Use of a Tissue Sectioner to Expose Internal Structures of Biological Samples for Scanning Electron Microscopy

A procedure yielding sections of unembedded biological samples for observation by scanning electron microscopy is described. Sections of samples, fixed and hardened in OsO₄, were obtained in quantity with a tissue sectioner. Subsequent treatments to osmium-coat cut surfaces were employed prior to critical point drying. The procedure yields cleanly cut surfaces through cells and cytoplasmic organelles which are retained in their normal position. Sections of apple leaf and mouse kidney are illustrated. Sections can be readily cut in a desired plane with less structural damage than is typically encountered by other sectioning or dissection techniques.     

ELECTRON MICROSCOPY OF STRUCTURAL DETAIL IN FROZEN BIOLOGICAL SPECIMENS

A procedure is described whereby preshadowed replicas can be obtained from frozen biological specimens which have been cut and then etched by sublimation of the ice from their surfaces. Electron micrographs showing details of the internal structure of plant virus crystals are presented to demonstrate the values of the procedure. Crystals of purified tobacco ringspot virus and squash mosaic virus and some portions of turnip yellow mosaic virus crystals have been shown to exhibit hexagonal packing. Sections through in situ crystals of tobacco mosaic virus show the rods to be parallel within each layer and arranged in a square net as viewed end on. Individual rods in each layer of the latter measure 300 mµ in length and are somewhat tilted with respect to the rods of adjacent layers. This results in the formation of a herring-bone appearance when a crystal is cut perpendicular to its hexagonal face. It is suggested that the procedure outlined here might well serve to supplement other procedures for the preparation of many cytological specimens for electron microscopy.     

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.     

A Technique for Embedding Undecalcified Bone Samples for Detecting Alpha-Emitters Using Vacuum Impregnation with Spurr's Resin

A method has been developed by which large samples of mineralized bone, containing an alpha-emitter, can be embedded in Spurr's resin in a fraction of the time required by conventional methods. Bone samples were freeze-dried or fixed and dried prior to impregnation with Spurr's resin under vacuum. Sections were cut for the preparation of either alpha-track or fission-track autoradiographs using the solid state detector CR-39. This method is applicable to samples containing a mobile form of a radionuclide that may be translocated during the processes of fixation and dehydration of the specimen.     

A Method for the Preparation of Serial Thick Sections of Plastic-Embedded Plant Tissues

A procedure is described in which thick sections (2-10μ or more) of plastic-embedded plant tissues are mounted in serial order on slides for use in routine light microscopy. Sections are cut with a steel knife on a rotary microtome while the block and blade are bathed with 40% alcohol. The cut sections are placed, in order, in 50% alcohol in the small wells of modified plastic trays where they become flat, pliable and suitable for subsequent handling. Sections remain separate and in correct order in the trays while they are stained, washed, and prepared for final mounting on slides. Mounting involves a simple and rapid procedure of transferring the sections to a slide and heating first on a 70-75 C hot plate (to slowly evaporate the water around the section and to partially affix the section) and then on a 100 C hot plate. This second heating ensures adhesion when xylene-base mounting media, which tend to loosen weakly adhered plastic from the slides, are used. The technique of staining the sections loose provides the following advantages: (1) the problems of section loss and entrapment of stain between section and slide during staining are eliminated, (2) relatively high staining temperature, akalinity, and alcohol concentration of the stain solvent (all of which promote loosening of pm-affixed sections from slides during staining) is allowed, and (3) staining is more even and selective. The procedure has been found to be reliable and fast enough to be of value in a significant variety of routine light microscope studies.     

A method for the preparation of serial thick sections of plastic-embedded plant tissues.

A procedure is described in which thick sections (2-10 mu or more) of plastic-embedded plant tissues are mounted in serial order on slides for use in routine light microscopy. Sections are cut with a steel knife on a rotary microtome while the block and blade are bathed with 40% alcohol. The cut sections are placed, in order, in 50% alcohol in the small wells of modified plastic trays where they become flat, pliable and suitable for subsequent handling. Sections remain separate and in correct order in the trays while they are stained, washed, and prepared for final mounting on slides. Mounting involves a simple and rapid procedure of transferring the sections to a slide and heating first on a 70-75 C hot plate (to slowly evaporate the water around the section and to partially affix the section) and then on a C hot plate. This second heating ensures adhesion when xylene-base mounting media, which tend to loosen weakly adhered plastic from the slides, are used. The technique of staining the sections loose provides the following advantages: (1) the problems of section loss and entrapment of stain between section and slide during staining are eliminated, (2) relatively high staining temperature, alkalinity, and alcohol concentration of the stain solvent (all of which promote loosening of pre-affixed sections from slides during staining) is allowed, and (3) staining is more even and selective. The procedure has been found to be reliable and fast enough to be of value in a significant variety of routine light microscope studies.     

A Simple Procedure for in Situ Immunolabeling, Embedding and Sectioning of Layers of Cultured Endothelial and Smooth Muscle Cells for both Light and Electron Microscopy

We present a simple procedure for in situ immunolabeling, embedding and sectioning of layers of cultured endothelial and smooth muscle cells for both light and electron microscopy. Endothelial and smooth muscle cells were seeded in tissue culture chambers /slides precoated with 30% (w/v) gelatin drops fixed with 0.5% glutaraldehyde. Live endothelial cell layers were labeled with an antibody against the surface membrane protein, anti-CD 13. After labeling, the cell layers were fixed and separated from the chambers/slides by lifting all of the samples with a spatula. Sections (1-2 mm) were cut, embedded and processed further for light or electron microscopy. Because of the delicate cell layers and the importance of preserving maximum integrity, labeling was performed under standard culture conditions and treated in situ during the entire procedure. Moreover, the small chamber size of the tissue culture dishes generated the additional advantages of requiring only a limited number of cells, small volumes of media, and little antibody.     

Alcoholic Thionin Counterstaining Following Golgi Dichromate-Silver Impregnation

Brains of cats that had been fixed 2 months or longer in 10% formalin were cut into 3-6 mm. slices and impregnated by Golgi's dichromate-silver procedure (6% dichromate solution, 4-6 days; 1.5% silver nitrate solution 2 days). Sections 100 µ thick were cut after embedding in low melting point paraffin. Three changes of xylene and three of absolute alcohol were followed by staining 3-5 minutes in a saturated solution of thionin in absolute alcohol. The sections were dipped quickly in absolute alcohol and cleared in xylene, then differentiation was effected by an equal-parts mixture of absolute alcohol and xylene. A final clearing in three changes of xylene and mounting in Permount completed the process. Counter-staining was most successful when applied to freshly cut sections.     

Plastic Embedding, Orientation in the Mold and Tape-Supported Sectioning of Sclerotized Insects and Other Hard Objects

Sections of large specimens such as whole honeybees or beetle adults embedded in plastic usually are difficult to cut with a constant thickness. The sections also compress and roll. Sections of even thickness have been obtained by using a mixture of methacrylates (ethyl, 1:butyl, 3) and by firmly supporting the block in the microtome with a special holder. Scotch tape #810 applied to the block before each section is cut eliminates section compression and rolling. The sections are attached to slides with 2% celloidin in an absolute alcohol-methyl benzoate mixture (5:5-7:3); and the tape is removed with heptane. Large sections can also be cut from blocks of styrene mixed with butyl methacrylate. The specimens are oriented in the monomer in gelatin capsules by directing them into the desired plane among the fibers of a wad of absorbent cotton previously placed in the bottom of the capsule. The cotton is sectioned with the specimen but its fibers do not interfere, and remain outside the tissue.     

The atrioventricular node, His bundle and bundle branches-a new histologic technique.

A technique for examination of the conducting system of the heart is described. A block of tissue embracing the ostium of the coronary sinus, the pars membranacea, the septal leaflet of the tricuspid valve, and appropriate amounts of interatrial and interventricular septum is flattened and fixed in a Kaiserling I solution. Blocks are subsequently cleared in methyl salicylate and trimmed. Sections are cut from the blocks after paraffin embedding beginning from the endocardial surfaces of the right heart chambers. The sections are mounted and stained on 35 mm unperforated leader film and covered with an acrylic preservative. For examination of the conducting system many fewer sections are required than with previous techniques.     

The Atrioventricular Node, his Bundle and Bundle Branches-a New Histologic Technique

A technique for examination of the conducting system of the heart is described. A block of tissue embracing the ostium of the coronary sinus, the pars membranacea, the septal leaflet of the tricuspid valve, and appropriate amounts of interatrial and interventricular septum is flattened and fixed in a Kaiserling I solution. Blocks are subsequently cleared in methyl salicylate and trimmed. Sections are cut from the blocks after paraffin embedding beginning from the endocardial surfaces of the right heart chambers. The sections are mounted and stained on 35 mm unperforated leader film and covered with an acrylic preservative. For examination of the conducting system many fewer sections are required than with previous techniques.     

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 x 3.0 cm. Mineralized sections are cut to 4 micrometer; demineralized at 3 micrometer. 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.     

In situ hybridization using PEG-embedded tissue and riboprobes: increased cellular detail coupled with high sensitivity

We describe a procedure for preparing tissue sections by embedding in polyethylene glycol for subsequent in situ hybridization analysis using single-stranded RNA probes. Improved tissue morphology is obtained as compared to frozen sections, and the embedding procedure is milder and faster than paraffin embedding. Sections as thin as 2 microns are readily cut from PEG-embedded brain tissue. A simplified hybridization protocol (Clayton et al.: Neuron 1:249, 1988) supports the detection of even low-abundance brain mRNAs (less than or equal to 10(-4) fractional mRNA mass). By employing high stringency washes in place of ribonuclease treatment after hybridization, cell RNA is retained for cresyl violet staining, and high signal:noise ratios are achieved. Solutions to problems with section mounting and adherence to glass slides are presented. The combination of improved morphology, high signal levels, and relative simplicity should make this procedure useful in a variety of applications.     

Diethylene Glycol Distearate Embedding and Ultramicrotome Sectioning for Light Microscopy

Diethylene glycol distearate can be used as an embedding medium for light microscopy. Two infiltration changes of about 6 hr each in the melted wax (melting point 47-52 C) are required before the final embedding which is done in 00 gelatin capsules for sectioning in the ultramicrotome by the procedure used in electron microscopy. Serial sections 1-2 μ thick can be cut without difficulty. No cooling devices are necessary for trimming and sectioning at laboratory temperature. Sections rarely become detached from the slides. The staining characteristics of the tissues are the same as when embedded in paraffin. For fluorescence microscopy, essentially the same procedure is followed. Tissues are not distorted and the intracellular structures are well preserved.     

Rapid low molecular weight polyethylene glycol embedding protocol for immunocytochemistry

We describe an alternative polyethylene glycol (PEG) embedding procedure which utilizes PEG 200 for dehydration and PEG 600 for infiltration and embedding of perfusion-fixed rat liver. PEG 600 has a melting point of 22 degrees C, enabling infiltration of fixed tissue to be performed at room temperature. Sections (2 microM) cut in a cryostat at -20 degrees C and immobilized in agarose were readily labeled by immunoperoxidase protocols with monoclonal antibodies to hepatocyte membrane antigens. Subsequent examination by light microscopy or by electron microscopy after re-embedding in resin and ultra-thin sectioning showed excellent preservation of morphology, with minimal impairment of antigenicity.     

Frozen Section Micro-Incineration

A method for micro-incineration of frozen sections is described. Material containing diffusible or soluble salts is cut on the freezing microtome and the sections are placed into xylol and mounted out of xylol onto Corex D slides previously filmed with glycerin-gelatin medium. Material containing non-diffusible or insoluble salts can be fixed in 10% formalin before sectioning. Sections of the fixed material are dehydrated thru 50, 70, and 95% ethyl alcohol and mounted out of absolute alcohol onto Corex D slides previously fumed with glycerin-gelatin medium. After mounting by either procedure the sections are incinerated in an electric furnace and the temperature of incineration is dependent on the type of tissues to be incinerated and the character of the salts present. The method is time saving and when no fixation is required the whole procedure can be carried out in one hour.     

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 simplified procedure for preparation of undecalcified human bone sections

A new type of apparatus for sectioning samples of hard, undecalcified bone is described. Slices of fresh or archeological human bone 4-5 mm thick are dehydrated and then embedded in epoxy resin. The apparatus used to prepare sections from the resulting blocks consists of a low-speed rim-type diamond cut-off wheel and a slowly advancing table carrying the specimen held in a rotating mount. Sections may be cut at a thickness of 80 micron +/- 1%. After cleaning in an ultrasonic bath, these can be mounted on slides for quantitative microscopic examination with transmitted light. Grinding and polishing are not necessary. The results obtained are illustrated.     

Oxidation of NADH by hypocotyl segments from soybean is stimulated by 2,4-D

Sections cut from regions of cell elongation of hypocotyls of dark-grown soybean seedlings oxidized externally supplied NADH as estimated from the decrease in A₃₄₀ measured spectrophotometrically. The oxidation of NADH by 1-cm sections was stimulated 1.5- to 2-fold by 1 μM of the synthetic auxin, 2,4-dichlorophenoxyacetic acid (2,4-D). 2,4-D-Stimulated oxidation of NADH was resistant to cyanide. Stimulations were also given by the naturally occurring auxin, indole-3-acetic acid (IAA) but not by the growth inactive 2,4-D analog 2,3-dichlorophenoxyacetic acid (2,3-D) and the growth inactive β-naphthaleneacetic acid (β-NAA). Since NADH is a membrane impermeant substrate, the findings confirm studies with inside-out and right-side-out vesicles that show the 2,4-D-stimulated NADH oxidase to be located at the external cell surface. Cut surfaces are not responsible for the activity as shown by experiments with lanolin-sealed sections. The external NADH oxidase measurements do not require special equipment and exhibit characteristics normally associated with enzyme-catalyzed reactions.     

Oil Blue Na as A Stain for Rubber in Sectioned or Ground Plant Tissues

Oil blue NA (Calco), a stain which colors rubber bright blue, has been used effectively in studying the distribution of rubber in several plant species. Fresh or fixed sections are cut, bleached with Javelle water or NaOCl solution, treated with 9% KOH in 95% ethanol, washed with several changes of water and finally with 95% ethanol, and stained with 0.05% oil blue NA in 70% ethanol. Sections are rinsed in 50%' ethanol, placed in 40% glycerin, and mounted in glycerin jelly.

For the detection of changes in the distribution and character of rubber in milled or ground tissues, much the same staining procedure is followed. The stained tissues usually are examined and dissected under a stereoscopic microscope, a procedure which permits rubber to be recognized by both its staining reaction and by a more specific property, elastic elongation.

A microscopic technic is presented whereby it is possible to determine approximately the relative proportion of dispersed and coagulated rubber latex in unstained tissues.