Adaptation of a sliding microtome for sectioning of material embedded in epoxy resins]

The employment of a sliding microtome of sectioning plastic embedded material with glass knives is described. Using a new knife holder and a modificated device for fixing plastic blocks succeeded in cutting sections 1--10 micron thick of relatively large pieces of tissue.     

A Ralph Knife Holder Assembly for Use with the Sorvall “Porter-Blum” MT-1 Ultramicrotome

The superiority of plastic embedding for the production of high quality sections for light microscopy is well known, but the use of conventional glass knives with a cutting edge of approximately 4 mm has severely restricted the size of specimens in the past. Ralph knives provide a much longer cutting edge and adapters are available for certain models of microtomes and ultramicrotomes. A modified knife holder for use with the Sorvall “Porter Blum” MT-2 microtome was described by Gorycki and Sohm (1979); however, this is not suitable for the MT-1 model. We have therefore designed and made an adapter which enables Ralph knives to be used with this instrument. The design allows approximately 18 mm of cutting edge to be used on each knife, allowing larger specimens to be sectioned than with a conventional glass knife and reducing the frequency with which the knife needs to be changed when working with smaller blocks.     

A perfusion-fixation procedure for the concurrent demonstration of Timm's, horseradish peroxidase (HRP), and acethycholinesterase (AChE) histochemistry

The sulfide-silver method of Timm has been a widely used histochemical technique to demonstrate the presence of heavy metals in biological tissue, particularly in the central nervous system. However, the use of this method or its several modifications results in less than optimal morphological preservation and requires embedding the tissue in paraffin or freezing it and cutting it directly onto slides with a cryostat. These procedures can decrease the sensitivity and limit the application of other histochemical procedures, particularly when experiments necessitate processing large specimens or reaction procedures require techniques using free-floating sections. A perfusion-fixation protocol is described that yields sufficient fixation to cut whole frozen blocks of tissue with a sliding microtome, permits the use of free-floating sections, and allows the concurrent demonstration of horseradish peroxidase and acetylcholinesterase histochemistry without loss of sensitivity. The method consists of a short initial exposure to a sodium sulfide solution followed by a prolonged exposure to a combined sulfide-aldehyde fixative solution.     

Some Improvements in the Preparation of Fresh Frozen Sections

For the histochemical demonstration of sensitive enzymes it is necessary to use fresh unfixed tissue sections. With the following procedure one can constantly obtain such sections 10-20μ thick with relative ease. Schanze's sliding microtome is employed. The microtome knife is deeply cooled by placing blocks of dry ice on its surface, and is provided with a device for preventing the sections from rolling up. The microtome is operated in an ordinary refrigerator maintained at a temperature of 0-3°C. For this purpose, the door of the refrigerator is replaced by a wooden door provided with a glass window, gloved arm holes, and a small door.     

Contributions to semithin sectioning on a conventional rotary microtome.

Procedures for obtaining sections 1 micrometer thick on a conventional rotary microtome are described. Hydrophilic resin blocks with adequate hardness and elasticity for semithin sectioning are made by addition of divinylbenzene and methylmethacrylate to a commercial embedding kit. The blocks are pinched between two simple adapters and mounted in the specimen holder of a microtome. A glass knife of the Ralph type with an effective blade length of 25 mm is made from a glass slide and attached to a metal bar with paraffin. The low cost assembly is set in the steel knife holder of a conventional rotary microtome. Sections 1 micron in thickness can be cut from the resin embedded blocks. Staining with the usual staining solutions may be weak due to the thinness of the sections, but the fine resolution and low distortion achieved are compensating gains.     

Freezing by Liquid Carbon Dioxide in Making Slides Permanent

The expansion of liquid CO₂ may be employed in a quick-freeze method for making aqueous slide preparations permanent. An apparatus is described for this purpose which could be duplicated satisfactorily by cutting a 22mm square hole in the top of a standard freezing microtome specimen holder. The edges should be filed smooth to provide a flat surface for the slide to rest on, and clamps added to keep the slide in place while freezing. Once the slide is frozen, the cover slip may be readily removed, leaving practically all of the tissue on the slide. Following simultaneous thawing and dehydration of the slide in 95% alcohol, covering is done with Diaphane or Euparal and a clean, dry cover slip.     

Polyester Resin Embedding for Sectioning of Hard and Soft Tissues

Soft and calcareous tissues embedded in polyester resin may be cut on a sledge microtome to produce thin sections of 3-4 β thickness. Fixed tissues, dehydrated in ethyl alcohol, cleared in methyl benzoate and chloroform, are taken into a wide-necked bottle containing equal parts of polyester resin and chloroform with 0.75% catalyst. The bottle kept in water bath at 37°C is connected to a vacuum pump. With the evaporation of the chloroform under reduced pressure (approximately 10 mm Hg) infiltration is complete. Tissues transferred into a blocking form containing pure polyester resin with 1.5% catalyst are polymerized at 37° C until blocks are firm (48 hr or more). Blocks are prepared with at least 5 mm margin of plastic surrounding the tissue. The edge of the block adjacent to the knife is then filed at an angle of 45° to the cutting movement. Sections are cut with a wide-backed biplanar knife having a cutting edge of 40-44° positioned at an angle of 30° to the plastic block. As the resin is permeable to most stains, staining is carried out through the plastic Sections carried through staining procedures in wire baskets are floated onto slides and mounted in polystyrene; the cover-glass is compressed with a spring-clamp. Microscopic examination shows no staining of plastic, minimal shrinkage and good cellular detail.     

Contributions to Semithin Sextioning on A Conventional Rotary Microtome

Procedures for obtaining sections 1 μ thick on a conventional rotary microtome are described. Hydrophilic resin blocks with adequate hardness and elasticity for semithin sectioning are made by addition of divinylbenzene and methylmethacrylate to a commercial embedding kit. The blocks are pinched between two simple adapters and mounted in the specimen bolder of a microtome. A glass knife of the Ralph type with an effective blade length of 25 mm is made from a glass slide and attached to a metal bar with paraffin. The low cost assembly is set in the steel knife holder of a conventional rotary microtome. Sections I micron in thickness can be cut from the resin embedded blocks. Staining with the usual staining solutions may be weak due to the thinness of the sections, but the fine resolution and low distortion achieved are compensating gains.     

Cryostat Sectioning; Modification of the Antiroll Plate

A replaceable antiroll plate and holder have been designed for use in the Ames Lab-Tek cryostat which replace the plastic plate supplied with the instrument and insure a flawless, properly aligned plate for maximum efficiency in thin section cutting. A metal plate holder is attached to the existing screw-driven bracket provided with the instrument by the manufacturer. Glass plates made from one half of a 1.5 × 3 inch microscope slide are coated on the leading edge with spray-on Teflon and provided with tape spacers. These plates slip into the holder and can be adjusted for angular inclination and alignment with the cutting edge by movement within the holder or manipulation of the adjustment screw.     

Paraffin Embedding; a Graded-Temperature Table Used with Multiple Blocking for Enhanced Efficiency

Details are given for the construction of a graded-temperature table having a cool and hot side. Aluminum baking pans smeared with glycerol are used to cast the multiple paraffin blocks. These are loaded with paraffin wax from an electrically heated paraffin wax dispenser incorporated in the graded-temperature table and the pieces of tissue and labels orientated in them. The pans are then moved to the cool side of the table before finally floating them on cold water to harden the wax. Arranged above the heated side of the table are two infrared lamps which prevent premature solidification of the surface of the wax. After removing the solid, multiple-block slabs from the pans, the infrared lamps are used to soften the wax to a cheese-like consistency. Individual blocks are cut apart and trimmed around their sides with single strokes to produce smooth-sided blocks which are ready for attaching to wooden holders, adapted to the microtome chuck.     

Staining method for whole-body autoradiography.

Sagittal whole-body sections of frozen mice were cut on a hydraulicly driven microtome in a cryostat at--15 C by applying cotton or nylon-backed adhesive tape to the mouse before cutting. Section thickness was 20 mu. The sections, still adhering to the tape, were dried in the cryostat (-15C) under atmospheric pressure. After autoradiography, the sections were pressed to a glass slide spread with a mixture of albumin and glycerin. The slide was immersed in xylene at 30 C for 15 min. The tape was then removed from the slide, where the section remained to be stained with hematoxylin-eosin. The section thus obtained enabled the tissue histology to be related to the autoradiogram. This method may also be applied to histochemical studies of substances insoluble in xylene.     

A Portable Dry-Ice Storage Chamber for Enhanced Preservation of Enzymes in Frozen Tissue Specimens

To meet the histochemical needs for enzyme procedures in a laboratory not equipped with cold storage facilities giving -75 C or below, the following procedures were adopted and found technically and economically satisfactory. During sectioning interruptions, the mounted tissue block, in the cryostat, is covered with aluminum foil to prevent surface drying; after cutting, the specimens still mounted on their carriers are individually wrapped in aluminum foil and placed in polyethylene bags. These are then placed in the bottom of a 15 × 34 cm Dewar flask, and the flask filled to capacity with approximately 1.9 kg of dry ice.     

The core-microtome: A new tool for surface preparation on cores and time series analysis of varying cell parameters

A microtome designed for the surface preparation of entire increment cores allows cutting plane surfaces on cores up to a length of 40 cm. Compared to the common sanding procedure, the wood cells of the annual rings remain open, not filled with swarf, and the cell walls are smooth and hence clearly visible. This article aims at describing the functionality of the microtome and the procedures needed for an accurate surface preparation to achieve a good contrast for subsequent image analysis. Possible applications for a more detailed analysis of variations in the tracheid structure of conifers and vessel sizes of oak are presented, which can be included in time series analyses.     

A Device for the Precise Transfer of Serial Sections for Electron Microscopy

A device based on a standard stereotaxic instrument, in which a Formvar-dipped loop carrying serial thin sections, and a rotatable grid holder are mounted in separate electrode holders, thus permitting accurate positioning of each with respect to the other and the precise transfer of the sections to the grid, is described and illustrated.     

Ultramicrotome Chucks for Flat Castings

Paraformaldehyde-induced fluorescence in frozen-dried tissues survives embedding in glycol methacrylate. After freeze-drying and treatment with paraformaldehyde vapor, tissues to be examined by this technique are immersed in glycol methacrylate and placed in a dessicator which is then evacuated. They are usually left overnight in the dark; next day, the polymerizer is added and the tissues are again left overnight in the dark in the evacuated dessicator; for smaller blocks or certain tissues, these times can be shortened. The blocks are cut on a JB-4 microtome. Sections of 1-10μ can be made readily with a dry glass knife according to standard procedures.     

Grid staining--a useful device.

A simple and disposable holder for electron microscope grids can be constructed from discs of silicon rubber. The discs (10 mm thick X 25 mm diameter) are scored 0.4 mm deep with a razor. Flexing the discs opens the scores for insertion of grids. Staining wells can be made from polyethylene snap-in vial tops by cutting away the nipple-like portion. After impaling the holders on the tips of a pair of forceps the grids can be washed by immersion. This holder is rigid, inert and inexpensive. It is of particular advantage for handling single-slotted grids.     

Glycol Methacrylate Sections of Frozen-Dried Tissues for Histofluorescence

Paraformaldehyde-induced fluorescence in frozen-dried tissues survives embedding in glycol methacrylate. After freeze-drying and treatment with paraformaldehyde vapor, tissues to be examined by this technique are immersed in glycol methacrylate and placed in a dessicator which is then evacuated. They are usually left overnight in the dark; next day, the polymerizer is added and the tissues are again left overnight in the dark in the evacuated dessicator; for smaller blocks or certain tissues, these times can be shortened. The blocks are cut on a JB-4 microtome. Sections of 1-10μ can be made readily with a dry glass knife according to standard procedures.     

FROZEN THIN SECTIONS OF FRESH TISSUE FOR ELECTRON MICROSCOPY, WITH A DESCRIPTION OF PANCREAS AND LIVER

A simple method has been developed that allows frozen thin sections of fresh-frozen tissue to be cut on a virtually unmodified ultramicrotome kept at room temperature. A bowl-shaped Dewar flask with a knifeholder in its depths replaces the stage of the microtome; a bar extends down into the bowl from the microtome's cutting arm and bears the frozen tissue near its lower end. When the microtome is operated, the tissue passes a glass or diamond knife in the depths of the bowl as in normal cutting. The cutting temperature is maintained by flushing the bowl with cold nitrogen gas, and can be set anywhere from about -160°C up to about -30°C. The microtome is set for a cutting thickness of 540–1000 A. Sections are picked up from the dry knife edge, and are placed on membrane-coated grids, flattened with the polished end of a copper rod, and either dried in nitrogen gas or freeze-dried. Throughout the entire process the tissue is kept cold and does not come in contact with any solvent. The morphology seen in frozen thin sections of rat pancreas and liver generally resembles that in conventional preparations, although freezing damage and low contrast limit the detail that can be discerned. Among unusual findings is a frequent abundance of mitochondrial granules in material prepared by this method.