JP2007171216A - Capillary array electrophoretic device and separation/analysis method of sample - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To select a capillary array, where a plurality of capillaries are constituted collectively, according to the purpose, and to readily mount the capillary array to an electrophoresis device. <P>SOLUTION: A capillary array mounting section is formed so that the capillary array, having a plurality of lengths is mounted to a wall for constituting the space of a thermostatic chamber of the electrophoretic device. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a capillary array electrophoresis apparatus and a sample separation / analysis method that can be used for separation / analysis of samples such as DNA and proteins.

A technique is well known in which an array is configured by combining a plurality of capillaries, and an electrophoresis medium and a sample to be analyzed or separated are supplied to and moved to each capillary, and the target sample is used for separation and analysis. . A sample such as DNA or protein labeled with a fluorescent substance is supplied to the capillary. Such techniques are described in US Pat. Nos. 5,366,608, 5,529,679, 5,516,409, 5,573,850, 5,790,727, 5,582,705, 5,439,578, 5,274,240, and the like. From the viewpoint of separation and analysis throughput, there are many advantages of using a multicapillary rather than electrophoresis using a slab gel.

  The basic configuration of the capillary array electrophoresis apparatus includes an excitation optical system including a capillary array, a laser light source, and the like, a light receiving optical system for detecting fluorescence, a voltage application unit for electrophoresis, and the like. A capillary array is a structure in which capillaries are arranged in a plane, and a laser filled with a sample (fluorescent sample) labeled with a phosphor is irradiated from a direction parallel to the array surface of the capillaries, and the capillary action of the capillary array By condensing the laser, the fluorescent samples in all the capillaries are irradiated with the laser. The fluorescent sample irradiated with the laser emits fluorescence. This is a device for measuring a sample by detecting fluorescence from a fluorescent sample that emits light in a direction substantially perpendicular to the laser irradiation direction with a light receiving optical system.

  Since the time, separation, and resolution required for electrophoresis differ depending on the molecular weight and molecular structure of the target sample, it is necessary to change the length of the electrophoresis path depending on the target sample. It is necessary to selectively install different types of capillary arrays in the space in the thermostat.

US Pat. No. 5,366,608 US Pat. No. 5,529,679 US Pat. No. 5,516,409 US Pat. No. 5,730,850 US Pat. No. 5,790,727 US Pat. No. 5,582,705 US Pat. No. 5,439,578 US Pat. No. 5,274,240

  An object of the present invention is to provide an easy-to-use capillary array electrophoresis apparatus that can be easily replaced when replacing a consumable capillary array with the capillary array electrophoresis apparatus.

  The present invention provides a thermostat having a space in which a temperature can be adjusted and a plurality of lengths of capillary arrays can be replaced and installed, a capillary array selected according to a target sample and disposed in the space, and one end of the capillary array Means for supplying a sample of interest; means for supplying an electrophoretic medium to the capillary at the other end of the capital array; and the capillary array emits light to the sample existing in the space of the capillary outside the space. Provided is a capillary array electrophoresis apparatus having means for irradiating and generating fluorescence, means for detecting the fluorescence, and means for detecting the fluorescence. Thus, the capillary array can be selected according to the target sample to be separated and analyzed, and the capillary array can be easily attached in the thermostatic chamber space.

  The present invention also provides a capillary array electrophoresis in which a plurality of fans having different air suction and discharge directions are installed in the space of the thermostatic chamber at a position that is substantially farthest in the space to stir the air in the space. Providing equipment. With the arrangement of the plurality of fans, the air in the space in the thermostatic chamber can be well agitated without vibrating the capillary array.

  The present invention further comprises a first syringe having an internal volume and a second syringe having an internal volume smaller than the first syringe, and an electrophoretic medium is press-fitted into the first syringe, and the first syringe Provided is a capillary array electrophoresis apparatus including a pump device for press-fitting a predetermined amount of electrophoresis medium into a second syringe via a check valve, and the internal volume of the second syringe is substantially separated once. -Determined assuming an electrophoretic medium consumed for analysis. By providing this electrophoretic medium supply system, a series of scans up to medium refilling, sample supply, and sample separation / analysis can be automated.

  The present invention provides a capillary array electrophoresis in which the main components of the fluorescence detection means are arranged substantially on one plane, and the capillaries of the irradiation / detection section of the capillary array are arranged in a direction intersecting the plane. Providing equipment. By taking the arrangement of the capillary array and the optical system, the separation / analysis system can be miniaturized.

  The present invention also supplies a sample to the one end of the capillary array from the lower part into the space of the thermostat, and projects the other end of the capillary array containing the sample that has been electrophoresed from the side of the space. A capillary array electrophoresis apparatus that emits fluorescence by irradiating with light is provided. The arrangement of the capillary array can reduce the size of the electrophoresis apparatus.

  According to the present invention, there is provided a capillary array electrophoresis apparatus in which the array plane constituting the detection portion of the capillary array is arranged in a relationship substantially parallel to the laser beam. The arrangement of the optical system and the capillary array can reduce the size of the electrophoresis apparatus.

  In the present invention, the capillary array is installed in the space of the thermostatic chamber having a space where the temperature can be adjusted and a plurality of capillary arrays can be replaced and installed, and a target sample is supplied from one end of the capillary array, An electrophoresis medium is supplied so as to fill the capillary space at the other end of the capital array, and the sample existing in the capillary space is irradiated with a laser in a range where the capillary array protrudes from the space. Provided is a method for detecting the generated fluorescence and separating and analyzing the sample.

According to the present invention, it is possible to provide an electrophoresis apparatus that can easily exchange and hold capillary arrays of various lengths and can easily cope with various separation / analysis changes.

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

  FIG. 1 shows a state where the thermostat 102 is removed from the DNA sequencer base 101. In addition to the thermostatic chamber 102, the DNA sequencer has a gel pump unit 103 for refilling and replacing the gel polymer as a separation medium in the capillary array, and an irradiation / detection unit 104 that irradiates the capillary array with laser light and detects it. An autosampler 105 is provided for continuous measurement.

When the thermostat 102 is detached from the gantry 101 for assembly or maintenance, it is desirable that the correct positional relationship with the gantry 101 is always maintained. The capillary array is attached to the thermostat 102. If the positional relationship with the gantry 101 is not maintained, the positional relationship with the autosampler 105 is not maintained, and there is a high possibility that mechanical correction is necessary. . In the present invention, the gantry 101 is provided with guide pins 106 and 107 for maintaining the positional relationship with the thermostat 102.

FIG. 2 is a view of the thermostatic chamber as viewed from the back. A guide hole 202 and a guide hole 203 are formed at positions corresponding to the guide pin 107 and the guide pin 106 in FIG. The correct positional relationship is maintained by keeping the fit between these pins and holes smaller than the required positional accuracy at the time of detachment that requires tolerance. The required position accuracy is determined by accuracy that does not require correction or position accuracy that can be corrected by software. If the positional relationship is maintained at the time of attachment here, it fixes to a mount frame with the fixing screw 201. FIG. It is desirable to use a plurality of fixing screws.

  In addition, this constant temperature bath uses a Peltier element as a heat source during heating and cooling, and in addition to the set temperature of 50 ° C. or higher used in a normal DNA sequencer, the temperature can be set to room temperature or lower. Peltier unit heat dissipating fins 204 are installed on the back surface, and heat exchange efficiency is improved by a Peltier heat dissipating fan 205.

  The figure which opened the door of the thermostat in FIG. 3 is shown. Packing 301 is made around the door, and locking is performed in a state where the packing 301 is crushed by a lock 302, thereby ensuring adhesion between the thermostatic bath and the door, and suppressing the inflow and outflow of air. As a result, the temperature distribution and fluctuation in the thermostat can be kept small.

The capillary array attachment portion 307 must maintain the relative positional relationship between the attached capillary array and the autosampler, and since the elastic packing cannot be used, the inflow / outflow of air is not zero. If the operating environment of the device is high temperature and humidity and the control temperature in the thermostat is lower than room temperature, it will enter the thermostat as a result of the water vapor or air flow that was originally in the thermostat. The resulting water vapor may condense. When water droplets generated by condensation flow and reach the lower part of the thermostatic chamber (near the array mounting part), there is a possibility that arc discharge occurs near the array mounting part near the high voltage application electrode. Therefore, a condensation receiver 303 having a rain gutter structure is provided inside the thermostatic bath. The water droplets that reach the condensation receiver 303 are transmitted to the drain hole 304 provided in the thermostatic bath, and are discharged out of the thermostatic bath through the drain (not shown). This prevents damage to the thermostatic chamber due to arc discharge.

The thermostatic bath is provided with an interlock switch 305, and an interlock switch pin 306 is attached to the corresponding position of the door. When the door is closed, the interlock switch 305 is pressed, and the thermostatic chamber functions. When the door is opened, the operator may touch the irradiation detection unit, so the laser is automatically turned off to ensure safety. Since the operator may touch the vicinity of the heat source, the Peltier power supply is automatically shut off to ensure safety. This also has the effect of protecting the Peltier element. When the door is opened while the Peltier element is controlled at a high temperature, the temperature in the thermostatic chamber is lowered at once, and the controller performs a heating operation to return the temperature to the set temperature again. If the door is left open, the control unit continues to issue a heating command, and the Peltier element may be damaged by the heat. In this embodiment, such an accident can be prevented.

  A Peltier unit 312 including a heat radiating fin and a heat radiating fan as a heat source is in contact with an aluminum (Al) plate 308 on the back surface of the thermostatic chamber. An insulating film is adhered to the Al plate to prevent arc discharge. The Al plate 308 transfers the heat from the heat source into the thermostat by heat conduction, and keeps the temperature in the thermostat constant. The heat of the heated or cooled Al plate 308 stabilizes the temperature of the space by agitating and circulating the air in the thermostat by the fan 309 and the fan 310 installed in the thermostat. The Al plate 311 is placed in close contact with the dense part of the capillary array heading from the thermostat to the detection part, and is installed to diffuse the heat generated when a high voltage is applied. The temperature in the space of the thermostatic chamber is monitored by the internal temperature sensor 313 and temperature control is performed.

Details of the capillary array holder 1201 are shown in FIG. Moreover, the detailed mounting structure of the thermostat and the holder 1201 is shown in FIG. A holder 1306 for fixing the capillary array holder 1201 is provided at the lower part of the thermostatic chamber of FIG. The capillary array holder 1201 is provided with latches 1303 and 1304, and these latches are attached to the mounting holes 1301.
, 1302. An electrode 1305 is provided in the recess 1306 and is connected to the electrode connecting portion 1401 shown in FIG. One end of each capillary of the capillary array is inserted into each hole 1307 of the capillary array holder 1201 and connected to the electrode 1308.

The structure of the capillary array itself is shown in FIGS. The capillary array will be described with reference to FIG. It comprises an array holder section 401 for attaching a capillary array to a thermostat, a capillary 402, a photometry section 403, a gel injection section 404, and an electrode section 405. Here, since an example of simultaneous measurement of 16 samples set in a commercially available 96-hole or 384-hole microtiter plate is shown, 16 capillaries 402 and 16 electrode portions 405 are included in the capillary array. The material of the capillary is usually fused silica, and a polymer protective coating such as polyimide is formed on the surface of each capillary except for the portion that irradiates laser light and detects fluorescence. In order to set the plurality of capillaries in the thermostatic bath so as not to be entangled with each other and not to be densely bundled as described above, a separator as shown in FIG. 9 is used. The separator 501 is a film or a plate, and slits 503 for holding the capillaries 502 one by one are formed at both ends of the separator. The capillary array should be stored, managed, and handled with a separator attached. The number of separators is increased according to the length of the capillary array. For example, if it is a capillary array of about 36 cm, one is sufficient. If it is about 80cm, attach about 5 pieces.

  The separator is set between the array holder 401 of the capillary array and the photometry unit 403, and holds the capillaries 502 so as not to be densely entangled. The holder 401 and the separator 501 prevent the capillaries from being densely entangled and entangled even when heat is generated from the capillary due to a high voltage applied to the capillary during electrophoresis. Prevent it from rising.

Even if a separator is provided to improve ventilation, the capillary is usually not rigid and has elasticity, so that the capillary should always be installed at a specified position in the thermostat even when the capillary is changed or the operator changes. is important. Therefore, a separator holder 601 whose top view and front view are shown in FIGS. 10a and 10b is used on the thermostatic chamber side. The separator attached to the array is inserted from above the front view shown in FIG. 10a. As is apparent from the side view shown in FIG. 10B, the separator holder 601 has two legs 602 extending.

  The separator holder is attached to and detached from the thermostatic chamber in the following manner. The foot 602 is inserted into the mounting hole 702 of the separator holder 701 opened at the position where the separator of the Al plate 308 in the thermostatic chamber is to be set, and the holder is rotated 90 degrees. When the foot portion of the separator holder is projected, it has an elliptical shape or a long axis shape, so that the long axis direction of the foot portion and the short axis of the mounting hole become parallel by rotating 90 degrees. Since the long axis of the foot is longer than the short axis of the attachment hole, the separator holder is fixed to the Al plate 308. When removing the separator holder, the separator holder 701 can be removed from the mounting hole by rotating it 90 degrees again so that the long axis of the foot and the long axis of the mounting hole are parallel. The separator holder can be easily detached from the thermostat as described above.

  When using capillary arrays having different lengths, a number of separator holders corresponding to the respective lengths are set at positions corresponding to the respective lengths. If it cannot be removed simply or at all, a separator holder that is not used for a certain length will interfere with the capillary array.

  FIG. 11 shows, in a virtually superposed manner, the positions of the separator holders used in all the lengths when the capillary arrays having lengths of 36 cm, 50 cm, and 80 cm are set in the thermostat. Actually, only one capillary array is used in one separation / analysis. When the shortest capillary array A is used, it is arranged and held in a preferred shape by the common array holder E, the holder a of the array A, and the common holder D on the inner wall of the thermostatic chamber. When the somewhat long capillary array B is held, it is held by the common holder E, the holders b1 and b2, and the common holder D. The longest capillary array is held by a common holder E, holders c1, c2, c3, c4, and c5 and a common holder D.

  The position of each separator holder is set to a position where the separator does not block the wind of the fan for air circulation in consideration of the wind direction of the fan in each thermostat. Further, in order to reduce the number of holes opened in the Al plate 308 as much as possible, the installation positions that can be shared are made common. In this example, the position closest to the separator holder 601 and the position closest to the photometry unit are set as a common position. In this way, by using the separator holder 601 in common, the electrophoresis apparatus can be miniaturized.

  Since the separator holder is desorbed according to each length of the capillary array, the mounting hole is used in the vicinity of the insulating film-shaped separator holder mounting hole in close contact with the Al plate 308 or the Al plate 308. Make a mark. Thereby, it is possible to avoid an erroneous operation of attaching the separator holder to an incorrect position.

Next, the case where a capillary array holder is attached to a thermostat will be described. 3, 4 and 5 show the structure and mounting position of the capillary array holder 1201. FIG. In the drawing, the capillary portion of the capillary array is omitted. The thermostatic chamber is notched at the set position of the array holder so that the surface that contacts the thermostatic chamber door when the array holder is set and the surface of the array holder on the door side are flat. Furthermore, the array holder is fixed to the thermostat by pushing the latch 1303 and the latch 1304 attached to the capillary array holder 1201 into the attachment hole 1301 and the attachment hole 1302. This mounting position reproducibility is also important because it determines the relative positional relationship between the capillary array and the autosampler. Therefore, a non-circular recess 1306 is provided in the electrode 1305 portion of the array holder mounting portion of the thermostat. Non-circular refers to a shape such as an oval or an ellipse. FIG. 5 is a view of the array holder of FIG. 4 as viewed from the back. A protrusion 1401 is provided at a position corresponding to the depression of the thermostatic bath. The reproducibility of the attaching / detaching positions in the left / right, up / down, and rotational directions is maintained by keeping the dimension crossing in the fitting between these depressions and protrusions to the accuracy required for attaching / detaching the array. The position reproducibility in the depth direction is maintained by contact between the reference surface 1402 of the capillary array and the corresponding surface of the thermostat.

  A high voltage of 15 kV or higher is applied to the electrode 1305. There is a recess around the electrode 1305, and an insulating rubber is placed in the recess so as to be in close contact with the protrusion of the capillary array holder 1201. This eliminates the air gap between the electrode 1305 and the capillary array holder. Further, the creeping distance from the high voltage portion to the grounding portion can be increased by the fitting structure of the depression and the protrusion, and arc discharge can be suppressed.

The schematic structure of the thermostatic chamber is shown in FIG. 6a (plan sectional view) and FIG. 6b (side sectional view). The Peltier unit is brought into contact with the Al plate 1501 from the back surface of the thermostat bath to the Al plate 1501 for uniformly transferring heat from the Peltier heat source to the thermostat bath and stabilizing the temperature. The reason why the Peltier unit is used is that it can be set to a temperature higher than room temperature, and can be set to a temperature lower than room temperature. The heat transferred from the Peltier to the Al plate 1501 is transferred to the air in the thermostat, and the air is stirred and circulated by the fan 1503 and the fan 1504 to further stabilize the temperature in the thermostat. The temperature in the thermostatic chamber is monitored by a temperature sensor 1505.

The periphery of the thermostatic chamber is covered with a heat insulating material 1506 to block heat from entering and exiting the thermostatic chamber. Also, the temperature of the Peltier can be monitored by a Peltier temperature sensor 1507.

7a and 7b show the air suction direction and the blow-out direction of the two flat fans used in the thermostatic chamber. As shown here, the thickness of the thermostatic chamber can be reduced by using a fan in which the air suction direction and the blowing direction are not parallel. 7c and 7d are views of the fan as seen from the back. An example in which a fan is installed as shown in FIGS. 7a and 7b is shown in FIGS. 6a and 6b. 6a shows the installation position of the fan, and FIG. 6a is a sectional view in the direction of the arrow in FIG. 6b.

  When the fan is arranged as shown in FIG. 6b, the air inlet is in the direction away from the door side of the thermostat, that is, the heat source. When a fan is installed on the opposite wall surface to that of FIG. 6b, the air inlet is on the thermostatic chamber side and is close to the heat source. By sucking air from the direction close to the heat source as shown in FIG. 6b, it is possible to circulate the air closer to the temperature of the heat source than the current temperature in the constant temperature bath. In actual installation, the fan may be fixed to the door side, or if the fan cannot be fixed to the door side due to problems such as wiring, a spacer or holder is provided on the thermostat side and the fan is installed on the thermostat side. May be. In the example shown in FIG. 3, a fan is installed on the thermostatic chamber side. As shown in FIG. 7a, the blowing direction of the fan is shifted from the central axis of the air inlet. When it may be difficult to blow air in a target direction depending on the shape of the fan, not all the air inlets of the plurality of fans may be the heat source side, and only a part thereof may be the heat source side. In the example of FIG. 3, the air inlet of the fan 309 is on the thermostat side (heat source side), but the air inlet of the fan 310 is on the door side.

  From the viewpoint of air circulation, a fan with a larger airflow is more effective without air stagnation. However, if the airflow is too large for the capillary and the capillary vibrates, this is the cause of electrophoresis. It becomes a factor to worsen separation. For this reason, a fan having a large air volume is used in a portion where there is no influence of vibration even if a capillary is set, and a fan having an air volume that does not vibrate is selected for a fan installed in a portion where vibration is affected. In FIGS. 6a and 6b, the air volume of the fan 1504 is selected to be smaller than the air volume of the fan 1503.

In actual control, a method of monitoring only the air temperature in the thermostatic chamber and feeding back the output of the Peltier is common. In addition to the temperature sensor 1505 in the thermostatic chamber, both of the Peltier temperature sensors 1507 can be used for control. A block diagram of an example of the control is shown in FIG. This example is an example of proportional-integral control. In the figure, K1 to K5 are control constants, and + Toff is a correction constant by software when the read temperature indication value from each sensor has an offset, and is normally zero. K1 is a proportional coefficient. K2 · Σ is an integral term indicating that multiplication is performed after a constant for integration of K2 is applied.

  The final output of the control is the output of the Peltier, and the temperature of the Peltier with respect to the output of the Peltier has a quick temporal response and is direct. In addition, the temperature in the thermostatic chamber is indirect because the time response is slow with respect to the output of the Peltier. Therefore, if the Peltier temperature is used for the control, it is preferable that the undulation of the time constant of the temperature can be reduced as compared with the case where only the temperature in the thermostatic chamber having a slow response is used for the control.

  The functions necessary for the capillary array used in the capillary array electrophoresis apparatus of the present invention are the buffer solution inlet installed in the buffer solution container, the light detection unit for irradiating the laser to detect the fluorescent material, and the sample. A capillary array structure having all three functions of a sample introduction part for applying a voltage necessary for electrophoresis is used in the present invention.

  As shown in FIG. 8, it comprises a capillary 402, a buffer and electrophoresis medium injection port 404, a light detection unit 403, and a sample introduction unit 405. Electrodes are fixed to the capillaries in the sample introduction part of the capillary array shown in FIG.

  Using the second syringe 410 of the simplified gel injection pump system 414, the electrophoresis medium and the buffer solution are press-fitted into the gel injection unit 404 of the capillary array 402 from the buffer solution reservoir 412. A high voltage is applied between the electrode 407 provided in the buffer solution reservoir 412 and the electrode portion 405 of the capillary array.

  The overall operation of the electrophoresis apparatus using the capillary array of the present invention will be described with reference to FIG. In the capillary array of the present invention, a plurality of capillaries 3001 are bundled at one end, and a buffer solution inlet 3010 set in a buffer solution container for injecting a buffer solution and a part of the plurality of capillaries are removed. The detailed structure is shown in FIG. The removed portions are arranged in a planar shape, and the portions in which at least some of the plurality of capillaries are arranged in a planar shape are held by a holding substrate 4005. The holding substrate is provided with a window 4011 through which detection light passes in a portion corresponding to each capillary. The holding substrate has a light detection portion provided with a light shielding region that partitions a window through which the detection light passes.

  In FIG. 12, at the other end of the plurality of capillaries, a fluorescently labeled sample introducing portion 3032 for taking a fluorescent sample into a capillary array is configured, and an electric electrode is provided in the vicinity of each capillary at the tip of the fluorescent sample introducing portion. An electrode (not shown) for applying a voltage necessary for electrophoresis is provided. A voltage for electrophoresis is applied between an electrode provided on the capillary array holder 3030 from a power source 3119 and a reservoir 3136 for supplying an electrophoresis medium.

As shown in FIG. 12, the capillary array electrophoresis apparatus includes a sample measurement component 3116, a buffer solution container 3117, a fluorescence sample container 3118, a high voltage power supply 3119, a laser light source 3120, a mirror 3121, a beam splitter 3122, and a condensing lens 3123. First lens 3124
, Optical filter and transmission type grating 3125, second lens 3126, CCD camera 3127, arithmetic processing unit 3128, and the like. The sample measurement component 3116 includes a capillary 3001, a light detection unit 3020, a buffer solution injection port 3030, a conductive fluorescent sample injection port 3032, and the like.

  Next, the operation principle will be described. As shown in FIG. 12, the laser 3133 generated by the laser light source 3120 is divided into two by a beam splitter 3122, and the traveling direction is changed by a mirror 3121. The laser 3133 is condensed by the condensing lens 3123 and irradiates the capillary 1 from a direction parallel to the plane in which the capillary 1 is arranged. The inside of the capillary 3001 is filled with a fluorescently labeled sample (fluorescent sample 3134), and the fluorescent sample 3134 emits the fluorescent light 3135 by irradiating the fluorescent sample 3134 with the laser 3133. The fluorescence 3135 is detected by making the fluorescence 3135 that emits light in a direction substantially perpendicular to the plane in which the capillaries 3001 are arranged into parallel light by the first lens 3124, image / color division by the optical filter and the transmission type grating 3125, and then the second The image is formed on the CCD camera 3127 by the lens 3126 and detected by the CCD camera 3127. The detected measurement data is processed by the processing arithmetic device 3128.

  In FIG. 12, the laser 3133 irradiates from both sides of the light detection unit 3020, but may be configured to irradiate only one side. The light receiving optical system is not limited to the configuration shown in FIG. The number of capillaries 3001 is not limited to 16, and the configurations of the buffer solution inlet 3030 and the conductive fluorescent sample inlet 3032 are not limited to those shown in FIG.

  An operation procedure of the capillary array electrophoresis apparatus will be described. The buffer solution 3136 contained in the buffer solution container 3117 is injected into the capillary 3001 from the buffer solution inlet 3010. Next, a conductive fluorescent sample injection port 3032 is inserted into a fluorescent sample container 3118 filled with the fluorescent sample 3134, and the fluorescent sample 3134 is injected into the capillary 3001. Thereafter, the conductive fluorescent sample inlet 3032 is placed in a buffer container (not shown) containing a buffer solution, and a high voltage is applied between the buffer inlet 3010 and the fluorescent sample inlet 3031 by a high voltage power source 3119. To cause electrophoresis. Since the migration speed of electrophoresis is proportional to the magnitude of the charge of the molecule and inversely proportional to the magnitude of the molecule, the fluorescent sample 3134 is separated. Electrophoresis occurs for a long time by continuously applying a high voltage for a long time, and fluorescence 3135 emitted at this time is continuously measured.

  The sample introduction unit 3032 has a structure in which a capillary is inserted into a stainless steel tube. Each stainless steel tube 3321 is soldered to an electrode plate with a protective cover, and a voltage is guided to all the stainless steel tubes by applying a voltage to the connection portion 3031. As described above, necessary for the electrophoresis by introducing the buffer solution inlet 3010 attached to the buffer solution container 3136 necessary for the capillary array itself, the light detection unit 3020 for detecting the fluorescent material by irradiating the laser, and the fluorescent sample 3134. Since all the functions of the sample introduction unit 3030 for applying a voltage are provided, the capillary array can be replaced with very good operability.

Note that the tip of the fluorescent sample introduction portion 3032 is sealed with an adhesive so that the sample or the like does not carry over. The type of adhesive should be sufficiently cured using an epoxy adhesive so as not to affect electrophoresis. The gap between the insertion portion 3033 of the capillary 3001 and the fluorescent sample introduction portion 3032 and the cover of the sample introduction portion 3030 is sealed with an adhesive. Moisture such as sample and buffer solution penetrates into the stainless steel tube cover and prevents deterioration of electrical insulation.

  When the capillary array is once removed from the apparatus and stored after the measurement of the sample, a container cover (not shown) for preventing drying is attached so that the buffer 3136 is not dried. The container cover is a dry prevention cover for the sample introduction unit 3030. Pure water is put into the container and the container cover is attached to the sample introduction unit 3030. An O-ring is attached to the container cover to prevent drying. It is also effective to provide a drying prevention cap (not shown) for the buffer solution inlet 3010. Again, the cap is put on the buffer solution inlet 3010 in a state where pure water is slightly injected. The cap prevents drying by making the inner diameter 5-15% thinner than the outer diameter of the buffer inlet 3010. The material of the cap is preferably made of silicon rubber, which does not affect the buffer solution or electrophoresis. These cover 3034 and cap also have a role of protecting the tip and preventing contamination when the capillary array is shipped to the customer.

  The capillary 3001 used in the capillary array described above is a fused silica tube having an inner diameter of 50 ± 10 μm and an outer diameter of 340 ± 20 μm. Since the fused quartz tube itself is very easy to break, a 15 ± 5 μm thick polyimide coating is applied to the surface of the capillary. The inner diameter of the capillary is preferably thinner considering the microscopic amount of the fluorescent sample 134, but it is difficult to measure even if the inner diameter is too small considering the concave lens effect due to the refractive index difference between the fluorescent sample 3134 and the fused silica. The inner diameter of the fused quartz tube is suitably 50 to 100 μm. In order to suppress the influence of the refractive index difference, the outer diameter is preferably thinner. However, if the outer diameter is thin, it is difficult to assemble due to static electricity. Therefore, the outer diameter of the fused quartz tube is appropriately 250 to 350 μm. The covering material for the capillary 3001 is not limited to the polyimide resin, and a member having the same electrical insulation and other various characteristics as the polyimide resin may be used.

FIG. 13 is an exploded view showing the structure of the irradiation / detection unit of the capillary array used in the present invention. The glass substrate 4023 has a groove 4011 for laser irradiation and a black coating 4056 on the back surface of the substrate. The surface of the glass substrate 4023 with which the polyimide coating comes into contact is processed with high accuracy to such an extent that interference fringes are observed, and the flatness is high.

  A plurality of capillaries 4001 are arranged in contact with the above-described highly flat surface via a polyimide coating. As a result, the plurality of capillaries 4001 and 4010 follow the glass substrate 4023 and can be arranged accurately and easily.

The polyimide coating on the irradiation / detection part of the capillary is removed to form a transparent part 4009. This removal may be performed by removing a predetermined size separately for each piece, and then aligning the removed portions. At this time, if it is removed one by one, a processing error occurs in a predetermined removal width, and the removal width varies. Further, alignment is performed so that the boundary (boundary where the polyimide resin 10 is cut) of the removed portion is aligned, but alignment error occurs at this time, and a lot of work time is required.

  Usually, it can be confirmed immediately because the boundary does not match. In the worst case, the polyimide resin is visible from the through window 4006, which greatly affects detection.

  Therefore, without removing the coating for each one, first, the capillaries are aligned, and then the polyimide resin is removed in a lump, so that the removed portions of the polyimide resin 4010 of the plurality of capillaries are neatly aligned. Whether this method is used or not can be immediately confirmed by the fact that the above-mentioned boundary portions are aligned. The predetermined width and the predetermined position of the removal unit can be freely changed together with a plurality of capillaries.

The capillary 4001 is sandwiched between the glass substrate of the irradiation detection unit and the facing member 4002. The facing member is provided with a detection window 4006, and fluorescence is emitted from the transparent capillary 4007. A capillary holding groove 4008 is formed on the inner surface of the facing member.

  When there is no black coating 4056, the laser beam passes through the plurality of capillaries arranged with high accuracy as described above. At this time, the scattered light from the surface of the capillary 4001 passes through the glass substrate 4023, is irradiated to the fluorescent material on the surface of the facing member 4002 facing the glass substrate 4023, and the emitted light is then returned to the capillary and further passes through the through window 4006. Then head to the first lens and pick up noise. The same applies to the case where a fluorescent material is attached to the back surface of the glass substrate 4023, which causes noise.

  However, if the black coating 4056 is applied to the back of the glass substrate 4023, the scattered light is blackened even if there is a fluorescence generating material on the facing member or even if the fluorescence generating material adheres after applying black coating. Absorbed and the cause of noise is removed. Use a paint that does not generate fluorescence as the physical properties of black paint. A silk screen or the like is used as a typical painting operation. Other printing methods may be used, and hand-painting is sufficient.

  The optical system in the present invention will be described. In an embodiment of the present invention, a laser beam is irradiated onto one or both ends of a capillary array composed of a plurality of capillaries arranged on one flat surface, and the laser beam propagates one after another to adjacent capillaries. A CCD is used as fluorescence detection means of a capillary array electrophoresis apparatus traversing the capillary array. At this time, the aligned portion of the capillary array constituting the irradiation / detection unit is placed parallel to the laser emission direction. More specifically, the irradiation / detection unit is placed substantially vertically, and the laser beam is irradiated on the detection unit from above or in two directions by dividing the laser beam into two parts. FIG. 8 shows this configuration. Further, in FIG. 12, the irradiation / detection unit is depicted as being placed horizontally for drawing, but as shown in FIG. The capillary array is irradiated. This arrangement is suitable for downsizing the irradiation / detection optical system. In addition, according to this configuration, as far as the relationship with the laser beam is concerned, it can be configured so that the laser beam does not come to the side on which the operator normally works, and thus the safety is high.

  The light emission intensity from a single capillary is defined as the light intensity detected by the CCD pixel having the number of pixels closest to the full width at half maximum of the light emission distribution curve of the capillary in the capillary array direction in imaging on the CCD. In addition, a rotation angle adjustment function having a rotation angle accuracy of about 0.1 ° around the optical axis is provided for the CCD and the diffraction grating.

  In a capillary electrophoresis DNA sequencer, when a sample is migrated by applying a high voltage to the capillary, it is determined by monitoring the value of the current flowing through the capillary whether the electrophoresis is correctly performed. Generally, this monitor uses a built-in high-voltage power supply, but current leakage occurs when the insulation around the high-voltage electrode is poor, and it shows a value other than the current flowing through the capillary. There is a drawback. Therefore, as shown in FIG. 16a, an appropriate resistor R is inserted between the end of the capillary 2001 and the ground, and the voltage at both ends thereof is measured so that only the current flowing in the capillary can be accurately monitored. Can be accurately determined whether or not

  In order to perform capillary electrophoresis, it is necessary to apply a voltage of several KV to several tens of KV to the sample. In the present invention, a method is adopted in which a needle is inserted into the sample together with the capillary from the capillary holder. If the insulation between the needle and the surrounding metal part is poor, a discharge occurs from the high voltage part and accurate measurement cannot be performed. As a method for enhancing the insulation, it is conceivable to increase the distance between the needle and the surrounding metal part according to the voltage, but there are structural limitations. In the present invention, a structure that is inevitably close in structure is a sealed structure with an insulator. Moreover, the part which supplies a high voltage to a capillary holder is detachable, and it is a plug-in type in order to make a sealing structure, and has a structure which obtains a sealing degree with rubber | gum.

  Embodiments of the present invention will be described below with reference to the drawings of the pump unit. FIG. 14 shows a schematic diagram of an electrophoresis apparatus equipped with a gel injection mechanism according to an embodiment of the present invention.

  The capillary array 8118 is composed of at least two capillaries. One end is inserted into the block 8116 and the other end is integrated with an electrode connected to the power source 8121.

The capillary array 8118 is filled with a gel serving as a separation medium or an electrophoresis medium from the block 8116 side before measurement. The block 8116 is provided with an injection syringe 8113 for injecting the gel into the capillary array 8118 and a refill syringe 8114 for replenishing the gel to the injection syringe. The internal volume of the refill syringe 8114 that is the first syringe is larger than the internal volume of the injection syringe 8113 that is the second syringe. The second syringe basically has an internal volume capable of supplying gel polymer for one separation / analysis. The block 8116 includes a first flow path that connects the refilling syringe 8114 and the injection syringe 8113, and a second flow path that connects the injection syringe 8113 and the capillary 8118. In the second flow path, there is provided a branch path to the buffer reservoir 8126 that becomes a ground potential during electrophoresis.

Further, a check valve 8115 is inserted between the flow path connecting the refilling syringe 8114 and the injecting syringe 8113 to prevent the backflow of the gel to the refilling syringe 8114. The refilling syringe 8114 and the injection syringe 8113 are pressurized by driving units 817 and 818 controlled by the control unit 812, respectively. Drive unit 817
, 818 are respectively attached with linear encoders 819, 8110. By reading the values of the linear encoders, position information of the drive unit is transmitted to the computer 811 via the control unit 812.

  After the capillary array 8118 is filled with the gel, it moves to the sample container 8122, sucks the sample by electrical action, and then moves to the buffer tank 8123. When a voltage is applied to the buffer tank 8123 through the electrode portion of the capillary, an electric field is generated in the capillary, and the introduced sample starts electrophoresis. The introduced sample can detect a separated sample by the detection unit 8117 due to a difference in migration speed caused by molecular weight or the like. When the analysis is completed, the capillary array 8118 is replaced with a new gel by the injection syringe 8113, and the next measurement starts again.

FIG. 15 shows a cross-sectional view of a connection portion between the capillary array 8118 and the pump system. In this structure, an air bubble removal structure 8201 is provided in the flow path 8202 of the pump system so that air bubbles do not enter the capillary from the connection portion. Further, by making the tip of the ferrule 8205 WD (oval), it is possible to prevent the ferrule from rotating at the same time when the push screw 8204 is tightened. In addition, by making the ferrule longer and protruding from the push screw, the gel is prevented from seeping out. Further, the sleeve 8203 can be replaced by being made independent.

  When a refillable gel is used, it is necessary to equalize the pressure at both ends so that the gel in the capillary does not move. For this purpose, the liquid level of both the cathode and anode buffer tanks must be the same. In this embodiment, the block is divided into two upper and lower parts, so that the lower block, which becomes the buffer tank, is arranged so as to be the same height as the other buffer tank, and the other upper block is used for gel injection into the capillary. It is placed in a place where it is easy to do (actually, the place where the shortest capillary reaches).

A flow chart of the gel injection operation is shown in FIG. Upon receiving the gel injection command from the computer 511, the control unit 512 first performs an initial operation of the gel injection unit (step 202) and closes the buffer valve 5124 (step 203). Thereafter, the drive unit 517
The position of the plunger 5111 of the injection syringe 5113 is automatically detected (step 204). Subsequently, the drive unit 518 is similarly lowered to the position of the plunger 5112 on the refilling syringe side (step 205). Thereafter, first, the residual gel amount in the injection syringe 5113 is confirmed from the value of the injection side linear encoder 519 (step 206).
. If the gel in the injection syringe 5113 is insufficient, the gel replenishment operation from the refill syringe 5114 to the injection syringe 5113 is executed prior to the gel injection.

The gel replenishment operation is executed as follows. First, the gel remaining amount is confirmed from the value of the replenishment side linear encoder 5110 (step 212). If the remaining amount is sufficient, the injection side drive unit 517 moves to the position of the plunger when the injection syringe is full (step 213), and then pressurization of the refill syringe by the drive unit 518 is started (step 214). At this time, most of the gel pushed out from the refilling syringe 5114 and flowing into the block 5116 flows into the injection syringe 5113 while pushing up the plunger 5111 of the injection syringe 5113 instead of the capillary due to the difference in flow path resistance. When the injection syringe 5113 becomes full, the plunger 5111 hits the injection side drive unit 517 and the gel is no longer replenished. At this time, the control unit periodically checks the encoder value of the drive unit 518 (at intervals of 1 second), and if there is no change for 5 seconds (if the drive unit 518 does not move), the gel replenishment operation is completed. Judgment is made and the motor is stopped (step 215). When the gel replenishment is completed, in order to release the pressure, the replenishment side drive unit 518 rises and waits for the next command (step 216). If the remaining amount of the refilling syringe 5114 is insufficient, a message indicating that the remaining amount is insufficient is displayed on the screen of the computer 511, and the user manually refills the refilling syringe 5114 and then restarts. (Step 218).

When the remaining amount in the injection syringe 5113 is sufficient or after the gel replenishment, the injection side drive unit 517 starts pressurizing the injection syringe 5113 and starts the gel injection into the capillary 5118 ( Step 207). At this time, the check valve 5115 prevents the backflow of the gel to the refilling syringe 5114. Further, since the buffer valve 5124 is closed, the gel pushed out from the injection syringe 5113 is the only flowable channel. It flows into a certain capillary 5118. When a certain amount of gel is filled, the injection side drive unit 517 stops the pressurization (step 208), and moves upward to stand by to release the pressure (step 209). Subsequently, after the buffer valve 5124 is opened (step 210), a voltage is applied to the electrode portion of the capillary, and electrophoresis starts (step 211).

In DNA sequencer, it is necessary to refill the gel in the capillary for each measurement. For this purpose, it is necessary to generate a high pressure for injecting the highly viscous gel into the capillary and to secure a capacity for continuous injection. . However, generally a syringe with high pressure resistance has a small piston cross-sectional area and a small capacity. In other words, since a syringe that satisfies the required pressure resistance and volume at the same time was not found, a high pressure-resistant injection syringe and a large-capacity refill syringe are used here. Moreover, in order to perform replenishment and injection automatically, a structure using a check valve is required. Further, when the gel in the refilling syringe runs out, the user manually refills the gel, and at that time, the syringe is detached. When the syringe is attached, the device of the present invention automatically recognizes the position of the plunger of the syringe by the plunger position detection function, so that automatic continuous measurement can be performed immediately after the user attaches the syringe.

As an operational safety measure of the present invention, as shown in FIGS. 18a and 18b, a metal plate (shutter) is attached to a stepping motor that rotates in the forward and reverse directions to constitute a laser light shutter, and within the reciprocating motion range of the shutter. Two shock-absorbing rubbers 901 and 902 are placed on the door, and the shutter 903 hits the shock-absorbing rubber and stops when it is opened and closed. In addition, a metal plate (shutter) is attached to a stepping motor that rotates in the forward and reverse directions to form a laser light shutter, and the motor mounting rotation angle prevents the shutter from straddling the vertical axis during the open-close operation. Adjust.

  In a shutter having a metal plate (shutter) attached to a stepping motor that rotates in the forward and reverse directions, the shutter vibrates when opened and closed. As a result, in spite of the closed state, the laser light is emitted from the shutter, and the exposure time may vary, or the signal reading of the CCD may be abnormal. Also, depending on the motor mounting angle, it may not be closed due to its own weight when the power is turned off.

A part of the plane on the side on which the glass-based capillary array on which the capillary array is arranged is pressed against all or part of the array mounting reference plane 1 of the optical system. At this point, the array mounting reference plane, which is the reference plane on the electrophoresis apparatus side, coincides with the glass base, which is the reference plane on the capillary array side.

On the side of the electrophoresis apparatus, the position of the laser beam is 10 with respect to the array mounting reference plane.
Determined with position accuracy of μm or less. When the position of the laser beam is determined by the laser focusing lens, the position of the laser focusing lens with respect to the array mounting reference plane is determined with a positional accuracy of 10 μm or less. In this case, a laser beam incident on the lens at a certain angle can be irradiated to a predetermined position on the capillary array.

  On the capillary array side, the position of the capillary relative to the glass substrate can be determined with a positional accuracy of 10 μm or less by pressing the capillaries against the glass substrate. Therefore, by pressing the array mounting reference plane and the glass base, the positions of the capillaries and the laser beam can be realized with a reproducibility with an accuracy of about 10 μm.

1 is an external perspective view of a capillary array electrophoresis apparatus of the present invention. It is a perspective view of the thermostat of FIG. It is a perspective view which shows the state which opened the door of the thermostat of FIG. It is a perspective view which shows the relationship between the lower structure of the thermostat of FIG. 3, and a capillary array holder. It is the perspective view seen from the back of a capillary array holder. It is a cross-sectional schematic diagram which shows the internal structure of a thermostat. It is the schematic which shows the direction of the airflow of two fans installed in a thermostat. It is the schematic which shows the structure of the principal part of the electrophoresis apparatus of this invention. It is a perspective view which shows the structure of the separator which aligns and hold | maintains each capillary of a capillary array. It is the top view and side view which show the structure of the separator holder for hold | maintaining the separator of FIG. 9 to the wall of a thermostat. It is the schematic which shows the virtual attachment condition of the capillary array from which length differs in a thermostat. It is the schematic explaining laser beam irradiation and detection of the capillary array electrophoresis apparatus of this invention. It is an exploded view which shows the structure of the irradiation / detection part of the capillary array used in this invention. It is the schematic for demonstrating the gel pump system in this invention. It is a detailed sectional view of a connection part with a capillary array of the gel pump system in FIG. It is a diagram which shows the example of a capillary current monitor system. It is a control block diagram of a thermostat. It is a flowchart explaining the gel injection | pouring procedure to the capillary array by a gel pump system. It is the schematic explaining the mechanism which stops a laser beam automatically when stopping the driving | operation of the capillary array electrophoresis apparatus of this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 101 ... Base, 102 ... Constant temperature bath, 103 ... Gel pump part, 104 ... Detection part, 105 ... Autosampler, 202 ... Guide hole, 309, 310 ... Fan, 501 ... Capillary spacer, 601 ... Separator holder, 1201 ... Capillary array holder .

Claims (8)

  A thermostat having a space in which a plurality of capillary arrays can be replaced and installed, a means for controlling the temperature of the thermostat, a selected capillary array disposed in the space, and one end of the capillary array Means for supplying the target sample to the capillary, means for supplying the electrophoresis medium to the capillary at the other end of the capillary array, and the lens action of the capillary by irradiating the capillary array with light outside the thermostatic chamber A capillary array electrophoresis apparatus having means for simultaneously irradiating adjacent capillaries by means of, and means for detecting fluorescence generated by irradiation.   A capillary array disposed in a thermostatic chamber having a temperature-controllable space, means for supplying a target sample to the capillary from one end of the capillary array, and supplying an electrophoresis medium to the capillary from the other end of the capillary array Means for irradiating the capillary array outside the space and irradiating all the capillaries by the lens action of the capillaries, and means for detecting the fluorescence, and having a plurality of lengths in the space. A capillary array electrophoresis apparatus in which a plurality of capillary array holding portions are provided on a wall constituting the space so as to exchange and hold the capillary array.   A thermostat configured so that the temperature can be adjusted and a plurality of lengths of the capillary array can be selectively installed, means for supplying a target sample from one end of the capillary array, and the capillary from the other end of the capillary array Means for supplying an electrophoretic medium, means for irradiating all capillaries from the side and parallel surfaces of the capillary array outside the space to generate fluorescence from a sample in the capillary, and means for detecting the generated fluorescence A capillary array electrophoresis apparatus having a plurality of fans having different air suction directions and air discharge directions in the space and substantially stirring the air in the space by installing the fans at the farthest position in the space.   A capillary array disposed in a thermostatic chamber having a temperature-controllable space, means for supplying a target sample from one end of the capillary array, and supplying an electrophoresis medium to the capillary from the other end of the capillary array Means for irradiating the sample in the capillary outside the space with the capillary array, sequentially irradiating adjacent capillaries by the lens action of the capillary, and means for detecting the fluorescence. A first syringe having a second syringe having an inner volume smaller than that of the first syringe, an electrophoretic medium is pressed into the first syringe, and a check valve is inserted into the second syringe from the first syringe. A capillary array electrophoresis apparatus comprising a pump device for press-fitting a predetermined amount of electrophoresis medium.   A capillary array disposed in a space capable of adjusting temperature, a means for supplying a target sample to the capillary from one end of the capillary array, a means for supplying an electrophoresis medium to the capillary from the other end of the capillary array, A means for emitting fluorescence from a sample existing in the capillary by irradiating the capillary array outside the space and a means for detecting the fluorescence are supplied to the one end of the capillary array from the bottom in the space. A capillary array electrophoresis apparatus for projecting the other end of a capillary array containing a sample that has been electrophoresed from the side of the space, and emitting fluorescence by irradiating the laser beam.   A capillary array disposed in a thermostatic chamber having a space in which the temperature can be adjusted, means for supplying a target sample to the capillary from one end of the capillary array, and an electrophoresis medium from the other end of the capillary array to the capillary Means for supplying laser light to the capillary array outside the space, and means for detecting the fluorescence. The plane of the array constituting the detection part of the capillary array is substantially the same as the laser light. Capillary array electrophoresis apparatus arranged in a parallel relationship with each other.   A capillary array arranged in a space capable of adjusting the temperature, means for supplying a sample of interest from one end of the capillary array to the capillary, and means for supplying an electrophoresis medium to the capillary from the other end of the capillary array And means for generating fluorescence by irradiating the capillary array with laser light, and means for detecting the fluorescence, and the main components of the fluorescence detection means are arranged substantially on one plane, and the capillary A capillary array electrophoresis apparatus in which the capillaries of the irradiation / detection unit of the array are arranged side by side in a direction crossing the plane.   The selected capillary array is installed in the space of the thermostatic chamber having a space where the temperature can be adjusted and a plurality of capillary arrays can be replaced and installed, and a target sample is supplied from one end of the capillary array, An electrophoresis medium is supplied to the other end of the capital array, a sample existing in the capillary is irradiated with a laser at a position where the capillary array protrudes from the space, and the fluorescence generated by the laser irradiation is detected, and the sample is detected. To separate and analyze

Images