Serial Sectioning Techniques for A Modified LKB Historesin

A glycol methacrylate-based plastic that is capable of producing; serial sections has been introduced by LKB. This plastic, provided in the LKB 2218-500 Historesin Embedding Kit, has been tested in our laboratory for its ribbon forming capacity. Various block sizes, concentrations of the softening agent polyethylene glycol 400 (PEG), and tissue types have been examined to determine the optimal conditions for ribbon formation. Although unmodified LKB Historesin is capable of forming ribbons, these ribbons often break. The addition of PEG to the embedding solution enhances ribbon formation. When sectioning with glass knives the best results are achieved with the addition of 0.2 ml of PEG/5.0 ml of embedding medium. A conventional AO rotary microtome can be used to produce ribbons if, in addition to the added PEG (optimal concentration 0.25-0.30 per 5 ml of embedding medium) a thin layer of dental wax is added to the upper and lower surfaces of the block. Ribbons form more easily on microtomes, such as the LKB Historange, that have a retractable specimen arm. If serial sections are to be produced it is very important that the upper and lower faces of blocks be parallel.     

Serial Sectioning of Tissues in Glycol Methacrylate by Supplementary Embedding in a Paraffin-Plastic Matrix

Glycol methacrylate, while offering certain advantages over paraffin as an embedding medium, is difficult to use because it will not ribbon. Rohde (1965) developed a method for producing ribbons of methacrylate sections, but we had little success with it because the ribbons tended to fall apart when even slight stresses were applied to them. We have therefore made use of the principle of double embedding, as this has been used for obtaining serial sections of material embedded in nitrocellulose.     

Serial Sectioning of Tissues in Glycol Methacrylate by Supplementary Embedding in a Paraffin-Plastic Matrix

Glycol methacrylate, while offering certain advantages over paraffin as an embedding medium, is difficult to use because it will not ribbon. Rohde (1965) developed a method for producing ribbons of methacrylate sections, but we had little success with it because the ribbons tended to fall apart when even slight stresses were applied to them. We have therefore made use of the principle of double embedding, as this has been used for obtaining serial sections of material embedded in nitrocellulose.     

N-butyl Methacrylate and Paraffin as an Embedding Medium for Light Microscopy

A method of tissue embedding using n-butyl methacrylate and paraffin is described. Following alcohol dehydration and infiltration with the methacrylate monomer, tissues are embedded in gelatin capsules in a mixture consisting of 3.5 g of paraffin for each 10 ml of methacrylate. Benzoyl peroxide (0.2 g for each 10 ml of monomer) is added as the catalyst and the methacrylate polymerized in a 50 C oven for 18-24 h. Following polymerization the block is trimmed and embedded in paraffin to provide a firm support during sectioning. A water trough attached to the microtome knife is essential to facilitate the handling of sections and ribbons. For serial sections a mixture of equal weights of beeswax and paraffin is used to make the sections adhere to each other. Usual staining procedures can be used since the embedding medium is readily soluble in xylene.     

N-Butyl methacrylate and paraffin as an embedding medium for light microscopy.

A method of tissue embedding using n-butyl methacrylate and paraffin is described. Following alcohol dehydration and infiltration with the methacrylate monomer, tissues are embedded in gelatin capsules in a mixture consisting of 3.5 g of paraffin for each 10 ml of methacrylate. Benzoyl peroxide (0.2 g for each 10 ml of monomer) is added as the catalyst and the methacrylate polymerized in a 50 C oven for 18--24 h. Following polymerization the block is trimmed and embedded in paraffin to provide a firm support during sectioning. A water trough attached to the microtome knife is essential to facilitate the handling of sections and ribbons. For serial sections a mixture of equal weights of beeswax and paraffin is used to make the sections adhere to each other. Usual staining procedures can be used since the embedding medium is readily soluble in xylene.     

A Method for Making Ribbons of Semithin Plastic Sections

Epoxy resin sections form strong, heat resistant ribbons if, prior to sectioning, contact cement has been painted onto the leading and trailing faces of the block. The forming ribbon floats onto a drop of water held in place by a wax line drawn across the back of the glass knife parallel to the cutting edge. A long trough made from stainless steel tubing is inserted horizontally into the drop, and as the ribbon lengthens it is directed into the trough. The ribbon can be carried in the trough to a hot plate for expansion and then poured onto a slide for mounting. The serial ribbons obtainable by this simple procedure greatly facilitate three dimensional reconstruction of fine tissue structures.'     

Improved Polyester Wax Embedding for Histology

Polyester waxes are fatty add esters of polyethylene glycol. Polyethylene glycol 400 distearate melts at 35°C, infiltrates tissues well, and sections readily at 2 μ to more than 30 μ. Sections 2 μ to 6 μ are more easily cut when a kitchen strainer full of solid CO₂ (dry ice) is mounted above the microtome to cool the block and the knife, and when the knife crosses the block very slowly. Ribbons are flattened in water at room temperature and are mounted conventionally. Polyester ribbons are somewhat stickier than paraffin ribbons. Polyethylene glycol 400 distearate is slightly hydrophilic; immediately after microtomy and before the ribbon is affixed to the microscope slide, sections in the wax ribbon may conveniently be stained with 0.05% toluidine blue in aqueous benzoate buffer, pH 4.4. Tissue structure is better preserved in polyester than in paraffin wax, probably because structural lipids are better retained and localized. However, this difference between waxes is slight if tissues are well fixed and dehydrated. Other advantages of polyester wax are that sections fragment less, hard tissues rarely split away from the wax ribbon, no static electricity is generated, and the microtome knife seems to remain sharp for a longer time.     

Embedding, serial sectioning and staining of zebrafish embryos using JB-4 resin

Histological techniques are critical for observing tissue and cellular morphology. In this paper, we outline our protocol for embedding, serial sectioning, staining and visualizing zebrafish embryos embedded in JB-4 plastic resin-a glycol methacrylate-based medium that results in excellent preservation of tissue morphology. In addition, we describe our procedures for staining plastic sections with toluidine blue or hematoxylin and eosin, and show how to couple these stains with whole-mount RNA in situ hybridization. We also describe how to maintain and visualize immunofluorescence and EGFP signals in JB-4 resin. The protocol we outline-from embryo preparation, embedding, sectioning and staining to visualization-can be accomplished in 3 d. Overall, we reinforce that plastic embedding can provide higher resolution of cellular details and is a valuable tool for cellular and morphological studies in zebrafish.     

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     

Serial Sections of Cooked Rice Embedded in Carbowax

Serial sections of cooked rice kernels may be obtained by following either of two dehydration schedules and embedding in Carbowax. In the first schedule the cooked, rinsed and drained kernels are immersed several days in a nonaqueous fixative composed of: isopropyl alcohol, 10 ml; propionic acid, 30 ml; acetone, 10 ml; methylal, 40 ml; dioxane, 30 ml; and propylene glycol, 30 ml (Newcomer's, modified), followed by 7 or 8 days in equal parts of propylene glycol, dioxane and glycerol (changed once), and 4 days on a warming table in the same mixture with 5% Carbowax added. The dehydrated kernels are then infiltrated 4-24 hr with a Carbowax embedding mixture. In the second schedule they are immersed several days in an aqueous solution consisting of: propylene glycol, 12.5 ml; polyethylene glycol 400, 12.5 ml; either with 75 ml of water containing 0.1% thymol, or with a mixture of water, 65 ml; formalin, 10 ml; CaCl₂, 1 gm; and CdCl₂, 1 gm; followed by 3 or 4 days in 50% propylene glycol, and 3 or 4 days on a warming table in 80% propylene glycol with 5% Carbowax added. Infiltration is as above. The composition of the embedding mixture is varied according to the temperature and humidity likely to prevail during sectioning. The texture of the wax may be improved by adding small amounts of gum arabic, spermaceti, and glycerol. Serial sections 3-10 μ thick are placed on clean dry slides, and adhesive dropped at the edges of the ribbon of Carbowax until it is dissolved. The adhesive consists of water-glass (concentrated solution), 1 ml; concentrated ammonia, 1 ml; Carbowax, 5 gm; and water, 98 ml. After the slides are dry they are stored, or immersed 10 min in chloroform, collodionized, and passed to staining solutions. Atmospheric conditions affect not only the Carbowax, but also the response to reagents of cooked rice and of sections.     

A new method for transfer of polyethylene glycol-embedded tissue sections to silanated slides for immunocytochemistry

Polyethylene glycol (PEG) is an excellent embedding medium for immunohistochemical studies. It provides structural preservation superior to frozen sections and increased sensitivity of antigen detection compared with paraffin sections. One limitation of PEG embedment is that PEG sections are difficult to handle and adhere poorly to glass slides. Here we present a simple and effective method for embedding tissues in PEG and transferring the resultant sections onto silanated glass slides. In addition, a method for silver enhanced colloidal gold immunostaining was combined with common dye staining to demonstrate the excellent structure preservation and sensitive antigen detection. Bovine chorionic membrane was fixed with Bouin's fixative, embedded in polyethylene glycol (PEG) 1500, cut into 5-microns sections, flattened over agarose blocks (10 x 10 x 2 mm3), and blotted onto Digene silanated slides. Slides were then washed in PBS, which removed the PEG and agarose blocks. Tissue sections were immunocytochemically stained with dilute antiserum raised in a rabbit against purified bovine placental retinol binding protein (bpRBP). Sections were washed and incubated with 1-nm colloidal gold-labeled goat anti-rabbit IgG. The immunogold particles were enhanced by silver staining (IGSS). Specimens were observed and photographed with an Olympus epipolarization microscope. The new method offered excellent morphological preservation of cell structure and the epipolarization microscopy provided high sensitivity for detection of specific immunogold-silver particles.     

A new method of preparing embeddment-free sections for transmission electron microscopy: applications to the cytoskeletal framework and other three-dimensional networks

Diethylene glycol distearate is used as a removable embedding medium to produce embeddment -free sections for transmission electron microscopy. The easily cut sections of this material float and form ribbons in a water-filled knife trough and exhibit interference colors that aid in the selection of sections of equal thickness. The images obtained with embeddment -free sections are compared with those from the more conventional epoxy-embedded sections, and illustrate that embedding medium can obscure important biological structures, especially protein filament networks. The embeddment -free section methodology is well suited for morphological studies of cytoskeletal preparations obtained by extraction of cells with nonionic detergent in cytoskeletal stabilizing medium. The embeddment -free section also serves to bridge the very different images afforded by embedded sections and unembedded whole mounts.     

Floating-Out Technics for Rapid Placement of Ribbons of Serial Sections on Slides

The floating-out technic, popular for single paraffin sections, can be applied successfully to ribbons of serials by either of two procedures. (1) If spreading time for the sections is uncritical suitable lengths of ribbon for attachment to a slide are laid on water at a temperature about 8° C below the melting point of the paraffin and manipulated with a rubber bulb pipette to form a unit. This ensemble can then be picked up by the slide in much the same manner as a single section. (2) If spreading time is critical, as for objects that have had guide limes embedded with them, several ribbons are arranged on a cold, dry slide and transferred to the water as a unit. Placing the ribbons on the cold slide so that they slightly overhang one end and the sides of the slide allows them to make proper contact with the water as the slide is immersed. To facilitate controllable spreading in both methods, the water should have added to it 0.5 ml of albumen-glycerol adhesive per 100 ml. Adding water to the slide after the sections have been picked up or manipulation of the ribbons is generally unnecessary if the ribbons have been aligned accurately on the floating-out bath.     

Combined Lectin Binding and PAS/Alcian Blue Staining in Glycol Methacrylate Sections

Evaluation of cryofixation and paraffin and glycol methacrylate embedding showed that lectin binding was essentially independent of the embedding medium. Fluorescence intensity increased in the following order: glycol methacrylate, paraffin and cryostat sections, The optical resolution increased in the reverse order. Semi-thin glycol methacrylate sections provided satisfactory fluorescence intensities and the best resolution of all embedding techniques applied. Furthermore the lectin treated sections can be stained further using routine histological or specific histochemical methods. The potassium hy-droxide/alcian blue/periodic acid-phenylhydra-zine-Schiff method was used successfully to demonstrate sulfated and nonsulfated sialomucins. Lectins combined with mucin histochemistry allowed visualization of specific sugar residues in the same glycol methacrylate plastic section.     

A Simple Method for Collecting and Mounting Ribboned Serial Sections of Epoxy Embedded Specimens

A simple and rapid method of handling ribboned serial sections of epoxy embedded specimens is described. Ribbons are cut from a block having the leading and trailing sides coated with contact cement. A scoop made from polyethylene tubing is used to remove a ribbon of sections from the boat of a glass or diamond knife and to transfer it to a pool of water on a microscope slide. Many ribbons (comprising hundreds of sections) can be mounted on a single slide. This method requires the construction of only one simple, inexpensive tool, the polyethylene scoop, and otherwise utilizes only items commonly available in the laboratory.     

A simple method for collecting and mounting ribboned serial sections of epoxy embedded specimens

A simple and rapid method of handling ribboned serial sections of epoxy embedded specimens is described. Ribbons are cut from a block having the leading and trailing sides coated with contact cement. A scoop made from polyethylene tubing is used to remove a ribbon of sections from the boat of a glass or diamond knife and to transfer it to a pool of water on a microscope slide. Many ribbons (comprising hundreds of sections) can be mounted on a single slide. This method requires the construction of only one simple, inexpensive tool, the polyethylene scoop, and otherwise utilizes only items commonly available in the laboratory.     

Method for Staining and Washing Thin Sections on Support Films

A procedure is described for staining large numbers of thin sections on support films for use with one-hole grids. The film is picked up, carried and protected using easily made plastic blocks. Loop-tipped forceps are then used to transfer tissue ribbons from the knife boat to the support film. A large number of tissue sections can then be stained and washed simultaneously in a modified Pyrex dish without damaging the film. After staining, the slot in the one-hole grid is centered over the tissue ribbon, and the grid is attached to the film. The method is suitable for serial reconstruction and the unobstructed viewing of large thin sections in the TEM.     

Polyethylene glycol embedded tissue sections for immunoelectronmicroscopy

Summary Several methods for tissue embedding in polyethylene glycol (PEG) were compared with regard to their applicability for pre-embedding immunoelectronmicroscopy. Existing embedding procedures gave unsatisfactory results and therefore a modified procedure was developed. This method, consisting of very brief tissue infiltration with PEG 1500, to which 3% water is added, allowed adequate tissue sectioning. Using these sections for preembedding immunoelectronmicroscopical localisation of glucagon in bovine pancreatic islets adequate ultrastructural morphology was obtained in combination with excellent preservation of peptide hormone immunoreactivity.Supported in part by grant no. PAL 52-77 of the Queen Qilhelmina Cancer Foundation     

A method of mesa trimming with glass knives for obtaining large series of ultrathin sections

Ultrastructural analysis of tissue based on 3D reconstruction from serial ultrathin sections is one of the most adequate methods in studies of spatial organization of bio-objects. The sample preparation technique for 3D reconstruction includes the two most technically difficult procedures: an obtaining of stable ribbon of serial sections and mounting of this ribbon onto a slot grid coated with a support film. To mount the ribbon, special approaches and technical tools have been proposed and well evaluated. Much attention has also been paid to obtaining a large and stable ribbon, but this attention deals mainly with the choice of epoxy embedding media. The critical condition of obtaining the straight and stable ribbon is the precise parallelism of trailing and leading edges of mesa falling onto the knife cutting edge. The mesa trimming with dry diamond knife for cryoultratomy allows this condition to be maintained. In the present communication, the way of obtaining parallel sides of the mesa has been proposed with the aid of two forms of glass knives.     

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.