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.     

Factors affecting triple staining of human sperm

We have previously described a triple stain for evaluating normal acrosome reactions of human sperm. This procedure uses trypan blue to distinguish live and dead sperm, Bismarck brown to stain the sperm's postacrosomal region, and rose Bengal to stain the sperm's acrosome. We have recently found that batches of rose Bengal vary significantly in their ability to produce good staining of the acrosome in this procedure. This appears to be due to variations in the intrinsic pH of rose Bengal solutions and the presence of nondye contaminants in the stain. In this study, we have evaluated acrosomal staining using 6 batches of rose Bengal and report a method for achieving uniform staining quality with each batch. Solutions of rose Bengal (0.8%) are made up in 0.1 M Tris HCl (pH 2.3) buffer and adjusted to pH 5.3 if necessary. For most batches of rose Bengal this promotes precipitation of some of the dye and an unidentified contaminating crystal. The precipitate is removed by centrifugation, and the supernatants have been found to give good to excellent staining of the acrosomes for all batches tested. Solutions of both rose Bengal and Bismarck brown are stable for at least 5 days but their pH values should be monitored daily and adjusted to 5.3 and 1.8 respectively if drifting occurs. We have also observed some variation in the intensity of rose Bengal staining of the acrosome from donor to donor and recommend that staining times in rose Bengal be adjusted for each donor.     

Factors Affecting Triple Staining of Human Sperm

We have previously described a triple stain for evaluating normal acrosome reactions of human sperm. This procedure uses trypan blue to distinguish live and dead sperm, Bismarck brown to stain the sperm's postacrosomal region, and rose Bengal to stain the sperm's acrosome. We have recently found that batches of rose Bengal vary significantly in their ability to produce good staining of the acrosome in this procedure. This appears to be due to variations in the intrinsic pH of rose Bengal solutions and the presence of nondye contaminants in the stain. In this study, we have evaluated acrosomal staining using 6 batches of rose Bengal and report a method for achieving uniform staining quality with each batch. Solutions of rose Bengal (0.8%) are made up in 0.1 M Tris HC1 (pH 2.3) buffer and adjusted to pH 5.3 if necessary. For most batches of rose Bengal this promotes precipitation of some of the dye and an unidentified contaminating crystal. The precipitate is removed by centrifugation, and the supernatants have been found to give good to excellent staining of the acrosomes for all batches tested. Solutions of both rose Bengal and Bismarck brown are stable for at least 5 days but their pH values should be monitored daily and adjusted to 5.3 and 1.8 respectively if drifting occurs. We have also observed some variation in the intensity of rose Bengal staining of the acrosome from donor to donor and recommend that staining times in rose Bengal be adjusted for each donor.     

A triple-stain technique for evaluating normal acrosome reactions of human sperm

A triple-stain technique has been developed to score normal acrosome-reacted human sperm in fixed smears. Live and dead sperm are first differentiated using the vital stain trypan blue. Sperm are then fixed in glutaraldehyde, dried onto slides, and the postacrosomal region and acrosome are differentiated using Bismark brown and Rose Bengal. Slides are examined at 1,000 X with a bright-field microscope and assessed for 1) the percentage of sperm that were alive at the time of fixation and 2) the percentage of sperm that had undergone normal acrosome reactions. Experiments are included that show that trypan blue is a reliable stain for dead sperm and that Rose Bengal stains only sperm having intact acrosomes. This technique may have applications in experimental and clinical studies on sperm capacitation, acrosome reactions, and fertilization in laboratory and domestic animals as well as in man.     

Microspectrophotometric Analysis of Accumulation of the Fluorones K-Fluorescein, Rose Bengal and Phloxine Red in Living Plant Cells

Spectrophotometry investigations of dye solutions in different media and of living stained cells from the upper epidermis of the scaleleaf of Allium cepa were carried out with the dyes K-fluorescein, rose Bengal and phloxine red to elucidate the mechanism of the accumulation of these dyes in the cytoplasm, the nucleus and the cell sap. Thin layer chromatography and paper electrophoresis indicate that the K-fluorescein used here contains no detectable contaminants. Besides the main component, rose Bengal contains two components in small quantities with Rf values of 0.64 and 0.57, plus three more components in traces. Besides the two main components (Rf values of 0.83 and 0.73), phloxine red also contains five more components in traces. Electrophoretic investigations reveal that in aqueous solution the fluorones rose Bengal and phloxine red from pH 2.0-11 show a migration toward the anode. K-fluorescein from pH 2.9-10.4 shows a migration toward the anode, but at pH 1.9 a migration toward the cathode. By shaking aqueous solutions of K-fluorescein, rose Bengal and phloxine red at different pH values with different organic solvents, the above used stainings show different spectral absorption curves according to the polarity of the solvent. The position of the absorption maxima and the shape of the absorption curves of these three anionic dyes lead to the conclusion that the staining of the living cytoplasm and nucleus is due to ion accumulation by means of the “ion trap mechanism” within the aqueous phase of the cytoplasm (cytosol) and the nucleus. Adsorption of dye particles in the protein phase of the cytoplasm cannot be excluded. There seems to be a fundamental difference in the vital staining of the protoplasm by anionic and cationic dyes, the latter apparently accumulating as neutral dye molecules in the lipid phase of the protoplasm. The concentration of the dyes used in the living cytoplasm (cytosol) is approximately 0.2-0.05%. During natural and artificial displacement of K-fluorescein from the cytoplasm to the vacuole, it appears that accumulation of the dye within the vacuole is performed through an ion trap mechanism in the form of bivalent ions. Along with natural displacement, it is possible that ion accumulation also occurs in metabolic products.     

Use of triple stain technique for simultaneous assessment of vitality and acrosomal status in boar spermatozoa

The object of this study was to adapt the triple stain technique to diluted and incubated boar spermatozoa. Freshly ejaculated semen was resuspended in MR-A diluent to contain 3x10(7) cells/ml (diluted spermatozoa) and was subsequently capacitated (incubated spermatozoa). Experiments were conducted to show the conditions required for optimal staining quality and validation of triple stain technique. The most satisfactory staining solutions for diluted spermatozoa were 2% Trypan blue at 37 degrees C for 15 minutes, 0.8% Bismarck brown in 30% ethyl alcohol (pH 2.8) at 40 degrees C for 10 minutes and 0.8% rose Bengal in 0.1 M of Tris (pH 4.3) at 21 degrees C for 20 minutes. Satisfactory results were obtained for incubated spermatozoa with rose Bengal when the staining time was 10 minutes. Triple stain technique seemed to be a useful method for the simultaneous assessment of sperm vitality and acrosomal status; consequently, it should be valuable tool, for use in porcine in vitro fertilization systems.     

Iron Hematoxylin Chelates: II. Histochemistry of Myelin Sheath Stains

Aldehyde blockage, methylation, acetylation, amine blockage, and 4 min, 30 min and 24 hr deamination of paraffin sections of cat spinal cord were followed by staining with Lendrum's phloxine-tartrazine, Luxol fast blue MBS, PAS, phosphotungstic acid-hematoxylin, and Weil stains. Only the effects on staining of myelin are reported. These histochemical procedures separated the 5 stains into 3 groups: (1) phloxine-tartrazine and Luxol fast blue, (2) PAS, and (3) Weil and phosphotungstic acid-hematoxylin. The 3 patterns indicate that these stains may attach to 3 different reactive molecular sites in the sections. For the Weil and phosphotungstic acid-hematoxylin, such reactive sites are probably a secondary or tertiary amine or both.     

Selective Light Microscopic Demonstration of the Specific Granulation of the Rat Atrial Myocardium by Lead-Hematoxylin-Tartrazine

MacConaill's lead-hematoxylin as modified by Solcia et al. was found to be a highly selective stain for the specific granulation of atrial cardiocytes in the rat. The specific atrial granules were stained blue-black. Contrast was enhanced by counterstaining in a saturated solution of tartrazine in Cellosolve. The stain is compatible with several fixatives and may be used with paraffin or Epon-embedded material.     

Selective light microscopic demonstration of the specific granulation of the rat atrial myocardium by lead-hematoxylin-tartrazine.

MacConaill's lead-hematoxylin as modified by Solcia et al. was found to be a highly selective stain for the specific granulation of atrial cardiocytes in the rat. The specific atrial granules were stained blue-black. Contrast was enhanced by counterstaining in a saturated solution of tartrazine in Cellosolve. The stain is compatible with several fixatives and may be used with paraffin or Epon-embedded material.     

Selective Light Microscopic Demonstration of the Specific Granulation of the Rat Atrial Myocardium by Lead-Hematoxylin-Tartrazine

MacConaill's lead-hematoxylin as modified by Solcia et al. was found to be a highly selective stain for the specific granulation of atrial cardiocytes in the rat. The specific atrial granules were stained blue-black. Contrast was enhanced by counterstaining in a saturated solution of tartrazine in Cellosolve. The stain is compatible with several fixatives and may be used with paraffin or Epon-embedded material.     

A Clearing Technique for Detecting the Fungal Endophyte Acremonium sp. in Grasses

Leaf tissue of tall fescue Festuca arundinacea Schreb., hard fescue Festuca ovina L., red fescue Festuca rubra L. and perennial ryegrass Lolium perenne L. was stained with rose Bengal or aniline blue to detect the presence of the fungal endophyte Acremonium sp., Specimens were cleared using methyl salicylate, an optical clearing agent, and viewed using bright field microscopy. Tissue was presenred as dried tissue or stored in 70% aqueous ethyl alcohol before staining and clearing. Tissue was observed at 2, 4 and 12 weeks following clearing to check for stain retention. Staining with rose Bengal was inferior to aniline blue when followed by the clearing agent methyl salicylate. Fungal mycelia stained lighter with rose Bengal and were more difficult to detect than mycelia stained with aniline blue. The results illustrate the usefulness of combining staining and methyl salicylate clearing for detecting fungal endophytes.     

A Six-Dye Staining Schedule for Sections of Mesquite and Other Desert Plants

Materials are fixed in FPA (formalin, 2; propionic acid, 1; 70% ethanol, 17). Paraffin sections on slides are brought to 50% ethanol and stained as follows: (1) in Bismarck brown Y, a 0.02% solution in 0.1% aqueous phenol, 10-30 min; wash 30 sec in 0.7% acetic acid, and wash in distilled water 20-30 sec; (2) in crystal violet, 1% in 70% ethanol alkalinized with 1 drop of 1 N NaOH per 100 ml, 12-35 min; wash 30-60 sec in tap water to remove excess stain, and rinse 0.5 sec in 70% ethanol; then mordant in I₂-KI, 1% each in 70% ethanol, 40 sec, and rinse in 70% ethanol 2-5 sec; (3) in a mixture containing 0.4% acid fuchsin and 0.6% crythrosin B in 70% ethanol about 0.5 sec; rinse in 70% ethanol 5-15 sec to remove excess red; dehydrate in 70%, 95%, and absolute ethanol, 2-3 sec each; (4) in fast green FCF, 0.5% in a mixture of equal parts of methyl cellosolve, absolute ethanol, and clove oil, 5-15 sec; rinse in a mixture of clove oil, 10 ml; absolute ethanol, 100 ml; and methyl cellosolve, 10 ml, 5-7 sec; (5) in orange G, 0.75 gm in a mixture of clove oil, 40 ml; absolute ethanol, 40 ml; and methyl cellosolve, 60 ml, 5-30 sec; rinse clean in a 1:1 mixture of xylene and absolute ethanol, 5-20 sec Complete the clearing in pure xylene, 3 changes, 1.5 min in each, and apply a cover glass with synthetic resin. Slides are agitated in all steps except Bismark brown Y, crystal violet, and the xylenes. Contrast and staining intensity are adjusted by varying staining times in the dye solutions.     

A Rapid Phloxine-Methylene Blue Oversight Stain for Formalin-Fixed Material

A rapid method is described, which yields brilliant and selective differential staining with phloxine-methylene blue. Aqueous phloxine (1%) is treated with hydrochloric acid (1 ml/l gm of phloxine) and the water-insoluble precipitate is washed, dried, and dissolved in acidified 95% ethyl alcohol. Slides are stained for several minutes in this solution (0.2%) followed by brief staining in the usual azure-methylene blue solution and differentiated with colophonium-alcohol. The method eliminates the necessity for prolonged staining at elevated temperatures, reducing the total staining procedure to approximately 15 min. In addition, controlled differentiation with colophonium-alcohol can be carried out on formalin-fixed material without loss of phloxine. The selectivity and tinctorial attributes of phloxine are also considerably improved.     

Phloxine As An Histologic Stain, Especially In Combination With Hematoxylin

A staining schedule employing phloxine as a counter-stain to Erlich's acid hematoxylin is presented. Fixation is best with Zenker's fluid, although formalin can be used. The technic is similar to the standard hematoxylin-eosin formulae but because of the staining advantages of phloxine over eosin, the technic is simpler, and quicker, resulting in clearly differentiated sections which do not fade as soon as do eosin-stained slides. A brief summary of the uses of phloxine as a biological stain is given and its advantages over eosin are discussed.     

Staining with Phloxine

A double stain with Magdala red and anilin blue has sometimes given very satisfactory results; but, just as often, has been entirely worthless. The reason for the discrepancy seems to be that stains sold under the name of Magdala red are of various composition, some of them containing no Magdala red at all. The standardized stain phloxine seems to be identical with successful lots of Magdala red and results are rather uniformly successful. Detailed directions for staining with phloxine and anilin blue will be published in a forthcoming number of Stain Technology.     

Staining with Phloxine

A double stain with Magdala red and anilin blue has sometimes given very satisfactory results; but, just as often, has been entirely worthless. The reason for the discrepancy seems to be that stains sold under the name of Magdala red are of various composition, some of them containing no Magdala red at all. The standardized stain phloxine seems to be identical with successful lots of Magdala red and results are rather uniformly successful. Detailed directions for staining with phloxine and anilin blue will be published in a forthcoming number of Stain Technology.     

Initial and Persisting Staining power of Solutions of Iron-Hematoxylin Lake

A study was made of factors affecting the initial staining power and the stability of iron-hematoxylin lake solutions. The findings were applied to the preparation of a superior hematoxylin staining solution. This is made up as follows: in 50 ml. water dissolve, in order, 1.0 g. ferric ammonium sulfate [FeNE₄ (SO₄)₂⋅ 12H₂O], 0.8 ml. sulfuric acid, 50 ml. 95% ethyl alcohol, 0.5 g. hematoxylin. Filter the solution to remove the insoluble, white crust of the ferric ammonium sulfate. The solution stains well ten minutes after it has been made. Peak performance is attained within 5 hours, and is maintained for 4 to 8 weeks. Staining time is 3 to 30 minutes. Excess stain can be rinsed off the slide and section by immersion in water, after which destaining, if necessary, can be accomplished with a solution of 50 ml. water, 50 ml. 95% ethyl alcohol, 0.18 ml. sulfuric acid. The slides may or may not be placed next in a neutralizing solution of 50 ml. water, 50 ml. 95% ethyl alcohol, 0.5 g. sodium bicarbonate. They may then be passed through 50 ml. water, 50 ml. 95% ethyl alcohol on the way to alcoholic counterstaining solutions, or through water leading to aqueous counterstains.

The nuclear stain produced is black, intense and very sharp and has proved to be consistently excellent on a variety of animal and human tissues following a number of different fixatives.     

Luxol Fast Blue Mbs and Phloxine; a Stain for Mitochondria

The applicability of Luxol fast blue MBS as a 0.1% solution in 0.05% acetic acid to the staining of mitochondria, first recognized in rat kidney by Shanklin and Nassar (Stain Techn., 34: 257-60. 1959), was confirmed in various organs (formalin-Zenker and Regaud's fixations; paraffin embedding) of the mouse and bullfrog. In liver cells and in the epithelium of renal tubules, mitochondria were stained green, selectively and clearly. The dark cells of the renal tubules and the middle piece of sperms in both animals were conspicuously demonstrated by their dense assemblages of green granules. The periodic acid-Schiff procedure proposed by Shanklin and Nassar as a counterstain was replaced by staining in 0.5% aqueous phloxine, 2-3 min; differentiation in 5% phosphotungstic acid, 2 min; and washing in water, 5 min. This simplified and accelerated the techique, and gave a better color contrast. Advantages of Luxol fast blue MBS and phloxine staining over traditional methods for mitochondria in paraffin sections are: durability of the stain, high specificity, simplicity of procedure, and constant result.     

Permanent Stained Preparations of Synovial Fluid for Detection of Calcium Compounds Using Alizarin Red S

Permanent preparations of air dried synovial fluids were prepared by staining calcium compounds with alizarin red S stain; each slide was coverslipped with Permount. Variables studied were: (a) concentration of the solution of alizarin red S, (b) pH of staining solution, (c) time of incubation in staining solution and aqueous and ethanolic content of staining solution. The staining effect of each solution was tested on calcium pyrophosphate dihydrate, calcium oxalate, apatite and monosodium urate (MSU). Of all the solutions, best results were obtained with 0.25% alizarin red S in 50% ethanol at pH 7.0 for 30 min. With this solution, the calcium-containing compounds were well stained. MSU did not stain and still preserved negative birefringence on polarizaton. Fixation of smears with ethanol served a double purpose: It fixed the slides without dissolving or removing MSU or the calcium compounds, yet it did dissolve five corticosteroids commonly used for intra-articular injection which may interfere with interpretation of compensated polarized light microscopy of synovial fluids.     

Basic Two-Dye Stains for Epoxy-Embedded 0.3-1 μ Sections

Dyes used in the 3 methods recommended are: I, thionin and acridine orange (T-AO); II, Janus green and Darrow red (JG-DR); III, methyl green and methyl violet (MG-MV). The first 2 methods were two-solution stains, applied in sequence; the third, required only one solution since methyl violet is present in commercial methyl green. Staining solution and timing was as follows: Method I. 0.1% thionin in a 45% ethanolic solution of 0.01 N NaOH, 5 min at 70 C; rinsing in water and followed by 1 min in a 1% aqueous solution of acridine orange made up in 0.02 N NaOH, also at 70 C, then washed, and dried on slides. Method II. 0.5% Janus green in aqueous 0.05 N NaOH, 5 min at 70 C; rinsing in water then into 0.5% Darrow red in 0.05 N NaOH (aq.), 2 min at 70 C., washing, and drying on slides. Method III. 1% methyl green (commercial, unpurified) in 1% aqueous borax for 15-20 min at 20-25 C, washing and attaching to slides. All staining was performed by floating the sections on the staining solutions, all drying at 70 C, and mounting in a resinous medium. T-AO gave blue to violet cytoplasmic structures, darker nuclei which contrasted strongly with yellow connective tissue and the secretion of goblet cells. JG-DR resembled a hematoxylineosin stain, but by shortening the staining time in DR to 0.5-1 min, collagenous and elastic tissue retained more of the green dye. MG-MV gave dark green nuclei in light green cytoplasm, with collagenous and elastic tissues in blue to violet. As with most methods for staining ultrathin sections, thicknesses of less than 1 μ required longer staining times.