EP0539379A1 - Automatic tissue staining for immunohistochemistry - Google Patents

Abstract

Apparatus (10) for automatically coloring fabrics, comprising a body (12) on which a circular plate (16) rotates. The circular tray (16) can carry a plurality of lamellae (24) carrying tissue samples. A supply head assembly (18) is mounted on the body (12) so as to move over the entire diameter of the circular plate (16). The head assembly includes a cleaner nozzle (20) and a sprayer nozzle (22). A version (50) of the spray nozzle (22) for spraying a liquid biochemical agent on a coverslip (24) comprises a main body (52), a closure element (56) in the main body (52) and a cap (54) located on said main body (52), between which there is a swirl chamber (68) through which the liquid from the body (52) passes. The liquid enters the swirl chamber (68) so that the flow in the chamber (68) is concentric with the axis of the chamber and then it flows from the body (52) through an orifice outlet (66), thereby minimizing deterioration of the biochemical agent.

Description

AUTOMATIC TISSUE STAINING FOR IMMUNOHISTOCHEMISTRY

This invention relates to iraraunohistochemistry, and in particular relates to apparatus for automatically staining tissue sections, or cell preparations.

Histochemistry is a branch of biochemistry devoted to the study of the chemical composition and structure of animal and plant tissues. It involves the use of microscopic, x-ray diffraction and radioactive tracer techniques in examining the cellular composition and structure of bones, blood, muscle and other animal and vegetable tissues.

Immunohistochemistry is useful for directly viewing the cellular distribution of a molecule (marker) using labelled antibodies or other ligands including nucleic acid probes. Labels include enzymes, radioisotopes and fluorescent molecules. The technique can be applied to whole cells, for example for identification of lymphomas (white blood cell cancers) or to tissue sections, for example for cancer diagnosis.

The specific (or primary) antibody may be labelled directly. Alternatively and more often, a second antibody carrying the label is used to specifically bind to the first. Also, the tissue may require pretreatment to reveal the marker of interest (enzymic) or to remove non-specific effects.

A number of methods have been developed to amplify the visual signal and this may add several steps to the technique. Ultimately, in the case of an enzyme-label a substrate is applied which produce^ a coloured product at the site of the label. The surrounding tissue is then counterstained to provide contrast. Therefore most protocols for carrying out staining involve a large number of incubations of various time periods, separated by washing to remove spent reagents.

Each operation requires considerable care in the application of small amounts (50 to 200 microlitres) of reagents to cover the tissue adequately and also in the washing steps to ensure complete removal of spent reagents and o avoid accidental removal of tissue from the slide. Thus, when a large number of slides are involved the procedure is labour intensive, tedious and can suffer from a lack of reproduc- ibility .

A manual technique currently utilised for staining tissue involves a skilled technician performing all operations manually.

Firstly, glass specimen slides are supported on trays. When staining is carried out above ambient temperature, heating is normally provided using a specially designed temperature- controlled template with provision to allow high humidity.

The slides are washed with a buffer stream from a hand- operated dispensing bottle. The slides are then cleared of liquid by being set vertically to drain, and wiped around the specimen with paper towel material.

The biochemical agent delivery is via a manual pipettor positioned by eye such that the fluid is spread to cover the tissue sample. Chemical reagents with short active lives are manually mixed in vials using standard pipettors.

The control of event sequences and times is performed manually with the aid of a stopwatch and note pads.

It is obvious that such a manual process is inherently inaccurate, time consuming and costly.

There have been prior attempts to automate such a process, and details of such attempts appear hereunder. (l)Stross, W.P., Jones, M. , Mason, D.Y.

J. Clin. Pathol. Jan 1989 42(1) p 106-112

These authors have modified en existing tissue processing instrument (Histokinette E7326; British American Optical Corporation) to carry out immunohistochemical staining of tissues in a semi-automated manner. Slides are placed in racks which are dipped into tanks of reagents which are used repeatedly for up to four months. The method was only applied to the (APAAP) Alkaline phophatase staining method and did not automate the application of primary antibody or substrate. (2)Brigati, D.J., Budgeon, L.R., Unger, E.R., Koebler, D., Cuomo, C, Kennedy, T., Perdomo, J.M. J. Histotechnol. .11(3), 1988 p 165-183

These authors claim to have developed the first automated method for immunocytochemistry. The method uses a triaxial robotic slide system to move racks of slides between reagents. The slides are paired so that reagents fill the gaps between slides by capillary action. The system is claimed to be able to carry out the complete immunostaining procedure as well as in-situ hybridisation and has been commercialised by Fischer Scientific Co. (U.S.A.). (3)Stark, E., Faltinat, D., Von der Fecht, R. , J. Immunological Methods 107 (1988) p 89-92

These authors have described an instrument in which up to 30 slides are carried on a carousel which can be rotated rapidly to remove reagents. The antibodies or other solutions are pipetted onto the slides by standard plastic syringes.

This approach has a major disadvantage in that it uses large volumes of expensive reagents and does not automate the primary antibody step.

(4)Mehven, L., Med. Lab. World Feb 1989 p 45-46

Described a novel coverslip device which is used to create a capillary gap between the slide and coverslip. Reagents are transfered from vials in a carousel to a funnel part of the coverslip using an automatic pipette and an x-slide device. 10 basic method programs can be used to run 20 slides automatically with a variety (up to 9) primary antibodies. The instrument has been commercialised by Shandon Scientific (U.K..) under the "Cadenza" trade name.

(5)Recently Lipshaw (U.S.A.) have released an instrument for the automatic staining of batches of slides by the peroxide technique. The system involves the transfer of a rack of slides between baths of reagents with a robotic arm. The instrument is limited to use for slides undergoing identical methods, is not useful for adding primary antibody and uses large volumes of other reagents. It is an object of the present invention to provide improved apparatus for immunohistochemical staining tissue or cell preparations.

The invention provides apparatus for immunohistochemical sample processing, including sample support means, washing means for dispensing washing fluid onto said sample, clearin means for cleaning said sample, and agent dispensing means fo dispensing an agent onto said sample.

The invention also provides apparatus for processing tissu samples in immunohistochemistry, including slide support mean for supporting at least one slide, said slide support mean being constituted by a rotatable carousel, and head assembl means adapted to move relative to said slide support means, an adapted to dispense fluid to a slide on said support means.

The invention further provides a device for spraying a surface with fluid, said device including a body having a bore therethrough for the passage of said fluid, means located in said body for changing the flow of said fluid from a direction generally along said bore to a generally annular flow,- there being a swirl chamber located in proximity to a fluid exit, said swirl chamber being adapted to turn said generally annular flow to a generally concentric flow prior to fluid leaving said chamber through said fluid exit.

A preferred embodiment of the invention, will be described in^' detail hereinafter with reference to the accompanying drawings, in which^*:-

Fig. 1 is a perspective view of automatic tissue staining apparatus;

Fig. 2 is a perspective view of a detail of apparatus generally similar to that of Fig. 1;

Fig. 3 is a front elevation of a clear nozzle;

Fig. 4 is a side elevation of the nozzle of Fig. 3;

Fig. 5 is a rear elevation of part of the nozzle of Fig. 3;

Fig. 6 is an underneath plan view of the nozzle of Fig. 3;

Fig. 7 is a section along the lines A-A of Fig. 3;

Fig. 8 is a side elevation of a spray nozzle;

Fig. 9 is an end elevation of a spray nozzle body;

Fig. 10 is a section along the lines A-A of Fig. 9;

Fig. 11 is a section along the lines B-B of Fig. 10;

Fig. 12 is a perspective view of a spray nozzle end cap;

Fig. 13 is a front elevation of the cap of Fig. 13;

Fig. 14 is a partially sectioned side elevation of the cap of Fig. 13; Fig. 15 is a rear elevation of the cap of Fig. 13;

Fig. 16 is an end elevation of a plug; and

Fig. 17 is a side elevation of the plug of Fig. 16.

Referring firstly to Figs. 1 and 2, the automatic tissue stainer 10 includes a body 12 having a hinged portion 14 in an open position showing a horizontal carousel 16, a delivery head assembly 18, clear nozzle 20 and spray nozzle 22.

As shown in Fig. 2 - which represents a slightly different model to that illustrated in Fig. 1 - the carousel 16 is adapted to rotate about a generally vertical axis, and is further adapted to carry slides 24 on a single level surface near its periphery, and reagent or the like containers 26 towards the axis of the carousel 16.

Delivery head assembly 18 is adapted to move across the diameter of carousel 16, on rails 28 and 30, and it. can be seen that a combination of rotational movement of the carousel and translational movement of the head 18 enables nozzles 20, 22 to direct material onto any part of any slide 24 or to any container 26. Preferably a third (wash fluid delivery) nozzle is also mounted on head assembly 18, and preferably each nozzle is capable of vertical movement relative to the assembly.

The apparatus 10 enables automatically controlled sequences to be carried out using various electro-mechanical systems (not shown). The apparatus 10 is operated and controlled by a keypad 32 and display 34.

The carousel 1.6 is adapted to be heated, preferably from beneath and possibly⁴ utilising hot air.. Preferably, use is made of heated water located beneath the slide, which are located upon supports. Preferably, automatic temperature and control, of the water, is provided.

Head assembly 18 may also include a .slide wash facility (not shown) which involves the delivery of a stream of buffer or wash liquid from a dispenser, in a controlled fashion, from the aforementioned third nozzle to a slide 24 located beneath the dispenser on carousel 16. Preferably, the head lrf moves along the slide axis, to evenly distribute the liquid on the slide. Preferably, the buffer liquid is supplied from a pressurised storage bottle with a valved on/off control. The head assembly 18 also includes a slide clear facility, which is used to clear a slide 24 of liquid dispensed as described in the preceding paragraph. To so clear the slide, the nozzle 36 of Figs. 3 to 7 inclusive is utilised, whic nozzle 36 may take the place of generalised nozzle 20 of Fig. 1.

Clear nozzle 36 includes a body 38 with a widened dispensing end 40 over which is located a plate 42. There is ,above 44 in body 36, communicating with a plenum 46 in end 40. An exit orifice 48 directs a '.'curtain" of air onto a slide 24. Preferably, air from a pressurised manifold is supplied to nozzle 36.

Nozzle 36 is moved by head 18 along the axis of slide 24, and the stream or curtain of air from orifice 48 pushes any fluid on the surface of slide 24 along the axis and off the sides and ends of the slide.

Head 18 also includes a biochemical agent delivery facility, using the spray nozzle 50 of Figs. 8 to 17 inclusive, which nozzle 50 may take the place of generalised nozzle 22 of Fig. 1.

Spray nozzle 50 includes a main body 52, an end cap 54 and a plug 56. Main body 52 has a knurled portion 58 adapted to be used to secure body 52 to end cap 54. Body 52 also has flow- splitting channels 60 and a ferrule seal 62, the latter for connection to a vacuum source, a pipettor or the like for operating the spray nozzle.

End cap 54 has an internal circumferential lip 64 which seals with main body 52. The cap has an axially-located exit orifice, behind which is a swirl chamber 68.

In Fig. 13 (rear elevation) is shown a structure 70 which acts to direct fluid (see the arrows) into the swirl chamber 68 to ^"ensure that the flow is concentric to the chamber axis.

Plug 56 has a spigot 72 and a locating boss 74.

In the assembled nozzle 50 of Fig. 8, the direction of fluid is shown by arrows. The nozzle 50 achieves a small vortex spray chamber effect where fluid is forced under pressure into a circular chamber (68) in such a manner that the flow is concentric to the axis. The spray exits through central outlet 66.

The structure and operation of the spray nozzle 50 is such that antibodies - as a reagent sub-group - may be sprayed onto a surface without loss of activity.

The proteins in antibodies are susceptible to shear forces normally encountered in conventional spray nozzles. This results in the antibodies being denatured and to consequently lose activity. For that reason, spraying of antibodies has not been considered possible.

It appears that when using the spray nozzle 50, the fluid path is such that antibodies emerge unscathed from the exit 66.

It is preferable to minimise spray head "dead space" and to optimise the fluid velocity and flow so that the correct spray section and pattern are provided to cover an area of a slide 24 from the delivery position. Preferably the area is less than the total area of the slide, more preferably in the range 1/4 to 3/4 of the total slide area, and more preferably 1/3 the total slide area, and the nozzle 50 is preferably located between 10mm and -100mm above slide 24, more preferably about 30mm above a slide 24.

Furthermore, it is preferable that the nozzle 50 perform with a total fluid volume . per spray of between 50 and 200 microlitres. This small volume is selected to cover the slide area with a consistent layer of fluid.

The various parts (52,54,56) of nozzle 50 are preferably formed from injection-moulded plastics material, and the nozzle is preferably connected via ferrule 62 to the delivery conduit of a pipettor delivery head. The pipettor is preferably an electrical/electronic pipettor system (not shown) which acts on a syringe to draw fluid from a container 26 (storage vial) to deliver the fluid via nozzle 50 to slide 24.

The pipettor facilitates the obtention of fluid by a controlled vertical motion whereby it moves down such that the syringe is within the fluid storage vial 26; the pipettor then operates to draw the required amount of fluid into the system; and the syringe moves up in a controlled manner to withdraw from the storage vial 26.

Some chemical agents require mixing just prior to use; they have short active lifetimes after mixing. These items may b mixed by the use of the pipettor system drawing up one agen from its storage vial and dispensing it into the storage via in which the second agent is held. The mixed solution is the drawn up and dispensed onto the slides as described.

As described earlier, the apparatus 10 provides a automatic tissue-staining or slide washing/drying coatin process.

Preferably, there are six modes of operation:

Process Mode: Unit automatically running program.

Load Mode: Operator loading slides/reagents with unit prompt.

Program Mode: Operator setting up a specific protocol program for use in process mode.

Unload Mode: Cycle complete, operator unloads processed slides.

Self Clean Mode: Unit self flushing the working surfaces.

Self Test Mode: Unit running pre-run checks.

The apparatus is capable of performing any combination of the programmed protocols up to a limit of ten. The apparatus - is capable of processing up to twenty slides.

Preferably, the apparatus carries a power failure battery back up to enable processing to be satisfactorily shut down at an appropriate stage.

It can be seen that this invention provides apparatus which enables the old manual techniques to be replaced by automatic procedures, operated by a less skilled operator.

Claims

1. Apparatus for immunohistochemical sample processing, including sample support means, washing means for dispensing washing fluid onto said sample, clearing means for cleaning said sample, and agent dispensing means for dispensing an agent onto said sample.

2. Apparatus according to claim 1, wherein said sample is a sample located on a slide.

3. Apparatus according to claim 2, wherein said sample support means is a rotatable carousel having a flat surface for supporting said slide.

4. Apparatus according to any preceding claim, wherein said washing means, said clearing means and said agent dispensing means are located on a head assembly which is movable relative to said support means.

5. Apparatus according to claim 4, wherein said clearing means includes a nozzle adapted to deliver a curtain of air to said slide.

6. Apparatus^* according to claim 4, wherein said agent dispensing means is associated with a pipettor system.

7. Apparatus according to any preceding claim, wherein said agent is a reagent or biochemical agent.

8. Apparatus for processing tissue samples in immunohistochemistry, including slide support means for- supporting at least one slide, said slide support means being constituted by a . rotatable carousel, and head assembly means adapted to move relative to said slide support means, and adapted to dispense fluid to a slide on said support means.

9. A device for spraying a surface with fluid, said device including a body having a bore therethrough for the passage of said fluid, means located in raid body for changing the flow of said fluid from a direction generally along said bore to a generally annular flow, there being a swirl chamber located in proximity to a fluid exit, said swirl chamber being adapted to turn said generally annular flow to a generally concentric flow prior to fluid leaving said chamber through said fluid exit.

10. A device according to claim 9, wherein said body includes a plug means adapted to successively produce a increased-diameter annular flow, and means to direct sai annular flow into said swirl chamber to produce said generall concentric flow.

11. A device according to claim 9 or claim 10, wherei said fluid exit is co-axial with said swirl chamber.

12. A device according to any one of claims 9 to 11 wherein said directing means is at least one channel adapted t intercept said annular flow and deliver fluid from that flow a a tangent to said chamber periphery.