JP2006084411A - Electrophoresis system, sample tray, and electrophoresis method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electrophoresis sample tray which can easily allow alignment with higher accuracy, when inserting a capillary into a sample hole of a sample plate, because trace sample retained in the sample hole is not introduced sufficiently into the capillary and affects the analytical accuracy of the sample, if alignment between the capillary and the sample hole is improper due to difficulty in alignment during the insertion of the capillary into the sample hole, as number of the sample holes increases to make pitches between holes smaller. <P>SOLUTION: This is the sample tray equipped with an alignment mechanism. This alignment mechanism is engaged with the alignment mechanism provided on the analyzer to achieve alignment between the sample hole and the capillary. Thus, the alignment in insertion of the capillary into the sample hole will be of high precision. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a technique for separating and analyzing a sample by electrophoresis.

  In a capillary electrophoresis apparatus, an autosampler that automatically supplies a sample plate and reagents is provided at the tip of the capillary. A sample adapter is usually attached to the sample plate. The autosampler carries the sample plate with the sample adapter attached. Here, the form in which the sample plate is attached to the sample adapter is called a sample tray.

  In the example of Patent Document 1, an adapter that holds a sample plate, a septa that covers the sample plate to prevent evaporation of the sample, and a septa holder that fixes the sample plate and the septa to the adapter are used.

  A number of sample holes are formed in the sample plate. Commercially available sample plates include 96-well thermal titer plates (hereinafter referred to as 96-well plates), 384-well thermal titer plates (hereinafter referred to as 384-well plates), and 1536-hole thermal titer plates (hereinafter referred to as 1536-well plates). Etc. In the 96-well plate, 96 sample holes are provided at intervals of 9 mm on an approximately 12 × 8 cm plate. In the 384-well plate, 384 sample holes are provided at an interval of 4.5 mm on a plate of about 12 × 8 cm. In the 1536 hole plate, 1536 sample holes are provided on a plate of about 12 × 8 cm at intervals of 2.25 mm.

JP 2001-324474 A

  As the number of sample holes in the sample plate increases and the pitch between the holes decreases, the alignment when inserting the capillaries into the sample holes in the sample plate becomes difficult. If the positional relationship between the capillary and the sample hole is not appropriate, a very small amount of sample held in the sample hole cannot be sufficiently introduced into the capillary, which may affect the analysis accuracy of the sample.

  An object of the present invention relates to easy and high-precision alignment when inserting a capillary into a sample hole.

  The present invention relates to a sample tray having a positioning mechanism. The positioning mechanism engages with a positioning mechanism provided in the analyzer, thereby aligning the sample hole and the capillary.

  Preferably, the sample tray is movably held in the sample tray transport mechanism via a spring mechanism or an elastic sheet, or the sample tray is placed on the sample tray transport mechanism so as to be minutely movable, and the sample tray transport mechanism Alignment below the minimum operation amount.

  According to the present invention, the alignment when the capillary is inserted into the sample hole is highly accurate.

  FIG. 1 shows an outline of an electrophoresis apparatus. The electrophoresis apparatus of this example includes a pump unit 11, a laser irradiation / detection unit 12, an oven unit 13, an autosampler unit 14, and a capillary array 15, and separates and analyzes a sample by electrophoresis. The capillary array 15 includes a large number of capillaries, and includes a capillary head 107 on the pump unit 11 side and an electrode 123 provided on the opposite side. The pump unit 11 includes a capillary filling syringe 101, a check valve 102, a polymer block 103, a polymer bottle 104, a valve 105, and a buffer jar 106, and fills a capillary with a polymer that is a medium for separating a sample.

  The capillary head 107 is connected to the capillary filling syringe 101 via the polymer block 103, is connected to the polymer bottle 104 via the check valve 102, and is further connected to the buffer jar 106 via the valve 105. When the valve 105 is closed, the plunger of the filling syringe 101 is pulled out, and the inside of the filling syringe 101 is set to a negative pressure, the polymer contained in the polymer bottle 104 is introduced into the filling syringe 101. Next, when the plunger of the filling syringe 101 is pushed in, the polymer in the filling syringe 101 is filled into the capillary array 50 via the capillary head 107. The check valve 102 prevents the polymer in the filling syringe 101 from returning to the polymer bottle 104.

  The oven unit 13 has a thermostatic chamber 109 for storing the capillary array 15, and keeps the temperature of the capillary array 15 constant.

  The auto sampler unit 14 includes a top plate 110 and an auto sampler 122 provided therebelow. The autosampler 122 automatically transports samples and reagents to the position of the electrode 123 of the capillary array 15. Details of the autosampler 122 will be described later with reference to FIG.

  The top plate 110 is provided with a buffer station 111 for storing the buffer tray 117, a cleaning water station 112 for storing the cleaning water tray 118, and a waste liquid station 113 for storing the waste liquid tray 119. The top plate 110 further includes a stacker 114 for stacking and storing the sample trays 120 before measurement, a sample parking 115 for temporarily storing the sample tray 121 being measured, and a receiver 116 for storing the sample tray after measurement. Is provided.

  When performing electrophoresis, the valve 105 is opened, and a voltage from the high voltage power supply 124 is applied between the electrode of the buffer jar 106 and the electrode 123 at the tip of the capillary. The sample in the sample moves in the capillary from the electrode 123 toward the capillary head 107 and is detected by the laser irradiation / detection unit 12.

  The configuration and function of the capillary array 15 and the laser irradiation / detection unit 12 will be described with reference to FIG. As shown in FIG. 2A, the capillary array 15 includes a large number of capillaries 201. The capillary array 15 includes a capillary head 202 formed by bundling capillaries 201, a separator 203, a load header 204 that holds the capillaries at equal intervals, and an electrode 123. The laser irradiation / detection unit 12 includes a laser light source and a CCD camera. The capillary 201 has a detection unit with a surface coating peeled off in a region where the laser irradiation / detection unit 12 is provided. Laser light from the laser light source irradiates the sample in the capillary at the detection unit. The fluorescence from the fluorescent material of the sample is detected with a CCD camera.

  As shown in FIG. 2B, the electrode 123 is formed in a pipe shape so as to cover the capillary 201. The tip of the capillary 201 is exposed from the tip of the electrode 123.

  An example of the circuit configuration of the electrophoresis apparatus, particularly the circuit configuration of the autosampler 122 will be described with reference to FIG. The electrophoresis apparatus includes a pump unit 11, a laser irradiation / detection unit 12, an oven unit 13, an autosampler 122, a CPU 301, a ROM 302, and a RAM 303. The electrophoretic device is connected to the terminal device 306 via the communication line 305. The terminal device 306 includes a monitor 307 and an input device 308.

  The autosampler 122 includes a CPU 41, ROM 42, RAM 43, X motor 411, X linear guide 401, X origin sensor 421, Y motor 412, Y linear guide 402, Y origin sensor 422, Z motor 413, Z linear guide 403, Z origin. A sensor 423, a gripper motor 414, and a gripper 404 are included. The X motor 411, the Y motor 412, and the Z motor 413 are stepping motors. The X origin sensor 421, the Y origin sensor 422, and the Z origin sensor 423 detect the origin in the X direction, the origin in the Y direction, and the origin in the Z direction.

  As shown in FIG. 4, the autosampler 122 includes a tray mounting portion 405 that holds a sample tray or a buffer tray. The gripper 404 fixes the tray on the tray mounting unit 405. The CPU 41 transmits drive commands to the X motor 411, the Y motor 412, and the Z motor 413. Thereby, the X linear guide 401, the Y linear guide 402, and the Z linear guide 403 operate. The tray mounting unit 405 moves in the X direction by the X linear guide 401, moves in the Y direction by the Y linear guide 402, and moves in the Z direction by the Z linear guide 403.

  A first example of a sample tray according to the present invention will be described with reference to FIGS. FIG. 5A is a perspective view of the sample tray of this example, and FIG. 5B is a plan view thereof. The sample tray of this example includes a clip 501, a sample adapter 502, and a sample plate 503. The clip 501 has a function of fixing the sample plate 503 to the sample adapter 502. The sample tray is assembled by fixing the sample plate 503 to the sample adapter 502 with the clip 501.

  6A shows a cross-sectional configuration of the sample tray, and FIG. 6B shows a cross-sectional configuration of the clip 501, the sample adapter 502, and the sample plate 503. The clip 501 includes a frame-shaped frame member 5011, an outer claw 5012 provided on both sides of the frame member, and an inner claw 5013. As shown in FIG. 5, a positioning hole 5014 is provided in the frame member 5011. The positioning hole 5014 is provided for inserting a positioning pin provided in the load header, and the details of the function will be described later.

  The sample plate 503 has a plate portion 5031, a skirt portion 5032 formed around the plate portion 5031, and a number of sample holes 5033. The sample plate 503 may be a commercially available sample plate. Commercially available sample plates include 96 holes, 384 holes, 1536 holes, and the like.

  The sample adapter 502 includes an upper substrate 5021, a lower base plate 5022, and a spring 5023 attached between the substrate and the base plate. The substrate 5021 has a flat plate and a supporting member 5025 provided around the flat plate as shown. The base plate 5022 includes a flat plate and a frame member provided around the flat plate. The frame member of the base plate 5022 is provided with a groove 5024 for receiving a claw 5012 outside the clip. The spring 5023 is formed of a plastic or an insulating material.

  Next, a method for assembling the sample tray will be described. First, the clip 501 is placed on the sample plate 503, and the clip 501 is pressed from above. Thereby, the claw 5013 inside the clip is engaged with the lower end of the skirt portion 5032 of the sample plate 503. Thereby, an assembly including the clip 501 and the sample plate 503 is formed. In this assembly, the sample plate 503 is supported by claws 5013 inside the clip.

  Next, this assembly is placed on the substrate 5021 of the sample adapter 502. When a force is applied from the top to the bottom of the clip 501, the assembly moves downward. First, the support member 5025 of the sample adapter 502 comes into contact with the lower surface of the plate portion 5031 of the sample plate 503. When further pressing is applied from above the clip 501, the spring 5023 is deformed, and the assembly moves further downward together with the substrate 5021. Thereby, the claw 5012 on the outside of the clip is engaged with the groove 5024 of the base plate 5022.

  When the pressure on the clip 501 is released, the assembly moves upward together with the substrate 5021 by the elastic force of the spring 5023 and stops at a predetermined position. At this time, the assembly including the clip 501 and the sample plate 503 is supported by the elastic force of the spring 5023. As shown in FIG. 6A, the dimension of the groove 5024 is sufficiently larger than the dimension of the tip of the claw 5012, and a gap or play 5024A is formed between them. When the spring 5023 is deformed, the assembly is movable in the vertical direction and the lateral direction within this gap or play range. The gap or play range is preferably equal to or less than the interval between the plurality of sample holes 5033 of the sample plate 503, and is preferably the minimum movement amount of the autosampler.

  FIG. 7 shows an example of the tip of the capillary array according to this example. As shown in FIG. 7A, a load header 602 is provided at the tip of the capillary array. A pipe-like electrode 603 is attached to the load header 602, and the tip of the capillary 601 is inserted into the electrode 603. As described with reference to FIG. 2, the tip of the capillary 601 is slightly exposed from the lower end of the electrode 603.

  According to this example, two positioning pins 604 are attached to the load header 602. The length of the positioning pin 604 is larger than the length of the capillary 601 extending downward from the load header 602.

  FIG. 7B shows an example of the structure of the tip of the positioning pin 604. The positioning pin 604 has a main body 6041, a lower tapered portion 6042 thereof, and a lower end portion 6044 thereof. The tapered portion 6042 has a conical surface, and the diameter of the upper end connected to the main body 6041 is larger than the diameter of the lower end connected to the distal end portion 6044. The diameter of the upper end of the tapered portion 6042 is smaller than the diameter of the main body 6041. Accordingly, a step 6043 is formed at the boundary between the main body 6041 and the tapered portion 6042.

  Next, a method for mounting the tip of the capillary array on the sample tray will be described with reference to FIG. As shown in FIG. 8A, a sample tray 500 mounted on the tray mounting portion 405 of the autosampler 122 is disposed below the load header 602. As shown in FIG. 8B, the auto sampler 122 moves the tray mounting portion 405 upward and the sample tray 500 moves upward. First, the distal end portion 6044 of the positioning pin 604 is inserted into the positioning hole 5014 of the clip 501.

  As shown in FIG. 8C, the auto sampler 122 moves the tray mounting portion 405 upward, and the sample tray further moves upward. As a result, the tapered portion 6042 of the positioning pin 604 enters the positioning hole 5014. When the center axis of the positioning pin 604 is not aligned with the center axis of the positioning hole 5014, the sample tray moves in the horizontal direction due to the engagement between the tapered portion 6042 and the positioning hole 5014.

  As shown in FIG. 8D, when the tray mounting portion 405 is moved upward by the autosampler 122 and the sample tray is moved further upward, the step 6043 of the positioning pin 604 comes into contact with the upper surface of the clip 501. The sample tray does not move any further. However, the spring 5023 is bent, and the base plate 5022 of the sample adapter 502 can move slightly upward. The distance that the base plate 5022 of the sample adapter 502 can move is the gap or play range between the groove 5024 and the claw 5012 as described above. The tip of the capillary exposed from below the electrode 603 is disposed in the sample hole 5033 of the sample plate 503. According to this example, position correction below the minimum operation amount of the motor can be performed.

  With reference to FIG. 9, a method of measuring a sample by an electrophoresis apparatus using the sample tray of this example will be described. Dashed steps S 1, S 2, S 4, S 6, S 8, S 10, S 11, S 13, and S 15 indicate operations by the autosampler 122. First, in step S1, the sample tray is transported from the stacker 114 to the sample parking 115. In step S2, the waste liquid tray 119 is transported from the waste liquid station 113 to a position below the electrode 123 of the capillary array. In step S3, the polymer filled in the capillary is refilled. In step S4, the waste liquid tray 119 is returned to the waste liquid station 113, and the washing water tray 118 is moved from the washing water station 112 to a position below the electrode 123. In step S5, the tip of the capillary is washed. In step S6, the washing water tray 118 is returned to the washing water station 112, and the buffer tray 117 is moved from the buffer station 111 to a position below the electrode 123. In step S7, preliminary electrophoresis is performed. In step S8, the buffer tray 117 is returned to the buffer station 111, and the washing water tray 118 is moved from the washing water station 112 to a position below the electrode 123. In step S9, the tip of the capillary is washed. In step S10, the washing water tray 118 is returned to the washing water station 112, and the sample tray is moved from the sample parking 115 to a position below the electrode 123. In step S11, as shown in FIG. 8, the auto sampler 122 moves the tray mounting portion 405 upward and moves the sample tray upward. Thereby, the tip of the capillary 601 is placed in the sample hole 5033 of the sample plate 503. In step S12, the sample is injected into the capillary. In step S13, the sample tray is returned to the sample parking 115, and the washing water tray 118 is moved from the washing water station 112 to a position below the electrode 123. In step S14, the tip of the capillary is washed. In step S15, the washing water tray 118 is returned to the washing water station 112, and the buffer tray 117 is moved from the buffer station 111 to a position below the electrode 123. In step S16, electrophoresis is started.

  Here, the reason why a plurality of positioning holes 5014 are provided in the clip 501 will be described. When the number of sample holes 5033 in the sample plate 503 and the number of capillaries 601 are the same, all samples in the sample holes 5033 can be measured by one measurement. In such a case, one positioning hole 5014 may be provided in each of the two sides of the frame member 5011 of the clip 501. In this case, the pitch of the capillaries, i.e. the dimension between adjacent capillaries, is equal to the pitch of the sample holes, i.e. the distance between adjacent sample holes.

  However, when the number of sample holes 5033 in the sample plate 503 is larger than the number of capillaries 601, a plurality of measurements are required to measure all the samples in the sample holes 5033.

  An example of FIG. 5 will be described. The number of capillaries included in the capillary array is 96, and the number of sample holes 5033 in the sample plate 503 is 384. In this case, four measurements are required. Four positioning holes 5014 are provided in each of the two sides of the frame member 5011 of the clip 501. The pitch of the positioning holes 5014 is the same as the pitch of the sample holes. The capillary pitch is twice the pitch of the sample holes. All the samples are measured by sequentially arranging the positioning pins so as to be inserted into the positioning holes 5014.

  A second example of the sample tray according to the present invention will be described with reference to FIG. 10A shows a cross-sectional configuration of the sample tray, and FIG. 10B shows a cross-sectional configuration of the clip 501, the sample adapter 502, and the sample plate 503. The sample tray of this example is different from the first example shown in FIGS. 5 and 6 in that the sample tray of this example uses an elastic sheet 1001 instead of the spring 5023. Other than that may be the same as the first example.

  The elastic sheet 1001 may be an insulating and elastically deformable sheet-like substance, and may be, for example, a sponge sheet, a sheet having an air layer, a rubber sheet, a polystyrene foam sheet, or the like. As described with reference to FIG. 8, when the tip of the capillary array is mounted on the sample tray, the elastic sheet 1001 is elastically deformed, so that the sample plate 503 moves and alignment is performed.

  A third example of the sample tray according to the present invention will be described with reference to FIGS. FIG. 11A is a perspective view of the sample tray of this example, and FIG. 11B is a plan view thereof. The sample tray of this example includes a clip 1101, a sample adapter 1102, and a sample plate 1103. As shown in FIG. 12, the number of capillaries 1202 included in the capillary array of this example is eight, which are arranged in one row. The number of sample holes 11033 in the sample plate 1103 is 384. In this case, 384/8 = 48 measurements are required. Forty-eight positioning holes 1114 are provided in two side portions of the frame member 1101A of the clip 1101, respectively. The pitch of the positioning holes 1114 is the same as the pitch of the sample holes 1103a. The pitch of the capillaries 1202 is twice the pitch of the sample holes 1103a.

  As shown in FIG. 12A, first, the positioning pin 1201 is inserted into the left hole of the positioning hole 1114 in the first row, and measurement is performed. Next, the positioning pin 1201 is inserted into the right hole of the positioning hole 1114 in the first row, and measurement is performed. By repeating such an operation in all the rows of the positioning holes 1114, all samples can be measured.

  The number of positioning holes in the sample tray is equal to the number obtained by dividing the number of sample holes by the number of capillaries when there is one positioning pin for one position. Further, when two or more positioning pins are provided in one position, this number is multiplied by the number of positioning pins.

A fourth example of the sample tray according to the present invention will be described with reference to FIG. 13A is a cross-sectional view of the sample tray of this example, FIG. 13B is a cross-sectional view of the sample plate, FIG. 13C is a cross-sectional view of the sample adapter, and FIG. 13D is a plan view of the sample tray.
The sample tray of this example includes a sample adapter 1302 and a sample plate 1303.

  The sample adapter 1302 includes an upper substrate 13021, a lower base plate 13022, and a spring 13023 mounted between the substrate and the base plate. Claws 13024 are provided on both sides of the substrate 13021. In this example, the sample plate 1303 is held by the claw 13024 instead of the clip.

  The sample plate 1303 has a plate portion 13031, a large number of sample holes 13033, and a positioning hole 13034.

  In this example, as in the first example of FIGS. 5 and 6, a capillary array having 96 capillaries is used. There are 1536 sample holes 13033 in the sample plate 1303. In this case, 1536/96 = 16 measurements are required. Sixteen positioning holes 13034 are provided in two side portions of the sample plate 1303, respectively. The pitch of the positioning holes 13034 is the same as the pitch of the sample holes 13033. The pitch of the capillaries is twice the pitch of the sample holes 13033.

  In FIG. 13, the positioning holes 13034 are provided at both ends in the longitudinal direction of the sample plate 1303. However, the positions of the positioning holes need not be here, and may be arbitrary locations on the sample plate 1303.

  As described above, the embodiment in the case where the present invention is applied to the electrophoresis apparatus has been described, but in addition to this, the position of the present invention is also applied to, for example, an automatic dispensing apparatus and an analytical apparatus for dispensing a sample on a sample plate. An adjustment mechanism can be applied. The position fine adjustment mechanism of the present invention can also be applied to an apparatus that introduces a sample in a sample plate into a capillary by pressure.

  The example of the present invention has been described above, but the present invention is not limited to the above-described example, and it will be understood by those skilled in the art that various modifications can be made within the scope of the invention described in the claims. Let's be done.

FIG. 1 is a schematic diagram of the entire electrophoresis apparatus. FIG. 2 is an external view of the capillary array and the laser irradiation / detection unit. FIG. 3 is an electrical system diagram of the electrophoresis apparatus. FIG. 4 is a schematic view of a mechanism portion of the autosampler. FIG. 5 is a schematic view of a first example of a sample tray according to the present invention. FIG. 6 is a detailed view of a first example of a sample tray according to the present invention. FIG. 7 is a schematic view of a load header of a capillary array to which positioning pins are attached. FIG. 8 is a diagram showing a procedure for positioning with the positioning pins and the sample tray. FIG. 9 is a diagram showing a procedure of an experiment using the electrophoresis apparatus. FIG. 10 is a detailed view of a second example of a sample tray according to the present invention. FIG. 11 is a detailed view of a third example of the sample tray according to the present invention. FIG. 12 is an explanatory diagram for explaining the operation of the third example of the sample tray according to the present invention. FIG. 13 is a detailed view of a fourth example of a sample tray according to the present invention.

Explanation of symbols

11 ... Pump unit, 12 ... Laser irradiation / detection unit, 13 ... Oven unit, 14 ... Autosampler unit, 15 ... Capillary array, 41 ... CPU, 42 ... ROM, 43 ... RAM,
101 ... Syringe for filling capillary, 102 ... Check valve, 103 ... Polymer block, 104 ... Polymer bottle, 105 ... Valve, 106 ... Buffer jar, 107 ... Capillary head, 108 ... Laser light source, 109 ... Constant temperature bath, 110 ... Top plate 111 ... Buffer station, 112 ... Washing water station, 113 ... Waste liquid station, 114 ... Stacker, 115 ... Sample parking, 116 ... Receiver, 117 ... Buffer tray, 118 ... Washing water tray, 119 ... Waste liquid tray, 120, 121 ... Sample tray, 122 ... Autosampler moving part, 123 ... Capillary tip electrode, 124 ... High voltage power supply, 201 ... Capillary, 202 ... Capillary head, 203 ... Separator, 204 ... Load header, 401 ... X linear guide, 402 ... Y linear guide , 403 ... Z linear guide, 404 ... Gripper, 405 ... Tray mounting part, 501 ... Clip, 503 ... Sample plate, 502 ... Sun Adapter, 601 ... capillary, 602 ... load header, 603 ... electrode, 604 ... positioning pin, 1001 ... elastic sheet, 1101 ... clip, 1103 ... sample plate, 1102 ... sample adapter, 1114 ... positioning hole, 1303 ... sample plate , 1302 ... Sample adapter, 5014 ... Positioning hole, 5012, 5013 ... Claw, 5021 ... Substrate, 5024 ... Groove, 5023 ... Spring, 5022 ... Base plate, 13034 ... Positioning hole, 13024 ... Claw

Claims (15)

Multiple capillaries;
A positioning mechanism in a predetermined positional relationship from the tip of the capillary;
An autosampler capable of transporting a sample tray including a sample plate having a plurality of sample holes and a positioning mechanism in a predetermined positional relationship from the sample plate to the position of the tip of the capillary;
And the capillary positioning mechanism is engaged with the positioning mechanism of the sample tray, thereby aligning the capillary and the sample hole.   2. The electrophoresis apparatus according to claim 1, wherein the autosampler holds the sample tray via an elastic body.   The electrophoresis apparatus according to claim 1, wherein the sample tray is held by the autosampler so that the micro movement can be performed at a distance equal to or smaller than the interval between the sample holes.   2. The electrophoresis apparatus according to claim 1, wherein the capillary positioning mechanism is a positioning pin, and the sample tray positioning mechanism is a positioning hole.   5. The electrophoresis apparatus according to claim 4, wherein the positioning holes of the sample tray are provided at the same pitch as the pitch of the sample holes.   5. The electrophoresis device according to claim 4, wherein the positioning pin includes a main body having a cylindrical surface, a tapered portion connected to the main body and having a conical surface, and a tip end connected to the tapered portion. An electrophoresis apparatus, wherein a step is formed at a boundary between the tapered portions.   In a sample tray having a sample plate having a plurality of sample holes and a sample adapter and movably held by an autosampler, it engages with a positioning mechanism in a predetermined positional relationship from the tip of a capillary in the electrophoresis apparatus. When a positioning mechanism is provided and the sample tray is conveyed to the position of the tip of the capillary by the autosampler, the positioning between the sample hole and the capillary is performed by the engagement of the two positioning mechanisms. A sample tray characterized by that.   8. The sample tray according to claim 7, wherein the autosampler holds the sample tray via an elastic body.   8. The sample tray according to claim 7, wherein the positioning mechanism is a positioning hole that engages with a positioning pin provided in an electrophoresis apparatus, and the sample plate is inserted into the positioning hole when the positioning pin is inserted into the positioning hole. A sample tray that moves on an adapter, thereby aligning the sample hole and the capillary.   The sample tray according to claim 9, wherein the number of the positioning holes is equal to a number obtained by dividing the number of the sample holes by the number of the capillaries.   The sample tray according to claim 9, wherein the positioning holes of the sample tray are provided at the same pitch as the pitch of the sample holes.   10. The sample tray according to claim 9, wherein the positioning holes are provided in outer peripheral portions on both sides of the sample plate. A sample tray having a sample plate having a plurality of sample holes, a sample adapter, and a positioning mechanism in a predetermined positional relationship from the sample plate is moved so as to approach the tips of the plurality of capillaries in the electrophoresis apparatus,
An electrophoresis method for aligning a sample hole and a capillary by engaging a positioning mechanism having a predetermined positional relationship from the tip of the capillary with the positioning mechanism of the sample tray.   14. The electrophoresis method according to claim 13, wherein the capillary positioning mechanism is a positioning pin, and the sample tray positioning mechanism is a positioning hole.   15. The electrophoresis method according to claim 14, wherein the positioning is repeated while sequentially shifting the positioning holes of the sample tray to be engaged with the positioning pins of the capillary.

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