GB2234348A - Apparatus for treating specimens with liquids - Google Patents

Abstract

Apparatus for treating e.g. histopathology, haematology or cytology specimens has a reaction chamber formed by adjacent surfaces (112, 113) separated by O ring seals (114). Chamber has liquid inlet and outlets (115 and 116). At least one of the surfaces may be a microscope slide. <IMAGE>

Description

APPARATUS FOR REACTIONS WITH LIQUIDS This invention relates to apparatus for carrying out reactions with liquids.

In GB 1 454 365 (now lapsed) is described an apparatus for treating slide specimens, for example, specimens used in histopathology, haematology or cytology.

The slide specimens were supported on a slide carrier so as to form a recess into which a treament liquid, such as a stain, could be introduced so as to contact the specimen. The liquid was supplied to a plurality of recesses covered by specimen-carrying slides along a liquid supply channel and collected therefrom in a collection channel.

Various problems were encountered with the apparatus. For example, the slide carrier was formed of a glass or Perspex (Registered Trade Mark) block with a recessed ground upper surface. Problems were encountered with the build up of deposits on the ground glass or Perspex, which led to impaired sealing of the microscope slide on to the recess.

There was also perceived a need for more versatility and greater economy for example of expensive reagents than the apparatus provided.

The present invention seeks to provide an apparatus which does not have the sealing problems of the apparatus of the above mentioned patent.

The invention comprises apparatus for carrying out reactions with liquids comprising reaction chamber means formed between separable, adjacent surfaces by o-rTng seal means pressed between the surfaces and liquid inlet and outlet means.

The apparatus may comprise a plurality of separate reaction chambers formed between two separable, adjacent surfaces by O-ring seal means.

At least one of said surfaces may be of a glass plate and one of said surfaces may be profiled to locate O-ring seals thereon.

Said chamber means may be formed on one side by a standard microscope slide, the O-ring seal means being so dimensioned as to be contained within the edges of the slide.

The inlet and outlet means may be in the same surface.

The O-ring seal means may be of silicone rubber or like material.

Embodiments of apparatus for carrying out reactions with liquids will now be described with reference to the accompanying drawings, in which Figure 1 is a part plan view of an upper portion of one embodiment of apparatus of the invention; Figure 2 is a part plan view of the apparatus of Figure 1 at a lower level, showing the channels for temperature controlled fluids to allow the slides, recesses and reagents to be heated or cooled; Figure 3 is a cross section taken along line III-III of Figures 1 and 2; Figure 3a is an enlargement of a fragmentary area of Figure 3; Figure 4 is a cross section along line IV-IV of Figure 1; Figure 5 is a cross section taken along line V-V of Figure 1; Figure 6 is a flow diagram of the apparatus.

Figure 7 is an elevation of another embodiment of reaction chamber means; Figure 8 is a section on the line VITI-VIlT of Figure 7; Figure 9 is a detail from Figure 8 drawn to a larger scale; Figure 10 is a section on the line X-X of Figure 7; Figure 11 is a section through another form of O-ring seal; and Figure 12 is a plan view of an automatic staining apparatus incorporating the reaction chamber means illustrated in Figures 7 to 11.

The drawings illustrate apparatus for carrying out reactions with liquids, in particular, in this case, for carrying out treatment of slide-mounted specimens used in histopathology, haematology or cytology with liquid, for example, a stain.

In such treatment, multiple operations, using different liquids, are often carried out on individual specimens, and it is highly desirable to automate the process. Many of the reagents used are expensive and so it is desired to use them only in small quantities and often to be able to recover them after use.

The housing of the apparatus illustrated in Figures 1 to 6 comprises the slide carrier shown in Figures 1, 2, 3 and 3a which includes an elongate block 2, formed of glass in the present example, having an upper plane surface 4 in which there are formed a series of eight rectangular recesses 6 spaced apart by bridge pieces 8 and having depths of about 1 mm. The upper faces of the bridge pieces are flush with the surface 4 of the block.

Stainless steel inlet and outlet tubes 10 and 12 respectively are provided for connection of each recess 6 to a supply of liquid reagent. These tubes are connected to a flow control system in the form of solenoid operated valves and a peristaltic pump arrangement to ensure the supply of the liquid in an even and controlled manner.

Figure 2 shows the temperature control system of the apparatus, cooling or heating liquid being circulated, through inlet 14 and outlet 16, to a serpentine chamber 18 which extends beneath the area occupied by the reaction recess 6.

Slides carrying specimens to be treated are laid inverted over the recesses so that each slide completely covers a recess. Liquid from each stainless steel tube 10 is drawn by suction from the passage 18 through the recess under the slide, thereby treating the specimen thereon, and eventually reaches the output stainless steel tube 12.

The slide carrier is shown more clearly in Figures 4 and 5 which illustrates the glass block 2 formed having a ground upper plane surface 4. The recess 6 formed in the plane surface 4 has a depth of approximately 1 mm. One inlet tube 10 and outlet tube 12, both made of stainless steel are shown which enter the recess 6 for delivery of reagent to the recess and for collection of used reagent therefrom, respectively.

It will be appreciated that the flow of liquid in tubes 10 and 12 is controlled by solenoid operated pinch valves to be described below.

In use, a slide S carrying a specimen to be treated is laid inverted over the recess 6 to completely cover it, the position of a 3H by 1" (70 mm by 25 mm) slide so placed being shown in Figure 1 in dotted lines. Liquid for the treatment is then drawn into the recess through the inlet tube 10 by the application of suction to the outlet tube 12.

In use, the slide carrier described above is employed in conjunction with the arrangement shown in the diagram of Figure 6.

The support arrangement for a series of containers 20 of liquid for treatment of the slide specimen is arranged in a so-called carousel comprising sixteen outer positions at A and sixteen inner position, B. It is thus possible to arrange as required admixtures of solutions from the outer positions B to containers in the inner positions A. The selection of containers 20 is according to a pre-arranged sequence and is entirely computer controlled.

Thus if the liquid in a container 20 in position B is required for mixing it is pumped in a desired quantity to the container in position A by means of a first peristaltic pump 22.

From the container 20 at A, liquid is drawn by the action of a second peristaltic pump 24 into a line 26 which supplied the liquid to all eight inlet tubes 10 of the reaction recesses 6 (only three shown in Figure 6). Selected recesses 6 may be omitted from the flow by means of solenoid operated pinch valves 28 on lines 10 and similar valves 30 on lines 12 which isolate the appropriate recesses 6 as required.

Thus various recesses may be subjected to a different liquid or selection of liquids as required.

Conveniently, a record is thus readily available of the sequences employed.

In the apparatus reagent liquid leaving the recess 6 through tubes 12 joins a line 32 which leads either to a return line 34 to be pumped via a filter 36 back to the container 20 at A to a waste line 38 to disposal receptacle 40 attached to a vacuum pump arrangement indicated at 42, according to the settings of motorised valves 46 and 48 on lines 38, 26 and 38'.

Should it be required for the apparatus to be supplied with a reagent other than those available in the containers of the carousel, for example distilled water or phosphate buffered saline solution, further containers 50 and 52 may readily be introduced into the flow circuit under control of valves 54 and 56 respectively.

As mentioned above the entire operation is computer controlled.

A computer controls the apparatus through a computer interface and includes a timing system to give accurate control of the process stages.

The staining machine as explained above is controlled by a series of solenoid pinch valves. Mains powered synchronous motors drive the peristaltic pumps, the vacuum pump, rotate the reagent carousel, and raise and lower dipper tubes, 58, into the reagents. These power devices are switched by the computer interface through isolating opto-couplers for the mains devices, and sensors on various parts of the machine are interrogated by the interface to detect specific conditions in the machine.

Each individual slide has its reagent reaction schedule stored in a series of "strings" describing the desired reagent treatment, time in the reagent, and temperature. The strings are constructed and modified by a programme which stores the finished technique allowing it to be called up as and when required under its specific technique name for use in the staining programme Each reagent schedule in the present example may have up to 85 individual steps in it and last up to 99 hours each or for as short a period as a few seconds.

The temperature may be varied for each stage within certain limitations but all slides are subjected to the same temperature at a particular time. Reagents in the apparatus may be maintained at a controlled temperature, typically 40C. It will be understood that the temperature conditions may be varied as desired by computer control.

With computer control, it is possible to treat automatically a number of different specimens with different series of liquids for specified durations all in a single piece of laboratory apparatus. In the apparatus illustrated in Figure 12, a number of reagents are loaded into pots 161 on a carousel 162 which rotates under the control of a programmed computer 163 until a selected pot 161 is at a pumping station 164. A dipper tube 165 is lowered into the pot 161 and reagent sucked out by peristaltic pump means (not shown) and fed through valve means 166 to a reaction chamber in reaction chamber means 167 illustrated in more detail in the other Figures.

The reaction chamber means 167 includes a number - as illustrated, eight - of individual reaction chambers each adapted to hold a different microscope slide-mounted specimen.

Since different treatments using different reagents will be carried out on different specimens simultaneously, it is desirable that the individual reaction chambers are liquid tight to avoid contamination of adjacent chambers - also to avoid wastage of expensive reagents.

Figures 7 to 12 illustrate reaction chambers 111 formed between separable, adjacent surfaces 112, 113 by O-ring seal means 14 pressed between the surfaces 112, 113 and liquid inlet and outlet means 115, 116.

One of the surfaces, 112, is of a glass block or plate 117 which is profiled to locate the O-ring seals 14 thereon. The block or plate 117 has raised lands 118 around which the O-ring seals 114 fit and intermediate raised retaining areas 119 separating the chambers.

The O-ring seals 114 fit snugly around the raised lands 118 (which may be adhesively secured to a flat face of the block or plate 117) and are so dimensioned that a standard microscope slide 21 (3" x 1" or 7.6 mm x 2.5 mm) will cover the O-ring seal 114.

The surface 113 is simply a flat face of another glass block or plate 122.

When the blocks or plates 117 and 122 are pressed together with slides 121 in position, the seals 114 hold the slides spaced from the raised lands 118 by about 0.5 mm.

Inlet and outlet tubes 115, 116 of e.g. stainless steel are fixed in the block or plate 117 e.g. by an epoxy adhesive.

The blocks or plates 117, 122 are pressed together by any convenient means such as spring clamps (not shown).

Figure 11 illustrates a different form of O-ring having a non-circular cross-section.

The apparatus illustrated has been found to operate in a working environment without any tendency to leak or to waste reagents and to provide convenient reaction chamber means with ready interchange of slide-mounted specimens. O-rings 114 of silicone material do not appear to develop undue wear despite constant use, and no special slides - just regular laboratory specimen slides - are needed to obtain good sealing.

By keeping tubing inner diameters small the amounts of expensive reagents needed can be kept correspondingly small and the apparatus can be operated, on account of the fluid-tightness of the O-ring seals in particular and the layout and operational flexibility of the apparatus in general, to process different specimens on adjacent slides with different reagents according to different treatment specifications as to duration of treatment and number of treatment operations, all under computer control so that the operations are carried out automatically without operator intervention except for the initial program specification and the loading of the reagents into the carousel pots. This loading can, of course, be carried out under computer prompting to avoid the possibility of loading error.

Reference is made to Application No. 8728271 (Publication No. 2 200 210) from which this application is divided.

Claims (7)

CLkIMS

1. Apparatus for carrying out reactions with liquids comprising reaction chamber means formed between separable, adjacent surfaces by O-ring seal means pressed between the surfaces and liquid inlet and outlet means.

2. Apparatus according to claim 1, comprising a plurality of separate reaction chambers formed between two separable, adjacent surfaces by O-ring seal means.

3. Apparatus according to claim 1 or claim 2, in which at least one of said surfaces is of a glass plate.

4. Apparatus according to any one of claims 1 to 3, in which one of said surfaces is profiled to locate O-ring seal means thereon.

5. Apparatus according to any one of claims 1 to 4, in which said chamber means are formed on one side by a standard microscope slide, the O-ring seal means being so dimensioned as to be contained within the edges of the slide.

6. Apparatus according to any one of claims 1 to 5, in which inlet and outlet means are in the same surface.

7. Apparatus according to any one of claims 1 to 6, in which said O-ring seal means are a silicone rubber.