JP2020523613A - Paraffin protective coating for microscope slides - Google Patents

Abstract

A protective coating on the microscope slide is provided. In particular, a selective application of a paraffin layer is provided to protect biological materials and inorganic chemical deposits from microbial attack and oxidation. In addition, in particular, the application of a paraffin layer to microscope slides as exposure protection on attached biomaterial reactive targets is also provided. The paraffin protective layer protects biological materials and chemical targets from exposure that could lead to oxidative degradation and provides resistance to fungal growth while protecting and co-existing using existing dyeing process steps. Paraffin is removed from the tissue section to be treated.

Description

This application claims the benefit of US Provisional Patent Application No. 62/520169 filed June 15, 2017, and US Provisional Patent Application No. 62/520319 filed June 15, 2017, each disclosure Are incorporated herein by reference in their entirety.

The present invention relates to protective coatings on microscope slides. The invention relates in particular to the application of paraffin layers for protecting biological materials and inorganic chemical deposits from attack and oxidation by microorganisms. In addition, in particular, the invention relates to the application of paraffin layers to microscope slides as exposure protection on attached biomaterial reactive targets. The paraffin protective layer protects biological materials and chemical targets from exposure that can lead to oxidative degradation and provides resistance to fungal growth while protecting and co-existing using existing dyeing process steps. Paraffin is removed from the tissue section to be treated.

Generally, paraffin wax is a white or colorless soft solid derived from petroleum, coal or oil shale and consists of a mixture of hydrocarbon molecules containing 20 to 40 carbon atoms. Paraffin wax is a solid at room temperature, begins to melt at about 37°C (99°F), and has a boiling point greater than 370°C (698°F). Common applications of paraffin wax include lubrication, electrical insulation, and candles. The dyed paraffin wax can be processed into crayons. Paraffin wax differs from kerosene and other petroleum products, which are sometimes referred to as paraffin.

In the pathology laboratory, paraffin wax is used to penetrate tissue prior to sectioning thin tissue samples. Increasing the concentration of alcohol (75% to anhydrous) removes water from the tissue and the tissue is clarified in an organic solvent such as one of the aliphatic substitutes such as xylene or xylol. The tissue is then placed in paraffin wax for several hours, set in a mold with the wax, cooled and solidified. After that, a section is cut out on a microtome.

Embedding tissue sections in paraffin is routinely done to preserve tissue sections for long periods of time. However, the application of paraffin as a thin coating layer on selected areas of microscope slides has not been reported. Selected regions may include proteins, conjugated proteins, antibodies, peptide chains or protein-coated beads, or other cellular material. Paraffin is originally known to contain antifungal and antibacterial agents that prevent oxidation of antigenic sites and acid/base degradation of exposed sites by air. Paraffin protective coatings change the lifespan of biological materials and chemical targets from 3-5 days to 1-2 years, allowing a useful product life for the end user. Removal of embedded paraffin is also routinely performed to expose tissue sections for subsequent immunohistochemistry (IHC) or hematoxylin and eosin (H&E) staining. Utilizing the same or similar paraffin formation for protection of other attached material on the same microscope slide ensures that no further slide treatment is required prior to the start of IHC or H&E staining.

Reference may be made to US Pat. No. 6,096,086 which discloses an alternative paraffin seal for a cover glass for sealing the two inlets of a chamber embedded in a glass slide. The sealed chamber allows for closed-system microscopy of samples without the risk of damage from microscopic observation or other manipulations. Such practice does not support direct encapsulation or IHC treatment of biological material, especially deparaffinization of tissue sections.

China Utility Model Registration No. 204790174

In general, one aspect of the invention is the application of paraffin coatings on biological materials and inorganic targets.

In another aspect of the invention, the biomaterial and the inorganic target are attached to a microscope slide and the paraffin coating is selectively applied as a protection to cover only a portion of the attachment.

In yet another aspect of the present invention, the resulting coated microscope slide is subsequently heated to melt and/or blend the paraffin particles and to seal both the deposit and the slide surface around the deposit. It has a smooth surface.

In yet another aspect of the present invention, the paraffin coating may be applied by spray coating, screen printing, inkjet method, pad printing, roller transfer printing and the like.

In yet another aspect of the invention, the paraffin coating increases the shelf life of the tissue section by preventing oxidation of antigenic sites and acid and/or base degradation by air of exposed sites.

Other aspects of the invention are disclosed in the description below.

FIG. 1 is a cross-sectional view of a selectively applied paraffin protective layer on biomaterials and chemical deposits. The paraffin is melted after deposition, eliminating the liquid needed to make the paraffin a liquid and sealing the edges of the slide and/or slide adhesive coating.

The present invention may be understood more readily by reference to the following detailed description of the invention which forms a part of this disclosure. The present invention is not limited to the particular devices, methods, conditions, or parameters described and/or shown herein, and the terminology used herein is merely exemplary. It is to be understood that it is not intended to limit the claimed invention. Also, as used in the specification, including the claims appended hereto, the singular forms ('a','an', and'the') that do not specify a quantity include the plural forms and references to specific numerical values. Includes at least the specific numerical value, unless otherwise specified by the content. Where expressed in other embodiments herein, ranges may be expressed as from “about” or “approximately” another particular value. Also, unless stated otherwise, the dimensions and material properties referred to herein are exemplary rather than limiting, and are intended to provide a better understanding of the preferred practical sample embodiments. It should be understood that variations out of value may also fall within the scope of the invention depending on the particular application.

The invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following description or illustrated in the drawings. Other embodiments of the invention are possible and can be implemented or practiced in various ways. Also, the terms and terminology used herein are for the purpose of description and should not be construed in a limiting sense. Use of "including," "comprising," "having," "containing," "involving," and variations thereof includes additional items. ..

Hereinafter, preferred embodiments of the present invention will be described in detail.

The tissue block and the section cut from the tissue block are immersed in paraffin to completely replace the water in the cell structure of the tissue with paraffin. Paraffin does not naturally support the growth of bacteria and fungi and ensures the long-term stability of the embedded biological material.

Target proteins attached to glass or plastic microscope slides provide a rich source of food for the bacterial or fungal antagonist. In addition, the antigenic site of the protein is prone to oxidation, which significantly loses the ability of the detection antibody to bind to the protein. Many of the binding sites in subsequent reactions are hydroxyl and can be compromised by reaction with acids and bases in air. Typically, slides containing attachment proteins are stored at temperatures below those that support microbial growth. However, such constraints limit the effective use of deposits. In addition, the protein-attached slides are housed in vacuum-sealed containers to prevent oxidative damage. The shelf life of unprotected protein-adhered slides in ambient air is between 2 and 5 days depending on ambient temperature and the level of contamination in air.

Targets that react specifically with the chemical structure of inorganic dyes are also easily oxidized and easily react with substances in the air. Targets that are reactants of such staining include hematoxylin, eosin, and targets of most specialty staining groups. The targets of these stains are specifically designed to react with only one type of stain. Biological targets often do not provide the specificity that chemical constituents can provide. Therefore, the present invention provides a solution by providing a method of selectively coating biomaterials and targets on any type of microscope slide to protect it from any type of degradation.

In one embodiment of the invention, paraffin is blended with a solvent to change the state of matter at room temperature from a solid to a liquid. The blends use Paraplast X-tra or equivalents of xylene or green xylene substitutes: aliphatic solvents, such as xylol, to reduce viscosity and delay coagulation after deposition. In another embodiment, the solvent may be selected from, but not limited to, toluene, paint thinner, turpentine oil, or a 50:50 mixture of acetone and kerosene.

In another embodiment, the solid paraffin is melted to a liquid at a temperature above the paraffin melting point of 75° C. or lower until it becomes liquid, and then the aliphatic solvent is added slowly until a saturation point is observed (a solid is formed). .. The mixture is cooled to 45° C. and more aliphatic solvent is slowly added until it is completely clear.

In another embodiment, the paraffin coating described above is a special stain material that reacts with biological materials and special stain reactive deposits and applied antibodies and secondary stain reagents that have been pre-applied to the adhesive coated microscope slide. Is coated onto a special staining reactive end group that specifically captures, the biological material comprising proteins, peptides, conjugated proteins, protein-coated beads, peptide-coated beads, or conjugated protein-coated beads. However, it is not limited to these.

In another embodiment, the paraffin layer can be deposited on adhesive coated microscope slides, including by spraying, inkjet deposition, transfer printing (eg pad printing), screen printing, and vapor deposition. , But not limited to these. In all attachment methods, the paraffin layer must be less than 5 μm thick to ensure that all paraffin (protective and tissue section embedded) can be dissolved and removed during the paraffin removal step of the staining process. Regardless of adhesion treatment/method, paraffin standards are:
Be a thin layer, preferably less than approximately 5 microns,
A melting point of less than 60° C., preferably less than 56° C., melting upon exposure to a xylene or xylol (aliphatic substitute) solvent, and
It has a hardness close to that of embedded paraffin at ambient temperature.

In another embodiment, paraffin materials for embedding tissue blocks include Thermo Fisher TissuePrep and TissuePrep 2 (melting point 56°C), Leica Paraplast and Paraplast plus (melting point 56°C), Leica Paraplast X-tra (melting point 50). C. to 54.degree. C.), but is not limited thereto. Paraplast X-tra in particular incorporates the phenolic antioxidant butylated hydroxytoluene to reduce oxidative degradation of proteins, peptides and inorganic targets.

In another embodiment, each is a blend of refined paraffin, synthetic polymer, and other materials for establishing melting point, hardness and viscosity. Paraffin does not originally help microbial growth.

In another embodiment, the special stain is Alcian blue, aniline blue-orange G solution, Azan stain, Birshawski silver stain, Brow & Benn Gram stain, Cresyl violet, DAB, Fontana Masson, Gordon. Sweet silver stain, Grocott's Methenamine silver stain, Hall bilirubin stain, Jones Methenamine silver stain, Luxor fast blue, Luxor fast blue-cresyl violet, Muchicarmine (Meyer) Method), Mueller-Morley colloidal iron, orange G, nuclea fast red, diastase-digested PAS, periodate Schiff (PAS), phosphotungstic acid, hematoxylin, picrosirius red, acidified toluidine blue, trichrome-gomory one step Method, Trichrome-Masson, Victoria Blue, Boncossa, Weigel Tresorcin Fuchsin, Weigert Iron Hematoxylin, Zell-Nielsen Method, but are not limited thereto.

In another embodiment, the target may be selected from, but not limited to, a pigmented deposit, which may include, for example, black and white, or any pigment color.

In another embodiment, the microscope slide to which the paraffin coating described above may be applied may be selected from, but not limited to, glass, plastic, or any polymeric material. In another embodiment, the paraffin may be purified and anhydrous.

In another embodiment, the resulting microscope slide is subsequently heated to melt and/or blend the paraffin particles into a uniform surface coating that seals both the deposit and the slide surface around the deposit. be able to.

In yet another embodiment, the resulting microscope slides are heated after the paraffin has been deposited to exclude the solvent from the paraffin and ensure that it returns to its hardened state. Heating should be from the paraffin side of the slide, preferably using infrared light. Melting the paraffin from top to bottom ensures that the solvent rises and can be evaporated from the paraffin unhindered. The result is shown in FIG. Figure 1 shows how molten paraffin ensures a good seal at the edges of the deposit.

The following examples are illustrative of the actual approach of the invention and should not be construed as limiting the scope of the invention.

Example 1
Spray application method Spray on the surface by a weak air flow. A mixture of a small amount of liquid and air is preferred. The mixture is sprayed onto the slide through a mask covering the PRS target. Typically, one to two passes will form a layer less than 5 microns thick. Both the paraffin mixture container and the spray head are heated to a temperature just above 56°C to ensure that the paraffin is fluid and remains fluid during the transfer from the spray head to the slide. The spray area from the head has a nominal width of 0.375 inches, but a mask may be used for smaller protection areas. Subsequent infrared reheating ensures 100% sealing.

Example 2
Screen Printing Method A stainless steel screen is heated by passing an electric current through the wire of the screen between two parallel planes. The temperature of the screen should be slightly below the melting point of paraffin to prevent the paraffin from falling off the bottom of the screen. Basically, paraffin behaves as a paste rather than as a liquid. PRS requires a reheat cycle to ensure 100% sealing.

Example 3
Inkjet Method Inkjet heads need to have a heater built into the printhead to keep the paraffin in a liquid state. Subsequent reheating cycles of the slides ensure 100% sealing.

Example 4
Roller Transfer Printing Method A heated roller pulls a film of paraffin from the heated container to the roller. The roller then transfers a film of paraffin to the slide in much the same way that a brushed roller paints a wall. Subsequent reheating cycles of the slides ensure 100% sealing.

Claims (14)

A microscope slide having a paraffin protective coating for biological material and/or inorganic deposits on the microscope slide, the paraffin protective coating comprising the steps of:
(A) melting the solid paraffin at a temperature in the range of 60°C to 75°C until it melts to liquid paraffin;
(B) adding a solvent to the liquid paraffin obtained in step (a) until a saturated mixture is obtained,
(C) cooling the mixture obtained in step (b) to a temperature between 30° C. and 33° C. and then slowly adding solvent until a nearly clear paraffin liquid is obtained,
(D) applying the layer of the transparent paraffinic liquid obtained in step (c) onto the biological material and/or inorganic deposits on the microscope slide, in all or selective areas of the microscope slide. Forming the paraffin protective coating above,
(E) evaporating the solvent from the paraffin protective coating using infrared heating to return it to a cured solid state;
A microscope slide coated on said microscope slide by. The microscope slide according to claim 1, wherein the solid paraffin is purified and anhydrous. The microscope slide according to claim 1 or 2, wherein the melting point of the solid paraffin is 50°C to 60°C. The paraffin is selected from TissuePrep and TissuePrep 2 of Thermo Fisher having a melting point of 56° C., Paraplast and Paraplast plus of Leica having a melting point of 56° C., and Paraplast X-tra of Leica having a melting point of 50° C. to 54° C. The microscope slide according to any one of claims 1 to 3. 5. The solvent is selected from xylene, aliphatic xylene substitutes (e.g. xylol), toluene, paint thinners, turpentine oil, 50:50 mixtures of acetone and kerosene, or mixtures of the listed solvents. The microscope slide according to any one of 1. 6. A microscope slide according to any one of claims 1-5, wherein the layer of step (d) has a thickness of between 1 micron and 5 microns, preferably between 2 microns and 3 microns. 7. The microscope slide according to any one of claims 1 to 6, wherein the biological material and/or the inorganic material is selected from a tissue section, a protein related sample, an inorganic target and an imaging related target, or a combination thereof. The protein-related sample is a protein, peptide, conjugated protein, protein-coated bead, peptide-coated bead, and conjugated protein-coated bead that reacts with the applied antibody and secondary staining reagent. 8. The microscope slide of claim 7, selected from 8. A microscope slide according to claim 7, wherein the imaging-related target is a deposit colored with a dye, preferably black and white dyes. The inorganic target is Alcian blue, aniline blue-orange G solution, Azan stain, Birshowski silver stain, Brow & Benn Gram stain, Cresyl violet, DAB, Fontana Masson, Gordon Sweet silver stain, Grocot Methenamine silver stain method. , Hall bilirubin stain, Jones mesenamine silver stain method, Luxor fast blue, Luxor fast blue-cresyl violet, muticarmine (Meyer method), Mueller-Morley colloidal iron, orange G, nuclea fast red, diastase digested PAS, excess. Iodic acid Schiff (PAS), phosphotungstic acid, hematoxylin, picrosirius red, acidified toluidine blue, trichrome-Gomori one-step method, trichrome masson, Victoria blue, boncosa, Wigel trescine fuchsin, Weigert iron hematoxylin, zel-Nielsen The microscope slide according to claim 7, which is a compound that reacts with staining selected from the methods. The step (d), wherein the transparent paraffin liquid obtained in the step (c) can be applied by a spray coating method, an inkjet deposition method, a transfer printing method, a screen printing method, and a vapor deposition method. 10. The microscope slide according to any one of items 10 to 10. The microscope slide according to any one of claims 1 to 11, which is either a glass or a plastic slide. The paraffin protective coating oxidizes the biological material and/or inorganic deposits on the microscope slide and/or attacks by microorganisms, and oxidizes the inorganic material and/or provides air-derived acids and/or corrosive materials The microscope slide according to claim 1, which is used to protect from a reaction. A microscope slide according to claim 1, wherein the paraffin protective coating is used to increase the shelf life of the biological material and/or inorganic deposits on the microscope slide.