Thionin Staining of Paraffin and Plastic Embedded Sections of Cartilage

The usefulness of thionin for staining cartilage sections embedded in glycol meth-acrylate (GMA) and the effect of decalcification on cartilage sections embedded in paraffin and GMA were assessed. Short decalcification periods using 5% formic acid or 10% EDTA did not influence the staining properties or the morphology of cartilage matrix and chondrocytes. The standard stain safranin O-fast green for differential staining of cartilage was used as control in these experiments. Prolonged exposure of safranin P stained sections to fast green resulted in disappearance of the safranin O stained matrix, thereby hampering the quantitative measurement of negatively charged glycosaminoglycans (GAG). Thionin stained evenly throughout all cartilage layers, independent of the staining times. In contrast to safranin 0, thionin did not show meta-chromasia in nondehydrated cartilage sections, which made it more suitable for assessing cartilage quality in GMA embedded cartilage. To evaluate the selectivity of thionin staining in cartilage, chondroitinase ABC and trypsin digestions were carried out. Thionin staining was prevented by these enzymes in the territorial matrix, representing the interlacunar network and the chondrocyte capsule. Staining with thionin of the interterritorial matrix was only slightly reduced, possibly representing keratan sulfate and hyaluronic acid in cartilage of elderly patients. Comparison of thionin stained GMA embedded cartilage with safranin O stained paraffin embedded sections showed significant similarity in optical densitometry, indicative of the specificity of thionin bound to negatively charged GAG in cartilage. In GMA embedded cartilage morphology was relatively intact compared to paraffin embedded sections due to less shrinkage of chondrocytes and the interlacunar network.     

Thionin Staining of Paraffin and Plastic Embedded Sections of Cartilage

The usefulness of thionin for staining cartilage sections embedded in glycol meth-acrylate (GMA) and the effect of decalcification on cartilage sections embedded in paraffin and GMA were assessed. Short decalcification periods using 5% formic acid or 10% EDTA did not influence the staining properties or the morphology of cartilage matrix and chondrocytes. The standard stain safranin O-fast green for differential staining of cartilage was used as control in these experiments. Prolonged exposure of safranin P stained sections to fast green resulted in disappearance of the safranin O stained matrix, thereby hampering the quantitative measurement of negatively charged glycosaminoglycans (GAG). Thionin stained evenly throughout all cartilage layers, independent of the staining times. In contrast to safranin 0, thionin did not show meta-chromasia in nondehydrated cartilage sections, which made it more suitable for assessing cartilage quality in GMA embedded cartilage. To evaluate the selectivity of thionin staining in cartilage, chondroitinase ABC and trypsin digestions were carried out. Thionin staining was prevented by these enzymes in the territorial matrix, representing the interlacunar network and the chondrocyte capsule. Staining with thionin of the interterritorial matrix was only slightly reduced, possibly representing keratan sulfate and hyaluronic acid in cartilage of elderly patients. Comparison of thionin stained GMA embedded cartilage with safranin O stained paraffin embedded sections showed significant similarity in optical densitometry, indicative of the specificity of thionin bound to negatively charged GAG in cartilage. In GMA embedded cartilage morphology was relatively intact compared to paraffin embedded sections due to less shrinkage of chondrocytes and the interlacunar network.     

Combined Carbowax-Paraffin Technic for Microsectioning of Fixed Tissues

A combined Carbowax-paraffin technic for microsectioning fixed tissues gave ribbon sections as do paraffin infiltrated and embedded tissues. Blocks of formalin or alcohol fixed tissues 2 mm. thick were infiltrated with H.E.M. (Polyethlene Glycol: Carbowax, Hartman-Leddon Co.) or with one of the following polyethylene glycol ester waxes (Glycol Products Co., Inc.) for 4 hours at (61°C.): Polyethylene Glycol 600(Di) Stearate; Carbowax 1000-(Mono) Stearate; Carbowax 4000 (Mono) Stearate; Carbowax 4000 (Mono) Laurate; Carbowax 6000 (Mono) Oleate. The Carbowax infiltrated tissues were placed for 10 minutes in xylene (61° C.), into paraffin (61° C.) for 30 minutes, then into molten paraffin contained in separate molds. (The xylene passage can be excluded for preparations which preclude its use). The blocks were hardened rapidly by submerging in ice water and were fastened to carriers as in the usual paraffin technic. Tissues were cut 6 µ thick. Segments of ribbon were spread on a water bath and mounted on slides. After drying, tissues were stained directly with hematoxylin-eosin or were carried through xylene and alcohols as in routine paraffin preparations prior to staining. The Sudan III fat stain and Best's carmine stain for glycogen were applied as in usual technics. Cellular detail was well preserved and structures did not show the extent of distortion and shrinkage encountered in ordinary paraffin technic preparations.     

Serial Sections of Cooked Rice Embedded in Carbowax

Serial sections of cooked rice kernels may be obtained by following either of two dehydration schedules and embedding in Carbowax. In the first schedule the cooked, rinsed and drained kernels are immersed several days in a nonaqueous fixative composed of: isopropyl alcohol, 10 ml; propionic acid, 30 ml; acetone, 10 ml; methylal, 40 ml; dioxane, 30 ml; and propylene glycol, 30 ml (Newcomer's, modified), followed by 7 or 8 days in equal parts of propylene glycol, dioxane and glycerol (changed once), and 4 days on a warming table in the same mixture with 5% Carbowax added. The dehydrated kernels are then infiltrated 4-24 hr with a Carbowax embedding mixture. In the second schedule they are immersed several days in an aqueous solution consisting of: propylene glycol, 12.5 ml; polyethylene glycol 400, 12.5 ml; either with 75 ml of water containing 0.1% thymol, or with a mixture of water, 65 ml; formalin, 10 ml; CaCl₂, 1 gm; and CdCl₂, 1 gm; followed by 3 or 4 days in 50% propylene glycol, and 3 or 4 days on a warming table in 80% propylene glycol with 5% Carbowax added. Infiltration is as above. The composition of the embedding mixture is varied according to the temperature and humidity likely to prevail during sectioning. The texture of the wax may be improved by adding small amounts of gum arabic, spermaceti, and glycerol. Serial sections 3-10 μ thick are placed on clean dry slides, and adhesive dropped at the edges of the ribbon of Carbowax until it is dissolved. The adhesive consists of water-glass (concentrated solution), 1 ml; concentrated ammonia, 1 ml; Carbowax, 5 gm; and water, 98 ml. After the slides are dry they are stored, or immersed 10 min in chloroform, collodionized, and passed to staining solutions. Atmospheric conditions affect not only the Carbowax, but also the response to reagents of cooked rice and of sections.     

Use of tissue-free glycol methacrylate sections as semi-permeable membranes: a simple way to shorten incubation times and to improve localization in enzyme histochemistry

Placing 2-microns sections of tissue-free glycol methacrylate on top of tissue sections is a simple way of forming semipermeable membranes to enhance enzyme histochemical staining. For demonstrating alkaline phosphatase in glycol methacrylate-embedded kidney by a standard azo dye method, such membranes enabled incubation times to be reduced to 1-2 hr, with azo dye reaction product being more crisply localized as compared to sections stained without membranes. Such effects are possible because the membranes are highly permeable to small molecules (e.g., substrate and diazonium salt), slightly permeable to molecules of moderate size (e.g., the final reaction product), and impermeable to large molecules (e.g., alkaline phosphatase and other tissue biopolymers). The implications of these findings for enzyme histochemistry and for enzyme-labeled antibody staining are discussed.     

The Mounting of Carbowax Sections with Lighter-Fluid and Rubber Cement

Serial sections cut from plant tissues embedded in Carbowax have been affixed to slides with rubber cement. A rather thick layer of undiluted rubber cement was first spread on the slides. The Carbowax ribbons were added next. Lighter-fluid, essentially petroleum ether which can be substituted for it, was then run under the sections to dissolve the rubber cement and to float the ribbons. This notation medium did not dissolve the Carbowax and the ribbons could be manipulated in it for accurate location. The slides were dried on a 45° C warming table which also helped to flatten the sections. Adhesion was best when drying times were held to 4 hr or less. All excess rubber cement was washed away with xylene immediately prior to covering and the cover slips were carefully applied with a very thin resinous mounting medium to prevent dislodging the sections. Both aqueous and alcoholic stains have been used successfully and the slides have been left in them for as long as 3 days without loss of sections. The method was developed for fluorescence microscopy but serves equally well for visible light microscopy. Slides stained with a safranin-fast green combination have been used for both purposes, the safranin staining and fluorescing in a manner similar to rhodamine B.     

Efficient Lipid Staining in Plant Material with Sudan Red 7B or Fluoral Yellow 088 in Polyethylene Glycol-Glycerol

Polyethylene glycol (400) with 90% glycerol (aqueous) is introduced as an efficient solvent system for lipid stains. Various lipid-soluble dyes were dissolved in this solvent system and tested for their intensity, contrast, and specificity of staining of suberin lamellae in plant tissue. The stability (i.e., lack of precipitation) of the various staining solutions in the presence of fresh tissue was also tested. When dissolved in polyethylene glycol-glycerol, Sudan red 7B (fat red) was the best nonfluorescent stain and fluorol yellow 088 (solvent green 4) was an excellent fluorochrome. These two dyes formed stable staining solutions which efficiently stained lipids in fresh sections without forming precipitates. Estimations of the solubilities of these dyes in the solvent compared with their solubilities in lipids of various chemical types indicated that they should both be effective stains for lipids in general.     

The Application of Miller's Elastic Stain to Glycol Methacrylate Tissue Sections

The application of Miller's dilute elastic stain followed sequentially by Gill's III hematoxylin and a fast green counterstain produced a reliable and consistent method for differentially staining elastic fibers, nuclei, muscle and collagen in glycol methacrylate tissue sections. Evaluation of different methods of fixation and conditions of staining on animal tissue sections showed that elastic fibers in both perfusion and immersion fixed tissues can be intensely stained. The stability of Miller's elastic stain offers the potential of a commercially available histological stain reagent for coarse and fine elastic fibers in glycol methacrylate tissue sections.     

The application of Miller's elastic stain to glycol methacrylate tissue sections

The application of Miller's dilute elastic stain followed sequentially by Gill's III hematoxylin and a fast green counterstain produced a reliable and consistent method for differentially staining elastic fibers, nuclei, muscle and collagen in glycol methacrylate tissue sections. Evaluation of different methods of fixation and conditions of staining on animal tissue sections showed that elastic fibers in both perfusion and immersion fixed tissues can be intensely stained. The stability of Miller's elastic stain offers the potential of a commercially available histological stain reagent for coarse and fine elastic fibers in glycol methacrylate tissue sections.     

Assessment of Demyelination in Glycol Methacrylate Sections: A New Protocol for Cresyl Fast Violet Staining

A simple staining technique for nervous tissue is described. Tissue perfused with glutaraldehyde and formaldehyde and postfixed with osmium tetroxide is embedded in glycol methacrylate. One-micrometer sections are stained with 0.05% cresyl fast violet aqueous solution at 60 C for 5 min, washed with tap water and air dried. With this method the details of all nervous tissue elements are clearly demonstrated. The technique is particularly useful for assessing demyelination because the staining of axoplasm allows demyelinated axons to be well visualized.     

Assessment of demyelination in glycol methacrylate sections: a new protocol for cresyl fast violet staining

A simple staining technique for nervous tissue is described. Tissue perfused with glutaraldehyde and formaldehyde and postfixed with osmium tetroxide is embedded in glycol methacrylate. One-micrometer sections are stained with 0.05% cresyl fast violet aqueous solution at 60 C for 5 min, washed with tap water and air dried. With this method the details of all nervous tissue elements are clearly demonstrated. The technique is particularly useful for assessing demyelination because the staining of axoplasm allows demyelinated axons to be well visualized.     

A Method for the Preparation of Serial Thick Sections of Plastic-Embedded Plant Tissues

A procedure is described in which thick sections (2-10μ or more) of plastic-embedded plant tissues are mounted in serial order on slides for use in routine light microscopy. Sections are cut with a steel knife on a rotary microtome while the block and blade are bathed with 40% alcohol. The cut sections are placed, in order, in 50% alcohol in the small wells of modified plastic trays where they become flat, pliable and suitable for subsequent handling. Sections remain separate and in correct order in the trays while they are stained, washed, and prepared for final mounting on slides. Mounting involves a simple and rapid procedure of transferring the sections to a slide and heating first on a 70-75 C hot plate (to slowly evaporate the water around the section and to partially affix the section) and then on a 100 C hot plate. This second heating ensures adhesion when xylene-base mounting media, which tend to loosen weakly adhered plastic from the slides, are used. The technique of staining the sections loose provides the following advantages: (1) the problems of section loss and entrapment of stain between section and slide during staining are eliminated, (2) relatively high staining temperature, akalinity, and alcohol concentration of the stain solvent (all of which promote loosening of pm-affixed sections from slides during staining) is allowed, and (3) staining is more even and selective. The procedure has been found to be reliable and fast enough to be of value in a significant variety of routine light microscope studies.     

A method for the preparation of serial thick sections of plastic-embedded plant tissues.

A procedure is described in which thick sections (2-10 mu or more) of plastic-embedded plant tissues are mounted in serial order on slides for use in routine light microscopy. Sections are cut with a steel knife on a rotary microtome while the block and blade are bathed with 40% alcohol. The cut sections are placed, in order, in 50% alcohol in the small wells of modified plastic trays where they become flat, pliable and suitable for subsequent handling. Sections remain separate and in correct order in the trays while they are stained, washed, and prepared for final mounting on slides. Mounting involves a simple and rapid procedure of transferring the sections to a slide and heating first on a 70-75 C hot plate (to slowly evaporate the water around the section and to partially affix the section) and then on a C hot plate. This second heating ensures adhesion when xylene-base mounting media, which tend to loosen weakly adhered plastic from the slides, are used. The technique of staining the sections loose provides the following advantages: (1) the problems of section loss and entrapment of stain between section and slide during staining are eliminated, (2) relatively high staining temperature, alkalinity, and alcohol concentration of the stain solvent (all of which promote loosening of pre-affixed sections from slides during staining) is allowed, and (3) staining is more even and selective. The procedure has been found to be reliable and fast enough to be of value in a significant variety of routine light microscope studies.     

Understanding microwave-stimulated Romanowsky-Giemsa staining of plastic embedded bone marrow

Summary Bone marrow smears were made and fixed in methanol or formaldehyde. Marrow sections of various thicknesses were also prepared from formaldehyde fixed marrows embedded in paraffin or plastic (glycol methacrylate). The different smears and sections were then stained by a Romanowsky-Giemsa procedure. Some specimens were stained using a standard microwave-stimulated method previously used diagnostically. The effects of technical variations were studied, including degree of microwave irradiation and the staining time. Comparisons of the resulting staining outcomes showed that microwave stimulated Romanowsky-Giemsa staining of plastic sections is a rate controlled process. Unusual aspects of the staining pattern of plastic sections (namely the purple basophilic cytoplasms and nucleoli, and blue chromatin) are due to microwave stimulation and formaldehyde fixation respectively.     

Propylene and Ethylene Glycol as Solvents for Sudan IV and Sudan Black B

Propylene or ethylene glycol is recommended as a solvent for Sudan IV and Sudan black B to replace the commonly used alcohol-acetone mixtures for general lipid staining in tissue sections. Either glycol is used as a dehydrating agent, dye solvent, and differentiating solution. They offer the advantages of a stable solution, inert with respect to solubilities of lipid material in it, and excellent control of differentiation without loss of dye from lipid particles. Sections remain pliable and are not shrunken by the glycols. Counterstains may be used after staining with Sudan IV but are generally not necessary after staining with Sudan black B. With the use of propylene glycol as a solvent, Sudan IV appears to equal the staining ability of Sudan black B as regards the type of lipid material detected, and the choice of dye to be used would depend on the color contrast desired.     

Staining Methods For Studying Ingredient Distribution In Baked Cakes

A method is described for preparing cake crumb for sectioning and staining. Previous to embedding, the fat was stained and fixed by exposing small blocks of cake to the fumes from a 5%, freshly-prepared, aqueous solution of osmic acid (OsO₄). This was followed by dehydration in ethyl alcohol and tertiary butyl alcohol, removal of air under vacuum and infiltration with paraffin.

Sections were cut 20 and 9Op thick and mounted with water.

Wax was removed by immersion in xylene. The sections were rehydrated in a series of ethyl alcohol dilutions, from concentrated to dilute, then transferred to distilled water.

Protein was then stained pink by immersion of the slides in an acidified 0.04% water solution of eosin Y, or starch was stained blue with a dilute aqueous solution of iodine. Ten grams iodine and 10 g. KI were dissolved in 25 ml. distilled water. This stock solution was diluted for use one to two hundred times.

The relationship between protein and starch was demonstrated by staining the sections with eosin, differentiating in 50% alcohol and staining with iodine.

When slides of cake crumb were prepared in this way, the fat was stained black, the protein bright pink and the starch granules a dark blue.     

The Stainability of Nerve Fibers by Protargol With Various Fixatives And Staining Technics

The influence of the commonly used tissue fixing reagents, individually and in various combinations, on subsequent staining by protargol was studied. The reagents used were formalin, formamide, picric acid, acetic acid, paranitrophenol, pyridine and chloral hydrate. Parraffin sections from intestine and peripheral nerve of cat, dog, monkey and rat were stained with protargol after fixation in various experimental mixtures of the fixing reagents. Satisfactory nerve stains of intestine were not obtained with regularity after any one fixing and staining procedure. (Good fixation and staining appeared to be influenced by properties inherent in the tissue itself and showed marked variations from animal to animal even in the same species.)Stains of nerve fibers in peripheral nerve trunks were much more easily obtained than in the intestine where good stains were sporadic and unpredictable. The use of a mixture of 0.5% protargol and 0.1% fast green FCF, is proposed as a silver-dye staining medium.     

Histochemical staining of chromium with 2-(8-quinolylazo)-4,5-di-p-tolylimidazole

A new highly sensitive staining agent for chromium (Cr) has been introduced. This staining agent, 2-(8-quinolylazo)-4,5-di-p-tolylimidazole (QTI), was found to be more than ten times as sensitive for Cr than the conventional staining agent, Chromazurol S, and QTI also stained cadmium, copper, lead and zinc. Differentiation between the staining of Cr and other metals was achieved by immersing the tissue sections in dilute alkylamine solutions before they were stained with QTI. Thus, it was possible to selectively stain for Cr by blocking other metals.     

Iron gallein elastic method---a substitute for Verhoeff's elastic tissue stain.

A method for staining elastic fibers in formalin fixed, paraffin embedded sections is described. After deparaffinizing and dehydration, sections are stained for 30 minutes in a solution prepared by mixing equal parts of 1% gallein dissolved in ethylene glycol and absolute alcohol (1:4), and 1.16% aqueous ferric chloride in 1% hydrochloric acid. The sections are washed in water and then differentiated in 2% ferric chloride for 2 minutes. After washing in water, the sections are counterstained with a variant of Van Gieson's picric acid-acid fuchsin for 1 minute. The results are similar to Verhoeff's elastic stain with elastic fibers staining black. An advantage to this staining procedure is that visually controlled differentiation is not necessary.     

Iron Gallein Elastic Method—A Substitute for Verhoeff'S Elastic Tissue Stain

A method for staining elastic fibers in formalin fixed, paraffin embedded sections is described. After deparaffinizing and dehydration. sections are stained for 30 minutes in a solution prepared by mixing equal parts of 1% gallein dissolved in ethylene glycol and absolute alcohol (1:4), and 1.16% aqueous ferric chloride in 1% hydrochloric acid. The sections are washed in water and then differentiated in 2% ferric chloride for 2 minutes. After washing in water, the sections am counterstained with a variant of Van Girson's picric acid-acid fuchsin for 1 minute. The results are similar to Verhoeff s elastic stain with elastic fibers staining black. An advantage to this staining procedure is that visually controlled differentiation is not necessary.