Adherence of Lr White Sections to Glass Slides for Silver Enhancement Immunogold Labeling

A continuing problem in immunogold labeling of 1 pm LR White sections for light microscopy is the lack of adherence of the sections to the glass microscope slides during silver enhancement. A technique is described to overcome this problem using a 2% Formvar solution to coat the glass.     

Wrinkle-Free Plastic Sections for Light Microscopy

Plastic sections 0.5 to 2 μm thick are routinely used for light microscopy. Although plastic sections have several advantages over paraffin or celloidin sections, a problem that is often encountered with plastic sections is wrinkling (Fig. 1). Wrinkling occurs during staining when sections dried on glass slides are covered with stain and heated to hasten the penetration of the stain. Mounted sections heated on glass slides, but not stained, ordinarily lack wrinkles, even when examined with phase contrast optics. Similarly, mounted sections covered with stain, but not heated, lack wrinkles; unfortunately, such sections fail to stain adequately. Unmounted sections floated on heated drops of stain also lack wrinkles (Millonig 1980). Thus, it is clear that wrinkling occurs only when mounted sections are covered with stain and heated.     

Alcian Blue Method for Attaching Glycol Methacrylate Bone Marrow Sections to Glass Slides

Detachment of glycol methacrylate sections from glass slides is a common problem during histochemical and immunohistochemical procedures, particularly when large or hard tissue sections are stained and when using caustic solutions, alcohols, or proteases.     

Automatic grinding of undecalcified bone sections with exact adjustment of thickness]

A new grinding machine for preparing thin undecalcified bone sections after methylmethacrylate embedding is described. About 20 rather small bone sections can be ground at the same time; bigger specimens, up to 8 cm of length, are allowed. Bone sections are mounted on a cylindrical specimen holder by an adhesive film. Then the final thickness of the sections is exactly adjusted by screwing three rubies out of the holder's bottom. Now the prepared holder is set in a guide ring on a turntable carrying a rough ended glass plate. The desired thickness of the sections is reached as soon as the three rubies touch the glass surface. The variation in the thickness of the sections is less than +/- 3 micron. The machine is simply constructed, easily to handle and rapidly to clean.     

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.     

Preparing Bone Sections for Radioautography

The method eliminates all contact of bone with aqueous solutions. One hundred to 200µ sections are first cut with a guided circular saw. These sections are simultaneously embedded and mounted on glass slides by means of a clear thermoplastic cement, Gelva. The mounted bone sections are then ground to 5-25µ on fine silicon carbide paper. The sections are finally polished with levigated alumina on a cloth pad. A procedure for preparing contact radioautograms of ground bone sections is given and the results obtained are illustrated.     

A new method for preparation of undecalcified bone sections

A new method for preparation of sections of undecalcified bone is described. Samples of ovine bone were embedded in methylmethacrylate and thick-sectioned with a cutoff machine or commercial band saw. Composite slides were prepared by gluing white acrylic to glass using cyanoacrylate glue. Bone sections were glued to the composite slide and then surface polished by grinding or ultramilling. The polished surface of the section was then etched and stained. The techniques described in this paper reduce the time spent grinding or milling sections and improve resolution of surface-stained features of undecalcified bone sections.     

A New Method for Preparation of Undecalcified Bone Sections

A new method for preparation of sections of undecalcified bone is described. Samples of ovine bone were embedded in methylmethacrylate and thick-sectioned with a cutoff machine or commercial band saw. Composite slides were prepared by gluing white acrylic to glass using cyanoacrylate glue. Bone sections were glued to the composite slide and then surface polished by grinding or ultramilling. The polished surface of the section was then etched and stained. The techniques described in this paper reduce the time spent grinding or milling sections and improve resolution of surface-stained features of undecalcified bone sections.     

A simple method for preparing thin (10 microM) histological sections of undecalcified plastic embedded bone with implants

A simple method for preparing undecalcified thin sections of bone with implants has been developed. After exposing a surface of bone and implant in a plastic block by sawing thick sections, the surface is stained prior to making a thin section. A glass coverslip is affixed with a thin layer of cement to the stained surface to stabilize the tissue and implant during sectioning. A mixture of glycerine and water is used as a coolant and lubricant. The orientation in situ is preserved allowing demonstration of bone architecture and cells, and the tissue-implant interface.     

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.     

A Simple Method for Preparing Thin (10 μm) Histological Sections of Undecalcified Plastic Embedded Bone with Implants

A simple method for preparing undecalcified thin sections of bone with implants has been developed. After exposing a surface of bone and implant in a plastic block by sawing thick sections, the surface is stained prior to making a thin section. A glass coverslip is affixed with a thin layer of cement to the stained surface to stabilize the tissue and implant during sectioning. A mixture of glycerine and water is used as a coolant and lubricant. The orientation in situ is preserved allowing demonstration of bone architecture and cells, and the tissue-implant interface.     

A Method for Processing Light Microscopy Sections for Oriented Ultramicrotomy

A simple technique is described for processing optical microscopy sections attached to glass slides for ultramicrotomy in any desired plane. A silicone rubber mold with a central orifice is clamped onto the slide so that the orifice overlies the section. Routine processing and embedding procedures are carried out in the well formed by the orifice.     

A New Time-Saving Device for Embedding in Paraffin

A simple device to be used in place of the usual paper boxes or watch crystals used for embedding in paraffin in the preparation of histological sections is described. Short lengths of cooled rubber tubing are placed on a glass surface, which has previously been painted with glycerin, and are filled with melted paraffin. The rubber tubing sections are best cut by stretching the tubing on a wooden rod and cutting while the wood is turning in a lathe.     

Embedding in Epoxy Resins for Ultrathin Sectioning in Electron Microscopy

Fixed tissue is dehydrated with tertiary butyl alcohol overnight. The following day it is cleared in toluene, infiltrated and embedded in Araldite resin-hardener-accelerator mixture without dibutyl phthalate, and polymerized at 60° C. More rapid than previous techniques, this method gives blocks which do not fracture unduly on trimming and provides sections of soft tissues at 1 μ for phase contrast microscopy, as well as ultrathin sections which cut as easily with glass knives as sections of methacrylate. Araldite manufactured in the U.S.A. and in England are different. Satisfactory proportions for the American are: hardener DDSA, 3.5 ml; casting resin 6005, 5.0 ml; accelerator B, 0.12 ml. For the British product, these are: hardener 964 B, 5.0 ml; casting resin M, 5.0 ml; accelerator 964 C, 0.25 ml. The use of 2% agar for orienting small specimens in Araldite is feasible. Mallory's borax-methylene blue has been applied to the staining of Araldite sections as thin as 0.5 μ mounted on glass slides.     

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.     

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.     

Preparation of Copolymers of Isobutyl Methacrylate and Styrene for Mounting Media

Details are given for the preparation of low molecular weight copolymers of isobutyl methacrylate and styrene for use in mounting microscopical sections between the slide and cover glass. Any refractive index in the range from 1.477 to 1.590 is available, depending upon the proportions of monomers used. A refractive index of 1.550 is recommended for general purposes, though other indices might be desirable in special cases including phase microscopy. The resin gives solutions in toluene of suitable fluidity at usable concentrations, adheres satisfactorily to glass, and has excellent light-transmission. The features which make it especially valuable are its optimum refractive index and its permanent water-whiteness.

Copolymers of isobutyl methacrylate and styrene may also be used to prepare plastic mounts of thick sections or gross specimens, which are optically cleared by the plastic mountant.     

A solvent-free coating-procedure for the improved preparation of cryostat sections in light microscope histochemistry.

A new technique is presented for the external stabilization of cryostat sections by spraying the specimen surfaces with an aqueous solution of poly(vinyl alcohol) before each sectioning stroke. The spray freezes upon the surface and forms a tough coating which facilitates subsequent sectioning and handling especially of difficult material. The sections are affixed upon cold glass slides covered with an improved formulation of pressure-sensitive adhesive. During further processing of the affixed sections, the PVA-coating and any surrounding supporting medium dissolve without traces in the first aqueous incubation or staining solution.     

Cytometrically coherent transfer of receptor proteins on microporous membranes.

A new method (Freeze-Transfer) is described for performing high-resolution immunocytochemistry for soluble cell proteins on frozen sections of biological tissues that involves thaw-mounting frozen tissue sections directly onto the surface of nitrocellulose thin films instead of directly onto glass slides. This technically straight-forward change in methodology resulted in chromogenic immunocytochemical assays for Her-2 and EGF receptors that were 1-2 orders of magnitude more sensitive while still fully utilizing the diagnostic resolving power of light microscopy. The effects of membrane pore size and surface chemistry on the resolution and intensity of Her-2 signal suggest that the enhanced sensitivity of Freeze-Transfer was caused by the cytologically coherent transfer of target molecules normally lost from cut surfaces of cells mounted on nonporous glass during assay.