Effects of Mounting Media on Fading of Toluidine Blue and Pyronin G Staining in Epoxy Sections

Available mounting media cause fading of histological preparations over time. A study was designed to find the most suitable medium for durable mounting of Araldite embedded semithin sections of rabbit cerebral cortex stained with toluidine blue and pyronin G. Among four synthetic mounting media tested, only DePeX prevented fading of the sections during the first month. All mounting media tested helped preserve staining intensity after one month, since the fading rate after one year is only about half that in sections prepared without mounting medium. The average optical density of sections after one year was higher in preparations mounted with DePeX than in sections treated with the other mounting techniques tested in this study. After one year, the average optical density of sections mounted with DePeX had decreased approximately 20%.     

False Cellular Localization of Aminopeptidase Caused by Resinous Mounting Media

Fresh frozen sections of rat submandibular gland were processed for leucine aminopeptidase localization with L-lencyl-β-naphthylamide hydrochloride and L-leucyl-β-naphthylamide. When the first substrate was utilized stained sections were dehydrated in an ethyl alcohol series, cleared in xylene, and mounted in water-insoluble (resinous) media. Sections were also removed at each stage of dehydration and cleared and mounted with glychrogel. When the second substrate was used, tissues were partially decolorized in 40% ethyl alcohol and mounted directly in glychrogel. Comparison of all sections mounted in glychrogel indicated that there was no variation in cellular localization, regardless of substrate used or degree of dehydration. Nuclei were unstained. After mounting in balsam or synthetic resin the nuclei exhibited an intense stain and the parenchymal reaction was stronger, but diffuse. Progressive staining of the nuclei was observed, microscopically, immediately after applying the resinous mounting medium. The use of an aqueous mounting medium appears to be mandatory in this procedure—glychrogel is recommended.     

A method for preparing and staining histological sections containing titanium implants for light microscopy

An improved method for preparing and staining ground tissue-implant sections for light microscopy is presented. Undecalcified tissue blocks with titanium implants were dehydrated in an ascending series of ethanol and stained in toto with basic fuchsin. Specimens were infiltrated and embedded in methyl methacrylate and sections were prepared using a cutting-grinding-system. The polished surface was counterstained with light green or anilin blue. Light polymerizing resin was used as slide mounting medium and for mounting the coverglass. The sections obtained were 10-15 microns thick with tissue architecture which clearly differentiated structures at the tissue-implant interface. The method was very useful for computer assisted morphometric analysis.     

A Method for Preparing and Staining Histological Sections Containing Titanium Implants for Light Microscopy

An improved method for preparing and staining ground tissue-implant sections for light microscopy is presented. Undecalcified tissue blocks with titanium implants were dehydrated in an ascending series of ethanol and stained in toto with basic fuchsin. Specimens were infiltrated and embedded in methyl methacrylate and sections were prepared using a cutting-grinding-system. The polished surface was counterstained with light green or anilin blue. Light polymerizing resin was used as slide mounting medium and for mounting the coverglass. The sections obtained were 10-15 μm thick with tissue architecture which clearly differentiated structures at the tissue-implant interface. The method was very useful for computer assisted morphometric analysis.     

Selective Staining by the Fluorochrome 5,5'-Diphenyl-9-ethyl-oxacarbocyanine. II. Application to Paraffin Embedded Nervous Tissue

We present a simple and rapid method to label specific structures of neural tissue in paraffin sections. After incubation of deparaffinized sections in the cyanine dye 5,5'-diphenyl-9-ethyl-oxacarbocyanine (DEOC), three different washing and mounting procedures were performed. Incubation in DEOC followed by washes in ethanol and water and mounting in glycerol-gelatin resulted in selective labeling of myelin in the central and peripheral nervous systems. Weak labeling of myelin and axons and staining of nuclei of neurons was seen after incubation in DEOC followed by washes in ethanol and xylene, and mounting in Eukitt. Nuclear proteins, the endoplasmic reticulum and the Golgi apparatus were stained strongly and exclusively after incubation in DEOC, washes in water, ethanol and xylene, and mounting in Eukitt. Thus the absorption pattern of DEOC is changed significantly by solvents applied after the fluorochrome. In any case, fluorescence did not fade even after repeated and intense fluorescence microscopy over a period of 6 months.     

Mucosal Whole Mounts Of Rodent Forestomach

The most convenient separation of the mucosa of the f orestomach of rats and mice was secured when the opened stomach was pinned flat (mucosa up) to the bottom of a paraffined petri dish and immersed 1-3 hours in 0.5-1.0% oxalic or acetic acid at room temperature. The separated mucosa was spread on a spatula and immersed in fixing fluid. Staining, dehydration, clearing and mounting in a syndietic mounting medium were by standard methods as used for celloidin sections.     

Non-aqueous permanent mounting for immunofluorescence microscopy

It is generally assumed that an aqueous mounting medium is necessary for the preservation of immunofluorescent-labelled microscopical preparations and polyvinyl alcohol-based solutions (e.g. Mowiol) being the most frequently used mounting media; however, both the quality and intensity of the fluorescence signal in most immunolabelled preparations after aqueous mounting slowly diminish with time, and finally, samples become unsuitable for examination. In the present work, we describe a very simple and rapid non-aqueous mounting procedure for cultured cells and tissue sections, which preserves the fluorescent signal in an excellent way after immunodetection or use of other specific labelling methods. It is based on the current histological protocol in which, after fluorescence labelling, preparations are dehydrated in ethanol, cleared in xylene and mounted in DePeX. Using this non-aqueous mounting medium, the fluorescent signal remains high and stable, allowing a suitable and permanent preservation of labelled and counterstained microscopical preparations.     

Application of microwave technology to the processing and immunolabeling of plastic-embedded and cryosections.

We have adapted existing microwave irradiation (MWI) protocols and applied them to the processing and immunoelectron microscopy of both plastic-embedded and frozen sections. Rat livers were fixed by rapid MW irradiation in a mild fixation solution. Fixed liver tissue was either cryosectioned or dehydrated and embedded in Spurr's, Unicryl, or LR White resin. Frozen sections and sections of acrylic-embedded tissue were immunolabeled in the MW oven with an anti-catalase antibody, followed by gold labeling. Controls were processed conventionally at room temperature (RT). The use of MWI greatly shortened the fixation, processing, and immunolabeling times without compromising the quality of ultrastructural preservation and the specificity of labeling. The higher immunogold labeling intensity was achieved after a 15-min incubation of primary antibody and gold markers under discontinued MWI at 37C. Quantification of the immunolabeling for catalase indicated a density increase of up to fourfold in the sections immunolabeled in the MW oven over that of samples immunolabeled at RT. These studies define the general conditions of fixation and immunolabeling for both acrylic resin-embedded material and frozen sections.     

Formation of short-wavelength chlorophyll(ide) after brief irradiation is correlated with the occurrence of protochlorophyll(ide)636–642 in dark-grown epi- and hypocotyls of bean (Phaseolus vulgaris)

Chlorophyll formation capacity along the seedling of bean ( Phaseolus vulgaris L. cv. Brede zonder draad) was investigated. After 7 days of irradiation a gradient was formed, where the primary leaf contained ca 300 times more chlorophyll per gram fresh weight than the lower hypocotyl section and ca 20 times more than the epicotyl. Similar chlorophyll gradients but at lower levels were seen when the seedlings were first placed in darkness for 7 days and then irradiated for 1, 2 or 7 days. Ultrastructural investigation of seedlings grown for 7 days in darkness and then irradiated for 24 h revealed a more developed inner membrane system with grana stacks in plastids of cells in the uppermost hypocotyl section compared to plastids of cells in lower hypocoty] sections. The higher up on the seedling the more the ratio increased of protochlorophyll(ide) emitting at 657 nm to short-wavelength protochlorophyll(ide). After flash irradiation of the different sections, fluorescence emission spectra with maxima at 680 and 690 nm, respectively, were observed, indicating the formation of short- and long wavelength chlorophyll(ide) forms. The lower the ratio of protochlorophyll(ide) emitting at 657 nm to the short-wavelength protochlorophyll(ide), the less long-wavelength chlorophyll(ide) was formed after irradiation. However, after continuous irradiation long-wavelength chlorophyll(ide) was formed. In dark grown roots, where only short-wavelength protochlorophyll forms were present, it was not possible to transform protochlorophyll to chlorophyll by flash irradiation. Possible explanations for this phenomenon are discussed.     

Ninhydrin Staining of Tissue Sections

This method represents a considerable improvement over earlier ninhydrin procedures. Celloidin sections were stained after mounting in a medium which clears with incubation at 55 °C. There appears to be no reason why paraffin section cannot be used. The sections were not placed in a large volume of ninhydrin (0.25% triketohydrindene hydrate in n-butanol) but only a small volume was sprayed onto the slide. Distortion resulting from heating in boiling water to develop the color was avoided by a slower treatment of 3 days' incubation at 55 °C. The use of water as a solvent in staining is also avoided, thus minimizing the possibility of color migration and insuring against the development of the intensely colored products of the ninhydrin reaction that occur in aqueous solution. Slides need not be observed upon the day of preparation, since the color was stable for about a week after its formation.     

Use of a Silicone Rubber (Clear Seal) as a Section Adhesive Resistant to Acid, Alkali and Heat

An optically clear silicone rubber adhesive is recommended for use in histochemical procedures in which detachment of tissue sections is likely. Procedure: Cut paraffin sections and float on a 45-50 C water bath; leave frozen sections on the microtome knife in the cryostat; spread the silicone rubber thinly and evenly over 2/3 of the slide (Clear Seal—General Electric, was used); pick up paraffin sections directly from the floatation water and frozen sections from the microtome knife with a warm slide; dry for 1.5 hr at 25 C; place paraffin sections in a 60 C oven for 0.5 hr, deparaffinize through xylene and hydrate through alcohols to water. Stain sections as desired, but avoid clearing agents before mounting after strong acid or alkaline treatment, and mount rapidly if a synthetic resin is used because of the solvent effect on the silicone rubber. Of the adhesives tried, silicone rubber is the only one capable of withstanding boiling 10% HCl for any period of time without detachment of sections.     

Paraffin Section Thickness—A Direct Method of Measurement

Paraffin section thickness may be directly measured by re-embedding the sections wider consideration, cutting them again at right angles to the original plane of sectioning, and taking direct measurements with a filar micrometer after staining and mounting. Conditions and materials with which relatively un-distorted 3 and 5 μ sections were secured include (a) a hand-honed knife with a 23° facet bevel, set at a clearance angle of 7°, and (b) a hard paraffin (56-58°) embedding medium, preferably with 5% beeswax and 5% bayberry wax added. By taking direct measurements, it was found that bull testis tissue cut at a microtome setting of 10μ averaged 10.82 μ in thickness. Settings of 5 μ and 3 m resulted in sections averaging 5.25 and 3.31 μ in thickness respectively. Stages in sporogenesis of Onoclea sensibilis, Lewitsky fixed, were examined after sectioning at settings of 10, 5, and 3 μ to determine necessity for thin sections. For this material, it was indicated that mitochondrial preparations as thick as 10 μ were worthless, regardless of good fixation and proper staining. Three-micron sections give the best results.     

Radiosensitivity of murine hemopoietic colony-forming units assayed in situ in the rib and in other marrow sites

The radiosensitivity of murine hemopoietic colony-forming cells, which produce colonies in situ and which were counted at Day 8 after irradiation in sections of the femur, humerus, sternum, and spleen, is characterized by a D0 value of 91 +/- 9 cGy. The radiosensitivity of such cells in the rib was assessed using a new technique measuring regeneration or ablation of marrow in transverse sections of ribs observed at Day 8 after irradiation. The mean D0 value over a range determined using several different criteria was 108 cGy. These results provide evidence for the common assumptions that radiosensitivity measured using conventional transplantation assays reflects radiosensitivity in situ, and that the radiosensitivity of stem cells in different medullary marrow sites is similar. The techniques could be used with other species where assays for stem cells are not available.     

A Bodian method for mounted frozen sections.

For application of the Bodian method to frozen sections, cut frozen peripheral nerve or muscle at 10 mum and mount. Fix for 4 days in 18 parts 80% ethanol, 1 part 10% formalin, and 1 part glacial acetic acid. Fix central nervous tissue in the same mixture prior to freezing and sectioning, and after mounting postfix for 4 days. Impregnate by the Bodian procedure. The results equal Bodian stains of paraffin sections. The technique is simple and reliable. The use of 10 mum frozen sections produces little artifact and allows alternate serial sections to be stained with other techniques.     

Permanent Mounts Of Chromosomes After 8-Oxyquinoline and Squashing

Fresh young root tips or free-hand cross sections thereof were placed in 0.002 M 8-oxyquinoline (aq.) at 10-14^oC. for 3 hours. After rinsing in water 1-2 minutes, they were soaked in N HC1 at 55^oC. for 25 minutes, rinsed again and squashed under a cover glass on a dry slide. Slide and cover glass were separated by placing in 70% alcohol and allowed to remain therein at least 0.5 hour after separation. Both slide and cover glass were passed through 50% and 30% alcohol to water and stained by the Feulgen procedure (without further hydrolysis) or with crystal violet after mordanting in 1% chromic acid overnight and washing in running water 3-4 hours. Dehydration and mounting in balsam completed the process. The smear on the slide was covered with a clean cover glass and the cover glass, bearing stained material, mounted separately.     

Polystyrene embedding: a new method for light and electron microscopy.

Polystyrene embedments of histological specimens can be obtained with a solution of 1:14 polystyrene-toluene, 5% benzyl alcohol and 1% dibutyl phthalate, allowing the solvent to evaporate in polyethylene containers for 2-3 days at 58 C. The resulting blocks are easily cut into truncated pyramids, each containing a piece of tissue, which are then glued to a Plexiglas support. Drying is completed at 80 C for 20 hr. The pyramids can then be sectioned to produce thick sections with a steel knife or to produce semi- or ultrathin sections with a glass knife. A 10% paraldehyde solution is used to mount the light microscopy sections on a slide heated on a hot plate to 80 C; these can be treated with the same techniques used with paraffin sections. The results are of high quality. Semithin sections of tissues fixed for electron microscopy can be stained directly after mounting, or by a wider range of stains once the polystyrene has been removed by organic solvents. In electron microscopy, the ultrathin sections obtained with the usual techniques are highly electron beam-resistant and given acceptable results.     

A Method for Histological Examination of Undecalcified Teeth

A method is presented for histological examination of undecalcified ground sections of tooth roots affected with periodontal disease. The roots were placed in Karnovsky's fixative overnight, postfixed in 2% buffered osmic acid, and dehydrated in an ascending series of ethanol. The specimens were then infiltrated with propylene-oxide and Epon-Araldite resin, embedded in Epon-Araldite, and sections were prepared using a cutting and grinding system. The resulting ground sections were 8-12 μm thick. The sections were allowed to air dry at room temperature. When thoroughly dried, a coverglass was applied using resinous mounting medium DPX. The specimens were examined by phase-contrast microscopy. The method is useful for simultaneous examination of mineralized dental tissue and bacterial morphotypes covering the root surface of teeth involved with periodontal disease.     

A Method for Histological Examination of Undecalcified Teeth

A method is presented for histological examination of undecalcified ground sections of tooth roots affected with periodontal disease. The roots were placed in Karnovsky's fixative overnight, postfixed in 2% buffered osmic acid, and dehydrated in an ascending series of ethanol. The specimens were then infiltrated with propylene-oxide and Epon-Araldite resin, embedded in Epon-Araldite, and sections were prepared using a cutting and grinding system. The resulting ground sections were 8-12 μm thick. The sections were allowed to air dry at room temperature. When thoroughly dried, a coverglass was applied using resinous mounting medium DPX. The specimens were examined by phase-contrast microscopy. The method is useful for simultaneous examination of mineralized dental tissue and bacterial morphotypes covering the root surface of teeth involved with periodontal disease.     

Optimization of red light-induced elongation in Avena coleoptile sections and properties of the phytochrome-mediated growth response*

Abstract Optimal conditions for studying the elongation response to a 1 mmol m^?2, 2-min pulse of red light in subapical coleoptile sections from dark-grown oat (Avena sativa L. ev. Lodi) seedlings have been determined. A technique for obtaining standard-length coleoptile sections without exposing either seedlings or sections to any light has been developed, and is described. The optimal conditions found were: sampling time, 12 h after irradiation; buffer conditions, 5 mol m^?3 potassium phosphate with 5% (w/v) sucrose (pH 5.9). The optima were determined by obtaining the time course for light-induced growth under various conditions. The red light-induced growth response is linear until 12 h after irradiation, when it undergoes an interruption. Optimal incubation conditions were determined by varying the buffer contents systematically and measuring the responses at the optimal lime determined. The results indicate a distinct difference between auxin-induced and light-induced growth responses. Even with variations of basal growth rate and several incubation conditions, the red light-induced elongation appears to be of a constant magnitude, to persist for a constant time period. and to exhibit a constant lag period between irradiation and the onset of response. The use of sections that were produced and handled in complete darkness yielded an unusual response to fusicoccin. A linear, high growth rate in response to I mmol m^?3 FC was observed for more than 12 h, both in the irradiated sections and in the dark controls.     

An Ultraviolet-Schiff Reaction for Unsaturated Lipids

Tissues are fixed 12-18 hr in cold, neutral, 10% aqueous formalin, sectioned on a freezing microtome and the sections placed in a shallow, open dish of water under an ultraviolet light source. Sections are then treated with Schiff's reagent for 15 min, rinsed in 3 changes of sulfurous acid (3 min in each) and in distilled water and mounted in an aqueous mounting medium. The time of irradiation necessary to produce a maximum reaction is determined empirically. The magenta color indicating the site of unsaturated lipids fades and runs in many preparations in a few days. Evidence is presented that this reaction is most likely the histochemical equivalent of an iodine number determination.