JP2005351905A - Capillary electrophoresis system and capillary array assembly - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To constitute pairs of electrodes and capillaries to be electrically connected to common electrodes and exclude complication when a capillary array is set. <P>SOLUTION: An electrode 23 provided for the vicinity (within the area of a well) of each capillary 2a provided in such a way as to be matched to the pitch of wells on the side of a sample plate 5 is brought into electrical contact with a common electrode part 24. The capillary 2a; the electrode 23; and the common electrode part 24 are integrated. By impressing a voltage on the common electrode part 24, a voltage is impressed on each electrode 23 for capillaries in this electrophoresis system. It is thereby possible to perform simultaneous insertion, removal, and attachment through the use of an inexpensive microtiter plate etc. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a capillary electrophoresis apparatus and a capillary array (a plurality of capillaries which are processed so as to be detachable, for example), and in particular, using a plurality of capillaries or fine channels as electrophoresis separation media, The present invention relates to a capillary electrophoresis apparatus (hereinafter referred to as an electrophoresis apparatus) suitable for use in a DNA sequencer (DNA base sequence analysis apparatus) for analyzing a biological sample such as DNA (deoxyribonucleic acid) and a capillary used therefor.

  In order to determine the base sequence of DNA having a long base sequence, the gel is swollen with two glass plates, and a voltage is applied to both ends of the glass plate to cause electrophoresis of the DNA sample. The capillary is moved to a capillary electrophoresis apparatus in which a gel is filled in a capillary tube (hereinafter referred to as a capillary), and a sample is electrophoresed by applying a voltage to both ends thereof.

  Capillary electrophoresis is capable of high-speed and high-sensitivity analysis compared to the slab gel method, and is less susceptible to Joule heat from self-heating due to electrophoresis current, so it has good resolution for electrophoresis analysis. Can be given.

  In recent years, in order to increase the number of analyzable units per unit time in one electrophoresis apparatus, an electrophoresis apparatus that can set a plurality of capillaries and simultaneously perform DNA analysis of a plurality of samples is becoming widespread.

  In these apparatuses, as a method of applying a voltage to the sample introduction side of the capillary during introduction of the sample into the capillary or electrophoresis, the sample plate on which the sample is set and the electrophoresis buffer tank itself are made of a conductor such as metal. In many cases, the electrode is built in, or an electrode is incorporated in these.

  As in the technique described in Patent Document 1, the electrophoresis apparatus is provided with an electrode structure that covers the periphery of the sample introduction portion of each capillary, and at the same time, through the wiring pattern connected to each electrode in the electrophoresis apparatus. There is also a method of performing electrophoresis by applying a high voltage.

JP-A-10-206382

  In the technique of constructing the sample plate and the electrophoresis buffer tank itself with a conductor such as metal, an analyst should use a sample plate having a voltage application structure unique to each DNA analyzer as described above for DNA analysis of a large number of samples. A large amount must be prepared. This increases the running cost related to the analysis and increases the burden on the analyst.

  Next, it is desirable that a general-purpose microtiter plate or the like can be used as the electrophoresis apparatus. However, the microtiter plate does not include an electrode portion that can be connected to the electrophoresis apparatus. Therefore, it is not possible to use a technique for incorporating an electrode in the electrophoresis apparatus.

  Furthermore, in an electrophoresis apparatus that has an electrode structure portion that covers the periphery of the sample introduction portion of each capillary and that has a wiring pattern connected to each electrode structure portion and that applies a high voltage, the capillary replacement operation Becomes very complicated.

  Furthermore, the capillaries have a lifetime, and it is necessary to reanalyze capillaries with different lengths depending on the application. At this time, the analyst has to set a plurality of capillaries one by one in the electrophoresis apparatus, which is very troublesome.

  In this method, in order to introduce the sample into the capillary, the cylindrical electrode is previously brought into contact with the sample in the sample plate, and then the sample plate is driven and moved to move the capillary inside the cylindrical electrode. In order to simultaneously insert a plurality of capillaries having an outer diameter of several hundreds of μm into a cylindrical electrode, the drive part of the sample plate requires very high accuracy, Alternatively, the cylindrical electrode must have an inner diameter with a sufficient margin.

  If the electrode cylinder is made thin and the drive unit has precision, the sample measured last time remains in the gap between the cylindrical electrode inner surface and the capillary outer surface due to capillary action, and accurate electrophoresis analysis can be performed. There is a problem of disappearing.

  If the electrode tube is made thicker and the drive unit does not require accuracy, the possibility of mixing another sample due to the above-mentioned capillary phenomenon also decreases, but since the electrode is thicker, an inverted conical shape that becomes narrower as it goes to the bottom There is a problem that the lower end of the electrode does not reach the bottom of the well of the sample plate.

  In principle, sample introduction and electrophoresis are impossible unless the lower end of the electrode reaches the sample or the buffer solution. Therefore, if the sample and buffer solution are brought into contact with each other and a general-purpose microtiter plate is used, the minimum sample amount must be set large in order to raise the liquid level of the sample and buffer solution. There was a problem.

  The present invention has been made to solve such problems of the prior art, reduces the running cost and the burden on the analyst, and facilitates the replacement and setting of the capillaries, enabling accurate analysis. The first object of the present invention is to provide a capillary electrophoresis apparatus capable of reducing the setting of the minimum sample amount.

  The second objective is to provide a capillary array that reduces the running cost and the burden on the analyst for analysis, facilitates capillary replacement and setting, enables accurate analysis, and reduces the minimum sample amount. Objective.

  The object of the present invention is achieved by the invention described in the claims.

  According to the configuration of the present invention, a plurality of capillaries and electrodes can be paired to easily align the sample stage with the sample stage of the capillary array.

  According to an embodiment of the present invention, a plurality of capillaries forming an electrophoresis path are provided, one end is a sample supply unit, the other end is a capillary array constituting a sample detection unit, and the sample supply unit is provided with the plurality of capillaries. A plurality of electrode members provided in pairs with the capillaries, a conductive member electrically connected to the plurality of electrode members and connected to a power source for applying a voltage to the capillary array, and the capillary array A capillary assembly having a capillary array holder for holding the electrode member and the conductive member, a sample holding portion having a sample holding portion at a position corresponding to the pair of each capillary and electrode member, and mounting the sample holding portion A capillary electrophoresis apparatus having a sample moving table is provided.

  Further, according to the embodiment of the present invention, it has a plurality of capillaries forming an electrophoresis path, one end is a sample supply unit, the other end is a capillary array constituting a sample detection unit, and the sample supply unit A plurality of electrode members provided in pairs with the plurality of capillaries, a conductive member electrically connected to the plurality of electrode members and connected to a power source for applying a voltage to the capillary array; and A capillary array assembly including a capillary array holder that holds a capillary array, an electrode member, and a conductive member is provided.

  The configuration of the capillary electrophoresis apparatus according to the first aspect of the present invention includes a sample plate having a plurality of wells for storing a sample, a buffer tank for storing a buffer solution for electrophoresis, and the sample plate And an autosampler for mounting the buffer tank, a plurality of capillaries that are filled with gel, are inserted into the wells one by one, contact the sample, suck the sample, and contact the buffer solution to form an electrophoresis path; A plurality of electrode members provided in the vicinity of the plurality of capillaries, a conductive member in electrical contact with the plurality of electrode members, the plurality of capillaries, the plurality of electrode members, and the conductive member are integrated. As a capillary array holder, and a power supply unit for applying a voltage to both ends of the capillary end and end And it is characterized in that at least and a control unit for controlling said autosampler and said power supply unit.

  The capillary electrophoresis apparatus having the above configuration will be briefly described. In order to reduce the burden on the analyst, a commercially available microtiter plate can be used, and the sample plate and the buffer container do not have an electrode structure.

  The electrode portion for applying a voltage to the capillary is integrated with the capillary array so as to be detachable from the electrophoresis apparatus. In this way, the complexity when setting the capillary is eliminated. The electrode portion is a metal wire arranged in parallel with the capillary at a minute interval near the capillary, for example, a distance of about 1 mm.

  In addition, the capillary is configured by inserting the capillary into a cylindrical electrode having an inner diameter substantially the same as the outer shape of the capillary, and further bonding the electrode and the capillary so as not to give a gap for mixing another sample. It is intended to be. Further, the capillary is an electrode part formed by vapor-depositing a metal thin film or a conductive material on the outer wall of the capillary.

  The above means makes it possible to use a general-purpose, inexpensive microtiter plate as a sample plate, which can simultaneously set a capillary array that has a lifetime and needs to be replaced according to the analysis, and eliminates the need for complicated samples. Thus, stable DNA analysis can be performed by preventing contamination of the DNA.

  Hereinafter, a plurality of embodiments of the present invention will be described. With reference to FIG. 1 thru | or 7, the Example of the capillary electrophoresis apparatus which concerns on 1st invention, and the capillary assembly which concerns on 2nd invention is demonstrated.

  1 is an explanatory diagram of a capillary electrophoresis apparatus for a DNA sequencer, FIG. 2 is an explanatory diagram of an electrode section in the electrophoresis apparatus of FIG. 1, and FIG. 3 is an explanatory diagram of connection of a power supply section in the electrophoresis apparatus of FIG. 4 is an explanatory diagram of another electrode unit in the electrophoretic device of FIG. 1, FIG. 5 is an explanatory diagram of still another electrode unit in the electrophoretic device of FIG. 1, and FIG. 6 is an electrophoretic device of FIG. Furthermore, FIG. 7 is an explanatory view of a capillary assembly.

[Example 1]
First, the overall configuration of the capillary electrophoresis apparatus optimal for the DNA sequencer according to the first invention will be described. In FIG. 1, 1 is a DNA sequencer capillary electrophoresis apparatus (referred to as an electrophoresis apparatus), 2 is a capillary array, 2a is a capillary, 3 is an air thermostat, 5 is a sample plate, 6 is a buffer tank, and 7 is in the XYZ directions. A movable autosampler, 8 is an array holder for fixing a capillary array (hereinafter referred to as an array holder), 9 is a gel block, 10 is an electrophoresis ground, 12 is a gel filling syringe, 13 is a light irradiation analysis unit, and 40 is A power supply unit 50 is a control computer.

  In FIG. 1, a capillary array 2 is composed of two or more capillaries 2a, and is fixed by an array holder 8 to constitute an electrophoresis unit. It is set so that most of the capillary array 2 is stored in the air thermostat 3. The air thermostat 3 is covered with a heat insulating material except for a part of the outer peripheral portion thereof, and the part where the heat insulating material is removed is either heated or heated / cooled to be brought into contact with the air in the air thermostatic bath. An element is provided.

  A sample plate 5 for setting a sample is disposed near the tip of the capillary array 2. Further, in the vicinity of the sample plate 5, there is disposed a buffer tank 6 for storing a buffer solution for preventing the discharge when a voltage is applied to the capillary array 2 and for electrophoresis of the sample. The sample plate 5 is a commercially available microtiter plate. Hereinafter, the sample plate 5 refers to a microtiter plate. The sample plate 5 is made of synthetic resin such as acrylic resin, has a rectangular planar shape, and is provided with 8 × 12 = 96 wells 21 in a matrix.

  The well 21 has a cross-sectional shape in which a tapered portion is formed from the upper surface side to the bottom portion of the sample plate 5. Thereby, the operation | work becomes easy at the time of injection | pouring and introduction | transduction of a sample.

  The sample plate 5 and the buffer tank 6 are mounted on an autosampler 7 that can move in the XYZ directions. The autosampler 7 is attached to the bottom surface of the casing of the electrophoresis apparatus 1, and the control computer 50 is positioned in the front-rear, left-right, and up-down directions, and a movement motor (not shown) is controlled to move.

  In the capillary array 2, 16 (8 × 2) capillaries 2a are arranged in a matrix, and the inside thereof is filled with gel for electrophoretic separation. The distal end side of the capillary array 2 corresponding to the sample plate 5 is fixed by the array holder 8, and the other distal end side of the capillary array 2 is connected and fixed to the gel block 9.

  The gel block 9 is filled with gel (polymer) as a separation medium from the connection portion with the capillary array 2 to the electrophoresis ground 10, and the power supply portion 40 is connected to the ground electrode side of the electrophoresis ground 10. . The electrophoresis ground 10 is attached to the bottom surface of the casing of the electrophoresis apparatus 1.

  The array holder 8 is arranged with the capillaries 2a at a pitch corresponding to the pitch of the wells 21 of the sample plate 5. As an example, the number is 8 in the figure. In the array holder 8 to which the capillaries 2a are attached, the capillaries and an electrode portion (not shown) made of a metal wire electrode and a common electrode are integrally formed. This integrated electrode structure will be described later. The high voltage side of the power supply unit 40 is connected to this electrode unit.

  An optical analysis unit 13 is disposed near the end of migration of the capillary array 2. The optical analysis unit 13 detects, for example, a laser light source (not shown) that irradiates and excites a sample in the capillary array 2 through a transparent window (not shown) of the capillary array 2 and excitation light generated by the excitation. And an optical sensor. From this optical sensor signal, the control computer 50 determines the DNA base sequence and identifies the DNA type.

  The electrophoresis apparatus 1 is provided with an electromagnetic valve 11 for preventing a backflow at the time of gel exchange, in a gel filling syringe 12 for exchanging the gel every time electrophoresis is performed. These operations are also controlled by the control computer 50. In FIG. 1, the power supply unit 40 and the control computer 50 are externally installed, but it goes without saying that they may be installed in the electrophoresis apparatus 1.

  With reference to FIG. 2, an explanation will be given of an integrated structure electrode portion including a capillary, a metal wire electrode, and a common electrode portion in the array holder 8 in the electrophoresis apparatus having the above configuration.

  FIG. 2 is an exploded view of the integrated structure electrode section divided into an insulating member 25a and an insulating member 25b constituting the array holder 8 so that the structure becomes clear. At the time of integration, the insulating member 25b constituting the array holder 8 and the insulating member 25a are engaged. It arrange | positions corresponding to the well 21 of the sample plate 5 corresponding to a capillary array.

  In FIG. 2, the same reference numerals as those in FIG. 1 are omitted because they are the same functions and equivalent parts, and are omitted. Only new reference numerals are described. Reference numeral 23 is a metal wire electrode, 24 is a common electrode part, 25a and 25b are insulating members, 25c is a circular through hole that penetrates the capillary 2a, and 26 is an insertion hole for the electrode rod 30 connected to the power supply part 40. .

  As shown in FIG. 2, the array holder 8 has a corresponding surface with the sample plate 5, and an insulating member 25b formed by horizontally arranging an L-shaped portion on the corresponding surface, and an insulating member 25b. It consists of an insulating member 25a that engages the corresponding surface and the L-shaped portion, and has a structure in which both members are integrated. The array holder 8 is attached to the wall surface of the air thermostat 3 in the drawing by an appropriate means. The same applies to the following modifications.

  The insulating member 25b is provided with capillaries penetrating the corresponding surface with the sample plate 5 at a pitch corresponding to the pitch of the wells 21 of the sample plate 5. A plurality of capillaries 2a (two in the figure as an example), a plurality of metal wire electrodes 23 disposed in parallel to the capillaries 2a in the vicinity of the plurality of capillaries 2a and passing through corresponding surfaces with the sample plate 5, and a sample A common electrode portion 24 fixed on the rising surface of the L-shaped portion orthogonal to the surface corresponding to the plate 5 is disposed. Here, the vicinity of the plurality of capillaries 2a means a position where the plurality of capillaries 2a are simultaneously inserted into the well 21 when the plurality of capillaries 2a are inserted into the well 21. The plurality of metal wire electrodes 23 are all in electrical contact with the common electrode portion 24. This electrode member may contact the capillary.

  Further, the number of through-holes 25c through which the plurality of capillaries 2a are inserted when the insulating member 25a and the insulating member 25b are engaged with each other depends on the pitch of the plurality of capillaries 2a. Only drilled.

  When the insulating member 25a and the insulating member 25b are engaged with each other to form an integrated structure, the capillary 2a, the metal wire electrode 23, and the common electrode portion 24 are engaged with each other. The outer peripheral surface is covered with the insulating member 25a, and only the capillary 2a and the metal wire electrode 3 are seen from the direction side of the sample plate 5. In addition, when setting it as an integrated structure, you may adhere | attach the engaging surface of member 25a, 25b with an appropriate means, for example, an adhesive material as an example.

  Further, in the case of the integrated structure, a plurality of capillaries 2a project outwardly from the through holes 25c of the insulating member 25a and serve as terminal portions of the electrophoresis unit. Therefore, only the capillary 2a can be seen from the opposite direction side of the sample plate 5. By covering the outer periphery with the insulating members 25a and 25b in this manner, arc discharge due to a high voltage applied to the capillary 2a can be prevented.

  With reference to FIG. 3, the voltage application method of the power supply part in the integrated structure of an array holder is demonstrated. FIG. 3A is a rear view of the integrated structure portion of FIG. 2, and FIG. 3B is a plan view of the integrated structure portion of FIG. . In FIG. 3, reference numeral 30 denotes an electrode part (hereinafter referred to as an electrode bar) connected to the power supply part 40. In FIG. 3A, the electrode rod 30 is not shown in order to clarify the integrated structure.

  One or more insertion holes 26 are provided in the common electrode portion 24 provided on the surface orthogonal to the sample plate 5 on the insulating member 25b. An electrode rod 30 is inserted into the insertion hole 26 and is electrically connected to the common electrode portion 24. At this time, although not shown, the electrode rod 30 is urged by an elastic member so as to reduce the electrical contact resistance with the common electrode portion 24. The negative high voltage side of the power supply unit 40 is applied to the other end of the contact surface of the electrode rod 30 with the common electrode unit 24, and the positive side of the power supply unit 40 is connected to the ground side of the electrophoresis ground 10.

  When the capillary array 2 is inserted into the well 21 and a high voltage is applied to the common electrode portion 24 via the electrode rod 30 inserted into the insertion hole 26, the metal wire electrode 3 is electrically connected to the common electrode portion 24. Touching. Since a high voltage is applied, the metal wire electrode 3 and the capillary 2a simultaneously contact the sample in the well 21 of each sample plate 5 or the buffer solution in the buffer container, and the sample is introduced into the capillary 2a or electrophoresed. Has been made.

  With reference to FIG. 4, the modification of the integrated structure electrode part in the array holder of FIG. 2 is demonstrated. In FIG. 4, the same reference numerals as those in FIG. Reference numeral 24a denotes an extended electrode portion of the common electrode portion 24, and 127 denotes an electrical contact portion.

  In FIG. 4, the array holder 8 is disassembled into an insulating member 25b and an insulating member 25a engaged therewith so that the integrated structure becomes clear. At the time of integration, the insulating member 25b and the insulating member 25a are engaged. The capillary array 2 in FIG. 4 is arranged corresponding to the well 21 of the sample plate 5.

  As shown in the figure, the common electrode portion 24 is disposed on a plane corresponding to the sample plate 5 in the insulating member 25b. The metal wire electrode 23 inserted into the insulating member 25b is joined to the common electrode portion 24 by an electrical contact portion 127 by an appropriate means such as welding. An extended electrode portion 24 a of the common electrode portion 24 is provided in the vicinity of the through hole 26 for penetrating the electrode rod 30. In this manner, a high voltage application portion is secured by the extension electrode portion 24 a electrically connected to the capillary array 2 and the metal wire electrode 23.

  With reference to FIG. 5, another modification of the integrated structure electrode portion in the array holder of FIG. 2 will be described. In FIG. 5, the same reference numerals as those in FIG. Reference numeral 128 denotes a platinum vapor deposition electrode deposited on the capillary 2a.

  In FIG. 5, the array holder 8 is disassembled into an insulating member 25b and an insulating member 25a engaged therewith so that the structure becomes clear. The capillary array and the sample plate 5 are arranged correspondingly. Is done. When the array holder 8 is integrated, the insulating member 25b and the insulating member 25a are engaged.

  The difference between this modification and FIG. 2 is that a vapor-deposited metal film is used as the electrode 28 instead of the metal wire electrode as each electrode. The vapor deposition electrode 128 is provided with a vapor deposition portion from the end portion on the sample side of the metallic tube of the capillary 2 a to a portion corresponding to the common electrode portion 24. The vapor deposition part is in electrical contact with the common electrode part 24.

  Further, the insertion hole for engaging the insulating member 25a in FIG. 2 with the insulating member 25b and projecting the capillaries 2a outward from the array holder 8 is a semicircular shape 25d.

  With reference to FIG. 6, the modification of the integrated structure electrode part in the array holder of FIG. 4 is demonstrated. In FIG. 6, the same reference numerals as those in FIG. 4 are equivalent products having the same function and the same specifications, so that the repetitive explanation is omitted and only new numbers are explained. Reference numeral 29 denotes a stainless steel cylindrical electrode.

  FIG. 6 shows the array holder 8 disassembled into an insulating member 25b and an insulating member 25a engaged therewith so that the structure becomes clear. The capillary array is arranged corresponding to the sample plate 5. The When the array holder 8 is integrated, the insulating member 25b and the insulating member 25a are engaged. The difference between this modification and FIG. 4 is that a cylindrical electrode 29 into which a capillary is inserted is used as an electrode for each capillary 2a, instead of a metal wire electrode.

  The cylindrical electrode 29 is provided with a cylindrical tube surrounding each capillary 2 a from the sample-side tip of the capillary 2 a to the common electrode part 24, and an electric contact part 27 between the common electrode part 24 and the cylindrical electrode 29 is provided. Is. In the present modification, the gap is filled by bonding such that another sample does not remain in the gap between the cylindrical electrode 29 and the capillary 2a.

  The shape of the insulating members 25a and 25b used in the above embodiments is not limited to the above, and various shapes may be used.

[Example 2]
Next, the overall configuration of the capillary array assembly will be described. With reference to FIG. 7, the configuration of a capillary array using the array holder shown in FIG. 6 will be described.

  As described with reference to FIG. 6, the array holder 8 is provided with a common electrode portion 24 (FIG. 7) in which a cylindrical electrode 29 surrounding each capillary 2a is provided on a surface corresponding to the sample plate 5 from the sample-side tip of the capillary 2a. In this case, the electrical contact portion 127 makes contact.

  As shown in the figure, 16 of the capillary array 2 and the cylindrical electrode 29 as described above are arranged according to the pitch of the wells 21 of the sample plate 5, and the array holder 8 is arranged so that eight are arranged in two rows. The insulating member 25 is passed through the hole.

  Although not described again, as described in FIG. 6, the insulating member 25 includes two insulating members 25a and an insulating member 25a (not shown in FIG. 7 because they are engaged with each other). Is engaged.

  Further, the common electrode portion 24 from the outside of the capillary array 2 is provided by an electrode rod 30 (see FIG. 3) inserted into a through hole 26 formed in a part or a plurality of portions of the insulating member 25 covering the common electrode portion 24 and the like. A high voltage can be applied to the electrophoresis part via

  When the cylindrical electrode 29 provided at the tip and the tip of the penetrated capillary 2a is inserted into each well 21 or buffer tank 6 (both not shown in FIG. 7) of the sample plate 5, Electrophoresis is performed. An optical analysis unit 13 is attached to the end of each capillary 2a. Then, the gel block 9 is connected.

  7 as described above, that is, the capillary array 2 using 16 capillaries 2a includes not only the capillaries 2a but also the cylindrical electrode 29 and the common electrode portion 24, and is attached to and detached from the electrophoresis apparatus. Can be done in a single operation and easy to insert into the well. Therefore, replacement of the capillary array is easy, and since the electrode and the capillary are integrated with one array holder, it is not necessary to pay attention to the arrangement accuracy between the electrode and the capillary. In the above description, the capillary array using the array holder shown in FIG. 6 has been described, but it goes without saying that the same applies to other array holders.

  Next, the operation of the electrophoresis apparatus having the above configuration will be described using the capillary array of FIG. In preparation for the operation of the electrophoresis apparatus, a sample is injected into each of 8 × 12 = 96 wells 5a of the sample plate 5 by pipetting. The lid of the air thermostat 3 is closed, and an air circulation flow is formed by the fans 27 and 28 attached to the inside. At this time, the air thermostat 3 covers the outer surface with a heat insulating material 26 except for a part, and a heat-coolable element 22 such as a Peltier element is provided at the portion where the heat insulating material is removed, and the inner surface has a good heat conducting member. 23, the heat transfer from the heatable / coolable element 22 is quickly transmitted through the inner surface.

  Further, the fans 27 and 28 are controlled by the control computer 50 and activated. Since the fans 27 and 28 use a fan that sucks air from the rotation direction and blows air in the radial direction, a circulating air flow with a large air volume is obtained, and the air thermostat 20 has a small thickness. The heat insulating member 26, the element 22 that can be heated and cooled, and the good heat conducting member 23 on the inner surface cooperate to make the temperature inside the air thermostat 20 uniform. The entire capillary array 2 of the electrophoresis apparatus 1 is maintained at a constant temperature.

  After such a state, the control computer 50 moves the microtiter plate 5 in the front-rear direction by the autosampler 7 and stops when each well 21 of the microtiter plate 5 comes directly below the capillaries 2a of the capillary array 2. . Next, the autosampler 7 is raised and stopped at the position where the capillary 2 a is inserted into the sample in the well 21.

  Next, the capillary array 2 is inserted into the sample in the well 21. At this time, 16 capillaries 2a, 16 electrodes 29, and the common electrode portion 24 in contact with these electrodes 29 are covered with insulating members 25a and 25b to form an integrated electrode portion. These members are easily and simultaneously inserted into the sample of the well 21.

  When the metal wire electrode 23 as shown in FIG. 2 is used, it should not be brought into contact with the capillary 2a in a state where the capillary array 2 is not inserted into the well 21 of the sample plate 5. When they are brought into contact with each other, another sample remains in the gap between the two due to capillary action, which hinders accurate analysis.

  In this inserted state, the power supply unit 40 is operated by the control computer 50, and the electrophoresis ground 10—the gel block 9—the gel of the capillary 2a through the electrode rod 30 (see FIG. 3) inserted into the through hole 26. -By applying a negative high voltage to the circuit formed by the sample-electrode 29, the sample in the well 5a is introduced into the capillary 2a. Here, the negative high voltage is cut off.

  The autosampler 7 is moved again and stopped at the position where the lower end of the capillary 2 a is inserted into the buffer tank 6. Next, the autosampler 7 is moved up and down, the capillary 2a is inserted into the buffer solution in the buffer tank 6, and the electrode 29 is also inserted into the buffer solution. The insertion at this time is performed simultaneously and easily as each member is inserted into the sample.

  In this state, a negative high voltage is applied again between the electrophoresis ground 10 -gel block 9 -gel-sample-buffer solution-electrode 29 in the capillary 2a. The sample introduced into the capillary 2a by this high voltage application is separated by electrophoresis.

  Note that the gel polymer in the capillary array 2 is replaced with a new gel polymer for each measurement. This closes the solenoid valve 11 and drives the gel filling syringe 12 to fill the capillary array 2 with the gel polymer in the syringe 12. These controls are performed by the control computer 50.

  The optical analysis unit 13 is shielded from the outside, and a sample excitation laser beam (not shown) is guided to the capillary 2 a at the position of the optical analysis unit 13. Fluorescence emitted from a fluorescent reagent bound to DNA to be electrophoresed inside the capillary 2a is detected, and DNA is analyzed from this detection signal by a computer. Further, the present invention can be applied to the supply of a sample stage such as a multiwell by electrophoresis in addition to the separation and analysis of a sample such as DNA.

It is a block diagram of the capillary electrophoresis apparatus for DNA sequencers. It is explanatory drawing of the electrode part in the electrophoresis apparatus of FIG. It is connection explanatory drawing of the power supply part in the electrophoresis apparatus of FIG. It is explanatory drawing of the other electrode part in the electrophoresis apparatus of FIG. It is explanatory drawing of the further another electrode part in the electrophoresis apparatus of FIG. It is explanatory drawing of another electrode part in the electrophoresis apparatus of FIG. It is explanatory drawing of a capillary assembly.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Capillary electrophoresis apparatus for DNA sequencers, 2 ... Capillary array, 2a ... Capillary, 3 ... Air thermostat, 5 ... Sample plate, 6 ... Buffer tank, 7 ... Autosampler, 8 ... Array holder, 9 ... Gel block, DESCRIPTION OF SYMBOLS 10 ... Electrophoretic ground, 12 ... Gel filling syringe, 13 ... Optical analysis part, 23 ... Metal wire electrode, 24 ... Common electrode part, 25a, 25b ... Insulating member, 26 ... Insertion hole, 127 ... Electrical contact part , 128 ... deposition electrode, 29 ... cylindrical electrode, 30 ... electrode part, 40 ... power supply part, 50 ... control computer.

Claims (9)

A capillary array having a plurality of capillaries forming an electrophoresis path, a plurality of metal tubes electrically connected to a power source that applies a voltage to the electrophoresis path, and a plurality of wells for storing samples A capillary electrophoresis apparatus comprising a sample moving table for moving a sample plate having
A capillary electrophoresis apparatus comprising a control device for controlling a sample moving table so that a capillary and a metal cylinder are inserted into a sample.   2. The capillary electrophoresis apparatus according to claim 1, wherein the capillary and the metal cylinder are cylindrical, and the outer diameter of the capillary and the inner diameter of the metal cylinder are substantially the same.   2. The capillary electrophoresis apparatus according to claim 1, wherein a gap between the capillary and the metal cylinder is bonded. A capillary array having a plurality of capillaries forming an electrophoresis path, a plurality of vapor deposition electrodes deposited on each capillary and electrically connected to a power source for applying a voltage to the electrophoresis path, and a plurality of wells for storing samples A capillary electrophoresis apparatus comprising a sample moving table for moving a sample plate having
A capillary electrophoresis apparatus comprising a controller for controlling a sample moving table so that a capillary and a vapor deposition electrode are inserted into a sample. A capillary array having a plurality of capillaries that form an electrophoresis path, a plurality of metal wire electrodes that are electrically connected to a power source that applies a voltage to the electrophoresis path, and that is disposed in the vicinity of each capillary, and contains a sample A capillary electrophoresis apparatus comprising a sample moving table for moving a sample plate having a plurality of wells,
A capillary electrophoresis apparatus comprising a control device for controlling a sample moving table so that a capillary and a metal wire electrode are inserted into a sample.   It has a plurality of capillaries forming an electrophoresis path, one end is a sample supply unit, the other end is a capillary array that constitutes a sample detection unit, and a power source for inserting a plurality of capillaries and applying a voltage to the capillary array A capillary array assembly comprising a metal cylinder electrically connected to the capillary array, a capillary array, and a capillary array holder for holding the metal cylinder.   A plurality of capillaries inserted into each well to form an electrophoresis path, a plurality of capillaries inserted into each well and electrically connected to a power source, and a plurality of capillaries and a plurality of metal tubes held together Capillary array assembly comprising a capillary array holder for   8. The capillary array assembly according to claim 6, wherein the capillary and the metal cylinder are cylindrical, and the outer diameter of the capillary and the inner diameter of the metal cylinder are substantially the same.   8. The capillary array assembly according to claim 6, wherein a gap between the capillary and the metal tube is bonded.

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