JP2007147447A - Gel cutter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a gel cutter capable of obtaining a plurality of electrophoretic gels having a predetermined size and capable of being washed easily. <P>SOLUTION: A large number of guide pieces 12 are externally provided to an attaching shaft 13 in a freely sliding state and the attaching shaft 13 is attached to a base 11 in a freely detachable manner in a state that the respective guide pieces 12 are arranged at a predetermined interval and the upper end surfaces 26 of them are arranged. A large number of cutting blades 33 are attached to a cutter part 30 so as to be arranged between the adjacent guide pieces 12 and the electrophoretic gels G are placed on the upper end surfaces 26 of the respective guide pieces 12 of the base stand 10 wherein the attaching shaft 13 is attached to the base 11. The respective cutting blades 33 of the cutter part 30 are inserted between the respective guide pieces 12 to obtain a large number of the electrophoretic gels G cut into a predetermined size. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a gel cutter that cuts an electrophoresis gel used for analyzing or observing proteins, nucleic acids (DNA), and the like into a predetermined size.

  In general, electrophoresis gels are widely used for analyzing and observing proteins and nucleic acids (DNA), and are cut into a predetermined size according to the purpose of the analysis and observation.

  As an apparatus for cutting this electrophoresis gel, conventionally, the electrophoresis gel is placed between a pair of guide wall bodies on the gel mounting table, and the electrophoresis gel is sandwiched between the pair of stopper plate bodies, so that a predetermined cutting position is obtained. There is one in which an electrophoresis gel is cut by moving a wire as a cutting tool along an insertion groove formed in a guide wall body (see FIG. 1 of Patent Document 1).

Japanese Patent Laid-Open No. 5-223780

  The apparatus described in Patent Document 1 described above must cut the electrophoresis gel by moving the wire as the cutting tool one by one among the insertion grooves provided at a plurality of locations on the guide wall body. In other words, there is a problem that cutting takes time and effort.

  In addition, a groove through which the wire of the cutting tool passes when the electrophoresis gel is cut is formed on the gel mounting table, and when the electrophoresis gel is cut, a part of the electrophoresis gel attached to the wire of the cutting tool However, when the wire passes through the groove, it adheres to the inner wall. Since this gel mounting table cannot be moved to widen the groove, there is a problem that a part of the electrophoresis gel attached to the inner wall of the groove cannot be easily washed away.

  Accordingly, an object of the present invention is to obtain a plurality of electrophoresis gels having a predetermined size and to obtain a gel cutter that can be easily washed.

  In order to solve the above-described problems, the present invention attaches a mounting shaft in which a plurality of guide pieces are slidably inserted in a detachable manner in a state where the guide pieces are arranged at a predetermined interval and the upper end surfaces thereof are aligned. And a plurality of cutter parts attached in a state where the cutting blades are arranged between the adjacent guide pieces.

  In this way, the electrophoresis gel is placed on the upper end surface of each guide piece, and the cutting blades of the cutter unit are inserted between the guide pieces, thereby obtaining a plurality of electrophoresis gels cut at intervals between the guide pieces. be able to.

  In addition, after the electrophoresis gel is cut by the cutter part, the mounting shaft through which the plurality of guide pieces are inserted can be removed from the base, and each guide piece of the mounting shaft can be slid to widen the interval. The electrophoresis gel attached to the guide piece can be washed away.

  In the above configuration, when the upper end surface of each guide piece is formed to be inclined downward in a direction perpendicular to the mounting shaft, the cut electrophoresis gel can be easily moved along the inclined upper end surface of each guide piece. It can be taken out.

  Moreover, it can also be set as the structure by which the chevron-shaped guide part which inclines downward toward some clearance gaps with the said guide piece arrange | positioned adjacently is formed in a part of upper end surface of each said guide piece. In this way, when cutting the electrophoresis gel by inserting the cutting blade of the cutter part between the guide pieces, even if the position of the cutting blade is slightly shifted, the cutting blade is a chevron with the upper end surface formed. It moves between each guide piece along the slope. For this reason, it is not necessary to strictly align the cutter part, and the electrophoresis gel can be easily cut.

  When the mounting shaft is provided with a holding means for holding the guide pieces in a state of being arranged at a predetermined interval, when the mounting shaft is attached to the base, the guide pieces are pressed so as not to widen. Since it is not necessary, the mounting shaft can be easily mounted on the base.

  Since the present invention is configured as described above, a plurality of electrophoresis gels having a predetermined size can be obtained and can be easily washed.

Embodiments of the present invention will be described below with reference to the accompanying drawings.
A gel cutter according to an embodiment of the present invention is shown in FIGS. As shown in FIG. 1, the gel cutter according to this embodiment includes a base 10 on which the electrophoresis gel G is placed and a cutter unit 30 that cuts the electrophoresis gel G on the base 10 into a predetermined size. Is done.

  As shown in FIG. 2, the base 10 includes a plate-like base 11, a mounting shaft 13 in which a plurality of guide pieces 12 are slidably inserted between a pair of sandwiching plates 15 a and 15 b, and the mounting shaft 13. The guide pieces 12 are arranged at predetermined intervals, and the insertion piece 14 is attached to the base 11 with the upper end surfaces thereof aligned.

  The base 11 is formed in a rectangular shape, and a pair of positioning plates 16 and 16 are fixed to face each other in the vicinity of both ends on the short side of the upper surface. A stopper plate 17 is fixed in the long side direction of the base 11 between the pair of positioning plates 16 and 16. Support legs 29 for supporting the base 11 are attached to the four corners of the lower surface of the base 11. A locking tool 18 is provided below the pair of positioning plates 16 and 16.

  The locking tool 18 includes a ball 20 inserted into a tubular member 19 that passes through each positioning plate 16 in the long side direction of the base 11, and a spring 21 that partially protrudes the ball 20 from the opposing surface of the positioning plate 16. It is biased and locked inward (see FIG. 6).

  The ball 20 of the locking tool 18 engages with a recess 35 provided on the outer surface of the lower part of a pair of sandwiching plates 15a and 15b described later. Thereby, the attachment shaft 13 in which the plurality of guide pieces 12 are inserted between the pair of sandwiching plates 15a and 15b can be detachably attached between the pair of positioning plates 16 and 16.

  As shown in FIG. 3, the mounting shaft 13 has one sandwiching plate 15a fixed at one end, a predetermined number of guide pieces 12 are slidably inserted through a spacer 22, and the other end is sandwiched by a sandwiching plate 15b. Is inserted. Guide plates 37 are fixed to the opposing surfaces of the pair of sandwich plates 15a and 15b by screws 38, respectively. The guide plate 37 is arranged such that its upper end is higher than the upper ends of the pair of sandwiching plates 15a and 15b. The temporary fixing nut 39 is screwed into the mounting shaft 13 outside the sandwiching plate 15b, and the cap nut 23 is further screwed. The temporary fixing nut 39 is a holding means that can hold the guide pieces 12 inserted through the mounting shaft 13 in a state where they are arranged at intervals of the spacers 22 by screwing them.

  Further, as shown in FIG. 6, the mounting shaft 13 is set to a length that the end portion on the side of the cap nut 23 is surplus by the thickness of the positioning plate 16 with the mounting shaft 13 mounted on the base 11. It is what is done. If it does in this way, the said clamping board 15b can be slid to the excess part of this attachment axis | shaft 13, and the space | interval of a pair of clamping boards 15a and 15b can be expanded (refer FIG. 3). Thereby, after the electrophoresis gel G is cut, the mounting shaft 13 is removed from the pair of positioning plates 16, and the temporary fixing nut 39 is loosened, whereby the interval between the guide pieces 12 can be increased. For this reason, the electrophoresis gel G adhering to each guide piece 12 can be easily washed away.

  Each guide plate 37 has a width equal to the short side length A of the guide piece 12 (see FIG. 4). In the state where the mounting shaft 13 is mounted on the base 10, the guide plates 37 are in contact with the guide pieces 12 disposed at both ends of the mounting shaft 13. For this reason, when cutting the electrophoresis gel G, the cutter blades 30 are moved downward while the cutting blades 33 arranged at both ends in the cutter member 30 are placed along the opposing surfaces between the opposing guide plates 37. Can be moved. Thereby, each cutting blade 33 can be easily guided between the adjacent guide pieces 12.

  Further, the mounting shaft 13 is held in a state where the upper end surfaces of the guide pieces 12 are aligned and the distance between them is the thickness of the spacer 22 by tightening the temporary fixing nut 39 to the sandwiching plate 15b. This eliminates the need to hold the pair of sandwiching plates 15a and 15b inward so that the distance between the guide pieces 12 does not increase, so that the attachment shaft 13 can be easily attached to the base 11.

  As shown in FIG. 4, the pair of sandwiching plates 15 a and 15 b are formed so that the width thereof is equal to the short side length A of the guide piece 12. For this reason, a pair of sandwiching plates 15a and 15b of the mounting shaft 13 is sandwiched between the stopper plate 17 of the base 11 and a support plate 28 of the insertion member 14 described later, and the upper end surfaces of the respective guide pieces 12 It can be set as the state which became complete. A recess 35 that engages with the ball 20 of the locking tool 18 described above is provided at the lower part of the pair of sandwiching plates 15a and 15b (see FIG. 3).

  As shown in FIG. 2, the guide piece 12 is formed in a plate-like rectangle and is provided with a through hole 24 through which the mounting shaft 13 is inserted. A chevron-shaped guide portion 25 that is inclined downward toward a gap with the adjacent guide piece 12 is formed in a part near the long side of the end surface on one short side. As a result, when the electrophoresis gel G is cut, even if the position of the cutting blade 33 of the cutter unit 30 to be described later is slightly deviated, the cutting blade 33 moves along the inclination of the guide portion 25 on which the upper end surface is formed. Move between the guide pieces 12. For this reason, the exact alignment of the cutter part 30 becomes unnecessary, and the electrophoresis gel G can be cut | disconnected easily.

  On the end surface where the guide portion 25 is provided, a gel placement portion 26 is formed that is inclined in a direction perpendicular to the mounting shaft 13, that is, downward as the distance from the guide portion 25 increases. Since the gel mounting portion 26 is inclined downward, the cut electrophoresis gel G can be easily taken out.

  The spacers 22 provided between the guide pieces 12 are formed in a ring shape having the same thickness as that of a cutting blade 33 of the cutter unit 30 described later. The material is preferably a material having good water resistance and solvent resistance, such as Teflon.

  As shown in FIG. 2, the insertion member 14 is a combination of an insertion plate 27 and a support plate 28 at a right angle. The length of the insertion plate 27 is equal to the distance between the pair of sandwiching plates 15a and 15b when the mounting shaft 13 is mounted on the base 11 with the guide pieces 12 arranged at a predetermined interval and the upper end surfaces aligned. Length. (See FIG. 6). The thickness of the insertion plate 27 is equal to the distance between the lower end surface of each guide piece 12 and the upper surface of the base 11 when the attachment shaft 13 is attached to the base 11 in the above state (see FIG. 4). ).

  The length of the support plate 28 is equal to the length between the pair of positioning plates 16 and 16 of the base 11 (see FIG. 1), and the height is equal to the height of the stopper plate 17 of the base 11. Are formed equally (see FIG. 4). Thereby, the said insertion member 14 can be inserted in the base 11 in the state which aligned each guide piece 12 with the said gel mounting part 26 in the upper end part.

  At this time, the height of the stopper plate 17 of the base 11 (the height of the support plate 28 of the insertion member 14) is determined by inserting the cutter unit 30 into the base 10 and cutting the electrophoresis gel G. The upper end portion of the cutting blade 33 of the cutter unit 30 is set to a height at which the upper end portion is positioned below the gel placement portion 26 of the guide piece 12. Thereby, it can prevent that the cut | disconnected electrophoresis gel G adheres to the cutting blade 33 of the cutter part 30. FIG.

  As shown in FIG. 1, the cutter unit 30 for cutting the electrophoresis gel G includes a rectangular frame 31, two support bars 32 attached in the long side direction of the frame 31, and the two support bars 32. Consists of a plurality of cutting blades 33 inserted into both ends, and a spacer 34 disposed between the cutting blades 33.

  The frame 31 is formed in a rectangular shape by a fixture 36 by combining two sets of two plate members having the same length. Two support bars 32 are fixed in parallel in the long side direction inside the frame 31. A plurality of cutting blades 33 are attached between the two support bars 32 in a state where the support bars 32 are inserted at both ends thereof.

  Each of the cutting blades 33 is formed of a metal plate and has the same thickness as the spacer 22 attached between the guide pieces 12 of the attachment shaft 13. A spacer 34 is disposed between the adjacent cutting blades 33 while being inserted through the support bar 32.

  The spacer 34 is formed in a ring shape, has a thickness equal to the thickness of the guide piece 12, and is rotatably inserted into the support rod 32. The distance between the spacers 34 inserted into the two support rods 32 on both sides of the cutting blade 33 is set to the length of the short side length A of the guide piece 12 (see FIG. 4). Since the spacer 34 is rotatably inserted into the support bar 32, when the electrophoresis gel G is cut by the cutter unit 30, the spacer 34 is connected to the side end surface of the guide piece 12 (the left and right end surfaces in FIG. 4). ) While rotating. Accordingly, the plurality of guide pieces 12 can be guided and inserted between the spacers 34 inserted through the two support rods 32, 32.

  As shown in FIG. 5, the distance between the cutting blades 33 arranged at both ends of the plurality of cutting blades 33 and the inner surface on the short side of the frame 31 is the thickness obtained by adding the sandwiching plate 15 and the guide plate 37. Set to minutes. Further, the interval between the cutting blades 33 disposed at both ends is formed to be equal to the interval between the guide plates 37 fixed to the pair of sandwiching plates 15 in a state where the attachment shaft 13 is attached to the base 11.

  In this way, as shown in FIG. 5, the sandwich plate 15 and the guide plate 37 can be passed between the inner surface on the short side of the frame 31 and the cutting blades 33 arranged at both ends. For this reason, the electrophoresis gel G can be cut by inserting the lower end of the cutting blade 33 of the cutter unit 30 to the vicinity of the upper end of the stopper plate 17 of the base 11.

  When the cutter unit 30 is inserted into the base 10, the cutting blades 33 of the cutter unit 30 are inserted between the guide pieces 12 inserted through the attachment shaft 13 as shown in FIG. 5. As a result, the electrophoresis gel G placed on the gel placement part 26 of the guide piece 12 is cut with the attachment interval of the cutting blade 33 of the cutter part 30, that is, with the thickness of the guide piece 12. A plurality of electrophoresis gels G can be obtained simultaneously.

  The gel cutter of this embodiment is comprised as mentioned above, Next, the usage method is demonstrated.

  First, the sandwiching plate 15b is slid toward the sandwiching plate 15a so that the distance between the guide pieces 12 is equal to the thickness of the spacer 22. Thereafter, the temporary fixing nut 39 of the mounting shaft 13 is tightened, and the pair of sandwiching plates 15 are held on the mounting shaft 13 in the above state. The mounting shaft 13 held in the above state is fitted between the pair of positioning plates 16 and 16 of the base 11 with the recesses 35 of the pair of sandwiching plates 15a and 15b below the mounting shaft 13, The ball 20 of the stopper 18 is engaged with the recess 35 of the pair of sandwiching plates 15a and 15b.

  Next, the insertion plate 27 of the insertion member 14 is abutted against an end surface of each guide piece 12 other than the gel placement portion 26 provided, so that the gel placement portion 26 is aligned with the upper end portion. . In this state, the insertion plate 27 of the insertion member 14 is inserted between the lower end of each guide piece 12 and the upper surface of the base 11 and abuts against the stopper plate 17 of the base 11 (see FIG. 1).

  As shown in FIG. 7, an electrophoresis gel G having a length substantially equal to the distance between the pair of sandwiching plates 15 is placed on the gel placement portion 26 located on the upper end surface of each guide piece 12 (see FIG. reference).

  Thereafter, as shown in FIG. 8, while the cutting blades 33 arranged at both ends in the cutter unit 30 are brought into contact with the opposing surfaces of the guide plates 37 of the pair of sandwiching plates 15a and 15b, the cutter unit 30 is moved to one side thereof. The support bar 32 is tilted to a position below the other. In a state where the cutter part 30 is tilted, a part of the cutting blade 33 near the support bar 32 located on the lower side moves between the guide pieces 12 along the inclination of the guide part 25 of the guide piece 12. .

  Next, the tilted cutter part 30 is moved downward with the other support bar 32 positioned on the upper side, with the one support bar 32 positioned on the lower side as a fulcrum, and each cutting blade 33 is moved. The gel mounting part 26 of each guide piece 12 is passed. If it does in this way, each cutting blade 33 will pass the gel mounting part 26 of the guide piece 12, maintaining the state inserted between each guide piece 12, respectively. Thereby, the electrophoresis gel G can be cut | disconnected with the attachment space | interval of the cutting blade 33, ie, the thickness of the guide piece 12. FIG.

  After cutting the electrophoresis gel G, when the cutter unit 30 is pulled up, a plurality of electrophoresis gels G cut to the thickness of the guide piece 12 are obtained on the gel placement part 26 of each guide piece 12. Since the gel mounting portion 26 is inclined, the cut electrophoresis gel G can be easily taken out by sliding on the gel mounting portion 26.

  Further, after the electrophoresis gel G is cut, the attachment shaft 13 is removed from the pair of positioning plates 16 and the temporary fixing nut 39 is loosened. Thereafter, the sandwiching plate 15b is slid outward to widen the interval between the guide pieces 12, so that the electrophoresis gel G adhering to the guide pieces 12 can be washed away and the gel cutter can be easily washed.

The exploded perspective view showing the gel cutter of an embodiment Exploded perspective view showing the base Sectional drawing which shows the state before attaching to the base of a mounting shaft same as the above Sectional drawing which shows the state which inserted the cutter part into the base same as the above The top view which shows the state which inserted the cutter part in the same base Side view showing a state where the cutter part is inserted into the base same as above The perspective view which shows the state which mounted the electrophoresis gel on the base same as the above Sectional drawing which shows the use condition which inserted the cutter part in the base same as the above

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Base 11 Base 12 Guide piece 13 Mounting shaft 14 Insertion member 15 Clipping plate 16 Positioning plate 17 Stopper plate 18 Stopper 19 Tubular member 20 Ball 21 Spring 22 Spacer 23 Cap nut 24 Through-hole 25 Guide part 26 Gel mounting part (Top surface)
27 Insertion plate 28 Support plate 29 Support leg 30 Cutter part 31 Frame 32 Support bar 33 Cutting blade 34 Spacer 35 Recess 36 Fixing tool 37 Guide plate 38 Screw 39 Temporary fixing nut G Electrophoretic gel

Claims (4)

A mounting shaft (13) into which a plurality of guide pieces (12) are slidably inserted is detachably attached in a state where the guide pieces (12) are arranged at predetermined intervals and the upper end surfaces (26) thereof are aligned. It consists of a base (10) and a cutter part (30) in which a plurality of cutting blades (33) are attached in a state arranged between the adjacent guide pieces (12),
The electrophoretic gel G is placed on the upper end surface (26) of each guide piece (12), and the cutting blades (33) of the cutter part (30) are inserted between the guide pieces (12). A gel cutter that cuts the electrophoresis gel G.   The gel cutter according to claim 1, wherein an upper end surface (26) of each guide piece (12) is formed to be inclined downward in a direction perpendicular to the mounting shaft (13).   A part of the upper end surface (26) of each guide piece (12) is formed with a chevron-shaped guide portion (25) that slopes downward toward the gap with the guide piece (12) arranged adjacently. The gel cutter according to claim 1 or 2, characterized in that   The holding shaft (13) for holding the guide pieces (12) in a state of being arranged at a predetermined interval is provided on the mounting shaft (13). Gel cutter.

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