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.     

Glass Knife Adapter for Cutting Epoxy Sections on a Conventional Rotary Microtome

Electron microscopy-style fixation followed by epoxy plastic embedding is often now the method of choice for preparing tissue even for light microscopy; I have found it excellent for fluorescence, autoradiographic and conventional histology (Shaw 1972, 1977). Sections more than about five microns thick can be cut on a really sharp steel knife if the plastic is reasonably soft (Stretton and Kravitz 1973, Shaw 1972), but this is much easier and knife marks are reduced if extra-wide glass knives are used on a special-purpose intermediate microtome like the Sorvall JB-4. Recent budgetary restrictions made us defer purchase of such a microtome, and some alternative had to be devised. I report here a simple but rugged adapter for glass knives which replaces the steel knife in a conventional Leitz rotary microtome and allows thin plastic sections to be cut as easily as with a more sophisticated cutter. It could be adapted for any rotary microtome, and can be readily constructed in most machine shops for negligible cost.     

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.     

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.     

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.     

An Inexpensive Trimmer for Paraffin Blocks

One of the minor difficulties in cutting serial sections with the rotary microtome is the accurate trimming of the block of paraffin so that the upper and lower edges facing the knife are parallel to each other and to the knife edge; this is necessary to ensure a straight ribbon. Several block trimmers have been described,¹ but they are all rather complicated and expensive to make. The device described below can be made in a short time at little or no expense in any laboratory.     

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.     

A Plastic Embedding Medium for Thin Sectioning in Light Microscopy

Tissue blocks with surface areas up to 2 cm² can be sectioned at 1 or 2 μ after embedding in a medium consisting of: methyl methacrylate, 27 ml; polyethylene glycol distearate MW 1540, 6 gm; dibutyl phthalate, 4 ml; and Plexiglas molding powder A-100, 9 gm (added last). The methacrylate mixture is polymerized at 50° C by benzoyl peroxide, 0.8 gm/ 100 ml of methacrylate. The polymerized matrix is transparent and the blocks can be cut on a rotary microtome with a steel knife. The plastic can be removed from sections with acetone prior to staining. Artifacts caused by embedding and sectioning are negligible     

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.     

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.     

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.     

Epoxy Embedding, Sectioning and Staining of Plant Material for Light Microscopy

By using a formula which gives a relatively soft epoxy embedding medium, it is possible to cut sections of plant material with a sliding microtome equipped with a regular steel knife. Blocks having a cutting face of 10 × 10 mm, giving sections of 4-10 μm, can be used. Tissues are fixed in Karnovsky's fluid, postfixed in 1 or 2% OsO₄, embedded in Spurr's soft epoxy resin, Araldite, or Epon mixtures. 5% KMnO₄, followed by 5% oxalic acid, then neutralized in 1% LiCO₃, are used to mordant the sections. Some of the stains used are Mallory's phosphotungstic acid-hemotoxylin, acid fuchsin and toluidine blue, or toluidine blue. Mounting is done with whichever soft epoxy resin was used in casting the blocks.     

A Modified Polyester Embedding Medium for Sectioning

A modified polyester resin designated as C. M. E. Tissue Support Resin can be cut on a rotary microtome and can yield sections from 5 to 50μ from tissue blocks that range from 5 to 16 mm in diameter. It is firm enough to support hard structures that lie adjacent to soft ones and retain all in their normal position. The resin-catalyst-promoter system cures oi hardens at a low temperature so that blocks are ready for cutting 6 hr aftei tissue has been routinely dehydrated. The resin is compounded from a plasticized rigid polyester and adjusted to a proper viscosity. Several grades of hardness can be attained by changing the formula. It has been tested with both soft and hard tissues, including limbs and tails of 7-mo old mice and mature whole grains of wheat, and provides a more substantial and more readily prepared embedding medium than celloidin. Sections can be stained before mounting, without removing the embedding material, with aqueous safranin O followed by fast green FCF in absolute alcohol. The plastic remains clear. Other staining processes require modifications to get good results.     

Interferometric analysis of intrasection and intersection thickness variability associated with cryostat microtomy

Summary Mach-Zehnder interferometric measurements were used to assess the extent of section thickness variability (inter- and intrasection) associated with cryostat microtomy of adrenal sections over a typical working range of 10–20 m. Sections were obtained using a Bright's Cambridge rocking type and a Damon rotary type cryostat microtome to allow comparative analyses. The effective thickness of tissue sections after being mounted onto slides by flash drying was reduced by 90% relative to microtome section thickness setting. A linear relationship between measured thickness and microtome setting was obtained with both instruments. Thickness variability between replicate sections over the range of microtome settings approximated 11% for the rocking microtome and 5% with the rotary microtome. Average intrasection variability was found to be 7% for rocking microtome sections and 4% for sections obtained with the rotary microtome. However, this variability is a negligible source of error in cytophotometric analyses, providing replicate sections are used and an adequate number of measurements are made on mask-delimited individual cells or tissue specimen areas.     

A SIMPLE MODIFICATION OF THE SPENCER ROTARY MICROTOME FOR CHUCK WITHDRAWAL ON THE UPSTROKE

A simple and accurate modification of the Spencer Model 820 rotary microtome is described in which the specimen is caused to withdraw from the knife on the upstroke. The modification, when used with glass knives, allows methacrylate-embedded tissues to be easily sectioned in the 1 to 5 β range. Interconvertibility from normal to modified operation is accomplished by simply turning a cam into one of two positions.     

Immunofluorescent Staining of Microtubules in Plant Tissues: Improved Embedding and Sectioning Techniques using Polyethylene Glycol (PEG) and Steedman's Wax

Methods for the indirect immunofluorescent staining of microtubules in embedded and sectioned plant tissues are described and compared. Root tips of Vicia faba, Saccharum officinale, Allium cepa, and root nodules of Glycine max were fixed using conventional methods, embedded in polyethylene glycol or Steedman's wax, sectioned with a glass knife on a rotary microtome, and dewaxed in water or alcohol. The addition of dithiothreitol (DTT), dehydrating at low temperatures and reducing the infiltrations times were found to reduce background fluorescence in Allium cepa. Steedman's wax yields a block that is similar to paraffin and is easier to section than PEG. Routine methods for indirect immunofluorescence were used to stain sections for tubulin/microtubules. The major microtubule arrays of mitotic cells are illustrated in this paper. The principal advantage of this technique is the preservation of cell-to-cell continuity in multicellular tissues. This method provides a much needed technique for the study of the cytoskeleton during growth and differentiation of plant tissues.     

A SIMPLE MODIFICATION OF THE SPENCER ROTARY MICROTOME FOR CHUCK WITHDRAWAL ON THE UPSTROKE

A simple and accurate modification of the Spencer Model 820 rotary microtome is described in which the specimen is caused to withdraw from the knife on the upstroke. The modification, when used with glass knives, allows methacrylate-embedded tissues to be easily sectioned in the 1 to 5 β range. Interconvertibility from normal to modified operation is accomplished by simply turning a cam into one of two positions.     

Use of a Silicone Rubber (Clear Seal) as a Section Adhesive Resistant to Acid, Alkali and Heat

An optically clear silicone rubber adhesive is recommended for use in histochemical procedures in which detachment of tissue sections is likely. Procedure: Cut paraffin sections and float on a 45-50 C water bath; leave frozen sections on the microtome knife in the cryostat; spread the silicone rubber thinly and evenly over 2/3 of the slide (Clear Seal—General Electric, was used); pick up paraffin sections directly from the floatation water and frozen sections from the microtome knife with a warm slide; dry for 1.5 hr at 25 C; place paraffin sections in a 60 C oven for 0.5 hr, deparaffinize through xylene and hydrate through alcohols to water. Stain sections as desired, but avoid clearing agents before mounting after strong acid or alkaline treatment, and mount rapidly if a synthetic resin is used because of the solvent effect on the silicone rubber. Of the adhesives tried, silicone rubber is the only one capable of withstanding boiling 10% HCl for any period of time without detachment of sections.     

Film tomography as a tool for three-dimensional image construction and gene expression studies

In order to observe three-dimensional (3D) expression patterns of genes in whole animals, whole organs, or whole tissues, in situ hybridization (ISH) of many sections must be carried out and then used to construct a 3D image. For this purpose, we have developed an automatic microtome to prepare tissue sections with an adhesive film. We used commercially available film suitable for sectioning and ISH. We constructed a microtome and, after adherence of the film to a paraffin-embedded tissue block, cut the block with a blade to prepare sections on film. Then, the sections-on-film were automatically set in a plastic frame that was the same size as a conventional glass slide. With this automatic microtome, tissue sections can be made for ISH or immunohistochemistry in addition to conventional hematoxylin and eosin staining without specific training. We demonstrate that we can construct 3D images of gene expression patterns obtained by ISH on sections prepared with this automatic microtome. We have designated this method as 'Film Tomography (FITO)'.     

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.