NL8702338A - METHOD FOR PROCESSING OF (BIO-) CHEMICAL OR (MICRO-) BIOLOGICAL REACTIONS USING MICRO-WAVES, METHODS AND APPARATUS THEREFOR - Google Patents

Description

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Method for conducting (bio-) chemical or (micro-) biological reactions, using microwaves, methods thereof and apparatus therefor.

The invention relates to a method according to the preamble of claim 1.

Such methods are known from "Rapid immunoperoxidase staining of lymphocyte antigens using microwave irradiation" from A.S. Leong and J. Milios from Journal of Pathology, vol. 148, 1986 and / or "Use of microwaves for rapid immunoperioxidase staining of paraffin sections" from K.Y.

Chiu from Medical Laboratory Sciences (1987) 44.

These methods use microwave radiation falling on a specimen for a short period of time; published test results proved difficult to reproduce and it was unclear when such results were and were not achieved. The experiments were surrounded with "black magic".

An object of the present invention is to obtain reliable, fast results, in particular for testing blood or mucus samples, but also for obtaining fast histological and cytological experimental results. Such an object is achieved by the method according to claim 1.

The method according to the invention makes it possible to allow biochemical reactions to take place much faster, eg instead of during a period of 24 hours, only for 1 or 2 hours, without the microwave radiation causing the temperature to exceed physiological limits, eg .

40 ° C or 80eC has entered the preparation to prevent damage to the preparation. The composition can comprise a piece of tissue or one or more cells, but can also be formed by a drop of blood or mucus.

Immunomicroscopy has become an important tool in research and surgical pathology, in particular 8702338 -2- t

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after the introduction of monoclonal antibodies. In immunodetection, staining of a cell or tissue component is achieved by binding to an antibody with a macromolecule (antigen) in the tissue. Staining or detection of the reaction product in the tissue is accomplished by enzymes visualized by providing a colored reaction product, such as peroxidase, fluorescent markers, or special markers, such as ferritin and colloidal gold. This gold is particularly sensitive to the electromagnetic microwave radiation.

In order to obtain a reaction product, the reagents must diffuse into the tissue; it has already been proposed to use microwaves for this purpose. Due to the microwave radiation, the bond between an antibody and an antigen takes place much faster, instead of hours it only takes seconds.

Further details, features and advantages of the invention will become apparent from a drawing, in which: fig. 1 shows a perspective view of a micro wave chamber, in which a drop of blood or mucus is placed, fig. 2 one of a coolant line provided tray for a specimen contained between two glass slides, Figures 3, 4 and 5 graphs of temperature versus time in experiments using the method of the invention.

A microwave chamber 2 provided with a microwave antenna 1 comprises a table or tray 3 arranged therein, where-30 is placed on a pre-cooled plate 4, which plate 4 is brought e.g. to -20 ° C in a freezer installation, on which a a plastic plate 5 is placed on which a drop of blood or mucus 6 is located, so that microwave beams drawn according to the broken lines can reach droplet 6 from antenna 1.

Fig. 2 shows another embodiment of the tableau 3 of FIG. 1, which is indicated by 3 ', in which or under which a conduit 7 to be flowed with a coolant is included, 8702338 -3-, through which for instance freon gas can flow. A piece of tissue or preparation 9 is arranged between two glass plates 8, whereby immuno-detection can take place relatively quickly under the influence of microwaves.

Fig. 3 shows that with the aid of the cooling with the plate from the freezer 5, a drop of 2.5 ml with a power of 150 watts supplied to the antenna 1 in a time of 4 minutes only of about 20 ml. ° C rises to about 35 ° C, which does not entail any physiological consequences for such a blood or mucous drop. Fig. 4 shows a graph of the temperature course of a drop of 2.5 ml at a power supplied to the antenna of 80 Watt, while FIG. 5 shows that even the temperature of a drop of 30 µl at an added fed power of 150 watts can remain almost constant.

The graphs shown in Figures 3, 4 and 5 have been measured with thermometers using an optical fiber; the periodic temperature fluctuations are striking here. The tests were performed in a Mielle M696 brand microwave chamber.

It will be appreciated that the temperature restriction can be achieved by means other than those shown in Figure 1, such as, for example, placing a buffer stock of electrolyte (water) in the microwave oven, or a wet sheet of paper under the composition. The buffer electrolyte stores excess radiation, thereby allowing indirect control of the emissivity sent by the micro wave antenna to the specimen.

Application possibilities of the present invention are numerous: marking reactions using color, or viewing processes using the electron microscope (eg using so-called gold-labeling) and all kinds of tests for blood and mucus, such as for AIDS. Previously, such tests usually required 24 hours to 35 hours and can now be carried out, for example, in two hours. Naturally, the microwave antenna can be designed in any possible way and the drawing shows only a single schematic exemplary embodiment. The principle of microwave radiation combined with cooling can also be applied for fixation with fixations for electron microscopy. Fine details in human, vegetable (yeast) and animal cells can be made visible in this way.

The method according to the invention will also be advantageously applicable in the analysis of yeast cells.

Treatment of, for example, a macrophage under the electron microscope shows that the method according to the present invention prevents shoots of such a macrophage from dying off.

When embedding a composition in a monomer material, where the monomer material is allowed to polymerize, temperature rise can be a problem; the method according to the present invention can therefore advantageously be applied in this embedding, in which the temperature may be allowed to rise to a value above 80 ° C, but not to above a predetermined higher limit temperature.

for the production and detection of proteins with a catalysing and anabolizing effect (enzymes), regulation of the temperature according to microwave radiation can be essential, irrespective of whether this concerns human, animal and / or vegetable tissue, cells and / or body fluids.

At the time of the drafting of the present patent application, proofs were available of a book of applicants to be published in October or November 1987, Dr. M.E. Boon and Dr L.P. Kok, entitled "Microwave Cookbook of Pathology, The art of microscopic visualization", to be published by Coulomb Press Leyden in Leiden; the microwave radiation applications mentioned therein are intended to be incorporated herein, and such applications are further claimed in the appended claims, which define the scope of the present invention.

8702338

Claims (19)

Method for conducting (bio -) - chemical or (micro-) biological reactions, in which microwaves are irradiated on a preparation in which the reaction takes place, characterized in that the temperature rise of the preparation is kept limited. 2. A method according to claim 1, wherein the temperature rise is kept limited by an air flow past the preparation, the air flow having a temperature lower than the predetermined, highest achievable temperature. The method of claim 1 or 2, wherein the rise in temperature is limited to 80 ° C, preferably to 50 ° or 40 ° C. 4. Method according to claim 1, 2 or 3, wherein the preparation is placed against a pre-cooled plate in a microwave cabinet provided with a microwave transmission antenna. The method according to any of the preceding claims, wherein the reaction is a DNA-DNA hybridization. The method of claim 1, wherein the reaction is a reaction between an antigen and an antibody. A method according to any preceding claim, wherein the reaction comprises coupling proteins. 8. Immunohistological or immunocytological method, using any of the methods according to any one of the preceding claims. The method of claim 8, wherein the immunohistological response is observed at the electron microscopic level. 10. Immunosorbent assay coupled to immunoenzymes (ELISA) using a method according to any of the preceding claims. Device for carrying out the method according to one of the preceding claims. 8702338 -6- t * The device of claim 11, comprising a sealed cabinet, a microwave transmitter antenna disposed therein, and a heat conducting container for a specimen. The device of claim 12, wherein the wood. 5 has a heat capacity which has a high value relative to that of the preparation and the energy content over the radiation period. Device as claimed in claim 12 or 13, wherein the holder is provided with cooling means. Fixation of a preparation by means of monomer material to be polymerized under the influence of microwave radiation, wherein the method according to any one of claims 1-4 is used. 16. Method for performing rinsing steps, as is usual in immuno techniques, in which a method according to any one of claims 1-4 is used. A method for sterilizing non-heat-resistant materials, using a method according to any one of claims 1-4. A method of producing and detecting enzymes, using a method according to any one of claims 1-4. 19. A method of preparing food, such as pudding, etc., using a method according to any one of claims 1-4. 8702338