Haematoxylin-Phloxine-Alcian Blue-Orange G Differential Staining of Prekeratin, Keratin and Mucin

This is a modification of Kreyberg's stain with Alcian blue 8GS used to stain acid much while phloxine B and orange G stain keratin and prekeratin. Procedure: Dewax formalin-fixed paraffin sections in xylene and hydrate through alcohol. Stain in Mayer's haemalum, 10 min; blue in tap water; wash in distilled water; stain in 1% phloxine, 3 min; wash in running water, 1 min; wash in distilled water; stain in 0.5% aqueous Alcian blue in 0.5 acetic acid, 5 min; wash in distilled water; stain in 0.5% orange G dissolved in 2.0% phosphotungstic acid, 13 min; dehydrate quickly in 2 changes of 95% alcohol and 2 changes of absolute alcohol; clear in several changes of xylene; mount in a synthetic resin. Acid mucopolysaccharides are stained turquois blue; prekeratin and keratin are orange to red orange.     

Lacto-Phenol Preparations

More or less permanent mounts of fungi, algae, root tips, epidermis, germinating spores, and other small objects may be made readily by transferring the material to Amann's lacto-phenol containing anilin blue, W. S. or acid fuchsin, used singly or mixed. The addition of 20 to 25% of glacial acetic acid to these mixtures is frequently advantageous; or material may be stained with various dyes—acid fuchsin, anilin blue, W. S. (cotton blue), rose bengal, phloxine, hematoxylin—in aqueous solutions containing 5% of phenol, and then mounted in lacto-phenol, 50% glycerin or phenolglycerin, depending on the dye used. The phenol solutions of acid fuchsin and anilin blue are acidified with acetic acid and those of rose bengal and phloxine are made slightly alkaline with ammonium hydroxide. The addition of ferric chloride to acid fuchsin or acidified hematoxylin may improve staining. Fixation may be preferable but may be omitted, especially with fungi. Formulae for the mounting media and ten staining mixtures are given.     

Differentiation of bone and soft tissues in formalin-fixed, paraffin-embedded tissue by using methylene blue/acid fuchsin stain

OBJECTIVE: To find a staining method for formalin-fixed, paraffin-embedded tissue that would distinguish bone from surrounding soft tissues, including muscle, periosteal tissue and bone marrow. STUDY DESIGN: A variety of stains were tested and compared with hematoxylin-eosin. The potential value of any given stain was evaluated based on its ability to stain bone and soft tissues different colors or shades that could be readily identified in photomicrographs. Stains were evaluated using both endochondral (tibia) and intramembranous bone (calvaria) samples. RESULTS: In contrast to standard hematoxylin-eosin stain, which stains both bone and soft tissues pink, the methylene blue/acid fuchsin stain demonstrates remarkable contrast between bone and other tissues. Methylene blue/acid fuchsin stained bone bright pink and the surrounding soft tissues blue-purple. CONCLUSION: In addition to the superior staining properties of methylene blue/acid fuchsin, other benefits of this stain include its stability, ease of use and low cost. This stain has many potential applications in the study of erosive bone disease in humans and also in animal models for research.     

Stains for the Primary Wall of the Cotton Fiber

Several methods are described for distinguishing between the primary wall of the cotton fiber and other fiber components, such as the lumen and the secondary wall. The primary wall, a membrane less than 0.5 μ thick covering the entire fiber, has been stained while still attached to the fiber as well as after it has been mechanically stripped from the fiber. The stains include aqueous or alcoholic solutions of ruthenium red, methylene blue chloride, Nile blue sulfate, oil red, Sudan black B, iodine, and Simons' stain. Various concentrations of sodium hydroxide, cupri-ethylenediamine hydroxide, or sulfuric acid have been used to enhance color changes and to cause cellulosic swelling. Fibers that have been stained with Simons' stain and then swelled with dilute cupri-ethylenediamine hydroxide have shown the greatest color differences between the primary wall and the lumen.     

Displacement.

Displacement is a noncommital term for the reactions that occur when slides previously stained in phloxine or rose Bengal are immersed for varying lengths of time in a solution of another dye in ethyl Cellosolve. In most histotechnic texts Lendrum's (1947) phloxine-tartrazine is given as the stain for acidophilic inclusion bodies. However the lack between the phloxine and tartrazine has been a serious limitation. A number of dyes were tried as possible substitutes for the tartrazine. A rose Bengal-Bismark brown Y procedure was developed which stains similarly to Lendrum's phloxine-tartrazine and which does have the needed contrast. After staining for 10 min in 1% aqueous rose Bengal and rinsing in isopropyl alcohol slides are placed for 20, 30, 40 and 50 min in 0.05% Bismark brown Y in ethyl Cellosolve. In various tissues and structures the rose Bengal is sequentially displaced by the Bismark brown Y. Thus collagen loses the red stain after 30 min while acedophilic structures like sperm heads and Paneth cell granules retain the red stain after 50 min in the displacement solution. The results are strikingly similar to staining with alkaline Biebrich scarlet.     

Distribution of Pratylenchus scribneri between Root and Soil Habitats

The abundance of Pratylenchus scribneri in soil and root habitats was compared in potato and corn plots during 1986-88. Nematodes were extracted from 100-cm³ soil samples and the roots contained within the samples. The percentage of the population recovered from soil, similar among years and crops, averaged ca. 50% at the beginning and end of the growing season and ca. 20% from early to late season. Proportionately more adults and fourth-stage juveniles than younger stages were located outside roots until harvest. In a related study, nematodes were isolated from the roots, root surfaces, and soil associated with roots of whole corn and potato plants sampled from the field. Nematode population estimates calculated from the whole plant samples were generally lower than those based on soil cores, but showed similar patterns of population growth. Nematode density per gram dry weight was highest in roots, intermediate on root surfaces, and lowest in soil. Estimates of the absolute abundance of nematodes in each of the three habitats were highest in roots or soil, depending on the sampling date, and lowest on root surfaces. This study demonstrates that P. scribneri inhabits soil environments even when host roots are present and illustrates the importance of considering all possible habitats when estimating the size of Pratylenchus spp. populations.     

Displacement

Displacement is a noncommital term for the reactions that occur when slides previously stained in phloxine or rose Bengal are immersed for varying lengths of time in a solution of another dye in ethyl Cellosolve. In most histotechnic tests Lendrum's (1947) phloxine-tartrazine is given as the stain for acidophilic inclusion bodies. However the lack of contrast between the phloxine and tartrazine has been a serious limitation. A number of dyes were tried as possible substitutes for the tartrazine. A rose Bengal-Bismark brown Y procedure was developed which stains similarly to Lendrum's phloxine-tartrazine and which doer have the needed contrast. After staining for 10 min in 1% aqueous rose Bengal and rinsing in isopropyl alcohol slides are placed for 20, 30, 40 and 50 min in 0.05% Bismark brown Y in ethyl Cellosolve. In various tissues and structures the rose Bengal is sequentially displaced by the Bismark brown Y. Thus collagen loses the red stain after 30 min while acidophilic structures like sperm heads and Paneth cell granules retain the red stain after 50 min in the displacement solution. The results are strikingly similar to staining with alkaline Biebrich scarlet.     

Penetration of Crotalaria juncea,Dolichos lablab,and Sesamum indicum Roots by Meloidogyne javanica

Penetration of Crotalaria juncea (PI 207657 and cv. Tropic Sun) Dolichos lablab cv. Highworth, and Sesamum indicum by juveniles (J2) of Meloidogyne javanica was assessed to investigate the mechanism by which these plants may reduce nematode numbers in the field. Growth chamber experiments were conducted at 25 C, with vials containing 90 g sand infested with 450 J2; tomato (UC 204 C) was included as a susceptible host. Fifteen days after inoculation, roots were stained and the nematodes within stained roots were counted. Both C. juncea lines were highly resistant to penetration, as they contained significantly fewer nematodes per cm of root and per root system than the other plants. Although containing more nematodes per cm of root than C. juncea, S. indicum and D. lablab had significantly fewer nematodes per root system and per cm of root than tomato. Roots were significantly longer in the plants with the lowest nematode penetration. Although C. juncea, D. lablab, and S. indicum may have potential utility as cover or rotation crops in soil infested with M. javanica, further quantitative information on the reproduction of M. javanica and other nematodes in these plants is needed.     

Staining Mast Cells for Morphometric Evaluation on an Image Analysis System

Multiple skin sections from three nonhuman primates (Macaca mulatta) and three hairless guinea pigs (Cavia porcellus) were stained with 12 different histologic stains to determine whether mast cells could be selectively stained for morphometric analysis using an image analysis system (IAS). Sections were first evaluated with routine light microscopy for mast cell granule staining and the intensity of background staining. Methylene blue-basic fuchsin and Unna's method for mast cells (polychrome methylene blue with differentiation in glycerin-ether) stained mast cell granules more intensely than background in both species. Toluidine blue-stained sections in the guinea pig yielded similar results. Staining of the nuclei of dermal connective tissue was enhanced with the methylene blue-basic fuchsin and toluidine blue stains. These two stains, along with the Unna's stain, were further evaluated on an IAS with and without various interference filters (400.5-700.5 nm wavelengths). In both the methylene blue-basic fuchsin and toluidine blue stained sections, mast cell granules and other cell nuclei were detected together by the IAS. The use of interference filters with these two stains did not distinguish mast cell granules from stained nuclei. Unna's stain was the best of the 12 stains evaluated because mast cell granule staining was strong and background staining was faint. This contrast was further enhanced by interference filters (500.5-539.5 nm) and allowed morphometric measurements of mast cells to be taken on the IAS without background interference.     

Stains for A, B, and D cells in fetal rat islets.

Ten techniques often used for identification of A, B, and D cells in adult islets of Langerhans were applied to fetal rat pancreas. Modifications were tried with many of these techniques. Two indole methods (xanthydrol and postocoupled benxylidene reactions) and a cryostat technique using o-phthaladehyde failed to stain fetal islets. Phosphotungstic acid hematoxylin and lead hematoxylin lightly stained fetal A cell granules in Helly's fixed tissue. The Grimelius silver nitrate technique stains adult rat A cells but failed to stain fetal cells. A modification of this technique stained fetal A cells and a possible 4th cell type. The specificity of this method was confirmed by restaining stained cells with a fluorescent antibody technique and with pseudoisocyanin. B cells, as previously reported, were readily stained by the aldehyde fuchsin technique. Fetal D cells were not stained by the Hellerstrom-Hellman alcoholic silver nitrate method, nor did they display pseudoisocyanin metachromasia after acid hydrolysis; they did fluoresce brightly with this technique when viewed with UV light. It was thus possible to distinguish the three usual cell types, plus a possible fourth type, in the fetal rat pancreas.     

Histopathology of Soybean Roots Infected with Heliocotylenchus dihystera

Soybean roots infected with Helicotylenchus dihystera in a greenhouse were stained with acid fuchsin in lactophenol or sectioned and stained with safranin and fast green. Adults and larvae were observed in semi-endoparasitic and endoparasitic feeding positions. Adults, larvae and eggs were observed within the root cortex posterior to the region of maturation. Small brown lesions, affecting the walls of six to ten cells, were observed in the immediate vicinity of the nematode. Endoparasitic nematodes were usually coiled within the walls of one or two cells. Cytoplasm of the infected cells appeared normal, and there was no indication of nuclear proliferation. Walls of the infected cells were thickened and llgnified, but there was no indication of swelling or giant cell formation. Uncoiled nematodes usually were aligned parallel to the vascular tissue, but were not consistently oriented with respect to the root apex. Nematodes moved through cell walls rather than between them; however, no persistent burrows were observed.     

A Versatile Stain for Pollen Fungi, Yeast and Bacteria

A versatile stain has been developed for demonstrating pollen, fungal hyphae and spores, bacteria and yeasts. The mixture is made by compounding in the following order: ethanol, 20 ml; 1% malachite green in 95% ethanol, 2 ml; distilled water, 50 ml; glycerol, 40 ml; acid fuchsin 1% in distilled water, 10 ml; phenol, 5 g and lactic acid, 1-6 ml. A solution has also been formulated to destain overstained pollen mounts. Ideally, aborted pollen grains are stained green and nonaborted ones crimson red. Fungal hyphae and spores take a bluish purple color and host tissues green. Fungi, bacteria and yeasts are stained purple to red. The concentration of lactic acid in the stain mixture plays an important role in the differential staining of pollen. For staining fungi, bacteria and yeasts, the stain has to be acidic, but its concentration is not critical except for bacteria. In the case of pollen, staining can be done in a drop of stain on a slide or in a few drops of stain in a vial. Pollen stained in the vial can be used immediately or stored for later use. Staining is hastened by lightly flaming the slides or by storing at 55±2 C for 24 hr. Bacteria and yeasts are fixed on the slide in the usual manner and then stained. The stock solution is durable, the staining mixture is very stable and the color of the mounted specimens does not fade on prolonged storage. Slides are semipermanent and it is not necessary to ring the coverslip provided 1-2 drops of stain are added if air bubbles appear below the coverslip. The use of differentially stained pollen mounts in image analyzers for automatic counting and recording of aborted and nonaborted pollen is also discussed.     

Aldehyde fuchsin staining, direct or after oxidation: problems and remedies, with special reference to human pancreatic B cells, pituitaries, and elastic fibers.

Successful production of aldehyde fuchsin (AF) having the unique properties described by Gomori depends on each of many critical variables. AF made from basic fuchsins which contain mainly rosanilin (C.I. 42510) do not stain properly-fixed pancreatic B cells, pituitary basophils, or elastic fibers in unoxidized sections. AF made from basic fuchsins containing mainly pararosanilin (C.I. 42500) stains these entities strongly. Substances stained by AF without oxidation fall into two classes: 1) nonacidic peptides and proteins, most of which contain half-cystines, and 2) polyanions, particularly when sulfated. Group 2 substances stain rapidly, Group 1 substances stain slowly. Many modifications of aldehyde fuchsin have been described. Modified aldehyde fuchsins (MAFs) differ in the kind of aldehyde and in the amount of aldehyde and hydrochloric acid used in their formulation; they differ also in the temperature and duration of the ripening necessary before they can be used. If microsections are first oxidized by acid permanganate or other oxidant, MAF staining of pancreatic B cells, pituitary basophils and other substances containing cystines is speeded and intensified. Most modified methods prescribe oxidation, but the author's does not. The chemical basis, final result and potential side-reactions of oxidation methods (OXMAF) differ from those of direct methods (DIMAF) such as the author's. DIMAF staining is slower but inherently simpler and less destructive. The time required for optimal staining with DIMAF depends on the potency of the stain, which in turn depends on how the stain was made and its age. Detection of DIMAF--reactive peptides and proteins may be hampered by the strong staining of polyanions. This can be remedied if the polyanions are first stained with Alcian blue (AB) or other durable basic dye of contrasting color resistant to acid ethanol. Experiences with the AB-DIMAF staining of pancreatic B cells, pituitaries and elastic fibers in formalin-fixed human tissues are detailed. Proper control of the variables which affect MAF will insure useful and reliable results either directly or after oxidation. Authors and editors are urged to be more careful hereafter to distinguish the results of DIMAF from those of OXMAF methods. Published reports should always specify the parameters that affect the properties of MAF. In OXMAF methods the steps intervening between oxidation and staining should be spelled out. Such care should help dispel the confusion and uncertainty which cloud the use and reputation of aldehyde fuchsin at present. This unique dye deserves wider and wiser use.     

Histopathology of Pea Roots Axenically Infected by Pratylenchus penetrans

The histological changes in pea roots axenically infected by Pratylenchus penetrans were studied and described. Roots of pea seedlings growing aseptically on the surface of nutrient agar slants were inoculated with axenized nematodes. Six hours after inoculation most of the nematodes introduced were probing the root epidermis, but none had completely entered though a few were observed with their anterior section already in the root. Most of the nematodes penetrated the roots after 12 hr inoculation. From 18 to 24 hr after inoculation the nematodes were mostly in the mid-cortex. Invaded regions of the cortex often showed orange discoloration. As incubation continued, the number of nematodes in these roots increased, and feeding and reproductive activities extended deeper into the cortex. These activities resulted in extensive breakdown of the cortex. No nematodes were observed within the stele of infected roots; however, the endodermis of infected roots stained dark-brown. Gravid female nematodes probed the root endodermis and some endodermal cells appeared to collapse after prolonged probing by the nematode. All stages in the life cycle of the nematode were observed in infected roots; the female to male ratio inside the root was about 5:1.     

Only aldehyde fuchsin made from pararosanilin stains pancreatic B cell granules and elastic fibers in unoxidized microsections: problems caused by mislabelling of certain basic fuchsins

The most distinctive property of aldehyde fuchsin is its staining of certain nonionic proteins and peptides in unoxidized cells and tissues. These substances include granules of pancreatic islet B cells, elastic fibers and hepatitis B surface antigen. Aldehyde fuchsin made from two different basic fuchsins, each certified by the Biological Stain Commission and labelled C.I. (Colour Index) No. 42500 (pararosanilin), did not stain pancreatic B cells at all. Stain Commission's records and retesting showed that each of the "faulty" basic fuchsins was not pararosanilin, but rosanilin, whose Colour Index number is 42510. These basic fuchsins were labelled with the wrong Colour Index number when packaged. Additional basic fuchsins were coded by V.M.E. and tested by R.W.M. for their capacity to make satisfactory aldehyde fuchsins. Only certain of these aldehyde fuchsins stained unoxidized pancreatic islet B cells. The same aldehyde fuchsins stained elastic fibers strongly. Each basic fuchsin whose aldehyde fuchsin was judged satisfactory proved to be pararosanilin. Aldehyde fuchsin solutions made from other basic fuchsins stained elastic fibers only weakly and did not stain pancreatic B cells at all in unoxidized sections. Each basic fuchsin whose aldehyde fuchsin was unsatisfactory proved to be rosanilin. It appears that only aldehyde fuchsin made from pararosanilin stains unoxidized pancreatic B cell granules dependably. We found that basic fuchsins from additional lots of Commission-certified pararosanilin and rosanilin were also labelled with incorrect Colour Index numbers when packaged. Steps were taken to prevent recurrences of such mislabelling which has made it difficult until now to correlate differences in the properties of pararosanilin and rosanilin. A table is provided of all basic fuchsins that have been certified by the Biological Stain Commission since 1963 when they began the practice of subdesignating basic fuchsins according to whether they are pararosanilins or nonpararosanilins. The consumer can readily determine from the certification number on the label the correct subdesignation of any Commission-certified basic fuchsin listed here. Until now, mislabelling of some lots of pararosanilin as rosanilin and vice-versa has confused and frustrated the users of basic fuchsins in other applications such as the carbol fuchsin staining of tubercle bacilli and certain cytochemical tests, e.g. esterase and acid phosphatase, that utilize hexazotized pararosanilin as a coupling reagent. Consumers experiencing trouble with any Commission-certified dye should look to the Biological Stain Commission for help. This is an important reason for purchasing, whenever possible, only Biological Stain Commission certified dyes.     

The role of paraldehyde in the rapid preparation of aldehyde fuchsin

Preparation of aldehyde fuchsin normally requires ripening for 3 to 5 days. By using a 5-fold excess of paraldehyde a fully potent aldehyde fuchsin can be prepared in 24 hr at room temperature. Aldehyde fuchsin prepared by both normal and accelerated ripening afforded comparable results, including selective staining of unoxidized pancreatic B cells. Dried aldehyde fuchsin prepared form pararosaniline and reconstituted in acid alcohol has spectrophotometric properties different form the ripened strain. Reconstituted aldehyde fuchsin stains unoxidized B cells adequately only if staining time is extended. Excess paraldehyde added to reconstituted aldehyde fuchsin retards decomposition but does not produce a normal stain by spectrophotometric standards. Warming of aldehyde fuchsin solutions to accelerate ripening has been shown to produce deleterious effects and should be avoided.     

Microwave-assisted technology for the clearing and staining of arbuscular mycorrhizal fungi in roots

The use of microwave irradiation as a source of energy to clear and stain intra-radical arbuscular mycorrhizal fungi propagules has been tested on a variety of indigenous and cultivated herbaceous plants. The aim of the study was to evaluate the efficiency of microwave irradiation on root softening, fungi tissue staining, and preservation of DNA integrity for subsequent molecular analyses. The proposed methodology has been adapted from the standard procedures used to detect and quantify mycorrhizal root colonization levels. Using a domestic microwave oven, tissue clearing and staining required together between 30 s and 1.5 min of microwave treatment to be completed, depending the diameter size of the roots. The well-performing chemical stains tested were acid fuchsin, trypan blue, and aniline blue. The acid fuchsin clearing and staining processes, as performed, were also demonstrated to preserve DNA integrity for further molecular analyses. Irradiation by microwaves has been used with success in our laboratory within the frame of several studies. It offers considerable time saving over traditional method, reducing processing times from several hours to a few minutes while decreasing considerably the amount of chemicals and energy required to perform analyses.     

Quantitative Determination of Murine Dermal Elastic Fibers by Color Image Analysis: Comparison of Three Staining Methods

We compared three different staining methods to determine if the dermal elastic fiber content of the HRS/Skh-1 hairless mouse could be accurately measured by color image analysis. Comparisons were made among Klig-man's modification of Luna's mast cell stain for elastin, Unna's orcein stain with or without potassium permanganate preoxidation, and Gomori's aldehyde fuchsin stain with potassium permanganate preoxidation. The color image analysis system could be used to identify and quantify murine dermal elastin fibers in sections stained by all three methods. Gomori's aldehyde fuchsin stain with preoxidation demonstrated twice the content of dermal elastic fibers demonstrated by either Kligman's modification of Luna's mast cell stain or Unna's orcein stain with or without preoxidation. Gomori's aldehyde fuchsin method with preoxidation should be considered the stain of choice for evaluating murine dermal elastic fiber content.     

Abscisic Acid and Ethylene Increase in Heterodera avenae-infected Tolerant or Intolerant Oat Cultivars

The relationship between root stunting caused by the cereal cyst nematode and levels of two root growth inhibiting hormones, abscisic acid and ethylene, was investigated in aseptically cultured root segments and in intact roots of two oat cultivars differing in tolerance to the nematode. Cultured root segments of oat cultivars New Zealand Cape (tolerant) and Sual (intolerant) were inoculated with sterilized Heterodera avenae second-stage juveniles. Suppressed growth of root axes and emerged laterals following nematode penetration corresponded to an increase in abscisic acid and ethylene in roots of both intolerant and tolerant cultivars. When the experiment was repeated on intact root systems, nematodes retarded root growth of Sual more than New Zealand Cape despite an increase in ABA and ethylene in both cultivars. Abscisic acid and (or) ethylene may be involved in growth inhibition of H. avenae-infected roots but appear to play no direct role in determining tolerance.     

Demonstration of Urinary Eosinophils in Schistosoma haematobium: a Comparative Study among Three Different Stains

Three stains, Hansel's stain, alkaline erythrocin B (AEB) and naphthalene black (NB), were used to demonstrate eosinophils in the urine of patients infected with Schistosoma haematobium. Hansel's stain was superior to the other two stains; it stained eosinophils bright red and their nuclei faint blue, and they were easily differentiated from neutrophils, lymphocytes, macrophages and epithelial cells. The method using AEB took longer than Hansel's stain and 10% of the specimens were lost during staining with this method. Like eosinophils, the neutrophils took up NB stain and their nuclei stained poorly with the counterstain.