KR101476924B1 - Viscosity measuring kit for blood - Google Patents

Abstract

The present invention relates to a blood viscosity measuring kit including a bottom channel section which has a plurality of micro channels, and is provided with a plurality of discharge passages; a main body section disposed on the bottom channel section with a plurality of damper sections and a sludge storage section, the plurality of damper sections allowing a reference fluid and blood to pass after being supplied from the outside and communicating with the reference fluid passage and the blood passage and the sludge storage section communicating with the discharge passage and storing the reference fluid and the blood after passage through the micro channel and measuring; and a cover section disposed on the main body section, and covers the sludge storage section. According to the present invention, the blood can be supplied with ease and stability, and the kit can be handled with ease. The sludge storage section is formed on the micro channel to stably accommodate the blood without leakage after the passage through the micro channel. Accordingly, continuous blood injection can be ensured. Also, a damper is formed in the vicinity of a blood inlet or a reference fluid inlet such that the generation of a vortex, or sedimentation of blood elements such as lipids and proteins can be prevented even when the blood is injected from a blood injection device such as a needle.

Description

{VISCOSITY MEASURING KIT FOR BLOOD}

The present invention relates to a blood viscosity measuring kit, and more particularly, to a blood viscosity measuring kit for measuring viscosity of a non-nutritional fluid such as blood, which is easy to be mounted, easy to measure and dispose of, And a blood viscosity measuring kit.

In recent years, studies for detecting signs of adult diseases have been progressing actively in accordance with an increase in various diseases including vascular diseases. For this purpose, researches on a device for measuring the viscosity of blood and a diagnostic kit are underway.

In general, a fluid viscometer for measuring the viscosity of a fluid such as blood is called a viscometer. Types of viscometers currently used include a capillary viscometer and a rotary viscometer. However, conventional viscometers such as a capillary viscometer or a rotary viscometer have a fear of generating errors due to environmental changes when measuring viscosity over various shear rates. Recently, a fluid viscosity measuring device capable of measuring the viscosity of a fluid to be measured by comparing a reference fluid having a reference viscosity with a fluid to be measured such as blood has been developed. However, the viscosity of a fluid such as blood is simple There is a limit to stable measurement. In addition, because blood contains non-Newtonian fluids that are not constant in relation to viscosity due to the presence of red blood cells and platelets in contrast to fluids such as water, viscosity can be measured stably at various shear rates A fluid viscosity measuring device is required.

As a viscosity measurement kit for such a non-newtonic fluid, Korean Patent No. 10-136365 is disclosed. The above-mentioned prior art discloses a fluid viscosity measuring apparatus which can easily measure the viscosity of a fluid by using a change in the interface due to a difference in relative viscosity between a reference fluid having a reference viscosity and a fluid to be measured.

As shown in FIG. 1, the conventional fluid viscosity measuring kit includes a first inlet for injecting a first fluid to be measured for viscosity, a second fluid not mixed with the first fluid, (Reference fluid), and a plurality of display channels connected to the fluid injection unit and configured to display a fluid interface due to a viscosity difference between the first fluid and the second fluid And a display channel section.

However, in the fluid viscosity measurement kit according to the related art, there is a fear that a vortex is formed in the fluid injection port portion. Particularly, when the fluid is blood, a part of the vortex is formed due to components such as lipid or protein contained in the blood There is a concern that an error may occur in the viscosity measured due to sedimentation, and the blood is not smoothly supplied to the display channel.

In addition, when the display channel is formed into a fine pattern channel of several tens of micrometers, the error of the viscosity measured due to the above-described problem seriously affects the display.

In addition, according to the above-described prior art, since blood that has passed through the display channel can not be properly accommodated, continuous infusion of blood is difficult and continuous measurement is impossible.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide an apparatus and a method for preventing vortexes and components such as lipids and proteins from being precipitated even when blood is injected from a blood injector such as a needle And a blood viscosity measurement kit.

It is another object of the present invention to provide a blood circulation system capable of easily and stably supplying a blood solution even when the display channel is formed with fine pattern channels of several tens of micrometers, And a blood viscosity measuring kit capable of continuously injecting blood and being easy to use.

In order to achieve the above object, the blood viscosity measurement kit of the present invention comprises a reference fluid flow passage through which a reference fluid passes, a blood flow passage through which blood flows, and a blood flow passage communicating with the blood flow passage and the reference fluid flow passage, A plurality of microchannels surrounding the outer circumferential surface of the first chamber and communicating with the first chamber, a second chamber surrounding the outer circumferential surface of the microchannel and communicating with the microchannel, A bottom channel portion communicating with the second chamber and having a plurality of discharge flow paths erected inside the outer peripheral surface of the second chamber; A plurality of dampers for passing the reference fluid and the blood supplied from the outside and communicating with the reference fluid channel and the blood channel, and a plurality of dampers for communicating with the discharge channel and storing the reference fluid and the blood, And a sludge storage unit for supplying sludge to the sludge storage unit. And a lid part installed on the upper part of the body part to cover the sludge storage part.

The damper portion includes a reference fluid inlet through which the reference fluid is supplied, a first damper communicating with the reference fluid inlet and the reference fluid passage, a blood inlet to which the blood is supplied, and a second fluid passage communicating with the blood inlet and the blood passage And a second damper which is connected to the second damper.

Here, the planar shape of the damper is characterized by having a circular arc portion in which a part of the inner wall is formed in an arc shape.

The lid part may include an air passage hole communicating with the sludge storage part and the outside of the blood viscosity measurement kit.

Here, the main body and the lid are formed of a liquid silicone material, and the liquid silicone is integrally formed by injecting and cooling the liquid silicone.

According to the blood viscosity measuring kit of the present invention having the above-described structure, the body part is formed on the bottom channel part where the microchannel is formed, so that even when the microchannel is formed with fine pattern channels of several tens of micrometers, the solution can be easily and stably supplied, And the sludge storage portion is formed on the upper portion of the microchannel so that the blood passing through the microchannel can be stably accommodated without being leaked so that the blood can be continuously injected and the blood viscosity A kit can be provided.

Further, by forming the damper in the vicinity of the blood injection port or the reference fluid injection port, even if blood is injected from the blood injection device such as a needle, it is possible to prevent a vortex or components such as lipids and proteins from precipitating.

1 is a view showing a blood viscosity measurement kit according to the prior art.
2 is a view showing a blood viscosity measurement kit according to the present invention.
3 is a plan view of a blood viscosity measurement kit according to the present invention.
4 is a view showing a bottom channel part of a blood viscosity measurement kit according to the present invention.
FIG. 5 is a bottom view of the main part of the blood viscosity measurement kit according to the present invention. FIG.
FIG. 6A is a sectional view taken along line A-A 'of FIG. 2, and FIG. 6B is a sectional view taken along line B-B' of FIG.

Hereinafter, a blood viscosity measuring kit according to the present invention will be described in detail with reference to the accompanying drawings.

2 to 6B, the blood viscosity measurement kit 1 according to the present invention includes a bottom channel portion 10 having microchannels for measuring the viscosity of blood to be supplied, A main body portion 20 for supplying blood to the bottom channel portion, and a lid portion 30 for covering the main body portion.

The bottom channel unit 10 includes a plurality of flow channels, a microchannel, and a discharge channel. The bottom channel portion 10 is formed of, for example, a glass material or a hard silicon material, and the plurality of channels and the microchannels are formed by a method such as etching, and the upper portions of the plurality of channels and the microchannels And is covered by the bottom channel portion of the material.

A reference fluid channel 13 through which a reference fluid passes is formed on one side of the bottom channel part 10 and a blood channel 14 through which blood flows is formed on a side opposite to the reference fluid channel.

The reference fluid is a fluid known in advance of viscosity and is a new-toned fluid which is not mixed with blood and has a constant viscosity regardless of the shear rate. In the present embodiment, the reference fluid may be phosphate buffered saline (PBS), but is not limited thereto.

The reference fluid channel 13 is formed by drilling a first vertical channel 11 communicating with a first damper to be described later in the thickness direction of the bottom channel part, And is configured to communicate with the flow path.

The blood channel 14 is formed by perforating a second vertical channel 12 communicating with a second damper (to be described later) in the thickness direction of the bottom channel portion, and is configured to communicate with the blood channel at an end portion thereof.

The reference fluid channel and the blood channel join together at a central portion of the bottom channel portion and communicate with the first chamber 15 as shown in Figs. 2 and 5. The reference fluid and the blood that have passed along the reference fluid channel and the blood channel are diverged in the first chamber so that the reference fluid flows from the left microchannel to the right side of Figure 2, From left to right.

A plurality of microchannels 16 are formed on the outer circumference of the first chamber. The microchannel 16 is formed with a very fine channel of, for example, 30 to 50 μm.

A second chamber (17) surrounding the outer circumferential surface of the microchannel and communicating with the microchannel is formed. The reference fluid and the blood, which have passed through the microchannel and used for the viscosity measurement, are temporarily stored in the second chamber.

In the present embodiment, the first chamber, the microchannel, and the second chamber are formed in a semicircular shape as shown in FIGS. 2 to 5, but the present invention is not limited thereto.

2 to 4, the reference fluid channel, the blood channel, the first chamber, the microchannel, and the second chamber are shown as being close to a plane, but the thickness of the reference fluid channel, the blood channel, Of course, not necessarily in a plane.

A plurality of discharge flow paths 18 are formed inside the outer peripheral surface of the second chamber. The plurality of discharge channels are formed by perforating the bottom channel part, one end communicating with the second chamber, and the other end communicating with a sludge storage unit described later.

In the case of forming the kit using only the bottom channel portion as in the above-described prior art, when the reference fluid and the blood are injected and the viscosity is measured, there is a fear that the reference fluid or the blood leaks through the discharge channel, There is a possibility that pulsation may occur between the vertical flow path and the flow path of the fluid and the viscosity measurement error may occur due to the bubbles contained in the reference fluid or blood.

Accordingly, the present invention includes a main body portion 20 provided on an upper portion of the bottom channel portion.

The main body part includes a damper part for preventing pulsation of a reference fluid or blood supplied to the vertical flow path, the reference fluid flow path, and the blood flow path and removing bubbles.

The damper unit includes a first damper (22) and a second damper (24).

The first damper 22 is formed so as to penetrate the main body part up and down. A reference fluid injection port 21 is provided at a substantially middle portion in the height direction of the first damper. An injection needle (not shown) is inserted into the reference fluid injection port, and a reference fluid supplied from a reference fluid supply source And is supplied to the first damper 22 through the reference fluid injection port. The lower surface of the first damper communicates with the first vertical flow path.

As shown in Figs. 3 and 5, the first damper is formed so that its planar shape has an arc portion 22a curved in an arc shape on both sides in the extending direction of the reference fluid injection port.

The second damper 24 is formed so as to penetrate the main body part vertically. An injection needle (not shown) is inserted into the blood injection port so that the blood supplied from the blood sample container is injected into the blood injection port and the blood injection port To the second damper (24). And the lower surface of the second damper communicates with the second vertical flow path.

The second damper is also formed such that its planar shape has a circular arc portion 24a curved in an arc shape on both sides in the extending direction of the blood injection port.

Thereby, the reference fluid or blood supplied from the outside is not supplied directly from the outside through the vertical flow path, and the reference fluid or blood supplied from the outside is firstly buffered in the damper, and then the reference fluid or the bubbles contained in the blood is supplied to the damper The bubbles of the reference fluid or blood can be removed by being accommodated in the space on the upper side of the injection port. In addition, by forming the arc portion in the damper, the supplied reference fluid or blood can be supplied smoothly and can pass through to the lower portion, so that there is no possibility of pulsation and precipitation of components such as lipids and proteins in the solution can be prevented .

A sludge storage unit 25 is provided on the rear side of the main body unit. In this embodiment, the sludge storage unit is provided by forming an empty space in the main body. As shown in Figs. 2 to 5, the sludge storage unit has a substantially rectangular shape in plan view along the shape of the outer peripheral surface of the second chamber And is configured to have a concave-cut shape.

And an arc-shaped inner side surface of the sludge storage portion is configured to communicate with a plurality of discharge flow paths installed upright inside the outer peripheral surface of the second chamber.

Thus, even when the reference fluid or the blood is supplied at a constant pressure, the reference fluid or the blood can be stably received without leakage of the reference fluid or the blood through the discharge channel, thereby enabling continuous infusion of blood.

On the other hand, a lid part 30 is provided on the upper part of the main body part. The lid part 30 is provided with an air passage hole 31 communicating with the sludge storage part and the outside of the blood viscosity measurement kit. By providing the air passage holes, it is possible to stably receive the reference fluid or the blood stored in the sludge storage portion through the discharge passage without being pressurized and flowing backward.

The lid portion 30 is preferably formed integrally with the main body portion 20.

In the present embodiment, the body portion and the lid portion may be formed of a soft material rather than the bottom channel portion. For example, the body portion and the lid portion may be formed of a liquid silicon material. The liquid silicon is injected into a mold having a predetermined shape and then cooled to form the body portion and the lid portion integrally.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to be exemplary and explanatory only and are not to be construed as limiting the scope of the inventive concept. And it is obvious that it is included in the technical idea of the present invention.

1: Blood viscosity measurement kit
10: bottom channel part
20:
22: first damper 24: second damper
25: sludge storage part
30:

Claims (6)

A reference fluid channel through which the reference fluid passes, a blood channel through which blood passes, a first chamber communicating with the blood channel and the reference fluid channel and branching the reference fluid and the blood, A second chamber surrounding and surrounding the outer circumferential surface of the microchannel and communicating with the microchannel; and a second chamber communicating with the second chamber and positioned inside the outer circumferential surface of the second chamber A bottom channel portion having a plurality of discharge flow paths to be installed;
A plurality of dampers for passing the reference fluid and the blood supplied from the outside and communicating with the reference fluid channel and the blood channel, and a plurality of dampers for communicating with the discharge channel and storing the reference fluid and the blood, And a sludge storage unit for supplying sludge to the sludge storage unit.
And a lid part installed on the upper part of the body part to cover the sludge storage part.
The air conditioner according to claim 1,
A reference fluid inlet through which the reference fluid is supplied,
A first damper communicating with the reference fluid inlet and the reference fluid passage;
A blood injection port through which the blood is supplied,
And a second damper communicating with the blood injection port and the blood flow path.
3. The method of claim 2,
Wherein the planar shape of the first damper and the second damper includes a circular arc portion in which a part of the inner wall is formed in an arc shape.
The method of claim 3,
Wherein the reference fluid injection port and the blood injection port are formed in the middle of the heights of the first damper and the second damper, respectively, and the space between the first damper and the second damper is filled with the reference fluid or the bubbles contained in the blood And a blood viscosity measuring device for measuring blood viscosity.
The method according to claim 1,
Wherein the lid part has an air passage hole communicating with the sludge storage part and the outside of the blood viscosity measurement kit.
The method according to claim 1,
Wherein the body portion and the lid portion are formed of a liquid silicone material, and the liquid silicone is injected into a mold and then cooled to form an integral body.

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