DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0066] FIG. 1 is a schematic perspective view showing one embodiment applying the first aspect of the present invention to a multi-capillary electrophoretic apparatus, which comprises detection means exciting a fluorochrome bonded to a sample component as a label for making the same fluoresce and detecting the fluorescence without influence by Raman scattering or Rayleigh scattering. FIG. 2 is a conceptual diagram showing one embodiment of the detection means of this embodiment This figure shows application to a four-color label DNA sequencer.

[0067] A pair of reservoirs 110 and 120 store electrophoresis buffer solutions 112 and 122 respectively, while electrodes 130 and 132 are provided in the buffer solutions 112 and 122 respectively.

[0068] Respective wells 102 of a sample plate 100 store samples bonded with fluorochromes having different fluorescent wavelengths such as a fluorescein derivative and a Rhodamine derivative in correspondence to the four types of end bases of DNA fragments. The sample plate 100 is formed with a wiring pattern, in which electrodes are arranged in the wells 102 respectively and connected to a high-voltage wiring cable through a connector part 106 respectively.

[0069] A high-voltage switching part 136 switchably connects the reservoir 110 and the sample plate 100 so that wiring can be switched, and an electrophoretic high-voltage power source 134 is connected between the high-voltage switching part 136 and the electrode 132 provided in the other reservoir 120 for switching and applying voltages for sample injection and electrophoresis.

[0070] In sample injection, one ends 2 a of capillary columns forming a capillary array 2 are inserted one by one into the wells 102 of the sample plate 100 , and after the sample injection, the ends 2 a are switched to the reservoir 110 to be dipped in the buffer solution 112 . The other ends 2 b of the capillary columns are dipped in the buffer solution 122 of the other reservoir 120 . The second ends 2 b are provided with a part to be detected 2 c irradiated with excitation light from an optical measuring part 210 detecting the samples by fluorescence so that the fluorescence is measured.

[0071] The capillary column ends 2 a of the capillary array 2 have two-dimensional arrangement corresponding to the arrangement of the wells 102 of the sample plate 100 , while the capillary columns are aligned with each other on the part to be detected 2 c and irradiated with the excitation light from a direction perpendicular to the plane of the arrangement of the capillary columns.

[0072] A moving mechanism (not shown in FIG. 1 ) switches and arranges the sample plate 100 and the reservoir 110 as indicated by the broad arrow so that either one selectively comes into contact with the first ends 2 a of the capillary columns.

[0073] The optical measuring part 210 comprises, for example, a laser beam source 212 such as a mode-locked titanium sapphire laser unit having a repetition rate of 78 MHz, a pulse width of 120 to 150 fs, an oscillation wavelength of 700 to 900 nm and an average output of about 1 W. The energy of one photon of its laser beam is smaller than excitation energy for the fluorochromes.

[0074] A dichroic mirror 214 reflecting laser beam is provided on the optical path of the laser beam from the laser beam source 212 , so that the laser beam is reflected by the mirror 214 and applied to the part to be detected 2 c of the capillary array 2 through a lens 216 .

[0075] Light from the part to be detected 2 c is transmitted to the dichroic mirror 214 through the lens 216 . Fluorescence included in the light is transmitted through the dichroic mirror 214 and thereafter separated into prescribed wavelength regions by dichroic mirrors 218 , 222 and 226 . The dichroic mirror 214 transmits light having a shorter wavelength than the laser wavelength of the excitation light in the light from the lens 216 . The light transmitted through the dichroic mirror 214 is transmitted to the dichroic mirror 218 so that light having a wavelength of not more than 510 nm is transmitted through the dichroic mirror 18 and incident upon and detected by a photomultiplier tube (PMT) 220 , while light having a wavelength longer than 510 nm is reflected by the dichroic mirror 218 and transmitted to the dichroic mirror 222 . In the light from the dichroic mirror 218 , light having a wavelength of not more than 560 nm is reflected by the dichroic mirror 222 and incident upon and detected by a photomultiplier tube 224 , while light having a wavelength longer than 560 nm is transmitted through the dichroic mirror 222 and transmitted to the dichroic mirror 226 . In the light transmitted through the dichroic mirror 222 , light having a wavelength of not more than 580 nm is reflected by the dichroic mirror 226 and incident upon and detected by a photomultiplier tube 228 , while light having a wavelength longer than 580 nm is transmitted through the dichroic mirror 226 and incident upon and detected by a photomultiplier tube 230 .

[0076] The optical measuring part 210 is scanned so that the excitation light reciprocates horizontally across the plane of arrangement of the capillary columns on the part to be detected 2 c for successively detecting all capillary columns. However, illustration of a scanning mechanism is omitted.

[0077] Operations of this embodiment shall now be described with reference to FIGS. 1 and 2 .

[0078] In sample injection, the one ends 2 a of the capillary columns are dipped one by one in the wells 102 , while the other ends 2 b of the capillary columns are collectively dipped in the buffer solution 122 of the reservoir 120 . The high-voltage switching part 136 is connected to the sample plate 100 , and the electrophoretic high-voltage power source 134 applies a high voltage between the wells 102 and the reservoir 120 . The samples in the wells 102 are injected into the capillary columns.

[0079] After the sample injection, application of the high voltage is temporarily stopped and the moving mechanism moves the sample plate 100 and the reservoir 110 , thereby dipping the one ends 2 a of the capillary columns on a sample side into the buffer solution 112 of the reservoir 110 . Thereafter a high voltage is applied between the reservoirs 110 and 120 for performing electrophoretic separation. The voltage for sample injection into the capillary columns and a electrophoresis power supply voltage are, for example, 30 kV and a current capacity is 10 to 30 mA.

[0080] Separated sample components successively pass through the part to be detected 2 c , and are detected by the optical measuring part 210 at this time.

[0081] The laser beam from the laser beam source 212 is applied to the part to be detected 2 c through the dichroic mirror 214 and the lens 216 so that the fluorochromes bonded to the samples absorb multiphotons and are excited to fluoresce. The optical measuring part 210 captures the fluorescence so that the photomultiplier tubes 220 , 224 and 228 detect fluorescence having a wavelength of not more than 510 nm, fluorescence having a wavelength longer than 510 nm and not more than 560 nm, fluorescence having a wavelength longer than 560 nm and not more than 580 nm and fluorescence having a wavelength longer than 580 respectively.

[0082] Base sequence can be determined by bonding the fluorescence having a wavelength of not more than 510 nm, the fluorescence having a wavelength longer than 510 nm and not more than 560 nm, fluorescence having a wavelength longer than 560 nm and not more than 580 nm and the fluorescence having a wavelength longer than 580 to DNA fragment samples for the respective bases respectively.

[0083] Since a Raman scattering line generated in the part to be detected 2 c due to irradiation with the laser beam has a wavelength at least 700 nm, it does not form background noise in fluorescence detection. Furthermore, the intensity of Rayleigh scattering is advantageously smaller than that of a conventional argon laser beam. In addition, four types of fluorochromes can be efficiently excited with a single laser wavelength due to the multiphoton absorption method, whereby it is not necessary to introduce a plurality of fluorochromes into the same molecule.

[0084] The optical measuring part 210 is not restricted to this embodiment but may have any system so far as the same can excite fluorochromes bonded to samples by multiphoton absorption for making the same fluoresce and detect the fluorescence.

[0085] While the present invention is applied to a multi-capillary electrophoretic apparatus in this embodiment, the present invention is also applicable to electrophoresis employing a single capillary column.

[0086] FIG. 3 is a side sectional view schematically showing one embodiment applying the second aspect of the present invention to a multi-capillary electrophoretic apparatus, and its multi-capillary array-electrophoresis part comprises a detection side holder fixing part fixing a detection side holder and a parallelism adjusting mechanism adjusting the parallelism between a detection part and a part to be detected.

[0087] A capillary array 2 is formed by arranging a plurality of capillary columns charged with gels of separation media. One ends (lower ends) 2 a of the capillary columns defining a sample injection side are two-dimensionally arranged and fixed by a sample injection side holder 4 to come into contact with a sample in a sample injection reservoir or a buffer solution in a lower reservoir for electrophoresis. The other ends 2 b of the capillary columns forming the capillary array 2 define a detection side on which the capillary columns are aligned with each other by a detection side holder 6 , and comes into contact with an upper reservoir buffer solution. A part to be detected 2 c is provided on the detection side ( 2 b side) of the capillary array on a position where the capillary columns are aligned with each other and supported by the detection side holder 6 .

[0088] FIGS. 4, 5 and 6 are a schematic front elevational view, a schematic left side elevational view, and a schematic top plan view showing an exemplary capillary array mounted on this embodiment

[0089] In the sample injection side holder 4 , a rubber plate 4 d of silicone rubber holding and fixing glass capillary columns in/to holes is held between resin holder plates 4 a and 4 b for two-dimensionally arranging the capillary columns and integrated by fixed screws 4 c . The holder plates 4 a and 4 b are provided with holes for receiving the capillary columns on 16 by 24 portions in correspondence to the positions of holes of a 384-hole microplate used for sample introduction. The diameters of the holes of the holder plates 4 a and 4 b are set larger than the outer diameters of the capillary columns. The capillary columns passing through the holder plates 4 a and 4 b and the rubber plate 4 d held therebetween are held in the holes of the rubber plate 4 d by elasticity of rubber, to be airtightly fixed to the holder 4 .

[0090] The detection side holder 6 holds the capillary columns closely arranged on a plane by a holder plate 6 a from below and by a rubber plate 6 d of silicone rubber from above. In order to press and fix the capillary columns against and to the holder plate 6 a with the rubber plate 6 d , holder plate 6 b is provided for fixing the rubber plate 6 d to the holder plate 6 a on both side portions of the arrangement of the capillary columns. Fixed screws 6 c fix the holder plates 6 a and 6 b to each other.

[0091] The total length of each capillary column is about 500 nm, and the part to be detected 2 c is provided on a position of about 400 nm from the end of the sample injection side. In order to form a detection window on the part to be detected 2 c , the holder plates 6 a and 6 b and the rubber plate 6 d are provided with elliptic openings 8 extending in the direction of the arrangement of the capillary columns so that the openings 8 overlap with each other on the part to be detected 2 c . Signal detection in electrophoresis is performed through the openings 8 .

[0092] The multi-capillary electrophoretic apparatus according to the present invention is provided on the detection part with location pins 44 a guiding the holder 6 to a fixed position as described later, and the holder 6 is provided with location holes 44 b receiving the location pins 44 a.

[0093] Each capillary column is made of quartz glass or borosilicate glass, and has an outer diameter of 200 to 300 μm and an inner diameter of 75 to 100 μm. The outer periphery of the capillary column is preferably covered with a film of a non-fluorescent material such as SiO ₂ not fluorescing or fluorescing to an extent not hindering fluorescence measurement with excitation light of ultraviolet to near infrared regions. In this case, the film may not be removed on the part to be detected 2 c . If the capillary column has a fluorescing resin film, the film is removed on the part to be detected 2 c.

[0094] The capillary columns are charged with a polyacrylamide gel, a linear acrylamide gel, a polyethylene oxide (PEO) gel and the like as gels of separation media. Samples containing four types of DNA fragments labeled with four types of fluorescent materials selected from FAM, JOE, TAMRA, ROX, R6G, R-110 and the like varied with the end bases are injected into the capillary columns respectively and simultaneously electrophoresed.

[0095] Referring again to FIG. 3 , an argon gas laser unit 10 is provided as an excitation light source for exciting the labeling fluorescent materials. The argon gas laser unit 10 is a multi-line type unit having an output of 40 to 100 mW and simultaneously oscillates laser beams having wavelengths of 488 nm, 514.5 nm and the like.

[0096] When applying the multi-capillary electrophoretic apparatus shown in FIG. 3 to an apparatus utilizing multiphoton absorption of the first aspect, a mode-locked titanium sapphire laser unit generating a laser beam having a longer wavelength than fluorescence generated by a labeled fluorochrome is used as the excitation light source in place of the argon gas laser unit 10 . The energy of one photon of the laser beam is smaller excitation energy for the fluorochrome.

[0097] An optical system 12 applying the laser beam from the laser unit 10 to the part to be detected 2 c of the capillary array 2 as excitation light and detecting fluorescence from the part to be detected 2 c is an epi-optical system shown in FIG. 7A in detail. Numeral 16 denotes a mirror perpendicularly applying a laser beam 14 from the laser unit 10 to a surface of the part to be detected 2 c of the capillary array 2 , numeral 18 denotes a tunnel mirror having a hole on its center for transmitting the excitation light beam through the hole and reflecting the fluorescence on a mirror surface, and numeral 20 denotes an objective lens consisting of a condenser lens condensing and projecting the excitation light onto a single capillary column and receiving fluorescence generated from a sample migrating in the capillary column. The objective lens 20 projects the excitation light and receives the fluorescence by the same lens, and forms the epi-optical system. The mirror surface of the tunnel mirror 18 reflects the fluorescence collected by the objective lens 20 .

[0098] Numeral 22 denotes an optical filter blocking an excitation light component from the reflected light and transmitting the fluorescence, numeral 24 denotes a pinhole slit for limiting a detection field, and numeral 26 denotes a diaphragm lens imaging the fluorescence transmitted through the optical filter 22 on the position of the pinhole slit 24 . A fluorescing point in the capillary column is imaged on the position of the pinhole slit 24 , thereby forming a confocal optical system. An edge filter or colored glass can be employed as the optical filter 22 for removing the excitation light. The pinhole slit 24 reduces the detection field for preventing invasion of stray light from adjacent capillary columns.

[0099] n order to divide the fluorescent image on the pinhole slit 24 into four luminous fluxes, a lens panel 28 shown in FIG. 7B is arranged. The lens panel 28 can be manufactured as that prepared by cutting single lenses and sticking the same to each other or a glass molding. A filter panel 30 formed by different spectroscopic filters for respective labeling fluorescent materials shown in FIG. 7C is arranged on optical paths of the four luminous fluxes. The filter panel 30 is a bandpass filter, which is formed by arranging four types of filters having different wavelength characteristics corresponding to the labeling fluorescent materials on the respective optical paths in parallel with each other. The transmission wavelengths of the respective filters correspond to light emission wavelengths of the fluorescent materials labeling fragment samples whose end bases are A (adenine), G (guanine), C (cytosine) and T (thymine). Four photomultiplier tubes 32 are arranged on the respective optical paths for detecting fluorescence transmitted through the filters.

[0100] he epi-optical system 12 including the mirror 16 , the tunnel mirror 18 , the objective lens 20 , the optical filter 22 , the pinhole slit 24 , the diaphragm lens 26 , the lens panel 28 , the filter panel 30 and the photomultiplier tubes 32 is mounted on a stage of a scanning mechanism 34 , and reciprocally moved along a straight line (perpendicular to the plane in FIG. 3 and vertical in FIG. 7A ) parallel to the plane of the part to be detected 2 c of the capillary array 2 and perpendicular to the electrophoresis direction, in order to detect fluorescence from all capillary columns on the part to be detected 2 c . The laser beam 14 is incident upon the mirror 16 in parallel with a scanning direction of the epi-optical system 12 , so that the optical axis of the laser beam 14 is not fluctuated by scanning of the epi-optical system 12 .

[0101] FIG. 8A is a sectional view of one embodiment of the detection side holder fixing part and its periphery as viewed from above, FIG. 8B is a front sectional view taken along the line B-B′ in FIG. 8 A and FIG. 8C is a side sectional view taken along the line C-C′ in FIG. 8 A, while FIG. 8A is taken along the lines A-A′ in FIGS. 8B and 8C . FIGS. 8A and 8B omit illustration of an upper electrode 58 and a detection side capillary end pressing member 60 , and FIG. 8A also omits illustration of a detected part pressing member 62 .

[0102] A movable plate 36 is provided on a position for fixing the detection side holder 6 . FIGS. 9A, 9B and 9 C are a top plan view, a front sectional view and a right side elevational view showing the movable plate 36 respectively.

[0103] The movable plate 36 is formed by a substrate 36 a and a detection position plate 36 b . The substrate 36 a is provided with a slot 38 in a direction where the epi-optical system 12 is scanned. The detection position plate 36 b slightly smaller in dimension than the opening 8 of the detection side holder 6 is arranged on the slot 38 . An epi-optical system scanning groove 40 is formed in the detection position plate 36 b on the substrate 36 a side, and a slot defining a light application window 42 is formed on the bottom surface of the scanning groove 40 . The objective lens 20 side of the epi-optical system 12 is arranged in the slot 38 and the scanning groove 40 and scanned along the slot 38 .

[0104] Two location pins 44 a are arranged on positions of the substrate 36 a corresponding to the location holes 44 b of the holder 6 . The holder 6 is correctly arranged on the movable plate 36 by registering the positions of the location pins 44 a and the location holes 44 b and those of the detection position plate 36 b and the opening 8 of the holder 6 .

[0105] Furthermore, set screws 46 are arranged on the substrate 36 a on positions corresponding to four comers of the holder 6 . The height for arranging the holder 6 can be adjusted by rotating the set screws 46 and adjusting the length of the set screws 46 projecting from the substrate 36 a.

[0106] Furthermore, the substrate 36 a is provided with a gate angle adjusting mechanism formed by two gate adjusting screws 48 a passing through the substrate 36 a and a gate adjusting supporting point pin 48 b provided on a side opposed to the side provided with the gate adjusting screws 48 a and opposite to the detection position plate 36 b . The parallelism between the movable plate 36 and a scanning axis of the epi-optical system 12 can be adjusted by rotating the gate adjusting screws 48 a.

[0107] The holder 6 is fixed to the movable plate 36 by fastening two clamps 50 provided in the vicinity of both ends of the movable plate 36 .

[0108] An upper reservoir 52 storing a buffer solution for dipping the other ends 2 b of the capillary columns forming the capillary array 2 and a cover 54 covering upper portions of the movable plate 36 and the upper reservoir 52 are provided in the vicinity of the movable plate 36 . The cover 54 can be opened/closed along a cover switching shaft 56 .

[0109] The upper electrode 58 covered with a cylindrical insulating member is mounted on the cover 54 and comes into contact with the buffer solution of the upper reservoir 52 in the state covered with the cover 54 . A capillary array end pressing member 60 is arranged on the cover 54 , for bending the other ends 2 b of the capillary columns forming the capillary array 2 toward the upper reservoir 52 and dipping the same in the buffer solution.

[0110] The cover 54 is provided with the detected part pressing member 62 on a position corresponding to the part to be detected 2 c . The pressing member 62 is formed with a plane smaller in dimension than the opening 8 of the holder 6 , and a rubber plate 64 of silicone rubber is stuck to this plane. Four rod members 66 provided on the cover 54 mount the pressing member 62 to be slidable in a direction perpendicular to the plane of the part to be detected 2 c . Springs 68 are arranged on the rod members 66 between the cover 54 and the pressing member 62 respectively, so that the pressing member 62 presses the part to be detected 2 c against the detection position plate 36 b with appropriate pressure through the silicone rubber plate 64 when the cover 54 is closed after arranging the holder 6 on the movable plate 36 .

[0111] The detection side holder fixing part according to the present invention is formed by the movable plate 36 , the gate adjusting screws 48 a , the gate adjusting supporting point pin 48 b , the clamps 50 and the detected part pressing member 62 .

[0112] As shown in FIG. 3 , the detection side holder 6 is fixed in an electrophoresis chamber 66 . A lower electrode 68 is mounted on a lower portion of the chamber 66 , to come into contact with a buffer solution in a lower reservoir and communicate with the lower ends 2 a of the capillary columns forming the capillary array 2 when the buffer solution in a sample injection reservoir or the lower reservoir for electrophoresis is pushed up to a position coming into contact with the lower ends 2 a of the capillary columns. A sample injection voltage or an electrophoresis voltage is applied between the buffer solutions in both reservoirs from a high-voltage power source through the electrodes 58 and 68 . For example, the power supply voltage is 30 kV and a current capacity is 10 to 30 mA.

[0113] The reservoir for electrophoresis and a sample injection reservoir 70 are arranged in a horizontal plane and supported on an X-Z sample stage 72 under the ends 2 a of the capillary columns on the sample injection side of the capillary array 2 . The X-Z sample stage 72 performs movement in a horizontal direction (X direction: perpendicular to the plane of FIG. 3 ) for locating either reservoir under the ends 2 a and movement in a vertical direction (Z direction: vertical in FIG. 3 ) for bringing the buffer solution in-the reservoir into contact with the ends 2 a or separating the former from the latter by a sample stage moving mechanism 74 .

[0114] A sample titer plate 76 formed with wells corresponding to the arrangement of the ends 2 a of the capillary columns is placed on the reservoir 70 . Bottoms of the wells pass through the sample titer plate 76 , membranes are formed on the bottoms and samples are adsorbed on the membranes of the wells. The buffer solution in the reservoir 70 comes into contact with the membranes, and the sample injection voltage is applied to the ends 2 a of the capillary columns from the lower electrode 68 through the buffer solution.

[0115] Operations of fixing the detection side holder 6 to the movable plate 36 and adjusting the parallelism between the plane of the part to be detected 2 c and the scanning axis of the epi-optical system 12 shall now be described.

[0116] The capillary array 2 having the part to be detected 2 c charged with a fluorochrome is prepared so that the holder 6 for the capillary array 2 is arranged on the movable plate 36 by opening the cover 54 and registering the positions of the location pins 44 a and the location holes 44 b and clamped and fixed by the clamps 50 . Thus, the part to be detected 2 c of the capillary array 2 can be fixed to the apparatus with excellent reproducibility.

[0117] The cover 54 is closed so that the pressing member 62 presses the part to be detected 2 c against the detection position plate 36 b and fixes the same onto the light application window 42 along the plane of the detection position plate 36 b while the pressing member 60 dips the ends 2 b of the capillary columns of the capillary array 2 in the buffer solution of the upper reservoir 52 .

[0118] The epi-optical system 12 is scanned and an image formed on the pinhole slit 24 is observed to determine whether or not the distance between the part to be detected 2 c and the objective lens 20 is proper. If the distance between the part to be detected 2 c and the objective lens 20 is improper, the gate adjusting screws 48 a are rotated for adjusting the distance between the part to be detected 2 c and the objective lens 20 . Thus, requirement for working accuracy in preparation of the detection side holder 6 and formation of the capillary array 2 can be relieved and reduction of detection sensitivity can be suppressed. Furthermore, since the distance between the part to be detected 2 c and the epi-optical system 12 can be adjusted, this electrophoretic apparatus is adaptive to various outer diameters of the capillary columns arranged on the capillary array 2 . In addition, outer diameter tolerance by manufacturing lot difference of the capillary columns can be allowed.

[0119] While this embodiment employs two gate adjusting screws and the gate adjusting supporting point pin as the gate angle adjusting mechanism, the present invention is not restricted to this but a gate angle may be automatically adjusted in correspondence to a detection signal at the time of scanning the epi-optical system by employing an actuator such as a piezoelectric element, for example.

[0120] Alteratively, an actuator moving the epi-optical system along the optical axis of applied light may be provided in place of the gate angle adjusting mechanism for automatically adjusting the distance between the part to be detected and the epi-optical system.

[0121] FIG. 10 is a perspective view of a capillary cassette of one embodiment arranging a plurality of capillary columns.

[0122] A plurality of capillary columns 102 of a capillary array 2 are arranged, sample injection sides are fixed by a cassette holder 4 and detection sides are fixed by a cassette holder 6 and a heat-shrinkable tube 80 on an end to form a capillary cassette 9 . One ends 2 a of the capillary columns 102 define a sample injection part and are two-dimensionally arranged and fixed by the cassette holder 4 . The other ends 2 b of the capillary columns 102 forming the capillary cassette 9 are planarly aligned with each other, fixed by the cassette holder 6 , and cylindrically bundled by a shrank heat-shrinkable tube 80 . A detection window is formed on the cassette holder 6 , and portions of the capillary columns 2 located on the detection window define a part to be detected 2 c.

[0123] For example, the outer diameter of each capillary column 102 is 300 to 400 μm.

[0124] FIGS. 11A to 11 C are model diagrams showing a procedure of bundling the ends 2 b of the capillary columns 102 by the heat-shrinkable tube 80 . FIGS. 12A and 12B are sectional views taken along the lines A-A′ and B-B′ in FIG. 11C . These figures show the capillary columns 102 in a reduced number.

[0125] Manufacturing is performed along the following sequence:

[0126] (A) After aligning the plurality of capillary columns 102 with each other, a filler 12 such as an epoxy resin adhesive or a silicon compound is applied to surface portions of the capillary columns 102 on prescribed positions from the ends 2 b.

[0127] (B) The ends 2 b of the capillary columns 102 are bundled and inserted into the heat-shrinkable tube 80 , which in turn covers the positions to which the filler 12 is applied.

[0128] (C) The heat-shrinkable tube 80 is heated and shrunk. The inner diameter of the heat-shrinkable tube 80 is reduced, the capillary columns 102 adhere to each other, and clearances therebetween are filled up with the filler 12 so that the capillary columns 102 are cylindrically bundled in an airtight manner. Clearances between the heat-shrinkable tube 80 and the capillary columns 102 and between the capillary columns 102 are sealed with the filler 12 , and both ends of the heat-shrinkable tube 80 do not communicate with each other except in the capillary columns 102 .

[0129] FIG. 13 is a model diagram showing a method of fixing a mounting member to a polymer charger to the ends 2 b of the capillary columns 102 .

[0130] The capillary columns 102 bundled by the heat-shrinkable tube 80 are inserted into a ferrule 86 serving as the mounting member for the polymer charger along with the heat-shrinkable tube 80 and fixed by a screw 88 so that each capillary column 102 attains sufficient pressure resistance in polymer injection.

[0131] It is preferable to set the outer diameter of the shrank heat-shrinkable tube 80 receiving the capillary columns 102 to a pipe outer diameter of a liquid chromatograph such as φ1.6 (outer diameter of 1.6 mm), φ2or φ3 by adjusting the outer diameters of the capillary columns 102 , the number of the capillary columns 102 and the thickness of the shrank heat-shrinkable tube 80 . Consequently, an existing ferrule employed for a liquid chromatograph or the like can be employed. When preparing a dedicated ferrule, the capillary columns 102 may be bundled in response to the inner diameter of the dedicated ferrule.

[0132] Irregularities of the bundled capillary columns 102 are removed due to the thickness of the heat-shrinkable tube 8 , and hence the thickness of the shrunk heat-shrinkable tube 80 is preferably increased.

[0133] In polymer charging, the ferrule 86 is connected to and mounted on a connection part of the polymer charger, for charging the capillary columns 2 with polymers by press-filling or suction.

[0134] FIG. 14 is a schematic perspective view showing one embodiment of a multi-capillary electrophoretic apparatus to which the capillary cassette 9 shown in FIG. 10 is applied. FIG. 14 omits illustration of the cassette holders 4 and 6 . This multi-capillary electrophoretic apparatus is identical to that shown in FIG. 1 except the structure on the side of the other ends 2 b , and hence redundant description is omitted.

[0135] The ends 2 b of the capillary columns are bundled by the heat-shrinkable tube 80 , and dipped in a buffer solution 122 in a reservoir 120 along with the heat-shrinkable tube 80 .

[0136] Operations in electrophoretic separation are also identical to those in FIG. 1 .

[0137] Such a multi-capillary electrophoretic apparatus preferably comprises an automatic polymer charging mechanism for reusing the capillary columns 102 by discharging used polymers from the capillary columns 102 and charging new polymers.

[0138] Although the present invention has been described and illustrated in detail, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation as the spirit and scope of the present invention are limited only by the terms of the appended claims.