present invention is capable of extracting pure plasma rich in platelets containing no impurities through a single centrifugation rather than two or more centrifugations, and can be used by anyone, even if not a skilled expert. It is easy to use and can increase the convenience of work.

The description of the present invention described above is for illustrative purposes, and those skilled in the art will understand that the present invention can be easily modified into other specific forms without changing the technical idea or essential features of the present invention. will be. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive.

1: Blood separation device 130: Lower cap
11: Platelet-poor plasma (PPP) 131: Lower cap thread
12: Platelet-rich plasma (PRP) 140: Lower container part
13: Red blood cell (RBC) 141: Lower border
110: upper container part 142: lower upper thread
111: upper border 143: lower lower thread
112: upper passage 144: expansion part
113: upper lower thread 145: lower sealing member
114: blood inlet 150: valve cock
115: Platelet-rich plasma recovery port 151: Valve handle
116: Extraction tube sealing part 152: Fixing part
120: extraction pipe 153: through hole
121: Diameter shaft 154: Adjuster
122: Extraction pipe sealing member

Claims (17)

A lower container portion in which a lower inner space capable of accommodating blood to be centrifuged is formed, and a lower cap that adjusts the volume of the lower inner space is coupled to the lower portion;
An extraction tube connected in a communication form to the upper side of the lower container, including a reduced diameter portion and an enlarged diameter portion at the bottom to reduce the diameter of the extraction tube, and through which blood can penetrate the internal space;
A valve cock located between the lower end of the extraction tube and the reduced diameter portion and the expanded diameter portion, which opens or blocks blood penetrating the extraction tube; and
An upper container portion connected to the lower container portion through a screw thread and forming an upper inner space therein; Includes,
The upper container portion is rotated to move the upper container portion downward, and the upper container portion further includes an upper passage connected to a lower portion of the upper boundary portion having a shape that narrows downward at a lower portion of the upper inner space, A blood separation device for extracting platelet-rich plasma, wherein the diameter of the upper passage is larger than the diameter of the extraction tube.
According to paragraph 1,
A blood separation device comprising an upper lower screw thread located on the lower inner side of the outer circumferential surface of the upper container portion, and screwed with a lower upper screw thread located on the upper outer side of the outer peripheral surface of the lower container portion to raise and lower the upper container portion through a rotational motion.
According to paragraph 1,
A blood separation device comprising a lower lower screw thread on the outer peripheral surface of the lower container portion, which is screwed with the screw thread of the lower cap and moves up and down through a rotational motion to adjust the volume of the lower inner space.
According to paragraph 1,
A blood separation device, wherein the upper internal space has a larger internal volume than the lower internal space.
According to paragraph 1,
A blood separation device, wherein the extraction tube has a smaller diameter than the upper and lower container parts.
According to paragraph 1,
A blood separation device characterized in that the upper portion of the lower inner space includes a lower border portion having a shape that narrows upward.
delete According to paragraph 1,
The upper inner peripheral surface of the upper passage includes an upper passage sealing member that seals the contact surface with the extraction pipe,
A blood separation device comprising a lower sealing member on the outer peripheral surface of the lower end of the lower container portion to seal the contact surface with the lower cap.
delete According to paragraph 1,
A blood separation device comprising a blood inlet on one side of the upper surface of the upper container portion.
According to paragraph 1,
A blood separation device comprising a platelet-rich plasma recovery port at the center of the upper surface of the upper container portion.
According to clause 11,
A blood separation device comprising an extraction tube sealing portion that seals the top of the extraction tube on both sides of the bottom of the platelet-rich plasma recovery port.
According to paragraph 1,
After the centrifugation, red blood cells (RBC) and platelet rich plasma (PRP) are accommodated in the lower inner space,
Platelet Rich Plasma (PRP) is received in the extraction tube,
A blood separation device characterized in that platelet poor plasma (PPP) is accommodated in the upper internal space.
In a method for extracting platelet-rich plasma,
(a) injecting blood into the blood inlet;
(b) centrifuging the input blood;
(c) adjusting the interface between red blood cells and platelet rich plasma (PRP) using a lower cap after centrifugation;
(d) after the adjustment, rotating the upper container downward until the upper part of the extraction tube comes into contact with the lower end of the extraction tube sealing part to seal the platelet-rich plasma (PRP) contained within the extraction tube; and
(e) extracting platelet-rich plasma (PRP) by injecting a needle into the platelet-rich plasma recovery port; A method for extracting platelet-rich plasma, comprising:
According to clause 14,
In step (c), the lower cap is rotated upward to place the platelet-rich plasma (PRP) contained in the lower container into the extraction tube, and the valve cock is rotated to prevent the platelet-rich plasma from mixing in the lower container. How to feature.
According to clause 14,
In step (d), platelets are rotated so that the top of the extraction tube containing Platelet Rich Plasma (PRP) is positioned higher than the Platelet Poor Plasma (PPP) contained in the upper vessel unit. Method for extracting rich plasma.
delete