Dry,High Resolution Autoradiography

Microtomed sections of freeze-dried, paraffin-embedded tissues are placed on pieces of thin sheet-Teflon backed by a felt pad. The sections are then pressure-mounted on dry photographic emulsion. After suitable exposure, the sections are firmly cemented to the emulsion with 0.45% cellulose acetate in a 10:1 mixture of 2-butanone and acetone. This prevents the specimens from falling off or moving during photographic processing, though the tissue can be stained through the cellulose acetate binder. The method has been tested with tissues containing tritium-labelled DNA, and it produced resolution comparable to that obtained with standard liquid emulsion or stripping film techniques.     

Ultrastructural autometallography: a method for silver amplification of catalytic metals

The autometallographic technique involves application of a silver bromide-containing emulsion on the surface of ultrathin sections placed on grids that are subsequently exposed to a photographic developer. In tissue sections from animals treated intravitally with gold, silver, or mercury compounds, accumulations of the metals are visualized by autometallography and can be used for quantitative studies. After amplification, sections can be stained with lead citrate and uranyl acetate. Using autometallography, particles of colloidal gold dispersed in a film of gelatin showed a time-dependent growth and were gradually amplified up to 3.5-fold after 15 min of development. Hence the method may prove useful tracing colloidal gold particles in sections with low particle density, and be a powerful tool for revealing metals in biological tissues.     

Histological Processing in Autoradiography: Loss of Radioactivity

Histological methods suitable for use in autoradiographic technics are described. An investigation has been carried out on the amount of activity lost from rat and human tissues during fixation and dehydration. Losses in the processing fluids varied from 25% to 90% of the initial activity for radioactive phosphorus and 4% to 20% for radioactive iodine in various fixatives.

The care necessary in handling sections if distribution of total activity is being studied is emphasized and floating on absolute alcohol is suggested as an alternative to warm mercury. Various procedures for staining sections before application of photographic emulsion and after developing are discussed. Ehrlich's hematoxylin applied regressively has given good results and eosin has been used successfully as a counterstain. Orth's lithium carmine is resistant to photographic developer and also Feulgen's stain counterstained with fast green can be used before covering the slides with photographic emulsion.     

Radioautography of Histologic Sections of Human Testicular Tissue

Two techniques suitable for qualitative radioautographic analysis of histologic sections of human testicular tissue are described. In one, deparaffinized wet slides are coated with photographic emulsion resulting in significant improvement in preservation of histologic quality of the tissue section. In the second procedure stained and processed slides are coated with a thin layer of H.S.R. prior to coating with photographic emulsion. This procedure allows excellent preservation of the stained tissue section and also enables visualization of the reactive cell and its radioautographic image at two different focal planes. The techniques can be applied with equal advantage to histologic preparations of other tissues.     

A method for preparing whole-body sections suitable for autoradiographic, histological and histochemical studies

A method for the preparation of whole-body sections suitable for autoradiographic and histochemical study is described. Radioactive calcium chloride or [14C]proline was injected into the abdominal cavity of a rat. Thirty-five minutes after injection of calcium chloride or 40 min after injection of proline the rat was frozen in a mixture of hexane and solid carbon dioxide and blocked in 5% sodium carboxymethyl cellulose. The carboxymethyl cellulose block was trimmed and a piece of copy paper was attached to the surface of the block with cellulose tape. Cryotome sections cut from the block were transferred from the paper to a glass slide coated with synthetic rubber adhesive. For whole-body autoradiography, sections were freeze-dried for 2 days and then placed against X-ray film. For light microscopic autoradiography, the freeze-dried sections were covered with a dried film of photographic emulsion. For histochemical use, the sections were fixed by raising the temperature to 4 C after immersion in 100% ethanol below -10 C. For histological observation, sections were postfixed with 2.5% glutaraldehyde and stained. Whole-body and light microscopic autoradiographs showed that sections so prepared could be used for the demonstration of soluble substances in whole-body sections and for detailed autoradiography at the light microscopic level, and the stained sections could be used for histological and histochemical studies.     

Contrasting of Lowicryl K4M thin sections

Summary A method is presented for increasing the contrast of cellular structures on ultrathin sections from tissues embedded in Lowicryl K4M. The method, designated UA/MC adsorption staining, is based on the uranyl acetate/methyl cellulose staining of thawed cryosections. Ultrathin Lowicryl K4M sections were exposed to a uranyl acetate/methyl cellulose solution and the excess solution was removed with filter paper, leaving the remainder to air dry on the section. Sections on the grids were then directly observed in the electron microscope. Parameters such as methyl cellulose and uranyl acetate concentrations, duration of staining, temperature and pH were all assessed for their effect on subsequent contrast formation. Conditions were achieved which yielded intense contrast of cellular membranes, basement membranes and extracellular matrix components usually not apparent in Lowicryl K4M thin sections routinely counter-stained with uranyl acetate and lead acetate. The enhancement of the contrast of these structures does not obscure colloidal gold particles used for immunocytochemistry or lectin labeling, thus making the UA/MC adsorption staining method useful for increasing membrane contrast in routine post-embedding immuno- and lectin cytochemistry on Lowicryl K4M thin sections.     

Contrasting of Lowicryl K4M thin sections.

A method is presented for increasing the contrast of cellular structures on ultrathin sections from tissues embedded in Lowicryl K4M. The method, designated UA/MC adsorption staining, is based on the uranyl acetate/methyl cellulose staining of thawed cryosections. Ultrathin Lowicryl K4M sections were exposed to a uranyl acetate/methyl cellulose solution and the excess solution was removed with filter paper, leaving the remainder to air dry on the section. Sections on the grids were then directly observed in the electron microscope. Parameters such as methyl cellulose and uranyl acetate concentrations, duration of staining, temperature and pH were all assessed for their effect on subsequent contrast formation. Conditions were achieved which yielded intense contrast of cellular membranes, basement membranes and extracellular matrix components usually not apparent in Lowicryl K4M thin sections routinely counter-stained with uranyl acetate and lead acetate. The enhancement of the contrast of these structures does not obscure colloidal gold particles used for immunocytochemistry or lectin labeling, thus making the UA/MC adsorption staining method useful for increasing membrane contrast in routine post-embedding immuno- and lectin cytochemistry on Lowicryl K4M thin sections.     

The Membrane Method of Electron Microscope Autoradiography

Thin sections of methacrylate and Araldite embedded tissues labelled with radioactive isotopes were transferred with a wire loop or brush from the knife edge onto thin formvar membranes which covered 7 mm holes in 76 × 25 × 1.5 mm or 76 × 38 × 1.5 mm plastic slides. To facilitate the mounting of sections, a platform supported the plastic slides close to the ultramicrotome knife. Photographic emulsion diluted 1:5 or 1:10 with water was applied with a pipette to the upper surface of each formvar membrane to cover the mounted sections. Excess emulsion was drained off and the remaining thin film was dried on a warm plate at 45 C to produce a uniform layer over the sections. After storing in the dark for several weeks, preparations were processed in photographic solutions and washed, and sometimes stained, before applying electron microscope grids to the underside of each formvar membrane. To detach each grid with its adherent formvar, section and emulsion, the membrane was pierced around the perimeter of the grid. Grain counts made over nuclei of cells labelled with tritiated thymidine indicate that emulsion is uniformly distributed over each section and that quantitative comparison is possible between labelled areas.     

Autometallography

Summary The autometallographic procedure represents a new technique that can substitute for the normal methods of physical development (PD). The physical developer (a solution of reducing substance, silver salt and protection colloid) is replaced by a photographic emulsion and chemical developer. Accumulations of gold, silver, metal sulphides and metal selenides can be amplified by the present technique.Tissue sections placed on glass slides are covered by a silver bromide containing emulsion, dried and exposed to a chemical developer. After development the emulsion is either removed or cleared and the sections are counterstained and embedded.The autometallographic procedure can also be applied to ultrathin sections.     

A Method for Preparing Whole-Body Sections Suitable for Autoradiographic, Histological and Histochemical Studies

A method for the preparation of whole-body sections suitable for autoradiographic and histochemical study is described. Radioactive calcium chloride or [¹⁴Clproline was injected into the abdominal cavity of a rat. Thirty-five minutes after injection of calcium chloride or 40 min after injection of proline the rat was frozen in a mixture of hexane and solid carbon dioxide and blocked in 5% sodium carboxymethyl Cellulose. The carboxymethyl cellulose block was trimmed and a piece of copy paper was attached to the surface of the block with cellulose tape. Cryotome sections cut from the block were transferred from the paper to a glass slide coated with synthetic rubber adhesive. For wholebody autoradiography, sections were freeze-dried for 2 days and then placed against X-ray film. For light microscopic autoradiography, the freeze-dried sections were covered with a dried film of photographic emulsion. For histochemical use, the sections were fixed by raising the temperature to 4 C after immersion in 100% ethanol below -10 C. For histological observation, sections were postfixed with 2.5% glutaraldehyde and stained. Wholebody and light microscopic antoradiographs showed that sections so prepared could be used for the demonstration of soluble substances in wholebody sections and for detailed autoradiography at the light microscopic level, and the stained sections could be used for histological and histochemical studies.     

An Artifact Of Liquid Emulsion Autoradiography

The localization of ³H-opiatcs in the myenteric plexus of the guinea pig ileum is subject to systematic artifact when stretch preparations of the myenteric plexus are dipped into liquid Kodak NTB-3 emulsion for autoradiography. The cause of the artifact was determined to be a discontinuous distribution, or retraction, of emulsion over plexuses. The apposition of frozen freeze-dried ilial sections to dried photographic emulsion avoids this source of error.     

Pyronin Y For Staining Stripped Autoradiographs Prepared from Plastic Embedded Sections of Rat Tissues Containing Plutonium

Autoradiography prepared by the stripping film technique from 1 μm sections of semithin plastic embedded liver and bone tissues were poststained for examination with a 1% pyronin Y solution. The use of this dye avoids heating the tissue section and the overlying photographic emulsion. It also allows the staining of the tissue section without excessive uptake of the stain by the gelatin of the stripping film.     

Stains Compatible with Dipping Radioautography

Paraffin sections of 13 different kinds of mouse tissues, containing tritiated thymidine, were used to test stains applied either before or after application of the nuclear emulsion by dipping. Criteria used to determine compatibility were good histological definition with moderate gelatin coloration, sharp contrast to silver granules and no artifact or bleaching. Stains which worked best when applied prior to dipping included Feulgen-fast green, chronium hematoxylin-phloxine, and aldehyde fuchsin-PAS. Stains which worked best when performed after photographic development included celestin blue-Mayer's haemalum, metanil yellow-iron hematoxylin, lithium carmine-picric acid, Weigert acid-iron hematoxylin, alum cochineal, methyl green-pyronin, indigo carmine-picric acid, methylene blue-azure A, toluidine blue, Nissl and Cason. “Combination” stains which worked well when tissues were partially stained before dipping and completed after development included trichrome-PAS, luxol fast blue-PAS, hematoxylin-eosin, and aniline blue-carbol fuchsin.     

Application of white cellulose acetate sheets on fossil wood investigation

Generally, transparent cellulose acetate sheets as a peel technique material are used in the identification of fossils, whereas white cellulose acetate sheets as a biochemistry technique material are applied in serum protein electrophoresis (SPE). Here we report the application of white cellulose acetate sheets for identifying a polished fossil wood from the Upper Mesozoic of West Liaoning, China. Based on the characters of transverse, radial, and tangential sections, the fossil wood is ascribed to a taxon of Protoglyptostroboxylon sp. Compared with transparent cellulose acetate sheets, white cellulose acetate sheets not only provide the similar information as that of the former, but also are more easily acquired in the Chinese market than the former. Because peel technique supported by white cellulose acetate sheets has the advantages of simple, time-saving, safe, reliable, and practical operation with lower material loss, it is a very good choice for the polished fossil wood investigation in labs, museums, geological parks, and handicraft shops. It is also a convenient approach to training students to learn the anatomic structure of fossil wood.     

Double Emulsion Autoradiography for Identifying Tritium-Labelled cells in sections

The sensitivity of tissue autoradiography can be doubled and the number of false negative cells nearly eliminated by interposing thin tissue sections between two layers of photographic emulsion. A mouse was given 50 μc of tritiated thymidine (SA 2,500 c/M) intraperitoneally and killed 1.5 hr later. A portion of the small bowel was removed, fixed and embedded in methacrylate in the usual way. Sections 2 μ thick were cut and allowed to flatten on water at 40° C. Some sections were used to make conventional single emulsion auto-radiographs and other sections were interposed between two layers of emulsion by first coating slides with NTB 3 emulsion, picking up the sections from a water bath at 18° C, drying, soaking 1 min in benzene, drying, and then dipping again in NTB 3 emulsion. They were exposed at 4° C in a low humidity, 100% CO₂ atmosphere for 10 days, developed and covered in the usual way. There was an average of 20.16 ± 1.4 grains per labelled cell in the double emulsion group compared with 10.6 ± 0.9 grains in the single emulsion group. In the double emulsion autoradiographs there were 55.1 ± 1.65 labelled cells per unit area as compared with 39.8 2 2.0 in the single emulsion group.     

Biodeterioration of cinematographic cellulose triacetate by Sphingomonas paucimobilis using indirect impedance and chemiluminescence techniques

The bacterium Sphingomonas paucimobilis, isolated from cinematographic films in an earlier project, was able to biodeteriorate the cellulose triacetate material (acetylation degree of 2.7). Film colonization was monitored by the indirect impedance technique and the production of carbon dioxide. The presence of ruggedness and irregularities on the surface of the film, produced when the plasticizer was extracted, accelerated the biodeterioration of the material. In contrast, cinematographic films with their layered structure made of photographic gelatine emulsion were protected and no colonization was observed. The cinematographic film without photographic emulsion reached a 5% level of biodeterioration after six weeks of incubation, confirming the possibility of biodeterioration of archival cinematographic materials if conservation conditions are not adequate. Through viscosity measurements, a decrease in relative viscosity was observed on the biodeteriorated sample, with respect to the original material, confirming a lower molecular weight as a result of enzymatic activity of S. paucimobilis. Also, using chemiluminescence, the film surface oxidation on the biodeteriorated sample was observed. This technique was very sensitive in detecting material oxidation by reactive oxygen species generated by bacteria, and could be useful to study microbiological biodeterioration in polymeric materials.     

Fluorometric assay for polyamines in urine and tissues using electrophoresis on Titan III cellulose acetate

A simple, rapid assay method for polyamines (putrescine, spermidine, and spermine) in urine and tissues using electrophoresis on Titan III cellulose acetate was developed. In this procedure, polyamines are preliminarily extracted from a hydrolysate of urine or from supernatants of tissue homogenates by use of a Bio-Rex 70 minicolumn. After electrophoretic separation, polyamines are fluorometrically detected by the reaction with o-phthalaldehyde and 2-mercaptoethanol. Six extracts and two external standards of polyamines can be separated and detected in 11 min on a cellulose acetate strip. This method permits the determination of polyamines in a range of 0.1 mM (25 pmol) to 1.0 mM (250 pmol).     

Locating Iodine in Tissues Autographically, Especially after Fixation by Freezing and Drying

The ability of radioactive elements to affect photographic emulsions enables the detection of radioactive iodine in the thyroid. By placing unstained histological sections of a thyroid (from an animal treated with radioactive iodine) in contact with the gelatin side of medium lantern slide plates, each accumulation of radioactive iodine in the section affects the photographic plate. After exposures prolonged for several days to several weeks depending on the amount of radioactivity in the tissues, the plate is developed and fixed by routine photographic methods. The histological section is stained and may be compared under the microscope to the reactions on the plate or “autographs”.

In an attempt to detect the location of the inorganic iodine which is displaced during fixation and embedding by ordinary methods because of its solubility, a simplified freezing-drying technic for fixation was devised which, at least with the thyroid, yielded well fixed sections. The quick freezing was obtained with acetone-dry-ice mixtures; and the drying was performed at -25° to -30° C. Preliminary addition of paraffin to the tube in which the drying was performed made possible the inclusion in vacuum by heating the tube when drying was completed. The tissue could then be sectioned at 10ju on the microtome. The slides were placed on photographic plates for detection of radioactive iodine as indicated above. Before staining, the sections were treated with absolute alcohol for denaturation of the proteins.     

Tannic acid-metal salt sequences for light and electron microscopic localization of complex carbohydrates.

Use of tannic acid (TA), in sequence with ferric chloride, uranyl acetate or gold chloride resulted in staining of selective but sometimes different sites in paraffin sections. TA-uranyl acetate of TA-ferric chloride stained sites rich in complex carbohydrates, wherease TA-gold chloride stained the collagen of various connective tissues different shades of red-purple to gray-black. Applied to epoxy-embedded thin sections of tissues fixed with glutaraldehyde and not post-osmicated, TA-uranyl acetate and TA-ferric chloride imparted density to subcellular sites known to contain a high concentration of mucosubstances, such as secretory granules and cisternae of the Golgi complex of certain cells. TA-gold chloride proved unsatisfactory for ultracytochemistry because of its tendency to form globular precipitates on thin sections. The effect of blockage procedures at the light microscopic level indicated that vicinal glycols are not required for binding of TA to tissue sites. Electrostatic forces were shown to be of minimal significance, whereas hydrogen bonding appeared to play a part in both TA-tissue and TA-metal binding mechanisms.     

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.