Luxol Fast Blue as a Selective Stain for Alpha Cells in the Human Pituitary

Human pituitaries fixed in Bouin's fluid or 10% formalin were stained by the PAS, Masson trichrome and luxol fast blue methods. By comparing adjacent sections stained by these 3 methods it was found that the alpha cells which are PAS negative, but stained red by the Masson trichrome method, were intensely stained by luxol fast blue. The beta cells which are stained blue by the PAS and Masson methods were not stained by luxol fast blue. Similar observations were made on a series of pituitaries from 8 other mammalian species. It is concluded that luxol fast blue is a selective stain for alpha cells in the mammalian pituitary.     

间接免疫过氧化物酶技术鉴定猪和牛的肥大细胞

用小鼠抗人肥大细胞类胰蛋白酶单克隆抗体ＡＡ１,ＡＡ３及ＡＡ５的间接免疫过氧化物酶技术对经Ｃａｒｎｏｙ液或中性缓冲福尔马林固定的猪和犊牛空肠,舌及胸腺的石蜡切片进行了免疫染色。对猪和牛的肥大细胞特异性免疫染色与常规的组织化学染色的结果进行了比较。     

Application of the Papanicolaou Stain to Paraffin Sections

Routine paraffin sections from tissues fixed either in aqueous formalin, 80% alcohol (with or without 1% trichloracetic acid added), Carnoy's alcohol-chloroform-acetic (6:3:1) and Bouin's fixative were stained as follows: Harris' hematoxylin, 6 min; running water, 2-3 min; ascending grades of alcohol to 95%; orange G, 0.5% and phosphotungstic acid, 0.015% in 95% alcohol, 5 min; 95% alcohol, 2 changes; Papanicolaou's EA36, 2.5 min; dehydration, clearing, and covering in Permount. The results show morphology better than hematoxylin and eosin and the technic is recommended particularly for keratin, which always stains bright orange.     

A Cresyl Fast Violet Stain for Bacteria and Fungi in Tissue

The cresyl fast violet staining method was modified to eliminate differentiation. Paraffin sections from tissues fixed in Zenker-formol were stained in a 1% aqueous solution of cresyl fast violet (Chroma), adjusted to pH 3.7 with acetic acid, washed in running tap water, dehydrated and covered. Because basophilia increases with time of fixation or storage in formalin or Kaiserling's fluid, dilution of the dye solution to 0.5-0.1% is recommended for such material. Bacteria, nuclei, Nissl substance, and lipofuscin were colored dark blue; fungi, blue to purple; and cytoplasm and muscle fibers, light blue. Collagen and reticulum fibers were only faintly stained. Thus, microorganisms were easily visible against the lightly colored background. In formalin-fixed material, bile pigment was colored olive green. Because this method does not require differentiation, it gave uniform results even in the hands of different users. Little or no fading was observed in sections stored for more than 2 yr.     

A Triple Stain for Deoxyribonucleic Acid, Polysaccharides and Proteins

Tissues from mammalian, amphibian, insect and plant sources were fixed in formalin or in Carnoy's, Helly's, or Smith's fluid and processed in the usual manner to mounted paraffin sections. These were stained by the sequence: Feulgen reaction (using azure-A-Schiff reagent); periodic acid Schiff (with basic-fuchsin-Schiff reagent); and a 0.02% solution of naphthol yellow S in 1 % acetic acid. Nuclei stained blue to green; polysaccharides, red; and proteins, yellow. Thus, deoxyribonucleic acid, vicinal hydroxy and hydroxy-amino groups, and free basic groups of proteins were demonstrated selectively. Of the tissues tested, stomach, intestine, kidney, thyroid gland and plant root tips were most strikingly stained.     

Effect of phosphomolybdic acid on the binding of Sudan black B

Paraffin sections of tissues fixed in absolute alcohol or Carnoy's fluid were mordanted in a 1% aqueous solution of phosphomolybdic acid, stained in saturated solutions of Sudan black B, acetylated Sudan black, various solvent and basic dyes in 70% ethyl alcohol for 5 min at room temperature, dehydrated in alcohol and covered in Permount. Sudan black B and other dyes with basic groups stained basement membranes, reticulum and collagen fibers intensely. Acetylated Sudan black, Sudan IV and oil red 0 did not color any tissue structures. Control sections, without pretreatment, did not bind Sudan black B. These findings indicate interaction between basic groups of the dye and free acid groups of phosphomolybdic acid.     

Immunocytochemical demonstration of carbonic anhydrase in human epithelial cells

Human tissues obtained early postmortem were immunostained to demonstrate carbonic anhydrase (CA) and, in some instances, to differentiate CA I and CA II, employing an immunoglobulin-peroxidase bridge method. Optimal immunostaining was obtained in tissues fixed a few hours in Carnoy's fluid or a buffered HgCl2 solution. Specimens fixed 1/2 to 2 hr with buffered formalin or Bouin's fluid stained less well but better than those fixed 24 hr with formalin. In tracheobronchial glands, serous acini and demilunes exhibited intense immunoreactivity demonstrative of the isozyme CA II. In kidney, all cells of the distal convoluted tubules were strongly positive for CA and cortical collecting tubule cells stained strongly but with some variability among individual cells. Cells in medullary collecting tubules ranged from intensely to negligibly reactive. Proximal convoluted tubules and thick ascending limbs showed moderate to light, uniform staining, but the thin limbs of the loop of Henle were negative. Renal cell immunoreactivity occurred only with antiserum to CA II. Seromucous acini in submandibular glands stained strongly and selectively for CA. Ducts in liver and pancreas showed strong selective immunostaining. The most superficial columnar cells lining the main lumen of the colon and appendix displayed strong reactivity, as did columnar cells lining the gall bladder.     

A Comparative Study of some Dehydration and Clearing Agents

An experiment to determine the advantages of diozan, iso-butyl alcohol, tertiary butyl alcohol, and ethyl alcohol as dehydrants and chloroform, toluol, xylene, benzol, methyl benzoate, methyl salicylate, and acetone as clearers is described. Materials fixed in Bouin's fluid, Zenker formol, and 10% neutral formalin were dehydrated, embedded, sectioned, and stained. Bouin's fluid produces less hardening, shrinkage and distortion than the other fixatives employed. Slow dioxan is the best method of dehydration. All the picric acid need not be removed from tissues to be embedded in paraffin. Tissue blocks not more than 4 mm. thick may be dehydrated and impregnated with paraffin by slow dioxan in 13 hours, fast dioxan in 10 hours, iso-butyl alcohol and tertiary butyl alcohol in 14 hours, and ethyl alcohol-chloroform in 17 hours without incurring any distortion due to rapidity of dehydration and infiltration.     

Polyacrylamide gel electrophoresis and immunoblotting of proteins extracted from paraffin-embedded tissue sections

We show in this communication that polyacrylamide gel electrophoresis (PAGE) and immunoblotting of proteins can be performed using one to two 5-7 micron paraffin sections of tissues fixed in non-cross-linking fixatives (acetone, alcohol, or modified Carnoy's solution). Proteins for study were extracted from paraffin sections of mouse foot pad and liver. The presence of unaltered keratin polypeptides in tissues fixed with either acetone or alcohol was demonstrated in gels stained with Coomassie brilliant blue. The preservation of their antigenic determinants was demonstrated with immunoblotting. Furthermore, the immunoreactivity of soluble proteins, such as albumin, remained unaltered in immunoblots obtained from paraffin-embedded mouse liver sections. These data indicate that tissues embedded and stored in paraffin are useful for the above-mentioned biochemical and immunological studies and may therefore be an important technique for diagnostic pathology or retrospective studies.     

Fixation and Staining of Planaria for Histological Study

Fixation and staining of planaria can affect the interpretation of histopathological changes following their exposure to various agents. We assessed several fixation protocols with various stains in planaria to determine an optimal combination. Planaria were fixed in each of the following: 10% neutral buffered formalin, 2.5%, glutaraldehyde, Bouin's, Zenker's, 70% ethanol, and relaxant. In addition, planaria were fixed in relaxant and postfixed in each of the fixatives above. Paraffin embedded sections from each fixation protocol were stained with hematoxylin and eosin (H & E), toluidine blue, periodic acid-Schiff (PAS), or phosphotungstic acld-hematoxylin (PTAH). Relaxant fixed planaria were also stained with Steiner's, Holmes, trichrome, Giemsa, Grocott's methenamine silver (GMS) and antibodies for intermediate filaments (cytokeratin, vimentin and desmin). Relaxant and Zenker's gave the best fixation with minimal artifacts. Formalin, glutaraldehyde, and ethanol were unacceptable because they caused contortions of the body, crenation, and a darkly pigmented epidermis. Gastroderm could be differentiated from stroma best when stained with H & E, toluidine blue and PTAH. Other organ systems differentially stained included the epidermis, marginal adhesion gland, nervous tissue, and muscle. PAS, Steiner's, Holmes, trichrome and the intermediate filament stains were not useful for planaria staining. The most morphological information was obtained with relaxant fixative and a combination of sections stained with H & E and PTAH.     

Immunoblotting of keratin polypeptides extracted from tissues preserved in standard histologic fixatives

Cytoskeletal polypeptides from fresh placental tissue, tissue stored at -30 degrees C, and tissue fixed in 10% buffered formalin, Bouin's solution, and Carnoy's solution were extracted, separated by electrophoresis, and immunoblotted using monoclonal antibodies immunoreactive with keratin polypeptides. Storage of the placental tissue at -30 degrees C, or fixation in Carnoy's solution did not alter the extractability, migration pattern, or immunoreactivity of the keratin polypeptides. Keratin polypeptides could not be adequately demonstrated in extracts prepared from formalin- or Bouin's solution-fixed tissues. Several unmasking procedures used on tissues before extraction and on nitrocellulose blots before application of primary antibodies failed to unmask keratin polypeptides, either in Coomassie blue-stained gels or in immunoblots reacted with anti-keratin antibodies. These data indicate that Carnoy's solution is the fixative of choice for tissues in which electrophoretic and immunoblotting analyses of keratin polypeptides might be required.     

A Phloxine-Azure-Hematoxylin Sequence for Differential Staining of Cells in Pancreatic Islets

Sections of 6 μ from tissues fixed in Susa or in Bouin's fluid (without acetic acid) and embedded in paraffin were attached to slides with Mayer's albumen, dried at 37 C for 12 hr, deparaffinized and hydrated. The sections fixed in Susa were transferred to a I₂-K₁ solution (1:2:300 ml of water); rinsed in water, decolorized in 5% Na₂S₂O₃; washed in running water, and rinsed in distilled water. Those fixed in Bouin's were transferred to 80% alcohol until decolorized, then rinsed in distilled water. All sections were stained in 1% aqueous phloxine, 10 min; rinsed in distilled water and transferred to 3% aqueous phosphotungstic acid, 1 min; rinsed in distilled water; stained 0.5 min in 0.05 azure II (Merck), washed in water; and finally, nuclear staining in Weigert's hematoxylin for 1 min was followed by a rinse in distilled water, rapid dehydration through alcohols, clearing in xylene and covering in balsam or a synthetic resin. In the completed stain, islet cells appear as follows: A cells, purple; B cells, weakly violet-blue; D cells, light blue with evident granules; exocrine cells, grayish blue with red granules.     

The effect of different fixatives and length of fixation time on subsequent AgNOR staining for frozen and paraffin-embedded tissue sections

Summary The AgNOR technique has been used extensively in studies investigating the possibility that the numbers and appearances of the intranuclear structures stained are markers of malignancy. The method has the advantage of being applicable to many different types of histological material, including paraffin-embedded tissue. However, it has been suggested that the visualization of AgNORs is dependent on the type and time of fixation employed. This study set out to measure this effect with the following commonly-used fixatives: acetone, absolute ethanol, methanol, Carnoy's fluid, Bouin's fluid, 4% glutaraldehyde, 10% neutral buffered formalin and 10% formol-saline. Both frozen sections and blocks of fresh tonsil were fixed for varying times, the blocks of tissue then being processed routinely. With the frozen sections AgNORs were easier to discern than in sections of paraffin-embedded tissue, and more intranucleolar AgNORs were visible when alcoholic fixatives were used than with aldehyde fixation. The effects of different fixatives on AgNOR appearance in paraffin sections is, however, more complex. Despite the variation caused by different fixatives, AgNORs could be demonstrated adequately with all the fixatives studied. It is concluded that fixation is not a limitation to the study of AgNORs provided that the time and type of fixative is controlled.     

üBisch Granules on Tapetal Membranes in Anthers; Rapid Selective Staining by Spirit Blue

Decapitate the anther and squeeze out its contents into a drop of water on a clean slide coated with Haupt's adhesive. Let slides air dry and stain the preparations for 4-6 hr in 0.005% spirit-soluble aniline blue, prepared in 50% ethanol. Pass the slides through acetone, 10 min; 1:1 mixture of acetone and xylene, 5 min; and xylene. Mount in a resinous medium. The technique is effective for both fresh anthers and anthers fixed in FAA, Carnoy's fluid, 1:3 acetic alcohol, and 10% formalin (commercial). For fixed anthers, follow customary methods of paraffin embedding and microtomy.     

Staining Nerve Fibers with Silver in Tissue Fixed with Bouin's Fluid

Nerve fibers, in organs fixed with Bouin's fluid, are usually refractive to the Davenport silver technic. The axons, however, can be successfully stained if the sections, on slides, are given a preliminary treatment with concentrated pyridine (1 hour), then a 24-hour bath of ammoniated alcohol (99 cc. 80% alcohol, 1 cc 28% ammonium hydroxide) and an interval in 40% aqueous silver nitrate (6-8 hours) before being immersed in the acidified alcoholic silver solution of Davenport. Following the silvering, reduction and toning of the axons, according to the procedure of Davenport, the surrounding non-nervous tissue elements can be counterstained with a combination of either azocarmine, light green and orange G, or azocarmine, aniline blue and orange G.     

Modifications of Kohn's chlorazol black E staining and Wheatley's trichrome staining for temporary wet mount and permanent preparation of Entamoeba histolytica.

Preparation of stained smears of Entamoeba histolytica has several drawbacks. We therefore tried to simplify the staining procedures by modifing Kohn's chlorazol black E staining and Wheatley's trichrome staining techniques. Trophozoites and cysts of axenically cultured E. histolytica and Entamoeba invadens, respectively, and trophozoites and cysts of E. histolytica in stools of patients were used. Karyosomes and peripheral chromatin of nuclei and chromatoid bodies became distinctly visible after amoebae were suspended in the basic solution of Kohn's stain. Amoebae fixed in suspension with either basic solution or Bouin's fixative were clearly stained with Kohn's and trichrome preparations, both as wet mounts directly and as permanent slides after processing for mounting. These procedures were easier when the basic solution was used as a fixative and trichrome stain was employed. Erythrocytes ingested by trophozoites, however, were not stained with either of these preparations after fixation in the basic solution but were clearly stained when Bouin's fixative was used. Cysts of E. histolytica in stools concentrated using basic solution (instead of formalin) and ether were also stained with these stains. Consequently, without employing highly toxic mercuric chloride, wet mounts and permanent smears can be prepared with permanent stains, and preserved cysts can be stained after concentration.     

Effects of fixation and processing on the immunohistochemical visualization of type-I, -III and -IV collagen in paraffin-embedded liver tissue

Summary We compared the effects of different fixatives and enzymatic-digestion procedures on the immunohistochemical visualization of type-I,-III and-IV collagen in paraffin-embedded normal human liver sections. None of the fixatives tested allowed the staining of these antigens without prior enzymatic digestion. The best results i.e. strong staining intensity and well-defined localization, were obtained when liver tissue was fixed in Bouin's fluid or in other solutions containing picric acid. Several other fixatives, including Carnoy's fluid, Lillie's AAF, 10% neutral formalin and 96% ethanol, gave unsatisfactory results. Pepsin was ineffective for unmasking type-I and-III collagen antigens, and was only partially effective for visualizing the type-IV collagen antigen. The best results were obtained when material fixed in Bouin's fluid was embedded in paraftin and digested with trypsin. Using this procedure, the results were comparable to those obtained in unfixed frozen sections with respect to the staining intensity, specificity and non-specific staining.     

Preparation of sand fly (Diptera: Psychodidae: Phlebotominae) specimens for histological studies

Phlebotominae sand fly specimens were prepared for histological and physiological studies. Different fixatives were tested on sectioned and whole bodied adult females in order to obtain good fixation and provide satisfactory penetration of the embedding media. All fixed specimens were infiltrated (up to seven days under 5 C) and embedded in hydroxyethyl metacrylate. Two-three m sections were stained, mounted in Canada balsam and observed by light microscopy. Best results were achieved when whole bodied insects were double fixed in Bouin's and Carnoy's fluids (4 h/2 h) and stained in Hematoxilin/Eosin or fixed in calcium formaldehyde and stained in mercury bromophenol blue.     

鸡中枢淋巴器官肥大细胞的组织化学与形态学

对哺乳动物的,特别是啮齿动物和人类肥大细胞已有了比较深入的研究, 但关于家禽肥大细胞的研究很少.本研究旨在阐明鸡中枢淋巴器官中肥大细胞的组织化学与形态学特征.本研究证实Carnoy 氏液是鸡肥大细胞的优良的固定液,而中性缓冲福尔马林(NBF) 却阻断了大多数肥大细胞的着染力.甲苯胺蓝和阿尔新蓝是鸡肥大细胞的良好的染料,但阿尔新蓝能使更多的肥大细胞着染,虽然其也可使杯状细胞着染.作者的一种新的染色法, 长时间阿尔新蓝染色(LAB-S)可用于NBF固定的组织中肥大细胞的染色,因为其着染的细胞数与Carnoy 氏液固定甲苯胺蓝染色的细胞数无显著差异(P<0.001).在胸腺髓质中见有大量的肥大细胞,而胸腺皮质仅可见个别肥大细胞位于血管周围及小叶间结缔组织中.腔上囊的皮质与髓质中很少见有肥大细胞.肥大细胞有血管周围分布的倾向,但一个有趣的发现是血管内偶尔也有个别肥大细胞.电镜下可见肥大细胞的胞浆颗粒内充满无定形的颗粒状基质,但其电子密度有的较高,有的较低.少数胞浆颗粒内有旋涡状及网状亚微结构.但未见有人类肥大细胞胞浆颗粒内特征性的晶格状和卷轴状的亚微结构,也未见到在绵羊肥大细胞中描述过的特殊亚微结构.     

The Demonstration of Beta Cells in Pancreatic Islets and Their Tumors

The stain is applied routinely to tissues fixed in 10% buffered formalin (pH near 7.0) or in Bouin's fluid. Bring paraffin section to water as usual and mordant 72 hr in 5% CrCl₃ dissolved in 5% acetic acid. Wash in water and in 70% alcohol and stain 6 hr. Formula of staining solution: new fuchsin, 1% in 70% alcohol, 100 ml; HCl, conc., 2 ml and paraldehyde, 2 ml, mixed together and added to the dye solution; let stand 24 hr before use. After staining, wash in running tap water 5-10 min, rinse in distilled water and counterstain if desired. Dehydration in alcohol, clearing and covering completes the process. When the paraldehyde is obtained from a freshly opened bottle, standardized staining times can be used and thus eliminate the necessity of differentiating individual slides. The granules of beta cells stained deep blue to purple and were demonstrated in the pancreatic islet of man, dog, mouse, frog, guinea pig and rabbit.