Electrophoretic sample excitation light assembly

Illumination – Light fiber – rod – or pipe – Laser

Reexamination Certificate

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Details

C362S558000, C362S583000, C362S268000, C362S324000, C204S451000, C204S601000

Reexamination Certificate

active

06364516

ABSTRACT:

TECHNICAL FIELD
This invention relates to an apparatus for performing electrophoresis. More particularly, it pertains to an automated electrophoresis system employing capillary cartridges which are configured for use with commercially available, microtitre trays of standard size and including a stacked, dual carrousel arrangement, a multi-wavelength beam generator, a gel delivery system and an off-line reconditioner to eliminate cross-contamination of samples, improve system capacity and increase system throughput.
BACKGROUND
Electrophoresis is a well-known technique for separating macromolecules. In electrophoretic applications, molecules in a sample to be tested are migrated in a medium across which a voltage potential is applied. Oftentimes, the sample is propagated through a gel which acts as a sieving matrix to help retard and separate the individual molecules as they migrate.
One application of gel electrophoresis is in DNA sequencing. Prior to electrophoresis analysis, the DNA sample is prepared using well-known methods. The result is a solution of DNA fragments of all possible lengths corresponding to the same total sequential order, with each fragment terminated with a tag label corresponding to the identity of the given terminal base.
The separation process employs a capillary tube filled with conductive gel. To introduce the sample, one end of the tube is placed into the DNA reaction vial. After a small amount of sample enters the capillary end, both capillary ends are then placed in separate buffer solutions. A voltage potential is then applied across the capillary tube. The voltage drop causes the DNA sample to migrate from one end of the capillary to the other. Differences in the migration rates of the DNA fragments cause the sample to separate into bands of similar-length fragments. As the bands traverse the capillary tube, the bands are typically read at some point along the capillary tube using one of several detection techniques.
The most popular fluorescent dyes for tag labeling the DNA samples have absorption maximum wavelength ranging from 490-580 nm. A basic detection technique consists of a CCD camera with a wide-angle lens, a capillary tube array placed under the camera lens with its planar surface parallel to the CCD imaging chip, and a laser beam illuminating across the capillary array. However, a single laser line provided in the basic detection technique cannot favor all of the tag labels at the same time; therefore, either multiple lasers or optical filters are used to compensate for this shortcoming.
Usually, multiple DNA preparation reactions are performed in a commercially available microtitre tray having many separate low-volume wells, each holding on the order of 200-1000 micro-liters. The microtitre trays come in standard sizes. In the biotech industry, the currently preferred microtitre tray has a rectangular array comprising of 8 rows and 12 columns of wells. The centers of adjacent wells found in a single row are separated by approximately 0.9 cm, although this figure may vary by one or two tenths of a millimeter. The same holds for the spacing between adjacent wells in a single column. The rectangular array of 96 wells has a footprint within an area less than 7.5 cm×11 cm.
Miniaturization has allowed more wells to be accommodated in a single microtitre tray having the same footprint. New trays having four times the density of wells within the same footprint have already been introduced and are fast becoming the industry standard. Thus, these new trays have 16 rows and 24 columns with an inter-well spacing of approximately 0.45 cm.
It is not uncommon to analyze several thousand DNA samples for a given DNA sequencing project. Needless, to say, it is time consuming to employ a single capillary tube for several thousand runs.
Prior art devices have suggested means for analyzing DNA bands in multiple capillaries simultaneously. Such a device is disclosed in U.S. Pat. No. 5,498,324 to Yeung et al, whose contents are incorporated by reference in their entirety. This reference teaches a means for detecting the DNA bands as they are separated in multiple capillary tubes which are positioned parallel to another. However, in such an arrangement, each capillary tube is filled with gel and a sample is introduced into each capillary tube.
The arrangement described above takes a considerable amount of time to fill each capillary tube with gel. It also takes considerable effort to introduce a reaction sample into one end of each of the tubes reproducibly and reliably.
It is also not uncommon that one uses the same capillary tube for several consecutive sample runs. This, obviously risks cross-contamination of samples, which is a further disadvantage in certain prior art arrangements.
SUMMARY OF THE INVENTION
One object of the invention is to provide a device which allows one to simultaneously introduce samples into a plurality of capillary tubes directly from microtitre trays having a standard size.
Another object of the invention is to provide a stacked, dual carrousel arrangement to eliminate cross-contamination of DNA samples without reducing system capacity.
Another object of the invention is to provide a gel delivery module to uniformly distribute gel through the capillary tubes quickly.
Another object of the invention is to provide an off-line capillary reconditioner to thoroughly clean a capillary cartridge off-line to improve system throughput with a minimal increase in cost.
Another object of the invention is to provide an apparatus that produces a multi-wavelength beam. This multi-wavelength beam apparatus allows simultaneous detection of DNA samples which are tagged with different fluorescent tag labeling dyes.
These objects are achieved by a disposable capillary cartridge which can be cleaned between electrophoresis runs, the cartridge having a plurality of capillary tubes. A first end of each capillary tube is retained in a mounting plate, the first ends collectively forming an array in the mounting plate. The spacing between the first ends corresponds to the spacing between the centers of the wells of a microtitre tray having a standard size. Thus, the first ends of the capillary tubes can simultaneously be dipped into the samples present in the tray's wells. The cartridge is provided with a second mounting plate in which the second ends of the capillary tubes are retained. In another embodiment, instead of the second mounting plate, the second ends of the capillary tubes are bundled together and received by a liquid delivery chamber, preferably a high pressure T-fitting.
Plate holes may be provided in each mounting plate and the capillary tubes inserted through these plate holes. In such case, the plate holes are sealed airtight so that the side of the mounting plate having the exposed capillary ends can be pressurized. Application of a positive pressure in the vicinity of the capillary openings in this mounting plate allows for the introduction of air and fluids during electrophoretic operations and also can be used to force out gel and other materials from the capillary tubes during reconditioning. The capillary tubes may be protected from damage using a needle comprising a cannula and/or plastic tubes, and the like when they are placed in these plate holes. When metallic cannula or the like are used, they can serve as electrical contacts for current flow during electrophoresis.
In the preferred embodiment, a stacked, dual carrousel arrangement eliminates a cross-contamination problem without reducing the capacity of the system. The system uses a buffer solution with the gel to provide a medium for the migration of DNA from one end of the capillary tubes to the other end during electrophoresis. Since the buffer solution also migrates through the capillary tubes during electrophoresis, one end of the capillary tubes must be immersed in buffer solution to continuously replenish the buffer supply in the capillary tubes. Accordingly, the buffer solution may become contaminated with the DNA sample during electrophoresis. Next, the

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