New embedding medium for sectioning undecalcified bone

Methylmethacrylate (MMA) is the most commonly used embedding medium for sectioning undecalcified bone; however, a number of problems exist with its use in a research laboratory. MMA requires a long infiltration time and temperature control, and it reacts with many polymers. We used Kleer Set resin? as an alternative embedding medium for sectioning undecalcified bone specimens. Fluorochrome labeled bone specimens were sectioned transversely using a ground section technique and longitudinally on a sledge macrotome. The slides were viewed using both transmitted light and epifluorescence microscopy. High quality sections were obtained using Kleer Set resin? for both sectioning techniques. We have shown that this new embedding medium is simpler, safer, quicker to use and does not interfere with visualization of fluorochromes.     

New embedding medium for sectioning undecalcified bone

Methylmethacrylate (MMA) is the most commonly used embedding medium for sectioning undecalcified bone; however, a number of problems exist with its use in a research laboratory. MMA requires a long infiltration time and temperature control, and it reacts with many polymers. We used Kleer Set resin™ as an alternative embedding medium for sectioning undecalcified bone specimens. Fluorochrome labeled bone specimens were sectioned transversely using a ground section technique and longitudinally on a sledge macrotome. The slides were viewed using both transmitted light and epifluorescence microscopy. High quality sections were obtained using Kleer Set resin™ for both sectioning techniques. We have shown that this new embedding medium is simpler, safer, quicker to use and does not interfere with visualization of fluorochromes.     

The routine sectioning of undecalcified bone for cytochemical studies

Synopsis A method is described by which serial sections of fresh, undemineralized adult bone can be obtained. Such sections are suitable for cytochemical investigations and can expedite diagnostic histology.     

Glycol methacrylate as an embedding medium for bone

A simple and reliable procedure for embedding undecalcified trabecular bone tissue in noncommercial glycol methacrylate (GMA) has been developed. The embedding mixture includes a monomer, methacrylic acid hydroxyethyl ester; a copolymer, methacrylic acid butyl ester; a cross-linker, ethylene glycol dimethacrylate; a catalyst, Luperco; a chemical initiator (N,N-dimethylaniline) and, to avoid excessive elevation of temperature during polymerization, a heat moderator, alpha-terpinene. The appropriate proportions of these components have been selected to give specimens which can be easily sectioned with classical microtomes and which do not swell but spread evenly on a water surface. Since polymerization occurs at -4 C, the method allows demonstration of such enzymatic activities as acid and alkaline phosphatase and carbonic anhydrase. It provides excellent preservation of bone tissue and in studies of bone metabolism allows histomorphometry as well as visualization of fluorescent labeling and radioactive markers. The cost is significantly less than available commercial kits. In our hands glycol methacrylate is at present more useful than methyl methacrylate and is used in our laboratory for routine embedding of bone tissue.     

Polyester wax embedding and sectioning technique for immunohistochemistry

We have developed a method useful for immunohistochemical studies by combining tissue fixation with buffered neutral formalin and polyester wax embedding. Buffered neutral formalin fixation preserves cell and tissue fine structure, and also the antigenicity of unstable enzymes. Polyester wax embedding makes possible thin serial sections of various tissues and preserves antigenicities for at least 6 months. We have demonstrated using this technique the localization of alpha-amylase in mouse salivary gland, parietal-cell specific antigen in mouse glandular stomach, and DNA polymerase alpha and beta in chick tissue.     

An embedding method for histochemical studies of undecalcified skeletal growth plate

We have used glycol methacrylate to study undecalcified skeletal growth plate and subchondral bone. Minor modifications of the original technique including dehydration in glycol methacrylate vacuum infiltration and polymerization in the cold make it quite suitable for embedding of such tisssues. Moreover, specimens can be processed quickly and the morphologic and biochemical integrity of the tissue retained so that histochemical procedures can be readily applied. Collagen, glycosaminoglycan, glycogen, lipid, calcium and the activity of alkaline and acid phosphatase were localized. This technique appears to be very useful for studying skeletal tissues.     

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 sensitive stain for aluminum in undecalcified cancellous bone

Aluminum is known to accumulate with age in bone and other tissues of humans, even in the absence of renal disease. Our study aimed to develop a histological staining method sufficiently sensitive to detect aluminum in plastic sections of undecalcified bone biopsies from healthy volunteers as well as from patients with renal and non-renal bone diseases. We used quantitative histomorphometry to measure the percentage of trabecular surface stained by aluminum and found that our new method was approximately 50% more sensitive for detecting aluminum than the Acid Solochrome Azurine (ASA) method which in turn was significantly more sensitive than the Aluminon method. Aluminon is widely used in pathology laboratories for diagnostic purposes despite concerns in the literature about Aluminon's limited sensitivity for aluminum. Our histomorphometric results showed that the newly developed method stained approximately 10% of the trabecular surface in bone sections from healthy controls, 38% from renal patients, 26% from patients with vitamin D deficiency, and 29% from patients with osteoporosis. Histomorphometric measurements of aluminum-stained trabecular surfaces in sections stained with ASA were consistent with those obtained in Walton-stained sections but proportionately lower. Moreover, the Walton and ASA methods stained aluminum at similar locations in adjacent bone sections. As the ASA and Walton methods are considerably more sensitive for bone aluminum than the Aluminon method, we recommend that either of them should be used in place of the Aluminon method for routine diagnostic purposes.     

A simplified procedure for preparation of undecalcified human bone sections

A new type of apparatus for sectioning samples of hard, undecalcified bone is described. Slices of fresh or archeological human bone 4-5 mm thick are dehydrated and then embedded in epoxy resin. The apparatus used to prepare sections from the resulting blocks consists of a low-speed rim-type diamond cut-off wheel and a slowly advancing table carrying the specimen held in a rotating mount. Sections may be cut at a thickness of 80 micron +/- 1%. After cleaning in an ultrasonic bath, these can be mounted on slides for quantitative microscopic examination with transmitted light. Grinding and polishing are not necessary. The results obtained are illustrated.