Distortion-Free Mounting of Frozen Sections by Handling on Paper Supports

Frozen sections are cut from the specimen until the level of interest is reached. A strip of paper (bond or similar writing paper) 5 cm long and about 1 cm wider than the specimen is moistened with water, closely applied to the surface of the specimen and frozen onto it. As the section is cut, the end of the paper strip above the knife is grasped and turned backward toward the other end of the strip. The section is then applied to an albumenized glass slide, firmed and thawed by finger pressure, and the paper removed. After thorough drying, the preparation is ready for further processing. When properly performed, mounted sections whose details coincide to those of the uncut block can be obtained. If thawing on the knife is prevented by cooling the knife, the technic can be performed without a cryostat, but it is also feasible to use a cryostat if a favorable temperature is maintained. The authors obtained 30 μ serial sections, suitable for stereotaxic mapping, from rabbit brain by this method.     

A semiautomatic instrument for the radioautographic coating technique.

By means of a mechanical coating instrument a fast, simple method to coat specimens with liquid nuclear track emulsion has been devised for quantitative light and electron microscopic radioautography. In both cases, the section is mounted on a glass slide. After the vertically held slide has been immersed in the melted emulsion, the instrument withdraws it at a slow, constant speed. As a result, the specimen is coated with a thin, uniform emulsion layer composed of homogeneously distributed silver bromide crystals. The thickness of the emulsion coat may be standardized by selection of an optimal combination of emulsion dilution, temperature and withdrawal speed.     

A simple method for preparing thin (10 microM) histological sections of undecalcified plastic embedded bone with implants

A simple method for preparing undecalcified thin sections of bone with implants has been developed. After exposing a surface of bone and implant in a plastic block by sawing thick sections, the surface is stained prior to making a thin section. A glass coverslip is affixed with a thin layer of cement to the stained surface to stabilize the tissue and implant during sectioning. A mixture of glycerine and water is used as a coolant and lubricant. The orientation in situ is preserved allowing demonstration of bone architecture and cells, and the tissue-implant interface.     

A Simple Method for Preparing Thin (10 μm) Histological Sections of Undecalcified Plastic Embedded Bone with Implants

A simple method for preparing undecalcified thin sections of bone with implants has been developed. After exposing a surface of bone and implant in a plastic block by sawing thick sections, the surface is stained prior to making a thin section. A glass coverslip is affixed with a thin layer of cement to the stained surface to stabilize the tissue and implant during sectioning. A mixture of glycerine and water is used as a coolant and lubricant. The orientation in situ is preserved allowing demonstration of bone architecture and cells, and the tissue-implant interface.     

Paraffin-Beeswax-Stearic Acid: An Embedding Mass for thin Sections

It is possible to cut 1-3 μ sections of rat tissue after passing it through ethanol and chloroform and infiltrating in a wax mixture consisting of 95% Shell Chemical Co. paraffin (MP 125-130° F) and 5% commercial beeswax (clarified by boiling with water and decanting), to which is finally added 10% of technical stearic acid (melted, and clarified by filtration). A potential disadvantage is the slow expansion of the section on the water flotation bath, due to a surface spreading effect of the contained stearic acid. This expansion can be minimised as follows: by adding 0.5% concentration of a secondary alkyl-aryl sulfonate detergent, such as Shell Chemical Co. Teepol, to the notation water; by keeping the temperature of the water at 45° C; by making sure that no section is left on the water for more than 30 sec; and by drying on chemically cleaned slides for 4-18 hr at 45° C., controlled to ±2°. The spreading effect is advantageous in reticulo-endothelial studies, where overlap of cells needs to be reduced to a minimum, and thinly layered cytoplasm expanded.     

Autoradiography of Water-Diffusible Substances in Sections of Whole Baby Rats

Rats, 7 days postnatal which had been injected with a radioactive nuclide, were quick frozen and sectioned in the frozen state. An adhesive cellulose tape (Sellotape) was used to support the section during cutting, through freeze-drying, and attaching to slides. Dehydration of the frozen sections consisted of 1 hr in a chilled desiccator containing silica gel, then at reduced pressure of 2-3 mm Hg until quite dry. The exposed side of the section was sprayed with celloidin dissolved in amyl acetate and allowed to dry. This side of the section was attached to a slide, previously coated with 1% gelatin containing 0.1% chrome alum, by means of an adhesive consisting of 4% gelatin and 5% formalin in 60% glycerol. In applying this adhesive it is mandatory that a border of about 3 mm of bare glass be left outside the adhesive, to allow intimate contact between the sticky side of the tape and the glass. The adhesive was allowed to set for 20 min, the slide immersed in water lor 50 sec, and the cellulose layer of the tape peeled off. The rubber base from the tape was removed with chloroform, the slide dried, and the exposed surface of the section coated with celloidin in amyl acetate, by dipping. After this treatment, the slides could be coated by dipping in autoradiographic emulsion without affecting water-soluble radioactive substances in the tissue.     

Producing Frozen Sections of Calcified Bone

We describe a procedure for the rapid production and maintenance of fresh frozen bone biopsies which can be used for a variety of immunohistochemical techniques. Within 5 min of excision. tissue is placed in cold 5% polyvinyl alcohol, surrounded with 3% carboxymethylcel-lulose in a hand made aluminum foil embedding mold and frozen by immersion in an absolute ethanol/dry ice slurry at -70 C. The tissue block is attached to the specimen stub with cryocom-pound and installed in a -32 C cryostat whose tungsten carbide D profile knife is maintained at -70 C. Automatic controls are set at a slow cutting speed and the “sectioning window” is adjusted to fit the biopsy size. Knife angle, thickness gauge and antiroll bar are changed to produce a complete section. The block face is smoothly “papered” with a polyvinylpyrrolidone (PVP) impregnated Ross lens paper strip. A single section is cut and positioned on a sequentially numbered, acid cleaned, double dipped chrome-alum gelatin coated slide: adhesion is aided by “press-blotting” with bibulous paper. Sections are stored at -20 C or in a desiccator at room temperature. A brief fixation followed by removal of the water soluble PVP and lens paper generates fresh frozen bone sections suitable for further analysis.     

An On-the-Slide Procedure for Microscopic Observation During Decalcification of Sections

A thin section of tooth was cemented to a microscope slide with Kodak 910 Adhesive and ground down to a thickness of approximately 6 μ The section was covered with a thin layer of dental impression material by squeezing it out under cellophane, using pressure on a second microscope slide. A channel was cut in the impression material exposing a portion of the tooth substance. The channel was covered with a coverglass enabling decalcifying solutions to be passed over the exposed area of the tooth and the section to be observed at the same time. This procedure enables sections of calcified tissue to be decalcified very slowly and the histological changes to be observed microscopically.     

Improved diethylene glycol distearate embedding wax

Diethylene glycol distearate wax and cellulose caprate resin, 4:1 respectively by weight, were melted together at 75 C for five hours with occasional stirring. The resin tempered the extreme brittleness of the wax without softening it, and raised the melting point only one degree to 50 C. Fixed plant tissues were dehydrated in ethanol, cleared in xylene, and infiltrated with wax. Modified diethylene glycol distearate was easier to trim and shape, and formed flat sections more consistently than the pure wax. Sections were cut singly on Ralph knives with attached water pools on an ultramicrotome. Sectionability was excellent at 2-3 micrometers, variable at 1.0 micrometer, but impossible at 0.5 micrometer. Sections were transferred onto water drops on slides, dried, dewaxed, stained, and coverglasses applied as in the paraffin method. Histological feature of plant tissues were much sharper in modified diethylene glycol distearate sections than in paraffin sections, and were similar to plastic sections.     

Using Scrapings from Formalin-Fixed Tissues to Diagnose Leptospirosis by Fluorescent-Antibody Techniques

Small specimens of formalin-fixed tissues approximatey 1 × 1 × 0.2 cm were cut from the suspect specimen. Several clean microscope slides were dipped in 1% aqueous gelatin and air-dried or dried on a slide warmer. Each tissue specimen was washed in running tap water for 2-5 min and then lightly scraped with a straight knife blade, cutting edge perpendicular to the surface of the specimen. The scrapings were allowed to build up and cling to the knife blade, which was then turned so that the broad surface contacted the slide; thus, the scrapings could be smeared onto the slide in a single motion. Sufficient pressure was applied to embed the tissue fragments in the gelatin coating. Smears, dried in air or on a slide warmer, were stained immediately by a standard direct or indirect technique to detect fluorescein-labeled antigens. This scraping method, adapted to the study of leptospirosis by fluorescent-antibody technique, could reduce the need for cryostat-cut tissues and facilitate the observation of individual leptospires.     

Preparation of Thin Undecalcified Bone Sections by Rapid Manual Method

Sections from 3 μ to over 100 μ thick of fresh, unfixed, unembedded, unde-calcified and undehydrated bone are made by grinding 1 to 2 mm slabs of the desired orientation on waterproof carborundum abrasive paper, grit No. 320, 360 or 400. The manner of controlling the section is the crux of the technique. The section is held by wrapping a fresh strip of sandpaper around a 3″ × 1″ slide and accomplishing the grinding on a used piece of paper. The abrasive points on the fresh paper effectively prevent the section from sliding off the slide. The specimen is kept wet with water during the entire procedure. Sections are then stained, and excess surface stain can be ground off in similar fashion. After washing in dilute detergent solution to remove adherent derbis, the section is air dried and mounted in any nonacidifying resinous media. The method is suitable for wood and for fruit pits also.     

Preparation of Thin Undecalcified Bone Sections by Rapid Manual Method

Sections from 3 μ to over 100 μ thick of fresh, unfixed, unembedded, unde-calcified and undehydrated bone are made by grinding 1 to 2 mm slabs of the desired orientation on waterproof carborundum abrasive paper, grit No. 320, 360 or 400. The manner of controlling the section is the crux of the technique. The section is held by wrapping a fresh strip of sandpaper around a 3' × 1' slide and accomplishing the grinding on a used piece of paper. The abrasive points on the fresh paper effectively prevent the section from sliding off the slide. The specimen is kept wet with water during the entire procedure. Sections are then stained, and excess surface stain can be ground off in similar fashion. After washing in dilute detergent solution to remove adherent derbis, the section is air dried and mounted in any nonacidifying resinous media. The method is suitable for wood and for fruit pits also.     

Stain Historadiography

Fresh bone specimens were dehydrated in acetone and embedded in Ward's Bio-Plastic. Sections 10-15μ thick were cut with a special bone-cutting microtome and subjected first to radiography and then stained with safranin-fast green. The radiograph was made with a Machlett AEG-50-A X-ray tube on a fine-grained, spectroscopic plate; which, after processing, was mounted (dry) on a glass slide adjacent to the stained specimen. By these means, it was possible to make a correlated study of the calcium-bearing parts of the tissue and determine accurately their relationship to the bone itself. The method serves well for investigations of growing bone and for bone that is undergoing pathological involution. It has been named “Stain Historadiography” because it combines a stained specimen with its radiograph.     

Epoxy Resin Embedding in Contrast Radioautography of Bones and Teeth

Contrast, or low-resolution, radioautographs of teeth and large specimens of bone are made from plane, polished surfaces of such material embedded in plastic. The specimen is cut with a motor-driven circular saw, fixed, dehydrated, and defatted with anhydrous acetone and ether. It is then infiltrated with a mixture of epoxy resin and reactive hardener. The resin-infiltrated specimen is placed in an easily constructed mold of aluminum and Lucite. Polymerization is complete in 4-6 hr. The surface of the specimen is exposed by machining and/or abrading. The prepared surface is apposed to an X-ray type emulsion to produce a radioautograph. The resolution obtainable is estimated to be 100-200 β.     

A Simple Holder for Efficient Mass Staining of Thin Sections for Electron Microscopy

An inexpensive simply-constructed gridholder for reproducible staining of sections and storage of grids is made of a platelet of dental wax (Ladd No. 2460, or Belladi, rosa, normal) mounted on a glass slide. The grids are simply inserted perpendicularly into the wax and are held securely at their edges by the slightly sticky wax. Staining solutions may be applied directly to the standing grids or the gridholder may be inverted in a trough containing the staining solution, thus avoiding excessive contact with the air. Washing is carried out by dipping the gridholder in a series of beakers with distilled water or by flushing gently. The grids may be labeled directly on the slide and are therefore identified easily. The wax-gridholder eliminates excessive handling of the grids with tweezers not only during the staining procedure but as well as during storage and thus helps to prevent mechanical damage of the delicate sections mounted on the grids. Waxes other than those specified should not be used because of a tendency for particles to adhere to the grids, with the attendant possibility of column contamination.     

Staining Osteoid Seams in Thin Slabs of Undecalcified Trabecular Bone

For qualitative and quantitative study of osteoid seams in trabecular bone, 5-7 mm thick slabs were cut from the bodies of fresh, frozen, undecalcified human vertebrae. After washing out the bone marrow and soft tissue in a jet stream of water, the slabs were stained in 0.5% aqueous basic fuchsin for 30-40 hr at 18-20 C. The specimens were then trimmed by sawing off both overstained surfaces, to make a 2 mm slab which was submerged in 50% ethanol (2 or 3 changes of 10-30 min each), until the nonosteoid trabeculae became pale pink. The slab was allowed to dry in air. Osteoid seams are stained dark red and are well differentiated under a dissecting microscope with reflected illumination, either dry or immersed in water. This method permits the various types of trabculae to be separately studied in the same specimen     

Affixing Polyester Wax Sections to Glass Slides by Celloidin and Cellulose Acetate Applied in Sequence

Sections cut from material embedded in polyester wax can be firmly attached as follows: One drop of a 2% solution of celloidin in amyl acetate is smeared on clean slides, and sections taken from the floatation water onto these slides are dried at room temperature. After drying the slides are immersed in a 2% solution of cellulose acetate in acetone for 1 min, transferred directly to absolute ethanol, through 50% ethanol, and into water. Sections affixed by this method and stained by either hematoxylin-eosin or toluidine blue schedules do not loosen and have negligible background staining.     

The development of the cuticle in Phormium tenax

Summary As seen in the scanning electron microscope the surface wax of leaves of Phormium tenax L. consists of vertical, plate-like crystals. These increase in size and number and undergo a change in form during development. The abaxial surface has a dense covering of wax crystals, but none are present on the ridges over vascular tissues. Numerous papillae are found between these ridges in later stages of development. On the adaxial surface both wax crystals and papillae are present only around infrequent stomata.When viewed in section normal to the leaf surface the cuticle is first apparent as a thin, lamellate layer. Another layer containing a reticulum of electrondense material increases in thickness beneath the lamellae during development. This layer eventually becomes the most extensive component of the cuticle. Both the adaxial and abaxial cuticles show a similar pattern of development.     

Comparison between slide and flow cytophotometric DNA measurements in breast tumors

Nuclear DNA analysis was performed in 37 human mammary adenocarcinomas in order to elucidate the difficulties and pitfalls connected with the interpretation of DNA histograms obtained using different methodologic approaches. For each tumor, DNA profiles were obtained by means of slide microspectrophotometry on a fine needle aspirate, slide cytophotometry on a 4-micron histologic section and flow cytometry on a suspension prepared from a cube of fresh tissue. When the DNA histograms were interpreted according to criteria usually applied to discriminate low-grade malignant tumors from high-grade malignant tumors, some tumors classified as euploid by one method were classified as aneuploid by another method. The main reasons for this weak correlation seem to be in specimen preparation and in tumor cell representation within the specimen between the methods. Another reason is that slide and flow techniques exhibit different sensitivities for malignancy-associated nuclear DNA changes: minor alterations of the DNA content of the tumor stemlines seem to be more exactly reported by means of the flow technique whereas structural alterations of the nuclear chromatin seem to be more sensitively recorded by means of the slide technique. It is suggested that thorough control of each step of the various DNA analysis procedures and the use of information obtainable by slide and flow techniques taken together may significantly improve the prognostic value of DNA measurements.     

Direct Access to Plant Epicuticular Wax Crystals by a New Mechanical Isolation Method

A new method for the isolation of wax crystals from plant surfaces is presented. The wax-covered plant surface, e.g., a piece of a leaf or fruit, is brought into contact with a preparation liquid, e.g., glycerol or triethylene glycol, and cooled to ca. -100 degrees C. When the plant specimen is removed, the epicuticular wax remains embedded in the frozen liquid. After it warms up, the wax layer can be captured on appropriate carriers for further studies. This isolation method causes very little stress on the wax crystals; thus the shape and crystal structure are well preserved. In many cases it is possible, by choosing a preparation liquid with appropriate wettability, to isolate either the entire epicuticular wax layer or only discrete wax crystals without the underlying wax film. These crystals are well suited for electron diffraction studies by transmission electron microscopy and high resolution imaging by atomic force microscopy. The absence of intracuticular components and other impurities and the feasibility of the selective isolation of wax crystals enable improved chemical analysis and a more detailed study of their properties.