KR20240029996A - Vertical electrophoresis device for research with LED - Google Patents

Abstract

The present invention includes a storage tank (100) in which an electrolyte solution is accommodated; It is coupled to the receiving tank 100 so that the electrolyte solution can be introduced, provides a casting space for casting of the acrylamide gel, and irradiates the light source of the LED when separation of the sample protein through electrophoresis is performed to detect the sample protein. A gel panel 200 configured to visually confirm the separation process; A hole blocking member 410 configured at the front of the gel panel 200 to block the inflow of the electrolyte solution; And a pressure panel 420 that pressurizes the hole blocking member 410 to maximize sealing with the gel panel 200 and prevents the outflow of the acrylamide gel in the state before casting. It is characterized by providing a vertical electrophoresis device for research equipped with LEDs that can directly observe the sample movement process with the naked eye in real time by irradiating an LED light source in the electrophoresis stage.

Description

Vertical electrophoresis device for research with LED}

The present invention relates to a vertical electrophoresis device equipped with an LED for research purposes. More specifically, the process of moving the sample can be observed directly with the naked eye in real time by irradiating the LED light source at the initial electrophoresis stage of the sample, and during electrophoresis. It relates to a vertical electrophoresis device for research equipped with LEDs that can dramatically simplify the steps and processes performed, as well as significantly reduce the time and cost required for electrophoresis.

In general, electrophoresis means separating differently charged molecules in a sample by using an electric field to cause them to move at different speeds through a gel. In electrophoresis, separation is based on differences in charge and size between different molecules. Molecules with a high charge move faster than molecules with a low charge, and low molecular weight molecules move faster than high molecular weight molecules.

For example, in Republic of Korea Patent No. 10-1470733, a vertical electrophoresis system includes a gel caster having a plurality of storage units; A leak-proof gel casting device has been published, which is characterized by including a sealing pad that is inserted into the receiving part of the gel caster and is provided in a shape to surround both sides and the lower edge of the plate set.

However, according to the above-mentioned prior art literature, only one plate set can be combined with one sealing pad, so in order to perform separation work on various types of samples, a separate plate set and sealing pad are constructed for each type. This has to be done, and as a result, there is a risk of confusion in the names of various types of sample proteins separated through each plate set and sealing pad, which has the problem of increasing research costs.

In addition, according to the above-mentioned prior art literature, there is a problem in that it is difficult to determine the process in which the sample moves.

The background or prior art described herein is only intended to help understand the technical significance of the present invention, and does not mean technology that is widely known in the technical field to which this invention belongs before the application of the present invention.

Republic of Korea Patent No. 10-1470733

In order to solve this problem, the present invention was developed based on the above-mentioned background technology, and is equipped with an LED that allows direct visual observation of the sample movement process in real time by irradiating an LED light source at the initial electrophoresis stage of the sample. The purpose is to provide a vertical electrophoresis device for research.

In addition, the present invention enables gel hardening even without a separate gel casting device and simultaneously separates proteins while arranged in a row, thereby improving the convenience and efficiency of work during electrophoresis. The purpose is to provide a vertical electrophoresis device for research equipped with LEDs that can dramatically simplify the steps and processes performed.

Additionally, the purpose of the present invention is to provide a vertical electrophoresis device for research equipped with LEDs that can significantly reduce the time and cost required for electrophoresis.

However, the purpose of the present invention is not limited to this, and of course, even if not explicitly mentioned, purposes or effects that can be understood from the means of solving the problem or the embodiment are also included.

According to an embodiment of the present invention for achieving this problem, a receiving tank 100 in which an electrolyte solution is accommodated; It is coupled to the receiving tank 100 so that the electrolyte solution can be introduced, provides a casting space for casting of the acrylamide gel, and irradiates the light source of the LED when separation of the sample protein through electrophoresis is performed to detect the sample protein. A gel panel 200 configured to visually confirm the separation process; A hole blocking member 410 configured at the front of the gel panel 200 to block the inflow of the electrolyte solution; And a pressure panel 420 that pressurizes the hole blocking member 410 to maximize sealing with the gel panel 200 and prevents leakage of the acrylamide gel in the state before casting.

According to one embodiment of the present invention, the gel panel 200 is made of a transparent material, guides the electrolyte solution to flow in, and has a solution penetration hole 212 that is selectively sealed by the hole blocking member 410. ) is formed on the transparent panel 210 and the rear portion of the transparent panel 210 to form a gel receiving portion 310 in which the acrylamide gel is accommodated, and the outflow of the gel injected for separation of the sample protein is formed. A leak prevention panel 220 that prevents leakage, a detection filter 270 that is coupled to the rear of the leak prevention panel 220 and allows blue light in the 470 nm range to be irradiated while passing through, and the detection filter 270. An LED main body 260 is coupled to the rear part of the LED and emits LED light when power is applied, and a sample receiving part 320 is coupled to the rear part of the LED main part 260 and accommodates the sample protein. - a power panel 230 configured to supply power, a power supply unit 240 coupled to the rear of the power panel 230 and supplying + power to the receiving tank 100, It is characterized by including a comb 250 that is inserted into the upper part of the gel receiving portion 310 to form a space where the sample protein is located when casting the acrylamide gel.

According to one embodiment of the present invention, the transparent panel 210 is further provided with a sealing means 214 in close contact with the hole blocking member 410 on the outer peripheral surface of the solution penetration hole 212. do.

According to one embodiment of the present invention, the hole blocking member 410 is configured to be in close contact with the sealing member 214, and is an elastic sealing member 430 that seals the solution penetration hole 212 to block the outflow of the gel. ), and a close-fitting inclined panel ( 412).

According to one embodiment of the present invention, the pressure panel 420 moves downward along the slope of the close contact slope panel 412 and presses the hole blocking member 410 toward the solution penetration hole 212. It is characterized in that the panel 422 is further configured.

According to one embodiment of the present invention, the LED main body 260 includes a plurality of LED modules 262; A transparent window 264 that allows the light source of the LED module 262 to be transmitted forward and irradiated toward the detection filter 270; A movement guide 266 formed on the upper surface to guide the movement of the electrolyte solution; And an outflow blocking flange 268 that blocks the electrolyte solution from flowing out to the side.

According to one embodiment of the present invention, the vertical electrophoresis device for research equipped with the LED further includes a protective cover 130 that protects the operator's eyesight by adjusting the intensity of the light source emitted from the gel panel 200. It is characterized by:

According to one embodiment of the present invention, the protective cover 130 is characterized by being made of an orange acrylic filter.

According to one embodiment of the present invention, the gel pad 200 is composed of a plurality and is configured to be inserted into the receiving tank 100 in the horizontal direction.

According to one embodiment of the present invention, it further includes a fixing clip 400 configured to secure the plurality of gel pads 200 and connect them to each other.

According to this embodiment of the present invention, the process of moving the sample can be observed directly with the naked eye in real time by irradiating the LED light source in the initial electrophoresis stage of the sample.

According to an embodiment of the present invention, it is possible to solidify the gel even without a separate gel casting device, and at the same time, it is possible to separate proteins while arranged in a row, thereby improving the convenience and efficiency of the work. It has the effect of dramatically simplifying the steps and processes performed during electrophoresis.

According to an embodiment of the present invention, there is an effect of significantly reducing the time and cost required for electric melting.

In addition, the various and beneficial advantages and effects of the present invention are not limited to the above-described content, and may be more easily understood in the process of explaining specific embodiments of the present invention.

1 to 3 are perspective views showing a vertical electrophoresis device for research equipped with an LED according to an embodiment of the present invention;
Figure 4 is an exploded perspective view showing the gel panel of a vertical electrophoresis device for research equipped with LEDs according to an embodiment of the present invention;
Figure 5 is a combined cross-sectional view showing the gel panel of a vertical electrophoresis device for research equipped with an LED according to an embodiment of the present invention;
Figures 6 and 7 are perspective views showing the power panel of a vertical electrophoresis device for research equipped with LEDs according to an embodiment of the present invention;
Figure 8 is a diagram showing the combined structure of the gel panel of the vertical electrophoresis device for research equipped with LEDs according to an embodiment of the present invention;
Figure 9 is a cross-sectional view showing a coupling clip member of a vertical electrophoresis device for research equipped with an LED according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. First, when adding reference signs to components in each drawing, it should be noted that the same components are given the same reference numerals as much as possible even if they are shown in different drawings. Additionally, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

In addition, terms such as “include,” “comprise,” or “have” described below mean that the corresponding component may be included, unless specifically stated to the contrary, and thus do not exclude other components. Rather, it should be construed as being able to further include other components, and all terms, including technical or scientific terms, are generally used by those skilled in the art to which the present invention pertains, unless otherwise defined. It has the same meaning as understood. Additionally, when describing the components of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only used to distinguish the component from other components, and the nature, sequence, or order of the component is not limited by the term. When a component is described as being “connected,” “coupled,” or “connected” to another component, that component may be directly connected or connected to that other component, but there is another component between each component. It will be understood that elements may be “connected,” “combined,” or “connected.”

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings.

As shown, the vertical electrophoresis device for research equipped with an LED of the present invention includes a storage tank 100 in which an electrolyte solution is accommodated at the bottom and a plurality of gel panels 200 can be seated, and a storage tank 100. It is coupled to the tank 100, provides a space for casting of acrylamide gel, and is configured to improve the identification of the separated sample protein by irradiating the light source of the LED when separation of the sample protein is performed through electrophoresis. It is composed of a gel panel 200.

The receiving tank 100 is configured to form a partition wall 110 in the center so that a plurality of gel panels 200 are arranged in the transverse direction of the receiving tank 100 to simultaneously perform the separation process for various types of sample proteins. It is designed so that you can check it.

In addition, in the above-mentioned dividing partition wall 110, the electrolyte solution contained in the front or rear end moves to each receiving space divided by the dividing partition wall 110, and the same amount of electrolyte solution is stored in each receiving space. It is preferable that a solution movement path 120 is further configured to accommodate the solution.

On the other hand, as shown in FIG. 3, the electrophoresis device of the present invention has a protection device that protects the operator's eyesight by adjusting the intensity of light (light source) emitted from the LED body portion 260 of the gel panel 200, which will be described later. A cover 130 is formed.

The protective cover 130 may be made of an orange acrylic filter, and its upper surface is detachably coupled to the power panel 230, which will be described later, and is inclined forward at a predetermined angle to be located in the front of the transparency panel 210. It is configured to adjust the intensity of the light of the LED passing through the transparent panel 210.

At this time, adjusting the intensity of the light of the LED means weakening the intensity of the light, and in the initial electrophoresis stage of the sample, the light source of the LED is illuminated so that the process of moving the sample can be directly observed with the naked eye in real time. At the same time, it means protecting the operator's eyesight from being damaged by the light source of the LED during observation.

The gel panel 200 is composed of a plurality of identical shapes, and is coupled to a transparent panel 210 made of a transparent material so that the separation process of the sample protein can be seen through, and the rear part of the transparent panel 210, and the sample protein A leak prevention panel 220 that prevents the outflow of the injected gel for separation, and a detection filter 270 that is coupled to the rear part of the leak prevention panel 220 and allows blue light in the 470 nm range to be irradiated while passing through. , an LED body unit 260 that is coupled to the rear portion of the detection filter 270 and emits LED light when power is applied, and a space that is coupled to the rear portion of the LED body portion 260 and accommodates the sample protein. Provided, - a power panel 230 configured to supply power, coupled to the rear portion of the power panel 230, and supplying - power to the power panel 230, while receiving + power. It is inserted into the casting space formed between the power supply unit 240 that supplies to the tank 100, the transparency panel 210, and the leak prevention panel 220, and forms a space where the sample protein is located when casting the acrylamide gel. It is configured to include a comb 250.

The viewing panel 210 is a panel formed in the front part of the gel panel 200 and provides a casting space so that the acrylamide gel can be cast, while allowing an electrolyte solution to flow in for separation of sample proteins. , It is configured to enable real-time confirmation of the separation process of the sample protein.

This transparent panel 210 is configured to provide a predetermined casting space so that acrylamide gel is injected and casted (hardened).

At this time, the transparency panel 210 is located at the bottom of the front side, and the electrolyte solution contained in the receiving tank 100 is a casting space formed between the transparency panel 210 and the leak prevention panel 220, that is, the gel in which the acrylamide gel is accommodated. A solution penetration hole 212 is formed to guide the solution to flow into the receiving portion 310.

The solution penetration hole 212 allows the electrolyte solution contained in the receiving tank 100 to flow into the solution penetration hole 212, and the upper surface of the rear portion thereof is formed to be inclined upward so that the introduced electrolyte solution can move upward.

In addition, the transparency panel 210 is configured so that the front part of the leak prevention panel 220 is tightly coupled to the rear part and at the same time a sealing member is closely adhered and inserted to provide sealing on both sides and the lower surface of the gel receiving part 310. It is structured so that it can be done.

Preferably, the transparent panel 210 is configured so that the sealing member is located on the lower and both sides of the solution penetration hole 212, and the upper surface is maintained in an open state to allow insertion and separation of the comb 250. It is structured so that it can be easily accomplished.

Meanwhile, the transparent panel 210 is equipped with a hole blocking member 410 that selectively seals the solution penetration hole 212, and the hole blocking member 410 is pressurized to maximize the airtightness of the solution penetration hole 212. A pressure panel 420 may be further configured to prevent leakage of the acrylamide gel before casting.

The hole blocking member 410 serves to block the outflow of the gel by sealing the solution penetration hole 212 before injection into the gel receiving portion 310 for casting of acrylamide gel. An elastic sealing member 430 having a predetermined elastic force is combined and disposed in the space between the receiving tank 100 and the transparent panel 210, and is in close contact with the sealing means 214 formed on the outer side of the solution penetration hole 212. It's very combined.

In addition, the hole blocking member 410 receives a predetermined pressing force from the pressing panel 420, and a close-fitting inclined panel 412 is formed at the front of the hole blocking member 410 to bring the elastic sealing member 430 into close contact with the sealing means 214 side.

The pressure panel 420 is coupled between the receiving tank 100 and the hole blocking member 410 in a fitting manner, and transmits a predetermined pressing force to the hole blocking member 410, and when coupled, the close-fitting inclined panel 412 ) A pressure inclined panel 422 is formed that presses the hole blocking member 410 toward the solution penetration hole 212 of the transparent panel 210 while moving downward along the inclined surface.

The pressure inclined panel 422 is formed integrally with the rear portion of the pressure panel 420 and is configured to have a slope corresponding to the close contact inclined panel 412.

The leak prevention panel 220 is coupled to the rear part of the viewing panel 210, provides a casting space where acrylamide gel is cast, and allows sample proteins to be introduced into the gel receiving portion 310 through the upper surface. A space for sample input is provided.

This leak prevention panel 220 may be made of a panel made of a transparent material, and its rear part is equipped with a detection device that allows only blue light from the light source emitted from the LED body 260 to pass through and be irradiated toward the transparent panel 210. Filter 270 is coupled.

At this time, the detection filter 270 is configured so that only blue light in the 470 nm band can be irradiated among the light sources emitted from the LED main body 260, and prevents scattering of the light source emitted from the LED main body 260 and uses a grid to prevent the scattering of the light source emitted from the LED main body 260. An anti-scattering film may be attached to the front portion to allow the light source to spread evenly.

When electrophoresis is performed, the LED main body 260 emits a light source toward the viewing panel 210, allowing the operator to check the separation process of the sample protein in real time, while providing identification of the sample protein separation process. It is a component that can be maximized and confirmed with the naked eye.

This LED main body 260 is equipped with a plurality of LED modules 262 inside, and a power cable for applying power to the LED modules 262 is provided on one side.

In addition, a transparent window 264 is formed in the front of the LED body 260 to allow the light source to be transmitted toward the detection filter 270, and a sealing member is formed along the outer peripheral surface of the transparent window 264. is combined to ensure close coupling with the detection filter 270, while preventing the electrolyte solution and sample protein from leaking out.

In addition, the LED main body 260 is preferably treated with silicone waterproofing to prevent electric leakage of the LED module 262, but is not limited thereto.

In addition, the LED body portion 260 serves as a dividing panel that divides the gel accommodating portion 310 and the sample accommodating portion 320, and at the same time, the electrolyte solution passing through the gel accommodating portion 310 flows into the sample accommodating portion. It is configured to allow the electrolyte solution to flow into (320) and to perform electrophoresis as the introduced electrolyte solution reflows into the gel receiving portion 310 together with the sample protein.

That is, a movement guide portion 266 is formed on the LED body portion 260 to guide the movement of the electrolyte solution to its upper surface.

In particular, both sides of the movement guide portion 266 are formed to extend upward, and block the electrolyte solution flowing into and passing through the gel accommodating portion 310 and moving toward the sample accommodating portion 320 from flowing out to the side. A blocking flange 268 is formed.

The power panel 230 is tightly coupled to the rear part of the LED main body 260 and forms a sample receiving portion 320 in which the electrolyte solution that has passed through the gel receiving portion 310 is accommodated and stored. By supplying current to the electrolyte solution contained in the part 320, the sample protein introduced into the gel receiving part 310 can be moved to the upper part of the gel receiving part 310 and re-introduced. It is configured so that it consists of a front power panel 232 and a rear power panel 234.

The front power panel 232 is coupled to the rear part of the LED main body 260 and has an open top so that the sample receiving part 320 and the movement guide part 266 of the LED main body 260 are provided. They are formed to communicate with each other and are configured to allow the inflow and outflow of electrolyte solutions and sample proteins.

The front power panel 232 is provided with a leak prevention means 236 that seals the space between the LED main body 260 and the sample receiving portion 320 to prevent the electrolyte solution and sample protein from leaking. At this time, the leak prevention means 236 may be a rubber packing, but is not limited thereto.

Here, the leak prevention means 236 has been described as being formed in the front part of the front power panel 232, but it is not limited to this, and is also formed in the rear part to accommodate the sample formed by combining with the rear power panel 232. It is configured to maximize the sealing force of the unit 320.

The rear power panel 234 is coupled to the front power panel 232, and a predetermined space is provided in the center of the front side to form a sealing surface for the rear part of the sample receiving unit 320, and into this predetermined space - current The wire housing 245 is coupled to ensure the supply of.

In this rear power panel 234, a packing insertion groove 234a is formed into which the above-described leak prevention means 236 is inserted and fixed, and this packing insertion groove 234a is formed on both sides and the bottom of the sample receiving unit 320. It is configured to maximize the sealing power.

In addition, the rear power panel 234 is integrated with the power supply unit 240 at the rear and is configured to supply + power and - power.

The power supply unit 240 is connected by a power supply cable, etc. to receive + power and - power, respectively, and supplies the supplied + power and - power to the electrolyte solution stored in the receiving tank 100 to prepare the sample protein by electrophoresis. It is configured so that a separation process can occur.

This power supply unit 240 is composed of a power main body 242 that is seated in the receiving tank 100 and a fixing block 244 that fixes the gel panel 200 to the receiving tank 100, and an upper part of the fixing block. In addition, the power supply terminal 246 is connected to the + supply part and the - supply part of the power supply cable individually, and the power line 248 is connected to the power terminal 246 to supply + power and - power to the electrolyte solution, respectively. It consists of:

Here, the fixed block 244 is composed of two pieces, spaced apart from each other by a predetermined distance, so that the + terminal portion 246a and the − terminal portion 246b of the power terminal 246 are individually coupled to each other.

In addition, the fixing block 244 may be further configured with a fixing groove on its lower surface so that it can be seated on the flange part of the receiving tank 100 and fixed to the receiving tank 100.

In addition, the power line 248 is composed of a + power line 248a and a - power line 248b connected to the + terminal part 246a and - terminal part 246b, respectively.

The + power line 248a is configured to have one side inserted into the inside of the power main body 242 and the fixing block 244 and connected to the + terminal portion 246a, and the other side is a power source configured at the lower part of the power main body 242. It is fixed to the fixing part 247 and is exposed to the outside, so that when power is supplied + power is supplied directly to the electrolyte solution stored inside the receiving tank 100, and the electrolyte solution is formed in the transparent panel 210. It is configured to allow inflow into the interior of the gel receiving portion 310 through the penetration hole 212.

At this time, the electrolyte solution supplied with + power passes through the acrylamide gel cast in the gel receiving portion 310 and passes through the gel receiving portion 310 to the movement guide portion 266 of the LED body portion 260. It is configured to move to the sample receiving unit 320 through .

- The power line 248b passes through the rear power panel 234, is connected to the power housing 245 coupled to the inner space of the rear power panel 234, and forms a sample receiving portion 320 corresponding to the inner space. To the side - supply power.

At this time, - when power is supplied, the electrolyte solution introduced through the movement guide part 266 moves toward the gel receiving part 310 while passing through the movement guide part 266 and enters the chamber formed by the comb 250. Injection is performed, and then the sample protein introduced into the chamber passes through the acrylamide gel cast by the injected electrolyte solution to separate the molecules, and only the electrolyte solution passes through the cast acrylamide gel to form a solution. The outflow occurs into the receiving tank 100 through the penetration hole 212.

This power line 248 may be composed of a typical platinum line, but is not limited thereto.

Meanwhile, the comb 250 of the present invention is formed with a flange portion seated on both upper sides of the transparent panel 210 and extending downwardly from the lower part of the flange portion, and is composed of a plurality of combs spaced at a predetermined distance to collect the sample protein. A chamber forming portion is constructed that forms a chamber through which injection will take place.

On the other hand, as shown in FIGS. 8 and 9, the vertical electrophoresis device for research equipped with an LED of the present invention includes a transparency panel 210 of the gel panel 200 arranged in the horizontal direction, a leakage prevention panel 220, A fixing clip that maintains a tighter bond between the power panel 230, detection filter 270, and LED body 260 to further maximize the effect of preventing leakage of acrylamide gel, electrolyte solution, and sample protein. 400) may be further configured.

The fixing clip 400 includes a first fixing clip 402 coupled to one side of the outer portion of the first and second gel pads 200a and 200b disposed laterally, and the first and second gel pads ( It is disposed between 200a and 200b, is configured at a position opposite to the first fixing clip 402, and is simultaneously combined with the first and second gel pads 200a and 200, and the first and second gel pads 200a It consists of a second fixing clip 404 connecting , 200b).

Here, the first and second fixing clips 402 and 404 grip one side and the other side of the transparent panel 210 and the power panel 230, respectively, and provide a predetermined pressing force to hold the transparent panel 210 and the power panel 230. It is configured to prevent the power panel 230 and the leakage prevention panel 220, detection filter 270, and LED body portion 260 configured between the transparent panel 210 and the power panel 230 from being separated.

The first fixing clip 402 includes a first clip body 410 that is formed in a 'ㄷ' shape so that the outer surfaces of the transparent panel 210 and the power panel 230 can be inserted, and this first clip body A support panel 430 is formed on the rear side of the power panel 230 and is in close contact with the outer surface of the power panel 230 to press the power panel 230 with a predetermined pressing force, and the support panel 430 is connected to the first clip body. It is connected to 410, is screwed together with an adjustment member 440 that adjusts the position of the support panel 430, and the first clip body 410, and presses the rear portion of the support panel 430 to create a transparent panel ( 210) and a fixing means 450 configured to enable coupling of the gel pad 200 including the power panel 230 and the first fixing clip 402.

The second fixing clip 404 fixes the other side of the first and second gel pads 200a and 200b that are not fixed by the first fixing clip 402 and simultaneously fixes the first and second gel pads 200a. , 200b), the second fixed body 420 is formed so that both sides are open, and the support panel 430 is formed on the rear side.

At this time, the second fixing body 420 is configured to connect the support panel 430 and the adjusting member 440 while the above-described adjusting member 440 penetrates, and the gel pad 200 and the first fixing body 420 are provided. A fixing means 450 configured to allow the clip 402 to be coupled is provided.

That is, the second fixing body 420 is composed of a support panel 430, an adjustment member 440, and a fixing means 450 on both sides of the rear portion, respectively.

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications and variations will be possible to those skilled in the art without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but are for illustrative purposes, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be construed as being included in the scope of rights of the present invention.

100: Receiving tank 110: Split bulkhead
120: Solution movement path 130: First detection filter
200: gel panel 210: transparent panel
212: solution penetration hole 214: sealing means
220: Leak prevention panel 230: Power panel
232: Front power panel 234: Rear power panel
234a: Packing insertion groove 240: Power supply unit
242: Power main body 244: Fixed block
245: wire housing 246: power terminal
247: wire fixing part 248: power line
250: Comb 260: LED main body
270: Detection filter 310: Gel receptor
320: Sample receiving part 400: Fixing clip
402: 1st fixing clip 404: 2nd fixing clip
410: 1st clip body 420: 2nd clip body
430: support panel 440: adjustment member
450: Fixing means

Claims (8)

A receiving tank (100) containing an electrolyte solution;
It is coupled to the receiving tank 100 so that the electrolyte solution can be introduced, provides a casting space for casting of the acrylamide gel, and irradiates the light source of the LED when separation of the sample protein through electrophoresis is performed to detect the sample protein. A gel panel 200 configured to visually confirm the separation process;
A hole blocking member 410 configured at the front of the gel panel 200 to block the inflow of the electrolyte solution; and
A pressure panel 420 that pressurizes the hole blocking member 410 to maximize sealing with the gel panel 200 and prevents leakage of the acrylamide gel in the state before casting;
A vertical electrophoresis device for research equipped with an LED, comprising:
According to paragraph 1,
The gel panel 200 is
A transparent panel 210 made of a transparent material and formed with a solution penetration hole 212 that guides the electrolyte solution to flow in and is selectively sealed by the hole blocking member 410;
A leak prevention panel 220 is coupled to the rear portion of the transparency panel 210 to form a gel receiving portion 310 in which the acrylamide gel is accommodated, and prevents leakage of the gel injected for separation of sample proteins; ,
A detection filter 270 coupled to the rear portion of the leak prevention panel 220 and allowing blue light in the 470 nm range to be irradiated while passing through,
An LED body unit 260 that is coupled to the rear part of the detection filter 270 and emits LED light when power is applied,
A power panel 230 is coupled to the rear portion of the LED body 260 and forms a sample accommodating portion 320 in which the sample protein is accommodated, and is configured to supply power;
A power supply unit 240 coupled to the rear portion of the power panel 230 and supplying + power to the receiving tank 100,
A comb 250 is inserted into the upper part of the gel receiving portion 310 to form a space where the sample protein is located when casting the acrylamide gel.
A vertical electrophoresis device for research equipped with an LED, comprising:
According to paragraph 2,
In the transparent panel 210,
A vertical electrophoresis device for research equipped with an LED, characterized in that a sealing means (214) in close contact with the hole blocking member (410) is further formed on the outer peripheral surface of the solution penetration hole (212).
According to paragraph 3,
The hole blocking member 410 is
An elastic sealing member 430 that is configured to be in close contact with the sealing member 214 and blocks the outflow of the gel by sealing the solution penetration hole 212;
A close-fitting inclined panel 412 configured at a position opposite to the elastic sealing member 430 and receiving a predetermined pressing force from the pressing panel 420 to bring the elastic sealing member 430 into close contact with the sealing means 214.
A vertical electrophoresis device for research equipped with an LED, comprising:
According to clause 4,
The pressure panel 420 is
Equipped with an LED, characterized in that the pressure inclined panel 422 is further configured to press the hole blocking member 410 toward the solution penetration hole 212 while moving downward along the inclined surface of the close contact inclined panel 412. Vertical electrophoresis device for research purposes.
According to paragraph 2,
The LED main body 260 is
Multiple LED modules (262);
A transparent window 264 that allows the light source of the LED module 262 to be transmitted forward and irradiated toward the detection filter 270;
A movement guide 266 formed on the upper surface to guide the movement of the electrolyte solution; and
An outflow blocking flange (268) that blocks the electrolyte solution from flowing out to the side;
A vertical electrophoresis device for research equipped with an LED, comprising:
According to paragraph 1,
The vertical electrophoresis device for research equipped with the LED,
It further includes a protective cover 130 that protects the operator's eyesight by adjusting the intensity of the light source emitted from the gel panel 200,
The protective cover 130 is a vertical electrophoresis device for research equipped with an LED, characterized in that it is made of an orange acrylic filter.
According to paragraph 1,
The gel pad 200 is composed of a plurality of pieces and is configured to be inserted laterally into the receiving tank 100,
A vertical electrophoresis device for research equipped with an LED, further comprising a fixing clip 400 configured to secure the plurality of gel pads 200 and connect them to each other.