KR20090002540U - Fixing structure for fixing a bio-chip in analyzing device - Google Patents

Abstract

The present invention relates to a fixing structure for fixing a biochip, and more particularly, by accommodating the biochip in a standardized strip, and configured to facilitate the fastening and detachment to the slide door, the biochip alignment in the biochip analyzer The present invention relates to a fixing structure for fixing a biochip, which can be placed at a uniformly accurate position in time and can effectively shorten the time required for alignment. The fixing structure for fixing the biochip according to an embodiment of the present invention, the receiving groove for receiving the biochip and a strip having an opening; And a hook for penetrating the opening to fix the strip and transferring the strip into the biochip analysis device to align the biochip. The fixing structure for fixing the biochip according to the present invention has the effect of easily and easily aligning the biochip in the biochip analyzer. In addition, the fixing structure for fixing the biochip according to the present invention has an effect that can be uniformly positioned at the correct position when the biochip is aligned in the biochip analysis device, and shorten the time required for alignment.

Biochip, Protein Chip, Strip, Biochip Analyzer

Description

FIXING STRUCTURE FOR FIXING A BIO-CHIP IN ANALYZING DEVICE}

The present invention relates to a fixing structure for fixing a biochip, and more particularly, by accommodating the biochip in a standardized strip, and configured to facilitate the fastening and detachment to the slide door, the biochip alignment in the biochip analyzer The present invention relates to a fixing structure for fixing a biochip, which can be placed at a uniformly accurate position in time and can effectively shorten the time required for alignment.

A biochip is a hybrid device made of a conventional semiconductor chip by combining biological organisms such as enzymes, proteins, antibodies, DNA, microorganisms, animal and plant cells and organs, and nerve cells of a living body and inorganic materials such as semiconductors. Types of biochips include biosensor, DNA microarray, protein chip, cell chip, neuron chip, bio-insertion chip, and lab chip. There are research products of bioelectronics that develop at the boundary of biotechnology and electronics classified as on-a chip.

A protein chip is a chip in which dozens or hundreds of proteins are immobilized on a substrate. The technology of a protein chip is a technique of fixing a protein on a substrate and analyzing a protein immobilized on a chip.

Among them, methods for analyzing the binding of proteins attached to protein chips can be largely classified into a labeling assay and a non-labeling assay.

First, the label-type assay does not affect light absorption and transmissive properties of the protein alone. Therefore, the labeled assay is a method of measuring and quantifying the intensity of fluorescence expressed by attaching a fluorescent substance to the protein. The label-type assay allows stable analysis by selectively attaching a fluorescent dye (Dye) to the protein to be analyzed.

Labeled assay, when the protein chip is inserted into the measurement and analysis device, the cover is opened, and then fixed to a separate fixing step to analyze or by sucking the glass substrate in the form of a roller from the side, The process for disposing the protein chip is cumbersome, and there is a problem in that the chip substrate is damaged or foreign substances are introduced. In addition, since it takes a long time for the fixing of the protein chip, if you want to analyze a large number of protein chips, it is inefficient in terms of time.

Unlabeled analysis is a method of directly measuring the concentration of the protein attached to the protein chip by measuring only the mass, refractive index or density of the protein. Compared to the label-type analysis method, productivity is increased, and a small amount of sample can be used to measure in real time.

Representative methods used in the unlabeled analysis method include an analysis method using surface plasmon resonance, which is an optical principle, and an analysis method using optical interference. The analysis method using surface plasmon resonance utilizes a phenomenon in which light is irradiated to a protein chip to which proteins are conjugated, and light is absorbed by an object without reflecting light at a specific wavelength. On the other hand, the analysis method using the optical interference uses the interference phenomenon generated on the protein chip by irradiating the light wavelength on the biochip bonded protein.

When analyzing a protein object conjugated to a protein chip by an optical interference analysis method, it is possible to obtain a higher sensitivity than when analyzing a protein object conjugated to a protein chip by an analysis method using surface plasmon resonance. In addition, the method of analyzing optical interference is relatively simpler than the method of analyzing surface plasmon resonance, and the optical interference analyzer is cheaper than the surface plasmon resonance analyzer. As a result, it is more efficient and economical to analyze protein objects conjugated to protein chips using optical interference than using surface plasmon resonance.

On the other hand, the unlabeled assay also has the same problem as described above, since the cover is opened and the protein chip is fixed for the analysis of the protein chip like the labeled assay.

An object of the present invention is to provide a fixing structure for fixing a biochip that can easily and easily align the biochip in the biochip analysis device.

Another object of the present invention is to provide a fixing structure for fixing a biochip that can be placed at a precisely uniform position when the biochip is aligned in the biochip analyzer, and can effectively reduce the time required for the alignment.

A fixing structure for fixing a biochip according to an embodiment of the present invention for achieving the above object, a strip having a receiving groove and an opening for receiving the biochip; And a hook for penetrating the opening to fix the strip and transferring the strip into the biochip analysis device to align the biochip.

The hook may comprise a pair of inclined surfaces movable along a fixing jaw formed on an inner surface of the opening of the strip; And through the opening may be configured to include a locking jaw to fasten the strip by engaging the fixing jaw.

The slide door may be configured to further include a push bar that is connected to the pair of hooks, respectively, and adjusts an interval between the pair of hooks according to the pressure of the user.

The strip may further include a slide cover movably installed on an upper surface of the receiving groove in which the biochip is accommodated.

The strip may include a front end groove for fixing the front end of the slide door, and the slide door may include a protrusion coupled to the front end groove.

The slide door may include an elastic bar installed on the surface on which the strip is in close contact with the strip.

The elastic bar may be made of a spring.

The fixing structure for fixing the biochip according to the present invention has the effect of easily and easily aligning the biochip in the biochip analyzer.

In addition, the fixing structure for fixing the biochip according to the present invention has an effect that can be uniformly positioned at the correct position when the biochip is aligned in the biochip analysis device, and shorten the time required for alignment.

In addition, the fixing structure for fixing the biochip according to the present invention is provided with a slide cover, thereby preventing the introduction of foreign matter into the biochip, there is an effect that can improve the analysis accuracy.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to a fixing structure for fixing a biochip according to a preferred embodiment of the present invention.

1 is a perspective view showing a strip according to an embodiment of the present invention.

Referring to FIG. 1, the strip 100 of the present invention has a substantially rectangular box shape, an accommodation groove 150 for accommodating the biochip 110 to be analyzed, and a slide door 200 to be described later. Is provided with an opening 120 for engagement.

The slide cover 130 is slidably mounted on an upper surface of the accommodation groove 150. The slide cover 130 slides on the upper surface of the accommodating groove 150 in which the biochip 110 is accommodated, and selectively closes the upper portion of the biochip 110 so that foreign substances are introduced into the biochip 110. Block it. The state shown in the figure indicates a state in which the slide cover 130 is moved backward, so that the biochip 110 is opened for analysis of the biochip 110.

In addition, a front end groove 140 for coupling with the slide door 200 is formed on one side of the strip 100.

2 is a perspective view showing a slide door according to an embodiment of the present invention, Figure 3 is a perspective view showing the internal structure of a slide door according to an embodiment of the present invention.

2 and 3, there is shown a slide door 200 to which the strip 100 is engaged and disengaged.

The slide door 200 serves to move the strip 100 into a biochip analyzer (not shown) in a state in which the slide door 200 is coupled to the strip 100, and moves to protrude outwardly or to be stored in the biochip analyzer. It is possible to install.

The slide door 200 has a guide 250 for guiding movement into and out of the biochip analyzer. That is, the guide 250 guides the slide door 200 to move to a predetermined position (biochip analysis position) in the biochip analysis apparatus. Accordingly, when the strip 100 is standardized and coupled to the slide door 200, the biochip 110 in the strip 100 may be uniformly disposed in the biochip analyzer.

Meanwhile, the slide door 200 is connected to the pair of hooks 210 fastened to the opening 120 of the strip 100 and the tip groove 140 of the strip 100 to be coupled to the strip 100. It has a protrusion 230 that is fastened.

The hooks 210 are fastened through the opening 120 of the strip 100 to secure the strip 100 to the slide door 200. In the present embodiment, a pair of hooks 210 is illustrated, but the hooks 210 may be configured as one or three or more, and penetrate the openings 120 of the strips 100 so that the strips 100 may be separated. If the configuration to be fixed to the slide door 200 is sufficient, its shape is also not particularly limited.

The hook 210 is fastened and fastened to the fixing jaw 122 through the inclined surface 212 that is movable along the fixing jaw 122 formed on the inner surface of the opening 120 of the strip 100 and the opening 120. It may include a locking jaw (214).

The protrusion 230 is coupled to the tip groove 140 of the strip 100 to fix the tip of the strip 100, and the opening 120 of the strip 100 is connected to the hook 210 of the slide door 200. Assist in being placed in the corresponding position.

In addition, the slide door 200 has a pair of push bars 220 to adjust the distance between the pair of hooks 210 on both sides thereof. The push bar 220 is connected to each of the hooks 210, so that when the user applies pressure to the push bar 220, the gap between the hooks 210 connected to the push bar 220 is narrowed, and the pressure is released. The hook 210 then returns to its original position.

With the strip 100 coupled to the slide door 200, when the user presses the push bar 220, the hook 210 moves into the area formed by the opening 120 of the strip 100, thus The strip 100 may be separated from the slide door 200.

In addition, the slide door 200 has an elastic bar 240 that is elastically protruded on the surface on which the strip 100 is fixed. The elastic bar 240 facilitates separation of the strip 100 by elastically pressing the strip 100 away from the slide door 200. That is, when the user releases the hook 210 by pushing the push bar 220, the elastic bar 200 pushes up the strip 100 so that the strip 100 is separated from the slide door 200. At least one elastic bar 240 may be provided on a surface on which the strip 100 is in close contact. The type of elastic bar 240 is not particularly limited, and may be, for example, a spring.

In FIG. 3, the elastic bar 240 is connected to the push bar 220 by the connection bar 242, and the elastic bar 240 and the connection bar 242 may move together.

On the other hand, the elastic bar 240 does not need to be connected to the push bar 220 by the connection bar 242, etc., as described above is composed of a spring or the like, it may be operated separately from the push bar 220.

When the hook 210 is fastened to the strip 100 through the opening 120, the elastic bar 240 is compressed, causing elastic deformation. When the push bar 220 is pressed to release the hook 210 from the strip 100, the strip 100 is pushed up from the slide door 200 by the elastic restoring force of the elastic bar 240.

4A and 4B are views illustrating a process of coupling a strip and a slide door according to an embodiment of the present invention.

4A and 4B, the tip groove 140 of the strip 100 is coupled to the protruding portion 230 so that the pressure of the opening 120 is lowered while the position of the opening 120 corresponds to the position of the hook 210. In this way, the strip 100 is fastened to the hook 210. When the inclined surface 212 of the hook 210 moves along the fixing jaw 122 during tightening, the gap between the hooks 210 becomes narrow, and when the inclined surface 212 passes completely through the fixing jaw 122, the hook As the interval between the 210 is restored, the locking jaw 214 is coupled to the strip 100 to fix the strip 100 to the slide door 200.

The slide door 200 then transfers the strip 100 into the biochip analyzer. After the analysis of the biochip 110, the push bar 220 may be pressed to easily disassemble the strip 100, and the other strip may be easily coupled to the slide door 200 through the above process. Can be.

Preferred embodiments of the present invention are described for the purpose of illustration, and those skilled in the art having ordinary knowledge of the present invention will be capable of various modifications, changes, additions within the spirit and scope of the present invention, such modifications, changes and Additions should be considered to fall within the following utility model registration claims.

1 is a perspective view showing a strip according to an embodiment of the present invention.

2 is a perspective view illustrating a slide door according to an embodiment of the present invention.

3 is a perspective view showing the internal structure of a slide door according to an embodiment of the present invention.

4A and 4B are views illustrating a process of coupling a strip and a slide door according to an embodiment of the present invention.

Claims (7)

In the fixing structure for fixing the biochip to align the biochip to be analyzed in the biochip analyzer, A strip having a receiving groove for receiving the biochip and an opening; And And a hook for fixing the strip through the opening, and including a slide door for aligning the biochip by transferring the strip into the biochip analyzer. . The method of claim 1, The hook is made of a pair, An inclined surface movable along a fixing jaw formed in an inner surface of the opening of the strip; And And a locking jaw to fasten the strip by engaging the fixing jaw through the opening. The method of claim 2, wherein the slide door, And a push bar connected to the pair of hooks, respectively, and configured to adjust a distance between the pair of hooks according to the pressure of the user. The fixing structure of claim 1, wherein the strip further comprises a slide cover movably installed on an upper surface of a receiving groove in which the biochip is accommodated. The fixing structure for fixing the biochip according to claim 1, wherein the strip has a tip groove for fixing the tip of the slide door, and the slide door has a protrusion coupled with the tip groove. . The fixing structure of claim 1, wherein the slide door has an elastic bar that is elastically protruded on a surface on which the strip is in close contact. 7. The fixing structure of claim 6, wherein the elastic bar is made of a spring.

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