JP2001099813A - Capillary electrophoresis apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electrophoresis apparatus which uses an air thermostat made compact and uniformed in internal temperature by using a fan in which an air in direction and an air out direction intersect. SOLUTION: The apparatus uses an air constant temperature bath 3 having an outer peripheral part covered with an insulating material 26, an element 22 which can heat and cool an internal air of the air constant temperature bath 3, and fans 27 and 28 for circulation which blow out the air in a diametrical direction to a rotary axis. A structure 29 and a curve member 30 are set to an inner wall face of the air constant temperature bath 3 to promote a circulation flow of the air. The air constant temperature bath 3 can thus be reduced in volume. A position dependency and a change of a temperature of the air in the bath are reduced. The electrophoresis apparatus of a good separating efficiency is obtained.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electrophoresis apparatus, and more particularly to a capillary electrophoresis analyzer suitable for use in a DNA sequencer (DNA base sequence analyzer) for analyzing a biological sample such as DNA (deoxyribonucleic acid). It relates to an air oven.

[0002]

2. Description of the Related Art In the analysis of a DNA base sequence by electrophoresis, the temperature fluctuation or temperature dependency of the electrophoresis section affects the migration speed of the sample in the electrophoresis section, and the temperature of the electrophoresis section is kept constant. Is essential for ensuring the resolution and accuracy of analysis. Conventionally, DNA base sequence analysis is performed by sandwiching a gel between two glass plates and applying a voltage to both ends of the glass plate to obtain a DNA sample.
The technology described in JP-A-8-297111 and JP-A-7-301419 is known as a technique for keeping the temperature of the electrophoresis section constant.

According to the technique described in Japanese Patent Application Laid-Open No. 8-297111, a glass plate for maintaining a constant temperature is installed in close contact with a member having good thermal conductivity, and the periphery thereof is covered with a heat insulating material to prevent heat radiation. The temperature of the glass plate is made uniform. In the technique described in Japanese Patent Application Laid-Open No. Hei 7-301419, two transparent glass plates sandwiching a gel forming an electrophoresis section, a temperature control plate which is in close contact with the glass plate, and a rear surface thereof are attached in close contact with each other. It includes a Peltier device, a radiating fin mounted on a heat radiation side of the Peltier device, and a radiating fan that radiates heat of the radiating fin.

In recent years, a capillary electrophoresis apparatus in which a quartz capillary (capillary) is filled with a gel and a voltage is applied to both ends thereof to electrophoretize a sample has become widespread. The number of capillaries in this capillary electrophoresis apparatus is usually one, and the temperature control method is similar to a combination of the above two techniques.

That is, the temperature control section uses two planar members having good heat conductivity as heat radiating plates, and further attaches an insulating sheet to sandwich the capillary as the electrophoresis section between the insulating sheets. Then, a heat source such as a heater is brought into contact with at least one surface of the member having good heat conductivity, and the surroundings are covered with a heat insulating material.

[0006] In the above-mentioned technique, an air thermostat is not used for controlling the temperature of the electrophoresis section of the electrophoresis apparatus. However, when an air thermostat is used, temperature control is performed. Control is performed in which a heater is attached to a metal plate in a thermostatic chamber and the internal air is circulated by a fan.

The fan used for the air circulation uses a fan that sucks air in a direction parallel to the rotation axis of the fan and blows out the air in the direction opposite to the suction direction. The size of the inside is not smaller than the diameter of the fan, and a certain thickness is required. Japanese Patent Application Laid-Open No. 7-27571 describes this.
No. 9 publication technology.

In the technique disclosed in Japanese Patent Application Laid-Open No. 7-275719, a fan is arranged at substantially the center of a thermostatic chamber, and a heat sink in contact with the heater is arranged around the fan, thereby radiating heat from the heater. Trying to increase efficiency.

[0009]

In the above, temperature control in the case of a single capillary and an air thermostat has been described. The technique disclosed in Japanese Patent Application Laid-Open No. 8-297111 only adjusts the heat radiation of Joule heat due to electrophoresis of a sample, and does not intend to control the temperature by installing a heat source for heating. JP-A-7-301419
In the technique disclosed in Japanese Patent Application Laid-Open Publication No. H11-157, there is a problem that the entire surface of the glass plate is not covered with the Peltier element, and only local temperature control is performed. In the technique disclosed in Japanese Patent Application Laid-Open No. 7-275719, the position of the fan in the thermostat is limited to almost the center, and the heat sink must be arranged uniformly with respect to the fan, which is a design limitation. There is a problem.

Further, when constructing a multi-capillary electrophoresis apparatus for simultaneously analyzing a plurality of samples, there is a problem in using a technique of sandwiching an electrophoresis section between planar heat source plates as in the related art.

When a sample to be analyzed is set in a commercially available microtiter plate, a 96-well commercially available microtiter plate has 8 × 12 = 96 matrix holes (hereinafter referred to as wells) for introducing a sample. It is arranged in a shape. When simultaneously analyzing samples in 8 rows of wells or 12 columns of wells among the 8 × 12 = 96 matrix-like wells, introduce a sample and perform electrophoresis. (Hereinafter, referred to as a capillary array) can be arranged in the same plane. Therefore, the temperature can be controlled by sandwiching the heat source between the planar heat source plates described in the related art.

However, when the number of samples to be analyzed simultaneously is, for example, 16 samples, a sample set in a 96-well microtiter plate is introduced into a capillary array and electrophoresis is performed. Usually, samples from 8 × 2 = 16 wells on a microtiter plate are simultaneously introduced into a capillary array for analysis. In this case, since it is impossible to arrange the sample introduction portion in the same plane, there is a problem that a conventional method of sandwiching the sample by a plate of a planar heat source cannot be adopted.

Further, a high voltage for electrophoresis is applied to each capillary, and a small amount of current flows through the capillary gel. For this reason, there is also a problem that the Joule heat is generated from the capillary itself, and the Joule heat cannot be ignored in the capillary array.

Further, the temperature control of the air thermostat using the conventional air stirring fan will be described with reference to FIG. FIG. 7 is an explanatory view of an air thermostat in which a conventional air circulation fan is used. FIG.
A case will be considered in which a fan is used which draws air from a direction parallel to the rotation axis (white arrow in the figure) and blows out air in a direction opposite to the rotation axis (white arrow in the figure) as shown in FIG. As shown in FIG. 7A, a square fan having an outer shape of about 20 mm is commercially available as the above fan. In this commercially available square fan, the thickness H of the thermostat is about 20 mm. Moreover, the air flow of such a fan is at most about 0.02 m ³ / min, and the maximum static pressure is less than 30 Pa (Pascal).

Therefore, when the above-mentioned square air circulation fan is used, the capacity of air volume and static pressure is small, and the thickness in the thermostatic chamber cannot be smaller than the diameter of the air circulation fan. In order to increase the air volume and static pressure capability,
The size of the air circulation fan must be increased, and the internal volume of the thermostatic chamber is more than necessary. For this reason, the position dependence of the temperature in the thermostatic chamber and the non-uniformity of the temperature are increased, which affects results such as resolution of analysis.
As a result, there is also a problem that the size of the capillary electrophoresis apparatus is increased.

The present invention has been made to solve these problems, and has been made in order to solve the above-mentioned problems. The size, particularly the thickness, of a thermostat in a capillary electrophoresis apparatus having a sample introduction portion that cannot be arranged in the same plane is provided. It is an object of the present invention to reduce the temperature and the position dependency and non-uniformity of the temperature in the air oven.

[0017]

In order to achieve the above object, a configuration of a capillary electrophoresis apparatus according to the present invention comprises an electrophoresis section having at least one or more capillaries, and a heat insulating material except for a part of the outer periphery. An air oven section that is covered and has at least one or more fans for forming the electrophoresis section and the air circulation flow, and heating for contacting air in the air oven chamber at a portion where the heat insulating material is removed. Alternatively, any of heating and cooling elements, and at least a control unit for controlling the temperature in the air chamber, the fan sucks air in the rotational axis direction and air outlet in the radial direction. Wherein the thickness direction of the fan and the thickness direction of the air constant temperature chamber are arranged so as to coincide with each other.

[0018] In the capillary electrophoresis apparatus according to the preceding paragraph, when the at least one or more fans are plural, the plural fans are arranged at mutually symmetrical positions in the air thermostat. It is. In the capillary electrophoresis apparatus according to the preceding paragraph, the air thermostat has a structure in which an inner surface of the air thermostat storage is configured to promote formation of the air circulation flow. In the capillary electrophoresis apparatus according to the preceding paragraph, the air outlet of the fan is directed toward the inner surface of the air oven chamber, and the air flow reflected by the inner surface is configured to promote the formation of the air circulation flow. It is assumed that. In the capillary electrophoresis apparatus according to the preceding paragraph, a good heat conductive plate material that covers at least one inner surface in the air thermostatic chamber, and contacts the air in the air thermostatic chamber via the good heat conductive plate. The present invention is characterized in that either heating or heating / cooling element is provided. In the capillary electrophoresis apparatus according to the preceding paragraph, the portion on the good heat conductive plate corresponding to the portion where the good heat conductive plate is in contact with any of the heating or heatable / coolable elements has a low heat conductivity. A member is provided. In the capillary electrophoresis apparatus according to the preceding paragraph, the low thermal conductive member has a structure that promotes the formation of an air circulation flow in the air chamber.

The above-configured capillary electrophoresis apparatus according to the present invention will be simply described. Since the capillary electrophoresis apparatus according to the present invention controls the temperature of a capillary array having a sample introduction portion that cannot be arranged in the same plane and cannot ignore the self-heating generated by the capillary itself, it is sandwiched between planar heat source plates. Instead of using the temperature control method, an air oven is used, and the air in the air oven is efficiently circulated by the fan. In order to control the temperature of the capillary array, to reduce the volume of the space in the air oven chamber, to improve the control efficiency, and to reduce the size of the entire electrophoresis apparatus, an air oven is possible. Make it as small as possible. Therefore, the thickness is almost the same as the thickness of the sample introduction portion that cannot be arranged on the same surface, or at most
It is configured to be a thin thermostat with a thickness of about twice.

When a local heating / cooling heat source is employed for temperature control, a plate-like material having good heat conductivity is installed in the thermostatic chamber so as to reduce the temperature gradient in the thermostatic chamber. I do. In addition, in order to perform electrophoresis, in order to prevent discharge at the time of applying a high voltage to the capillary array, when a metal material is used as a material having good heat conductivity, it is configured to be covered with an insulating film. is there.

Further, in order to efficiently circulate the air in the thermostatic chamber having a small thickness in the thermostatic chamber, a thin fan having a different air suction direction and a different blowing direction is installed. The fan shall be arranged at a position suitable for efficiently circulating air, and in order to promote the circulating flow of air, the inside of the air oven, particularly each corner in the oven, has a curved surface having a large curvature. And Alternatively, a member that promotes the circulation of air is provided in the thermostatic chamber.

By these means, the position dependence and non-uniformity of the temperature in the air chamber can be kept small, and the size of the air chamber cannot be arranged on the same plane. The bottom surface can be reduced to a size such that the capillary is routed from the sample introduction part to the electrophoresis result detection part.

[0023]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A capillary electrophoresis apparatus for a DNA sequencer according to the present invention will be described with reference to FIGS. 1 is an explanatory view of a capillary electrophoresis apparatus for a DNA sequencer, FIG. 2 is an explanatory view of an air thermostat in the capillary electrophoresis apparatus for a DNA sequencer of FIG. 1,
FIG. 3 is an explanatory view of the air direction of suction and blowing of the fan used in the air thermostat of FIG. 2, and FIG. 4 is an explanatory view of one fan having the air direction of suction and blowing shown in FIG. 5 is an explanatory view of an air oven equipped with another fan having the air directions of the suction and the blow shown in FIG. 3, and FIG. 6 is an explanatory view of a modification of the air oven of FIG.

First, the overall configuration of a capillary electrophoresis apparatus for a DNA sequencer will be described. In FIG. 1, 1 is a capillary electrophoresis device for a DNA sequencer (referred to as an electrophoresis device), 2 is a capillary array, 2a is a capillary, 3 is an air thermostat, 5 is a sample tray, 5a is a well, 6 is a buffer tank, 7 is a buffer tank. Is an autosampler movable in the XYZ directions, 8 is an array holder for fixing a capillary array, 9 is a gel block, 10 is an electrophoresis ground, 12 is a syringe for gel filling, 13 is an optical analyzer, 40
, A power supply unit; and 50, a control computer.

In FIG. 1, the capillary array 2 comprises at least one or more capillaries 2 a, most of which are set so as to be stored in the air thermostat 3. The air oven 3 is covered with a heat insulating material except for a part of the outer peripheral portion thereof, and the removed part is heated or brought into contact with the air in the air oven 3 by heating or heating / cooling. Are provided. When the electrophoresis measurement is performed, the lid of the air oven 3 (not shown, but attached to the front side of the air oven 3 by, for example, a hinge mechanism) is closed, and the air oven 3 is closed. An air circulating flow is formed by the attached fans 27 and 28 so that the temperature of the electrophoresis section in the refrigerator can be made uniform.

In the vicinity of the tip of the capillary array 2,
A sample tray 5 for setting a sample is provided.
Further, near the sample tray 5, a buffer tank 6 for preventing a discharge when a voltage is applied to the capillary array 2 and containing a buffer solution for performing electrophoresis is provided. The sample tray 5 is a commercially available microtiter plate. Although not shown in detail, the microtiter plate is made of synthetic resin, has a rectangular planar shape, and has 8 × 12 = 96 wells 5a arranged in a matrix.

Although the cross-sectional shape of the well 5a is not shown in detail, a cylindrical portion is formed from the upper surface side of the microtiter plate to the bottom portion, and then a tapered portion is formed. The tapered portion is designed to facilitate the work of injecting and introducing a sample. The sample tray 5 and the buffer tank 6 are mounted on an autosampler 7 that can move in the XYZ directions. Autosampler 7
Is mounted on the bottom of the housing of the electrophoresis apparatus 1 and positioned in the front-back, left-right, and up-down directions.
Controls a moving motor (not shown) to move.

The capillary array 2 includes a capillary 2
a; 8 × 12 = 96 pieces are arranged in a matrix, and the inside thereof is filled with a gel for electrophoretic separation. The tip end of the capillary array 2 corresponding to the sample tray 5 is fixed by an array holder 8, and the other tip end of the capillary array 2 is connected to and fixed to a gel block 9.

The gel block 9 is filled with a gel (polymer) as a separation medium from a connection portion with the capillary array 2 to an electrophoresis ground 10.
Are connected to the ground side of the electrophoresis ground 10. The electrophoresis ground 10 is attached to the bottom of the housing of the electrophoresis apparatus 1 while being electrically insulated. A metal (for example, SUS) electrode (not shown) is disposed near the periphery of each of the capillaries 2a, and is held by the array holder 8, so that the capillary 2a moves up and down, back and forth, and left and right, thereby moving the sample and the sample. When moving into the buffer solution, it moves at the same time. The high voltage side of the power supply unit 40 is connected to the electrodes.

An optical analyzer 13 is provided in the capillary array 2 near the end thereof in the drawing. The optical analyzer 13 includes, for example, a laser light source for exciting a sample in the capillary array 2 through a transparent window (not shown) of the capillary array 2 and an optical sensor for detecting the excited excitation light, The control computer 50 identifies the type of DNA from the detected optical signal.

Further, the electrophoresis apparatus 1 is provided with a gel filling syringe 12 for exchanging the gel every time one electrophoresis is performed, and an electromagnetic valve 11 for preventing a backflow at the time of the gel exchange. ing. Electrophoresis apparatus 1 described above
A control computer 50 is provided to control the components such as the autosampler 7, the electromagnetic valve 11, the gel filling syringe 12 for gel exchange, and the power supply unit 40.

In the above-mentioned electrophoretic separation apparatus, as described above, in order to improve the performance of the electrophoretic separation, the position dependence and the temperature non-uniformity with respect to the temperature in the air oven are reduced, and the air is separated. In order to reduce the size of the thermostat, the structure of the air thermostat, the size and function of the fan forming the circulating flow, and the mounting method have a great influence. Each embodiment of the structure of the air thermostat and the fan for forming a circulating flow in the electrophoretic separation apparatus of the present invention will be described in detail with reference to FIGS.

In the air thermostat of the electrophoresis apparatus according to the present invention shown in FIG. 2, FIG. 2 (a) shows the air thermostat of the electrophoresis apparatus according to the present invention in which a ceiling portion covered with a heat insulating material is removed. FIG. 2B is a plan view, FIG. 2B is a side sectional view, and FIG. 2C is an enlarged view of a circle in FIG. 2B.
In FIG. 2, 3 is an air oven, 21 is a mounting position of the capillary array 2, 22 is a heat source, 23 is a good heat conducting plate, 2
Reference numeral 4 denotes a space inside the thermostatic chamber, 25 denotes an insulating material, and 26 denotes a heat insulating material.

The dimensions of the oven chamber are, for example, the width (FIG. 1).
W) was assumed to be about 200 mm, the height (H in FIG. 1) was about 420 mm, and the thickness (T in FIG. 1) was about 20 mm. This size is substantially determined by the length of the capillary array 2 used. The reason will be described in detail below. As an example of a sample introduction part that cannot be arranged in the same plane, a capillary array 2 for simultaneously introducing a sample from 8 × 2 = 16 wells 5a of a microtiter plate having 96 wells 5a and performing analysis is used. The case of use will be described.

The wells 5a are arranged at a pitch of about 9 mm. Therefore, the dimensions required for the sample introduction part are as follows.
It is 63 × 9 mm. Since the size of 63 mm has eight wells 5a, the interval is 7 sections and 9 × 7 =
63 mm. In order to make the capillary array 2 detachable, the capillary array 2 having 16 capillaries 2a must be fixed by an array holder 8 having a predetermined thickness. It is assumed that the size of the array holder 8 after fixing the capillary array 2 is 72 mm in width × 18 mm in thickness.
At the set position 21.

Here, the arrangement pitch of the capillaries 2a is
Equal to the array pitch of the microtiter plate, 96
Since the arrangement pitch of the wells 5a in the microtiter plate of the individual wells 5a is 9 mm, the thickness of the air oven 3 needs to be 9 mm or more. here,
The thickness of the array holder 8 is set to 20 mm, which is approximately the same as the thickness of 18 mm, in order to prevent the capillary 2 a from contacting the inner wall surface of the air oven 3. It is not always essential not to contact the wall surface, but if there is a temperature gradient on the wall surface, the temperature of the capillary 2a is affected by the temperature gradient. In this way,
The dimensions of the air bath are determined.

Next, the structure of the air oven will be described. In FIG. 2B, a heat source 22 is arranged on the back (right side in the figure) of the air oven 3. The heat source 22 is desirably a planar heating element that covers the entire bottom surface of the inside of the air oven 3 and provides a uniform temperature distribution at all locations on the bottom surface. In addition, since the heating element can only be heated, if it is necessary to maintain the temperature inside the chamber of the air oven 3 below room temperature, a heat source capable of heating and cooling using a Peltier element or the like should be provided. Is preferred.

A Peltier element is more expensive than a rubber heater, and a Peltier element that cannot cover the entire bottom surface with one element is not commercially available. As shown in the heat source 22 of FIG. Of course, when a Peltier element is used as the heat source 22, it is needless to say that covering the bottom surface as much as possible gives a uniform temperature distribution in the air oven 3.

Further, as shown in FIG. 2 (c), the heat conductive plate 23 is disposed so as to cover almost the entire bottom surface of the inside of the oven 3 and is in contact with the heat source 22. Note that FIG.
FIG. 2C is an enlarged view of a part of FIG. 2B, and a portion where the heat conductive plate 23 and the heat source 22 are in contact is not shown.

Since the heat conductive plate 23 has a constant heat capacity, first, even if the temperature of the heat source 22 rises or falls due to temperature control, the temperature fluctuation is absorbed and the air inside the air chamber 3 is absorbed. The fluctuation of temperature fluctuation is reduced. Second, the heat source 22
Can be efficiently transmitted to the inside of the air oven 3 and a substantially uniform temperature distribution can be given to all locations on the bottom surface. Actually, the heat conductive plate 2 is affected by heat leak from the outer periphery of the air oven 3 and thermal conductivity of a member covering the outer periphery.
A temperature gradient occurs in the plane of No. 3.

The heat conductive plate 23 may be provided on the ceiling without contacting the heat source 22. It may be provided on both the bottom surface and the ceiling which are in contact with the heat source 22. Further, it may be provided on the side wall surface inside the refrigerator of the air oven 3. A change in the temperature of the heat conductive plate 23 is transmitted to the internal air layer 24 of the air thermostat 3, and the temperature changes.

When the material of the heat conductive plate 23 is a conductor, the entire heat conductive plate 23 or the entire inner wall of the air thermostat is covered with the insulating material 25. The heat conductive plate 23
This is not always necessary when the material of the first member is not a conductor. However, in the case of a conductor, after the capillary array 2 is set, arc discharge may occur due to the high voltage applied to the capillary array 2 in the chamber of the air thermostat 3 during electrophoresis. The insulating film 5 is also required for protection of the electric circuit around. For this reason,
The periphery of the air oven 3 is covered with a heat insulating material 26.

Next, the installation of a fan for forming an air circulation flow will be described. A fan 27 for forming an air circulation flow for temperature control is provided in the chamber of the air oven 3.
28 are provided. In the air thermostat 3, it is desirable to reduce the size of the air thermostat 3 as much as possible in order to reduce the volume of the space for temperature control and to improve the control accuracy and efficiency, and to reduce the overall size of the electrophoresis apparatus 1.

Therefore, as shown in FIGS. 3A and 3B, a fan that sucks air from the direction of the fan rotation axis and blows air in the fan radial direction is used. FIG.
One-way suction, one-way blowout, FIG. 3B shows one-way suction and one-way blowout. FIG. 4 shows a small-sized sirocco fan having a one-way suction and one-way blowout shown in FIG. 3B.

A fan having a blowing direction shown in FIGS. 3A and 3B has recently been sold as a standard product for cooling a CPU or the like of an electric circuit board, and has a thickness of 5 mm to 8 mm.
There are various types, and those having a maximum air flow of 0.04 m ³ / min or more and a maximum static pressure of 50 Pa or more are sold as standard products. The installation of the fan is performed by the capillary array 2
If a position that does not physically interfere with the fan is selected, the thickness is about 8 mm, so that the mounting becomes easy and the installation area of the fan can be increased.

The installation area of this fan is about 45 mm in width.
A case where a fan having an area of 45 mm in height is installed in FIG. 2A will be described with reference to FIG. In this case, the width of the fan refers to a fan diameter in the same direction as the width W of the illustrated air bath 3, and the height of the fan refers to a fan having the same size as the height H of the illustrated air bath 3. The diameter means the thickness of the fan, and the thickness T of the air bath 3 shown in the figure.
And the size orthogonal to the fan diameter in the same direction as the above.

FIG. 5 shows a case where the width in the blowing direction of FIG. 3A or FIG.
This shows a case where a fan having an area of 5 mm × 45 mm in height is installed. Since the area inside the chamber of the thermostat 20 is small and a strong air circulation flow is obtained, very good temperature control characteristics are obtained. An air thermostat having a temperature is obtained. In FIG. 5, a white arrow and a point in a circle indicate a position from the back of the paper to the paper.
In the circles, x indicates the wind direction from the front of the paper to the paper.

Further, among the small sirocco fans shown in FIG. 4, those having a thickness of less than 20 mm are sold as standard products. In the case of the sirocco fan shown in FIG. 4, since the thickness of the fan is slightly less than 20 mm, it is necessary to secure a space around the air suction port on the ceiling side of the inside of the air constant temperature bath 3; 06m ³ / min or more, maximum static pressure 70P
There are more than a. Although the air thermostat to which the sirocco fan is attached is not shown, the thickness is 20 mm as compared with the case where the fan in which the air suction direction and the blowout direction are parallel as shown in FIGS. 7A and 7B. Since the air volume can be secured three times or more and the air can be strongly circulated in a thermostat having a small thickness, an air thermostat having very good temperature characteristics can be obtained.

Next, a modification of the air thermostat in the electrophoresis apparatus according to the present invention will be described with reference to FIG. In this modification, the installation position of the fan, the blowing direction of the fan, and the circulation of the air flow are improved so as to promote the circulation of the air flow in the air oven chamber in the above embodiment.

FIG. 6 (a) is an improvement of the air oven 3 shown in FIG. 2 (a), and FIG. 6 (b) shows a case where there is a portion where the air flow in the air oven 3 stagnates. It shows a countermeasure. FIGS. 6A and 6B are plan views of the thermostat of the electrophoresis apparatus, in which a ceiling portion covered with a heat insulating material is removed. In FIG. 6, 27 and 28 are air circulation fans, 29 is a curvature structure provided at a corner of the internal space of the air oven, and 30 is a curved member for promoting air circulation in the air oven. .

In FIG. 6 (a), in order to reduce the position dependency and non-uniformity of the air temperature in the air oven chamber, the air in the air oven chamber is circulated by a fan. If there is a stagnant portion, the flow rate and amount of the air flow fluctuate, so that the temperature of the portion becomes unstable compared to a portion where the air flow does not stagnate.

Therefore, in order to generate a strong air circulation flow, each corner of the inner wall surface of the air thermostat 3 is provided with a structure 29 having a large radius of curvature. Preferably, the radius of curvature is as large as possible. With such a structure, the air can be circulated satisfactorily without stagnation at each corner of the inner wall surface of the air oven 3.

Further, FIG. 6 (a) shows that fans 27 and 28 are installed at two diagonal positions in order to promote the air flow, and the wind direction is set in a direction parallel to the inner surface in the air oven chamber. A circulating flow is generated in the thermostatic chamber. FIG. 6 (a)
In the air agitating fans 27 and 28, air is sucked in from above (indicated by x in the figure) or from the side (arrows with oblique lines in the figure), and the direction of the white arrow in the figure is It is. As shown in the figure, it can be seen that the suction direction of the fan and the blowing direction intersect.

In FIG. 6B, the fans 27 and 28 are installed at almost diagonal positions. However, when the wind direction is set parallel to the inner surface as shown in FIG. Is located at the lower left corner in the figure, and if the corner cannot have a curvature structure, the circulating air flow is stagnated. In order to prevent the stagnation, as shown in FIG. 6 (b), the air blowing direction is changed from the fan 27, and the air flow is once applied to the lower wall surface in the air oven, and the air flow due to the reflection is reduced to the lower left. Are formed upwards from the corners to promote air circulation.

Needless to say, it is preferable that there is no structure that hinders the circulating air flow as shown in FIG. 6A, but the structure that hinders the circulating air flow as shown in FIG. Even in the case where it exists, a strong circulating flow can be generated by examining the blowing direction of the air from the fan 27.

In order to examine the direction in which air is blown out from the fans 27 and 28 in FIG. 6B, it is sufficient to confirm the wind direction by simulation by numerical calculation or smoke or tuft. The above-mentioned tuft refers to a thin and light fiber that is made into a short tufted spring.

Further, in FIGS. 6 (a) and 6 (b),
As shown in FIG. 6C, a curved member 30 made of a heat insulating material is provided upright on the bottom surface in the air oven.
An aluminum plate 23 is provided on the bottom surface of the chamber of the air oven 3 with a heat insulating material 2.
6, the aluminum plate 23 and the curved member 30 are brought into contact with each other, and on the opposite side of the contact surface of the aluminum plate 23 with the curved member 30, the curved member with respect to the inner bottom surface portion is provided. A Peltier element heating / cooling unit 22 (hereinafter, referred to as a Peltier block) having substantially the same area as 30 is provided. The Peltier block is used because it can be stabilized at a temperature lower than room temperature and has high versatility.

The reason why the Peltier block is not disposed on the entire surface is that the Peltier block is more expensive than the heater. This is because the thermostat becomes large.

As described above, an aluminum plate is provided on the bottom surface of the air chamber to reduce the local concentration of heat from the Peltier block. The reason for this is that when the aluminum plate material 23 is not provided, the temperature of the bottom surface of the air thermostatic chamber in contact with the Peltier block 22 is closer to the temperature of the Peltier block 22 than its surroundings. This is a factor that increases the position dependence and non-uniformity of the temperature in the air oven chamber.

Therefore, the heat of the Peltier block 22 is once transmitted to the aluminum plate 23 so that the curved surface member 30 is not directly affected by the temperature of the Peltier block 22, and the air in the chamber of the air thermostat 3 is transferred from the aluminum plate 23. To transfer heat. It has a structure that circulates the air in the chamber of the heat-transferred air oven 3.

The curved surface member 30 is made of a heat insulating material, and each ridge of the polygonal column has a curvature so as to reduce the fluid resistance to the circulated air. The polygonal prism may be any of a cylinder, a triangle, and a gourd.
When the length of the capillary 2a to be used is determined,
When the capillaries 2a are installed, a plurality of curved surface members 30 for promoting the circulation of air may be provided at positions where they do not interfere with each other.

Next, the operation of the electrophoresis apparatus having the above configuration will be described. As a preparation for the operation of the electrophoresis apparatus, a sample is injected into each of 8 × 12 = 96 wells 5 a of the sample tray 5 by pipetting. The lid of the air bath is closed. At this time, the outer surface of the air thermostat 3 is covered with a heat insulating material 26 except for a part thereof, and a portion where the heat insulating material is removed is heated and heated.
Since the coolable element 22 is provided and the inner surface is covered with the good heat conducting member 23, the heat transfer from the heatable / coolable element 22 is quickly transmitted to the inner surface of the refrigerator. Further, although the connection with the power supply is not shown, the power supply is turned on and the fan 2 is turned on.
7. Start 7, 28. The fan 27, 28 is a fan that sucks air from the rotation direction and blows air in the radial direction, so that a circulating airflow with a large air volume is obtained and the air temperature chamber 3 becomes small in size. The heat insulating member 26 on the surface, the heatable / coolable element 22 and the good heat conducting member 23 on the inner surface cooperate with each other, so that the temperature inside the chamber of the air oven 3 is made uniform. The entire capillary array 2 of the electrophoresis apparatus 1 is made uniform at a constant temperature.

After such a state, the control device 5
0 controls the autosampler 7 and the sample tray 5
Is moved back and forth, and stops when each well 5a of the sample tray 5 comes directly below the capillary 2a of the capillary array 2. Next, the autosampler 7 is raised and stopped at a position where the capillary 2a is inserted into the sample in the well 5a.

Next, the capillary 2a is inserted into the sample in the well 5a. At this time, an electrode near the periphery of the capillary 2a is also inserted into the sample. In this inserted state, the control unit 50 operates the power supply unit 40 to apply a negative high voltage from the power supply unit 40 to a circuit formed by the electrophoresis ground 10-the gel block 9-the gel-sample-electrode of the capillary 2a. By applying the voltage, the sample in the well 5a is introduced into the capillary 2a. Here, the controller 50 cuts off the negative high voltage.

The autosampler 7 is moved again and stopped at the position where the lower end of the capillary 2a 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 electrodes are also inserted into the buffer solution. In this state, the electrophoresis ground 10
A negative high voltage is applied from the power supply unit 40 between the gel block 9, the gel in the capillary 2 a, the sample, the buffer solution, and the electrodes. The sample introduced into the capillary 2a is subjected to electrophoretic separation by application of the high voltage.

The gel polymer inside the capillary array 2 is replaced with a new gel polymer for each measurement.
This means that the solenoid valve 11 is closed and the syringe 12 for gel filling is closed.
Is driven to fill the capillary array 2 with the gel polymer in the syringe 12.

The light analyzing unit 13 is shielded from the outside from light,
The sample excitation laser light (not shown) is guided to the capillary 2 a at the position of the optical analyzer 13. The fluorescence emitted from the fluorescent reagent bound to the DNA to be electrophoresed inside the capillary 2a is detected, and the control computer 50 analyzes the DNA.

In the above electrophoresis apparatus, when a stagnant portion occurs in the air circulating flow, the direction in which the fan is blown toward the inner surface of the air chamber, and the air chamber inside the air chamber when there are a plurality of curved surface members. The control of the air circulating flow for temperature uniformization, etc. is performed by a control device that detects non-uniform temperature by at least one or more temperature sensors (not shown), controls the rotation speed of each of the plurality of fans, and controls the blowout damper of each of the plurality of fans. Control of the blowing direction, current control of the heating and heating / cooling elements, and the like are easily performed.

[0069]

As described in detail above, according to the configuration of the electrophoresis apparatus according to the present invention, a smooth air circulation flow is generated at the temperature inside the thermostatic chamber, and the position of the air temperature in the thermostatic chamber depends on the position. Characteristics can be reduced, and the fluctuation can be suppressed to be small. This can provide stable separation performance in electrophoretic analysis.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram of a capillary electrophoresis apparatus for a DNA sequencer.

FIG. 2 is an explanatory view of an air thermostat in the capillary electrophoresis apparatus for a DNA sequencer in FIG.

FIG. 3 is an explanatory diagram of the air direction of suction and blow-off of a fan used in the air oven of FIG. 2;

FIG. 4 is an explanatory view of one fan having the air directions of suction and blowing shown in FIG. 3;

FIG. 5 is an explanatory view of an air thermostat to which another fan having the air directions of suction and blowing shown in FIG. 3 is attached.

FIG. 6 is an explanatory view of a modification of the air oven of FIG. 2;

FIG. 7 is an explanatory view of an air thermostat when a conventional air circulation fan is used.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Electrophoresis apparatus, 2 ... Capillary array, 2a ... Capillary, 3 ... Air thermostat, 5 ... Sample tray, 5a ...
Well, 6: Buffer tank, 7: Autosampler movable in XYZ directions, 8: Array holder for fixing capillary array, 9: Gel block, 10: Electrophoresis ground, 12: Syringe for gel filling, 13: Optical analysis Part 1
6 heat insulating member, 21 mounting position of capillary array, 2
Reference numeral 2: heat source, 23: good heat conductive plate, 24: air in an air chamber, 25: insulating member, 27: air circulation fan, 2
8 ... air circulation fan, 29 ... curved structural part provided in the refrigerator, 30 ... curved surface member, 40 ... power supply part, 50 ... control computer

Claims (7)

[Claims] 1. An electrophoresis section having at least one or more capillaries, and at least one or more fans which are covered with a heat insulating material except for a part of an outer peripheral portion and which form the electrophoresis section and an air circulation flow. An air oven section having, a heating or heating / cooling element for contacting air in the air oven chamber at a portion where the heat insulating material is removed, and control for controlling a temperature in the air oven chamber. And at least a portion, wherein the fan has an air inlet in the direction of the rotation axis and an air outlet in the radial direction, so that the thickness direction of the fan coincides with the thickness direction of the air oven. A capillary electrophoresis apparatus, which is provided. 2. The capillary electrophoresis apparatus according to claim 1, wherein the at least one fan includes a plurality of fans.
The capillary electrophoresis apparatus, wherein the plurality of fans are arranged at symmetric positions in the air oven. 3. The capillary electrophoresis apparatus according to claim 1, wherein the air thermostat has a structure in which an inner surface of the air thermostat is promoted to form the air circulation flow. Electrophoresis device. 4. The capillary electrophoresis apparatus according to claim 3, wherein the air outlet of the fan is connected to the inner surface of the air thermostatic chamber when the inner surface of the air thermostatic chamber cannot be configured to promote the air circulation flow. Wherein the air flow reflected by the inner surface promotes the formation of the air circulation flow. 5. The capillary electrophoresis apparatus according to claim 1, wherein a good heat conductive plate material covering at least one inner surface of the air thermostatic chamber and the air thermostatic chamber via the good heat conductive plate. A capillary electrophoresis device provided with one of heating and a device capable of heating and cooling to contact air inside the device. 6. The capillary electrophoresis apparatus according to claim 5, wherein the good heat conductive plate corresponds to a portion where the good heat conductive plate is in contact with any of the heating or heatable / coolable elements. A capillary electrophoresis device, wherein a low heat conductive member is provided at the portion of (1). 7. The capillary electrophoresis apparatus according to claim 6, wherein the low thermal conductive member has a structure that promotes formation of an air circulation flow in the air chamber. .