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.     

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.     

The chemical determination of section thickness

Summary In quantitative histochemistry it is frequently desirable to know the exact thickness of the sections. The nucleic acid content of the tissue has been used as the basis of a method for determining section thickness. Such determinations agree remarkably well with the setting on the cryostat microtome although considerable variations in thickness can occur in sections cut at different speeds.     

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.     

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.     

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)'.     

Comparison of two histological techniques for age determination in small cetaceans

Age estimation in odontocetes is based on counts of growth layer groups (GLGs) deposited in recording structures such as teeth. Generally, tooth sections are obtained using a cryostat microtome. However, some researchers prefer obtaining thin sections using a traditional paraffin microtome. Little information is available on the application of this technique to dolphin teeth. Our main aim was to investigate if the paraffin technique can be a viable alternative. We considered whether estimated age would be affected by preparation technique, staining method, and section thickness, while controlling for effects of species, body length, and sex. We also analyzed whether the staining method would affect readability of GLGs and age reading variability. Teeth from 86 individuals (representing seven species) were used, but not all were prepared using both techniques because sufficient teeth were not available in all cases. Although the staining method had significant effects on the estimated age using both techniques, the variability of GLG counts was small and appeared to be similar for both techniques. Using Mayer's hematoxylin stained sections of 8 μm thickness, good agreement of ages was obtained from both techniques, with more preparations classified as "good quality" for the paraffin technique. Mayer's hematoxylin provided the best contrast of the GLGs when using the paraffin technique. We conclude that the paraffin technique is viable and represents a cost-effective alternative to a cryostat microtome when preparing cetacean teeth for age determination.     

Thin Sections from Unfixed Tissues for Histochemical Staining

Sections were cut from fresh unfixed tissues by means of a microtome provided with an apparatus for the simultaneous cooling of the knife and freezing stage. These sections were of uniform thickness and were found to be very suitable for histochemical staining. Such sections were immersed while still frozen in the fluid which contained the necessary chemicals for a specific technic. After remaining in the fluid for an appropriate time, the sections were put on slides and dried in warm air. The remaining steps were carried out on the slides. Several histochemical procedures (phosphatase, esterase, glycogen) were found to give good results when this technic was used.     

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.     

The Preparation of Sections of Mineralized Tissue Suitable for the Demonstration of Alkaline Phosphatase

Blocks of molar teeth and bisected knee joints from rats of 7-21 days were embedded, without previous decalcification, in tropical grade ester wax. Serial sections were cut at settings of 3-25μ on a base sledge microtome equipped with a Jung extra hard steel knife with a tool-edged profile. The sections were supported with Sellotape during actual cutting and were then coated with a 2% celloidin solution. Chloroform was used to free the sections from the Sellotape. The distribution of alkaline phosphatase activity in the knee joints and teeth was demonstrated in these sections with the coupled-azo dye technique of Gomori, using Brentamine fast red T.R. salt.     

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.     

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 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.     

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.     

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.     

Ultrarapid vacuum-microwave histoprocessing

Summary A novel histoprocessing method for paraffin sections is presented in which the combination of vacuum and microwave exposure is the key element. By exploiting the decrease in boiling temperature under vacuum, the liquid molecules in the tissues have been successfully extracted and exchanged at relatively low temperatures during each of the steps from dehydration, clearing, and impregnation. In this vacuum-microwave method, an extremely short time suffices for the preparation of optimal-quality paraffin blocks. No xylene (but isopropanol instead) was used as the intermediate solvent. Thirty biopsies (thickness 2–4 mm) can be processed in 40 min. In addition, this approach can be used to produce large sections of giant blocks (4 × 6 × 1 cm³) which can be easily cut on a routine microtome due to the optimal paraffin impregnation. These giant blocks do not shrink during this vacuum-microwave histoprocessing.     

A Motor-Controlled Device for Slow-Motion Cutting with the Ultramicrotome

The preparation of ultrathin sections of high quality with a Porter-Blum microtome requires that the drive wheel be rotated at a slow, uniform rate during actual cutting. A mechanical device to control the motion of the microtome drive wheel consists of a synchronous motor connected to a drive shaft (4 rev/min), which can be intermittently coupled to the rim of the microtome wheel by a friction drive of 1/2-inch diameter. The microtome drive wheel is rotated manually at a rapid rate until the specimen is about to come into contact with the knife; then the mechanical drive is engaged for slow movement during cutting. When the section has been cut, the drive is disengaged by a lever operated with the left hand; after which, the microtome wheel is turned quickly back to the cutting position with the right hand.     

A Motor-Controlled Device for Slow-Motion Cutting with the Ultramicrotome

The preparation of ultrathin sections of high quality with a Porter-Blum microtome requires that the drive wheel be rotated at a slow, uniform rate during actual cutting. A mechanical device to control the motion of the microtome drive wheel consists of a synchronous motor connected to a drive shaft (4 rev/min), which can be intermittently coupled to the rim of the microtome wheel by a friction drive of 1/2-inch diameter. The microtome drive wheel is rotated manually at a rapid rate until the specimen is about to come into contact with the knife; then the mechanical drive is engaged for slow movement during cutting. When the section has been cut, the drive is disengaged by a lever operated with the left hand; after which, the microtome wheel is turned quickly back to the cutting position with the right hand.