A Rapid Stain-Clearing Method for Video Based Cytological Analysis of Cotton Megagametophytes

Optical “clearing” is a cost saving method for preparing large numbers of whole, dissected or thickly sectioned cytological specimens such as plant ovules and ovaries. Minimal labor is required and specimens retain three-dimensional integrity. Previous development of high contrast stain-clearing methods using hemalum to impart contrast has facilitated analysis and photography under brightfield illumination for small ovules. The deep stain intensity of hemalum, however, often precludes adequate light transmission and contrast within internal focal planes, limiting the applicability of hemalum-based stain-clearing to small specimens. Having encountered this problem for nucelli of cotton (Gossypium barbadense L.), which are roughly 300 μm thick at fertilization, we have developed a modified stain-clearing system. The two key features of these new methods are the use of azure, C, which allows the intensity of staining to be readily regulated, and contrast manipulation via video signal and image processing. Intensity of azure C stain was readily controlled by modifying the staining and/or dehydration media to produce relatively low contrast specimens. Analysis was facilitated by indirect viewing on a video monitor using adjustments of sensitivity, exposure, and contrast of the charge-coupled device (CCD) camera. Digital processing provided further enhancement. Acceptable images were obtained from virtually all specimens. These methods, which combine low contrast (high transmittance) specimens with high contrast imaging, should facilitate data acquisition on reproduction, thus the developmental and genetic characterization of reproductive mutants. Other applications, e.g., in pathology and embryology, are readily envisioned.     

Mayer's hemalum-methyl salicylate: a stain-clearing technique for observations within whole ovules

Nondissected ovaries of tuber-bearing Solanum sp. were stained with Mayer's hemalum, a positive stain for chromatin and nucleoli, and then optically cleared with methyl salicylate, a clearing agent. Clarity, resolution and contrast within the ovules dissected from ovaries were comparable to those of sectioned, paraffin embedded ovaries. Contrast within ovules greatly exceeded that of unstained and nonspecifically stained clearings, and eliminated the need of special optics, i.e., Nomarski interference-contrast optics, for optimal viewing and photography. Much less time and labor were required than for embedded specimens. Usefulness of the technique for cytogenetic and cytological research was verified by analyzing meiosis and other features of megasporogenesis and megagametogenesis in normal, and in two meiotic mutants, of Solanum. The results illustrate the usefulness of combined Mayer's hemalum staining and methyl salicylate clearing, and suggest additional stain-clearing agent combinations have potential for cytological and cytogenetic research. Preliminary results with other species suggest the technique may also be useful for classroom instruction.     

Traditional staining for routine diagnostic pathology including the role of tannic acid. 1. Value and limitations of the hematoxylin-eosin stain

The components of the hematoxylin and eosin (H & E) stain (i.e. hemalum and eosin Y), their contributions to the typical staining pattern, and the reasons why the H & E stains are the preferred oversight stains for routine diagnostic histopathology are discussed. The essential diagnostic significance of effective nuclear staining by hemalum, providing information on nuclear morphology and texture, is emphasized; as is the ironic advantage for routine diagnostic histopathology of the limited range of colors provided by H & E staining, that allows recognition of significant features under low microscopic magnifications. Standardization of hemalum is considered, along with probable reasons why users show resistance to such a concept. Counterstaining with anionic (acid) dyes is discussed, as is the important phenomenon of contrast. The particular advantages and disadvantages of eosin Y and phloxin B as counterstains to hemalum are outlined. The concept of an “ideal routine histological stain” is considered, and H & E is compared to such an ideal case. Finally, deficiencies of H & E staining are discussed, and a program to develop an improved oversight stain is introduced.     

The influence of Romanowsky-Giemsa type stains on nuclear and cytoplasmic features of cytological specimens

The aim of the present study was to compare the staining pattern of the standard azure B-eosin Y stain with commercial May-Grünwald-Giemsa (MGG) stains on cytological specimens by means of high resolution image analysis. Several cytological specimens (blood smears, abdominal serous effusions, bronchial scrape material) were air dried, methanol fixed and stained with the standard azure B-eosin Y stain and with commercial May-Grünwald-Giemsa stains. Integrated optical density (IOD) and colour intensities of cell nuclei and cytoplasm were measured with the IBAS 2000 image analyser. Commercial MGG stains gave much higher coefficients of variation for all parameters than the standard stain. Reproducibility of cell nuclei segmentation versus cytoplasm was significantly better for the standard stain. Contamination of the standard stain with methylene blue partly copied the staining pattern of commercial stains. The standard azure B-eosin Y stain is recommended for high resolution image analysis (HRIA) of cytological samples.     

The Oxidation Products of Methylene Blue

The mechanism of the oxidation of methylene blue varies with the conditions. The formation of trimethyl thionin (azure B) and of asymmetrical dimethyl thionolin (azure A) is followed under alkaline conditions by that of dimethyl thionin (methylene violet) and under acid conditions by that of monomethyl thionin (named by authors azure C).

Simple and practical methods are given for the preparation of azure A and azure C. The latter product, which has not been obtained from methylene blue hitherto, has valuable staining properties as a nuclear and bacterial stain in tissue and may also be employed satisfactorily as a substitute for azure A in the MacNeal tetrachrome formula as a blood stain or substitute for the Giemsa stain.

Azure B has no particular merit in staining.

Azure C proves to be a very valuable stain. A procedure is given for its use with eosin Y and orange II as counterstains, by which it is possible to demonstrate bacteria in tissue and at the same time the cytological elements of the tissue.     

Traditional staining for routine diagnostic pathology including the role of tannic acid. 1. Value and limitations of the hematoxylin-eosin stain

The components of the hematoxylin and eosin (H & E) stain (i.e. hemalum and eosin Y), their contributions to the typical staining pattern, and the reasons why the H & E stains are the preferred oversight stains for routine diagnostic histopathology are discussed. The essential diagnostic significance of effective nuclear staining by hemalum, providing information on nuclear morphology and texture, is emphasized; as is the ironic advantage for routine diagnostic histopathology of the limited range of colors provided by H & E staining, that allows recognition of significant features under low microscopic magnifications. Standardization of hemalum is considered, along with probable reasons why users show resistance to such a concept. Counterstaining with anionic (acid) dyes is discussed, as is the important phenomenon of contrast. The particular advantages and disadvantages of eosin Y and phloxin B as counterstains to hemalum are outlined. The concept of an “ideal routine histological stain” is considered, and H & E is compared to such an ideal case. Finally, deficiencies of H & E staining are discussed, and a program to develop an improved oversight stain is introduced.     

Preparation of Large Epoxy Sections for Light Microscopy as an Adjunct to Fine-Structure Studies

Tissue blocks 2 × 2 × 0.4 cm were fixed 6-24 hr in phosphate-buffered 5% glutaraldehyde then sliced to 2 × 2 × 0.1 cm and soaked in 0.1 phosphate-buffer (pH 7.3) for at least 12 hr. Fixation was continued for 2 hr in phosphate-buffered 1-2% OsO₄. The slices were dehydrated, infiltrated with Araldite, and embedded in flat-bottomed plastic molds. Sectioning at 1-8 μ with a sliding microtome was facilitated by addition of 10% dibutylphthalate to the standard epoxy mixture. The sections were spread on warm 1% gelatin and attached to glass slides by drying, baking at 60 C, fixing in 10% formalin or 5% glutaraldehyde and baking again. Sections were mordanted in 5% KMnO₄ (5 min), bleached with 5% oxalic acid (5 min) and neutralized in 1% Li₂CO₃ (1 min). Several stains could then be applied: azure B, toluidine blue, azure B-malachite green, Stirling's gentian violet, MacCallum's stain (modified), tribasic stain (modified) and phosphotungstic acid-hematoxylin. Nuclei, mitochondria, specific granules, elastic tissue or collagen were selectively emphasized by appropriate choice of staining procedures, and cytologic detail in 1-3 μ sections was superior to that shown by conventional methods. Selected areas from adjacent 4-8 μ sections could be re-embedded for ultramicrotomy and electron microscopy.     

Investigation of Thiazin Dyes as Biological Stains I. The Staining Properties of Thionin and its Derivatives as Compared with Their Chemical Formulae

An investigation has been made of the staining properties of eight dyes of the thionin group. The dyes studied are as follows: tetra-ethyl thionin, asymmetrical di-ethyl thionin, tetra-methyl thionin (methylene blue), tri-methyl thionin (azure B), asymmetrical di-methyl thionin (azure A), symmetrical di-methyl thionin, mono-methyl thionin (azure C), and unsubstituted thionin. The staining properties were tested on sections of paraffin embedded material following five different methods of fixation. No counterstain was employed. It was shown that there was a general correlation between the extent of ethylation or methylation of the dyes and their staining properties. As one passes from tetra-ethyl thionin down the series to thionin itself, there is a progressive decrease in the amount of green showing in the preparations, and an increase in the amount of red present, also an increase in the metachromatic effects, and in the intensity of nuclear staining. There seems, also, to be a similar relation between staining qualities on the one hand and the color and solubility of the dye base on the other.     

Investigation of Thiazin Dyes as Biological Stains I. The Staining Properties of Thionin and its Derivatives as Compared with Their Chemical Formulae

An investigation has been made of the staining properties of eight dyes of the thionin group. The dyes studied are as follows: tetra-ethyl thionin, asymmetrical di-ethyl thionin, tetra-methyl thionin (methylene blue), tri-methyl thionin (azure B), asymmetrical di-methyl thionin (azure A), symmetrical di-methyl thionin, mono-methyl thionin (azure C), and unsubstituted thionin. The staining properties were tested on sections of paraffin embedded material following five different methods of fixation. No counterstain was employed. It was shown that there was a general correlation between the extent of ethylation or methylation of the dyes and their staining properties. As one passes from tetra-ethyl thionin down the series to thionin itself, there is a progressive decrease in the amount of green showing in the preparations, and an increase in the amount of red present, also an increase in the metachromatic effects, and in the intensity of nuclear staining. There seems, also, to be a similar relation between staining qualities on the one hand and the color and solubility of the dye base on the other.     

Zinc Chloride Methylene Blue, Ii. Preparation of Giesma and Wright Type Low Azure B Blood Stains from Dichromate Oxidized Commercial Dye

TO determine the amount of K₂Cr₂O₇ required to produce optimal Giemsa type staining, six 1 g amounts (corrected for dye content) of zinc methylene blue were oxidized with graded quantities of K₂Cr₂O₇ to produce 4, 8, 12, 16, 20 and 24% conversion of methylene blue to azure B. These were heated with a blank control 15 minutes at 100 C in 60-65 ml 0.4 N HCI. cooled, and adjusted to 50 ml to give 20 mg original dye/ml. Aliquots were then diluted to 1% and stains were made by the “Wet Giemsa” technic (Lillie and Donaldson 1979) using 6 ml 1% polychrome methylene blue, 4 ml 1% cosin (corrected for dye content), 2 ml 0.1 M pH 6.3 phosphate buffer, 5 ml acetone, and 23 ml distilled water. The main is added last and methanol fixed blood films are stained immediately for 20-40 min.

For methylene blue supplied by MCB 12-H-29, optimal stains were obtained with preparations containing 20 and 24% conversion of methylene blue to azure B. With methylene blue supplied by Aldrich (080787), 16% conversion of methylene blue to azure B was optimal. Eosinates prepared from a low azure B/methylene blue preparation selected in this way give good stains when used as a Wright stain in 0.3% methanol solution. However, when the 600 mg eosinate solution in glycerol methanol is supplemented with 160 mg of the same azure B/methylene blue chloride the mixture fails to perform well. The HCI precipitation of the chloride apparently produces the zinc methylene blue chloride salt which is poorly soluble in alcohol. It appears necessary to have a zinc-free azure B/methylene blue chloride to supplement the probably zinc-free eosinate used in the Giemsa mixture.     

Differentiated Staining of Osmium Tetroxide-Fixed, Vestopal-w-Embedded Tissue in thin Sections

Tissues were fixed at 20° C for 1 hr in 1% OsO₄, buffered at pH 7.4 with veronal-acetate (Palade's fixative), soaked 5 min in the same buffer without OsO₄, then dehydrated in buffer-acetone mixtures of 30, 50, 75 and 90% acetone content, and finally in anhydrous acetone. Infiltration was accomplished through Vestopal-W-acetone mixtures of 1:3, 1:1, 3:1 to undiluted Vestopal. After polymerisation at 60° C for 24 hr, 1-2 μ sections were cut, dried on slides without adhesive, and stained by any of the following methods. (1) Mayer's acid hemalum: Flood the slides with the staining solution and allow to stand at 20°C for 2-3 hr while the water of the solution evaporates; wash in distilled water, 2 min; differentiate in 1% HCl; rinse 1-2 sec in 10% NH,OH. (2) Iron-trioxyhematein (of Hansen): Apply the staining solution as in method 1; wash 3-5 min in 5% acetic acid; restain for 1-12 hr by flooding with a mixture consisting of staining solution, 2 parts, and 1 part of a 1:1 mixture of 2% acetic acid and 2% H₂SO₄ (observe under microscope for staining intensity); wash 2 min in distilled water and 1 hr in tap water. (3) Iron-hematoxylin (Heidenhain): Mordant 6 hr in 2.5% iron-alum solution; wash 1 min in distilled water; stain in 1% or 0.5% ripened hematoxylin for 3-12 br; differentiate 8 min in 2.5%, and 15 min in 1% iron-alum solution; wash 1 hr in tap water. (4) Aceto-carmine (Schneider): Stain 12-24 hr; wash 0.5-1.0 min in distilled water. (5) Picrofuchsin: Stain 24-48 hr in 1% acid fuchsin dissolved in saturated aqueous picric acid; differentiate for only 1-2 sec in 96% ethanol. (6) Modified Giemsa: Mix 640 ml of a solution of 9.08 gm KH₂PO₄ in 1000 ml of distilled water and 360 ml of a solution of 11.88 gm Na₂HPO₄-2H₂O in 1000 ml of distilled water. Soak sections in this buffer, 12 hr. Dissolve 1.0 gm of azur I in 125 ml of boiling distilled water; add 0.5 gm of methylene blue; filter and add hot distilled water until a volume of 250 ml is reached (solution “AM”). Dissolve 1.5 gm of eosin, yellowish, in 250 ml of hot distilled water; filter (solution “E”). Mix 1.5 ml of “AM” in 100 ml of buffer with 3 ml of “E” in 100 ml of buffer. Stain 12-24 hr. Differentiate 3 sec in 25 ml methyl benzoate in 75 ml dioxane; 3 sec in 35 ml methyl benzoate in 65 ml acetone; 3 sec in 30 ml acetone in 70 ml methyl benzoate; and 3 sec in 5 ml acetone in 95 ml methyl benzoate. Dehydrated sections may be covered in a neutral synthetic resin (Caedax was used).     

An Easily Controlled Regressive Trichromic Staining Method

Three modifications of Mallory's connective tissue stain are described and some features of the action of picric acid are discussed.

In the first and most critical method the nuclei are stained in an iron hematoxylin and then differentiated in a picric acid solution containing orange G. This not only differentiates the nuclei, but stains all other elements yellow. The section is then washed in running water to remove the yellow color from all tissues except those which are to remain yellow in the final preparation (usually the erythrocytes). The section is next stained in an acid fuchsin mixture and then differentiated until the desired depth and contrast is obtained. Staining in anilin blue follows and this in turn is differentiated to suit. The section is then dehydrated and mounted.

In the second method the nuclei are stained in hemalum (e.g. Harris's) for a short time; the section is then rinsed and immersed in a mixture of picric acid and acid fuchsin and thereafter is differentiated; it is next passed into anilin blue w. s. and then differentiated and mounted as before. This is less critical than method I, but can be applied to large batches of slides at a time.

The third method is a one-solution method. After staining the nuclei in hemalum, the section is immersed in the “Picro-Mallory” solution, differentiated briefly, dehydrated and mounted. This modification, while being the least critical, is most suitable for routine use when the tissues have been fixed in a fluid containing chromate; the other commonly used fixatives, while giving useful results, are not so good.     

Does progressive nuclear staining with hemalum (alum hematoxylin) involve DNA,and what is the nature of the dye-chromatin complex?

Previous investigators have disagreed about whether hemalum stains DNA or its associated nucleoproteins. I review here the literature and describe new experiments in an attempt to resolve the controversy. Hemalum solutions, which contain aluminum ions and hematein, are routinely used to stain nuclei. A solution containing 16 Al³⁺ ions for each hematein molecule, at pH 2.0–2.5, provides selective progressive staining of chromatin without cytoplasmic or extracellular “background color.” Such solutions contain a red cationic dye-metal complex and an excess of Al³⁺ ions. The red complex is converted to an insoluble blue compound, assumed to be polymeric, but of undetermined composition, when stained sections are blued in water at pH 5.5–8.5. Staining experiments with DNA, histone and DNA + histone mixtures support the theory that DNA, not histone, is progressively colored by hemalum. Extraction of nucleic acids, by either a strong acid or nucleases at near neutral pH, prevented chromatin staining by a simple cationic dye, thionine, pH 4, and by hemalum, with pH adjustments in the range, 2.0–3.5. Staining by hemalum at pH 2.0–3.5 was not inhibited by methylation, which completely prevented staining by thionine at pH 4. Staining by hemalum and other dye-metal complexes at pH ≤ 2 may be due to the high acidity of DNA-phosphodiester (pK_a ~ 1). This argument does not explain the requirement for a much higher pH to stain DNA with those dyes and fluorochromes not used as dye-metal complexes. Sequential treatment of sections with Al₂(SO₄)₃ followed by hematein provides nuclear staining that is weaker than that attainable with hemalum. Stronger staining is seen if the pH is raised to 3.0–3.5, but there is also coloration of cytoplasm and other materials. These observations do not support the theory that Al³⁺ forms bridges between chromatin and hematein. When staining with hematein is followed by an Al₂(SO₄)₃ solution, there is no significant staining. Taken together, the results of my study indicate that the red hemalum cation is electrostatically attracted to the phosphate anion of DNA. The bulky complex cation is too large to intercalate between base pairs of DNA and is unlikely to fit into the minor groove. The short range van der Waals forces that bind planar dye cations to DNA probably do not contribute to the stability of progressive hemalum staining. The red cation is precipitated in situ as a blue compound, insoluble in water, ethanol and water-ethanol mixtures, when a stained preparation is blued at pH > 5.5.     

Standard specimens for stain calibration: application to Romanowsky-Giemsa staining.

Standardized specimens with reproducible staining properties were fabricated from extracts of biological objects (bovine liver, nucleoprotamine and defatted muscle). The standard specimens were stained with two formulations of the Romanowsky-Giemsa stain (RG), using the same azure B and eosin Y. One formulation used methanol and Sorensen's buffer and the other DMSO and Hepes buffer as solvents. The standard specimens were stained either in the composite stain or in the individual dyes dissolved in the same solvents and at the same concentration as the composite stain. Solution spectroscopy demonstrated different spectra for the two formulations with some wavelength regions varying by more than an order of magnitude. The RG spectra were also very different from those of the individual dyes dissolved at the RG concentration in the respective solvents. The stained standard specimens were analyzed by microspectrophotometry and were found to have spectra similar to those of cell smears. Furthermore, the standard specimens were shown to be a repeatable substrate for stain uptake. The transmitted light intensity from random fields of the same standardized specimen varied +/- 5%. When specimens were stained at the same time, the specimen-to-specimen variation depended on preparation conditions and the measurement wavelength, but was as good as +/- 5% for some conditions. The quantitative stain performance of both formulations was studied and compared. The standardized specimens provide a tool for the quantitative study of staining processes and specimen preparation procedures and for stain calibration.     

Standard Specimens for Stain Calibration: Application to Romanowsky-Giemsa Staining

Standardized specimens with reprodcible staining properties were fabricated from extracts of biological objects (bovine liver, nucleoprotamine and defatted muscle). The standard specimens were stained with two formulations of the Romanowsky-Giemsa stain (RG), using the same azure B and eosin Y. One formulation used methanol and Sorensen's buffer and the other DMSO and Hepes buffer as solvents. The standard specimens were stained either in the composite stain or in the individual dyes dissolved in the same solvents and at the same concentration as the composite stain. Solution spectroscopy demonstrated different spectra for the two formulations with some wavelength regions varying by more than an order of magnitude. The RG spectra were also very different from those of the individual dyes dissolved at the RG concentration in the respective solvents. The stained standard specimens were analyzed by microspectrophotometry and were found to have spectra similar to those of cell smears. Furthermore, the standard specimens were shown to be a repeatable substrate for stain uptake. The transmitted light intensity from random fields of the same standardized specimen varied ±5%. When specimens were stained at the same time, the specimen-to-specimen variation depended on preparation conditions and the measurement wavelength, but was as good as ±5% for some conditions. The quantitative stain performance of both formulations was studied and compared. The standardized specimens provide a tool for the quantitative study of staining processes and specimen preparation procedures and for stain calibration.     

A Rapid Silver-Free Method for Staining the Myenteric Plexus

A method is presented for the relatively rapid demonstration of the myenteric plexus. Saturated Sudan black B in 70% ethanol followed by 0.01% aqueous buffered thionin were used on intestinal peels (whole-mounts) to stain myelinated and unmyelinated fibers and neuron cell bodies, respectively. In contrast to accepted silver methods, these two kinds of fibers were distinguished clearly; Schwann cell nuclei and nodes of Ranvier were visible. Preparations had the following attributes: relatively low optical density coupled with high visual contrast, freedom from metallic “mirroring,” low background staining of subjacent muscle fibers, and presentation of a polychromatic picture. The entire procedure was under the complete and repeatable control of the operator. Perikaryon and nuclear morphology were clearly demonstrated. The limitations of this method are that it does not provide good visualization of individual unmyelinated neuronal processes and does not permit preparation of permanent slides.     

Flat, Adherent, Well-Contrasted Semithin Plastic Sections for Light Microscopy

Semithin (0.5-2.0 μm) sections of plastic embedded specimens have long been used for identifying and orienting structures destined for electron microscopic observation. Improved staining methods and the development of more versatile plastics have increased the use of semithin plastic sections for histochemical and autoradiographic studies. The principal advantage of plastic over paraffin sections is the possibility of increased resolution. This advantage is often compromised, however, by problems arising during processing and staining. Wrinkles are common in sections containing tissues of different consistencies or when the hardness of the tissue does not match that of the surrounding plastic (Millonig 1980). Unfortunately, many of the methods designed to eliminate wrinkles (e.g., Alsop 1974, Sommer et al. 1979) require prolonged staining or repeated handling of the sections. Section adhesion problems usually arise during staining, particularly if the protocol requires alkaline or oxidizing reagents. Adhesives such as Mayer's albumen or chrome alum-gelatin (Hayat 1981) work well but may contribute to undesirable background staining or trapping of debris. A more complicated problem, inadequate stain contrast for photomicrography, usually can be traced to inability of the stain to penetrate the plastic, staining of the plastic, or nonspecific staining of the tissue. Alkaline staining solutions and chemicals which etch plastic can increase penetration, but may also cause section loss or staining of the plastic. The following is a simple method to eliminate these processing problems. It exploits the solvent properties and low surface tension of glycerol to aid in softening, flattening, and adhering semithin plastic sections to microscope slides.     

Staining Procedures for Ultrathin Sections of Tissues Embedded in Polyester Resin

Tissues were fixed for 30 min In cold (0-2° C) 1% OsO₄ (Palade) buffered at pH 7.7, to which 0.1% MgCl₂ was added. Dehydration was in a graded ethanol series (containing 0.5% MgCl₂) at 0-2° C, and terminated with 2 changes of absolute ethanol. Tissues were then transferred by a graded series to anhydrous acetone. Infiltration of the tissue with Vestopal-W (a polyester resin), is gradual with the aid of graded solutions of Vestopal-W in acetone. The infiltrated tissue is encapsulated and initial polymerization is done under ultraviolet light at room temperature for 8-16 hr. This is followed by final hardening at 60° C for 36-48 hr. Sections (0.2-1 μ) were cut, dried on slides, placed in acetone for 1 min and then treated by either of the following staining procedures: (1) Thionin-azure-fuchsin staining: Flood the preparation with 0.2% aqueous thionin and heat to 60-80° C for 3 min; if the preparation begins to dry, add stain. Rinse in distilled water. Flood the slide with 0.2% azure B in phosphate buffer at pH 9. Heat to 60-80° C for 3 min; do not permit the preparation to dry. Rinse in distilled water. Dip the slide in MacCallum's variant of Goodpasture's carbol-fuchsin stain for 1-2 sec. Rinse in distilled water. Check the preparation microscopically for intensity of the fuchsin stain. Repeat dips as may be needed to obtain the desired intensity. Rinse in distilled water. Dehydrate quickly in 95% and absolute alcohol; clear in 2 changes of xylene and cover in Permount or similar synthetic resin. (2) Thionin-azure counterstain for the periodic acid-Schiff reaction: Oxidize the tissue in 0.5% periodic acid for 15 min and transfer to Schiff's leucofuchsin solution for 30 min. Counterstain with 0.5% aqueous thionin for 3 min; wash in distilled water; stain in 0.2% azure B in phosphate buffer at pH 5.5; wash in distilled water; dehydrate; clear and cover as in the first method. For temporary preparations let dry after absolute alcohol and apply a drop of immersion oil directly on the section.     

Embedding Plant Tissue with Plastic Using High Pressure: A New Method for Light and Electron Microscopy

An embedding technique has been developed to overcome difficulties that confront light and electron microscopists working with so-called “hard-to-embed” plant tissue. The method was originally described for freeze-dried material. It uses a modified Quickfit Rotaflo Valve and low heat to generate high pressure to aid in the infiltration and embedding of tissue with propylene oxide and plastic. The technique is not too cumbersome and requires 6 days from the dehydration step to the end of the polymerization process. Thick sections (1-2 μm) obtained from material prepared by this method stain readily with toluidine blue, and thin sections for the electron microscope stain satisfactorily following standard treatment with uranyl acetate and lead citrate. The thin sections are stable under the beam of the electron microscope. Results indicate that the quality of tissue preservation with this high pressure embedding technique is as good as that observed using standard embedding methods for electron microscopy.     

Acetyl Sudan Black: A Nonexistent Reagent?

Acetyl Sudan black (AcSB) has been recommended as a readily prepared reagent which “appears to give less background staining and just as intense lipid staining as the untreated dye,” i.e. as nonacetylated Sudan black B (Lillie and Fullmer 1976).