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.     

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.     

Autoradiography of Tracks from Beta-Particle Emitters in Tissues

Mounted paraffin sections, 2-4μ thick, ˙were stained, dehydrated, allowed to air dry, and given a thin coating of 1 % Plexi-glas solution in chloroform. The chloroform was allowed to evaporate completely in a dry atmosphere. An emulsion whose dried thickness was 100-150μ, was prepared from Ilford G5 type in gel form and glued to the section by means of a 15% solution of shellac in absolute alcohol. The surface of the emulsion was then cleaned with absolute ethyl alcohol, to remove the impermeable shellac layer. The exposure for radiation reaction was made at about 2°C and required, in the conditions of our experiment, about 24 hrs. The emulsions were processed by the “temperature-development method.” With the described procedure, autoradiographs have been obtained of various organs of albino rats, labeled with P³², S³⁵ and other radioisotopes, and very precise localizations of the origin of electron tracks was attempted. This technic has allowed the fixing and staining of the tissues by means of all the reagents commonly employed in histology, without any damage to the emulsion and the obtaining of good adhesion and minimum separation between specimen and emulsion, thus permitting reliable extrapolations of electron tracks. Due to the fact that the emulsion is fully sensitized when placed in contact with the preparation the limits of the exposure times were well defined. The uniform development at all depths of the emulsion achieved by the temperature-development method facilitated the work with fast electron tracks.     

Epon-Embedded Tissue Stained with Aldehyde-Fuchsin for Radioautography

Four-week-old Holtzman rats were injected intraperitoneally with 20 μCi ¹²⁵I. Six or eight weeks later, they were killed by intracardiac perfusion with glutaraldehyde; thyroid and adrenal glands were excised, postfixed in osmic acid, and embedded in Epon. Steps in the staining procedure of 0.5-1 μm thick sections are: oxidation in 0.3% potassium permanganate in 0.625% sulfuric acid, 2-5 min at 70 C; brief rinse; bleaching with 2.5% NaHSO₃, 4-5 min; brief r-utse; let dry completely; aldehydefuchsm, 15-20 min at 50 C; 95% alcohol; rinse in absolute alcohol; let dry completely. seaions were coated with Kodak NTB2 emulsion and exposed for 3 to 8 weeks. Results indicate that (1) tissues are well stained even after an 8-week exposure, (2) aldehyde-fuchsin pduces no chemographic effect, and (3) structures underneath the emulsion are easily identified.     

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.     

Demonstration of Insulin in Mammalian Pancreas by the Fluorescent Antibody Method

A method for the staining of mammalian pancreatic islets with a specific fluorescent antibody to insulin using frozen-dried sections rather than those cut with a cryostat is described. Sections were cut on a Servall microtome at 1-2 μ or when embedded in paraffin they were cut at 4-5 μ on a conventional rotary microtome. The latter procedure greatly simplified the search for islets.     

Preparation of Large Epoxy Sections for Light Microscopy as an Adjunct to Fine-Structure Studies

Tissue blocks 2 × 2 × 0.4 cm were fixed 6-24 hr in phosphate-buffered 5% glutaraldehyde then sliced to 2 × 2 × 0.1 cm and soaked in 0.1 phosphate-buffer (pH 7.3) for at least 12 hr. Fixation was continued for 2 hr in phosphate-buffered 1-2% OsO₄. The slices were dehydrated, infiltrated with Araldite, and embedded in flat-bottomed plastic molds. Sectioning at 1-8 μ with a sliding microtome was facilitated by addition of 10% dibutylphthalate to the standard epoxy mixture. The sections were spread on warm 1% gelatin and attached to glass slides by drying, baking at 60 C, fixing in 10% formalin or 5% glutaraldehyde and baking again. Sections were mordanted in 5% KMnO₄ (5 min), bleached with 5% oxalic acid (5 min) and neutralized in 1% Li₂CO₃ (1 min). Several stains could then be applied: azure B, toluidine blue, azure B-malachite green, Stirling's gentian violet, MacCallum's stain (modified), tribasic stain (modified) and phosphotungstic acid-hematoxylin. Nuclei, mitochondria, specific granules, elastic tissue or collagen were selectively emphasized by appropriate choice of staining procedures, and cytologic detail in 1-3 μ sections was superior to that shown by conventional methods. Selected areas from adjacent 4-8 μ sections could be re-embedded for ultramicrotomy and electron microscopy.     

Whole joint Embedding in Polymethylmethacrylate: a Method for Preparing Intact Musculoskeletal Organ Systems for Histomorphology and 3-D Reconstruction

Large and medium size undecalcined joints were embedded in methylmethacrylate resin. Sections of 600 μm prepared from polymethylmethacrylate blocks show minimal distortion and are suitable for surface staining and three-dimensional reconstruction. The 5 μm sections prepared from these slabs retain good cytological detail. This method permits the examination of musculoskeletal organ systems at both macroscopic and microscopic levels.     

Emulsion-stabilizing properties of chitosan in the presence of whey protein isolate: Effect of the mixture ratio, ionic strength and pH

The emulsion-stabilizing properties of a chitosan preparation were compared as a function of the whey protein isolate/chitosan mixture ratio (WPI/CNI) and the ionic strength (μ), at pH 5.5 and 6.0. At both pH conditions, general decreases in emulsion stability towards charge neutralization flocculation and syneresis were observed at WPI/CNI > 5. This was particularly evident at pH 6.0, due to a lower surface net charge (lower electrostatic stabilization). In counterpart, when μ was increased, the higher load of chitosan at pH 6.0 produced higher stabilities (higher steric stabilization), in spite of comparable decreases of surface net charge at both pH conditions. The transition from soluble to insoluble protein–chitosan complex formation in mixtures at pH 6.0 and WPI/CNI > 5.0 was due to an emulsion destabilization towards syneresis, whereas soluble complex formation at pH 5.5 also produced syneresis. It showed that soluble protein–chitosan adsorbing complex formation prior homogenization is not essentially linked to emulsion stabilization.     

Hematoxylin Toluidine Blue-Phloxinate Staining of Glycol Methacrylate Sections of Retina and Other Tissues

For a detailed study of the developing chick retina a technique has been developed using glycol methacrylate embedding and a hematoxylin toluidine blue-phloxinate stain. After removal of the vitreous body, one half-segment of the eye is dehydrated through graded ethyl alcohols to 95%, infiltrated and embedded in glycol methacrylate, and sectioned at 2 μm. The sections are stained in alum hematoxylin and then in a mixture containing toluidine blue-phloxinate from a stock solution of the dye that has matured for 2-3 weeks. Differentiation is not required and there is only slight staining of the plastic matrix. The quality and clarity of the sections contrasts markedly with that of similarly stained 5 μm paraffin wax sections of the retina. This technique has also been applied to skin, spinal cord, dorsal root ganglia, pancreas and small intestine. The stained sections from these tissues have proved very useful in revealing structural components.     

Split Nucleoli as A Source of Error in Nerve Cell Counts

The number of nerve cells in a given ganglion or nucleus is usually determined by counting the nucleoli in serial sections. The possibility that nucleoli may split and appear in more than one section is recognized as a source of error. A determination of the value of this error was made as follows; from nodose ganglia of four cats were cut serial transverse sections in which the sections varied in thickness. Thus from one ganglion, four sections were cut at 12 μ, then six at 9μ, and eight at 6μ. The process was repeated over and over until the entire ganglion was sectioned. The other ganglia were sectioned similarly. After mounting and staining, separate counts were made of the nucleoli of each given ganglion from the sections of different thicknesses. If nucleoli split according to theoretical expectations, the percentage of nucleoli split in thick sections should be less than the percentage split in thinner sections and the counts based on the sections of different thicknesses should vary accordingly. The results obtained indicate that the counts from thin sections do not differ appreciably from counts from much thicker sections, i. e., the thickness of the sections does not affect the count. It is, therefore, concluded that no correction should be made for split nucleoli if the sections are around 10 μ in thickness and none but distinct and definite nucleoli are counted.     

The use of a fuel containing Chlorella vulgaris in a diesel engine

There is a need for sustainable fuels for diesel engines and fuels containing particles will function as a fuel in diesel engines. Some microalgae such as Chlorella vulgaris are unicellular and 5–10 μm in size, which is suitable for combining in an emulsion fuel. An emulsion consisting of transesterified rapeseed oil, a surfactant and a slurry of C. vulgaris was used as a fuel in an unmodified single cylinder diesel engine. The fuel consumption and emissions of this fuel was determined and although the carbon monoxide levels were higher the NO_x emission was lower than that of diesel.     

Thin Histological Sections Prepared from Large Thick Sections: a New Technique

A method is described for obtaining thin (1 μm) sections for light microscopy from large area thick (100 μm) sections of low viscosity nitrocellulose embedded specimens of human spinal osteoligamentous material.     

Marking Individual Nerve Cells Through Electrophoresis of Ferrocyanide from a Microelectrode

Microelectrodes filled with an aqueous mixture containing 0.5 M potassium ferrocyanide and 2.5 M KCl were used to electrophoretically mark single neurones in the snail brain. After a physiological experiment, 3-4 μa at 20 v were allowed to flow for 10-15 min and carry the ferrocyanide into the cell. Cells from 40 μ to 130 μ have been marked. There is no diffusion of the Prussian blue (formed by soaking 10-15 min in 1.1 M FeCl₃) outside the cell. The marked cell can be studied both in the whole brain and in sections. In many cases a length of axon is stained also, and it can be traced through successive sections of the brain.     

Pre-treatment of Caco-2 cells with zinc during the differentiation phase alters the kinetics of zinc uptake and transport(2)

The Caco-2 cell model was used to study the efficiency of absorption and endogenous excretion of zinc (Zn) regulated by dietary Zn concentration. Cells were seeded onto high pore-density membranes and maintained in medium supplemented with 10% FBS. After confluence, cells were treated with 5 or 25 μmol Zn/L for 7 d, and Zn uptake and transport were measured in both apical (AP) and basolateral (BL) directions by using ⁶⁵Zn. Similar cells were labeled with ⁶⁵Zn and the release of Zn to the AP and BL sides was measured. The AP uptake of Zn in cells exposed to 25 μmol Zn/L was slower (p < 0.05) than that in cells exposed to 5 μmol Zn/L. The AP to BL transport rate in the 25 μmol Zn/L group was only 40% (p < 0.05) of that in the 5 μM group. In contrast, the rate of BL Zn uptake was 4-fold higher in cells treated with 25 μmol Zn/L than in those treated with 5 μmol Zn/L (p < 0.05). The BL to AP transport rate was 2-fold higher in cells treated with 25 μmol Zn/L than in those treated with 5 μmol Zn/L (p < 0.05). Basolateral uptake was 6 to 25 times greater (p < 0.05) than AP uptake for cells treated with 5 and 25 μmol Zn/L, respectively. The rate of Zn release was enhanced about 4-fold (p < 0.05) by 25 μmol Zn/L treatment. Release to the BL side was 10 times greater than to the AP side. Zn-induced metallothionein (MT), thought to down-regulate AP to BL Zn transport, was 4-fold higher (p < 0.001) in the 25 μmol Zn/L group than in the 5 μM group, but the rate of BL Zn release was higher in cells treated with 25 μmol Zn/L than in those treated with 5 μmol Zn/L (p < 0.05). Induced changes in transport rates by media Zn concentrations could involve the up- and/or down-regulation of Zn influx and efflux proteins such as the ZIP and ZnT families of Zn transporters.     

Suggestions on the Preparation of Undecalcified Bone for Microradiography

In microradiography the thickness of the specimen usually governs the degree of discrete structural detail attainable. A cause of poor detail in the historadiography of bone sections thinner than 30 micra is distortion attributable to lack of uniform contact between the undecalciiied specimen and the photographic emulsion. The use of a strong but radio-lucent supporting membrane on which the section can be mounted is an approach to the solution of this difficulty. Cementing the polished section under pressure to a 2 μ nylon membrane mounted on a modified specimen ring produces a flat section in close contact with the film. By mounting microtome-cut sections of frozen-dried developing bone directly on a supporting film of a polyvinyl resin, histochemical staining as well as microradiography can be performed on the same section.     

Autoradiography of Mobile, C14-Labeled Herbicides in Sections of Leaf Tissue

Fresh leaf tissue containing a soluble, C¹⁴-labeled herbicide was mounted in cold 1% gelatin on a holder, quick frozen in a cryostat, and cross sectioned at 16 μ with single-edge, stainless steel razor blades. The sections were transferred (without thawing) to cold (—10 C) microscope slides which had been partly covered with double-coated Scotch tape #665. The tissue was freeze-dried in a vacuum desiccator at—20 C then secured to the tape with pressure. Autoradiography was accomplished in a darkroom by covering the slides with dry, nuclear track emulsion films. These films were made by dipping 2 inch diameter wire loops into liquid emulsion, letting the film dry, and applying it by blowing it as it was placed against the tissue. After a 19 day exposure in light-tight boxes at 25-27 C the preparations were processed in the usual manner. The method-was used successfully to trace the movement of soluble, C¹⁴-labeled herbicides in leaf tissue without the loss of labeling material or artifacts caused by its diffusion. High resolution autoradiograms with low backgrounds were obtained.     

Plastic Embedding of thick Celloidin Sections of nerve Tissue

A method is described for mounting Golgi-impregnated and Weigert-stained thick celloidin sections of brain and spinal cord in transparent plastic. Finished mounts have good optical properties and are suitable for macroscopic and microscopic observation. The durability of such preparations makes them superior to similar material prepared by the more conventional methods. Holes of suitable size were cut in matrices of 2.5 × 5 × 3/16 inches Plexiglas. Ward's Bio-plastic was used to form a base for the holes and also as the embedding medium for the sections. Plate glass formed a working substrate and gave a polished surface to the plastic base and later to the top of the preparation. For Golgi material (200μ) the celloidin was removed by dioxane. A dioxane-plastic bath preceded plastic embedding. For Weigert material (30-40μ) celloidin was not removed due to fragility of sections. Prior to plastic embedding, they were subjected first to benzol and then to a benzol-plastic bath.     

Improvements in Histological Techniques for Epoxy-Resin Embedded Bone Specimens

A procedure is presented in which some of the processing difficulties with fixation, embedding and cutting whole mouse bones and large bone pieces from other species are considered. The bone specimens are fixed in acetone or by a Karnovsky-formol-saline process which preserves intact endosteal surface-to-cortex layers. After fixation the bones are embedded in a hard mixture of epoxy resin to provide blocks with face sizes up to 3.5 × 3.0 cm. Mineralized sections are cut at 4 μm; demineralized at 3 μm. Sections are fastened to gelatin-subbed slides with pressure plates which produce flat, secure sections. After removal of the plastic, an unmodified Mayer's hematoxylin and a polychromatic eosin staining method is applied to demineralized sections, and a slightly modified method to mineralized sections.     

A Method for the Preparation of Undecalcified Bone Sections for Light Microscopy and Microradiography

A method which gives good quality 1-2 μm thick sections of undecaldfied cancellous and thin cortical bones for light miuoscopy is described. Formalin fixed material is dehydrated in graded acetones and embedded in a modiEed formula of Spurr's low viscosity embedding medium. After a 16 hour polymerisation period at 60 C, sections are cut at 1-2 μm thickness on a Porter-Blum JB4A rotary microtome Using glass knives. Sections are attached to clean glass slides with heat, the resin degraded in bromine vapour and removed in acetone. This allows comparative ease of staining. The technique is rapid, does not interfere with tetracycline fluorescence and the same specimens can be used to prepare thick sections for microradiography.