Easy Preparation of Bone Sections

Preparing paraffin sections of bone is often difficult, time-consuming, and attended by unpredictable results. This is especially so during preparation of sections of compact bone, as from the diaphysis of a long bone. By preparing frozen sections from decalcified blocks of compact bone and staining. with standard hematoxylin and eosin, preparations of high quality are obtained with comparative ease.     

A technique for retrieving antigens in formalin-fixed, routinely acid-decalcified, celloidin-embedded human temporal bone sections for immunohistochemistry.

The application of immunohistochemistry to routinely decalcified, celloidin-embedded human temporal bone sections has been hampered because of antigen loss during processing of the specimens. To our knowledge, there has been no published report to date describing immunohistochemical staining of such tissues suitable for examination by light microscopy. Here we report a novel antigen retrieval technique which can be successfully used to stain a variety of antigens in routinely formalin-fixed, trichloroacetic acid-decalcified, celloidin-embedded human temporal bone sections. The new procedure reported here for decalcified human temporal bone tissues simply requires immersing slides for 30 min at room temperature in an antigen retrieval solution. A total of 60 decalcified, celloidin-embedded human temporal bone tissues were tested with monoclonal antibodies (MAb) to 15 different antigens. Of these, 12 MAb showed definite positive staining, while three were negative. This technique may prove very useful in studying the expression of various antigens by immunohistochemistry in formalin-fixed, acid-decalcified, celloidin-embedded tissues.     

Methods for the Demonstration of Lipid Applied to Compact Bone

Sections of compact bone were cut from the diaphysis of the femur, tibia, and humerus from dogs and monkeys. These sections were either ground thin and decalcified, or decalcified and subjected to frozen sectioning. Decalcification of the sections was effected by immersion in either Decal, 10% formic acid, 10% formic acid-sodium citrate (pH 4.5) or 20% aqueous EDTA. Sections were routinely stained with oil red O, Sudan black B, or Fettrot 7B. In addition, Nile blue A and phosphine 3R were also employed. Sections stained with phosphine were viewed with a fluorescence microscope. Control sections were extracted with lipid solvents prior to application of the staining procedures. The results indicate that lipid is present in compact bone within the osteocytes, lacunae, canaliculi, and organic matrix. The significance of the lipid in these sites, particularly extracellularly, is unknown.     

A Simple Histological Method for Identification of Osteoid Matrix in Decalcified Bone

The present experiment indicated that cyanuric chloride fixation was very useful in identifying osteoid matrix, which is difficult to distinguish from mineralized matrix in sections decalcified in the routine fashion. Small slices of bone from 3 mm to 5 mm thick were fixed with 0.5% cyanuric chloride in methanol containing 1% N-methyl morpholine for from 1 to 2 days at room temperature. EDTA decalcified sections were prepared and stained with hematoxylin and eosin. The regions presumed to be osteoid matrix were intensely eosinophilic. It was shown that the eosinophilic regions correspond precisely to the unmineralized osteoid matrix which was radiolucent by microradiography and devoid of silver by the von Kossa method in undecalcified serial sections.     

In Situ Zymography and Immunolabeling in Fixed and Decalcified Craniofacial Tissues

In situ zymography is a very important technique that shows the proteolytic activity in sections and allows researchers to observe the specific sites of proteolysis in tissues or cells. It is normally performed in non-fixed frozen sections and is not routinely performed in calcified tissues. In this study, we describe a technique that maintains proteolytic activity in fixed and decalcified sections obtained after routine paraffin sectioning in conventional microtome and cryostat sections. We used adult rat hemimandibles, which presented bone, enamel, and dentine matrices; the substrate used was dye-quenched-gelatin. Gelatinolytic activity was colocalized with MMP-2 using fluorescent antibodies. Specific proteolytic activity was observed in all sections, compatible with metalloproteinase activity, particularly in dentine and bone. Furthermore, matrix metalloproteinase-2 was colocalized to the sites of green fluorescence in dentine. In conclusion, the technique presented here will allow in situ zymography reactions in fixed, decalcified, and paraffin-embedded tissues, and we showed that paraformaldehyde-lysine-periodate–fixed cryostat sections are suitable for colocalization of gelatinolytic activity and protein labeling with antibodies. (J Histochem Cytochem 57:615–622, 2009)     

Acid phosphatase activity is detected preferentially in the osteoclastic lineage by pre-treatment with cyanuric chloride

We previously reported a simple method to detect osteoid matrices in decalcified bone sections by pre-treatment with cyanuric chloride. We have applied this technique to identify osteoclasts and their precursors in rats. In JB-4 sections prepared from untreated bone tissues with cyanuric chloride, both acid phosphatase (ACP) and tartrate-resistant acid phosphatase (TRAP) were found not only in osteoclasts and bone marrow mononuclear cells but also in osteoblasts. In contrast, treatment of bones with cyanuric chloride resulted in staining ACP preferentially in osteoclasts and mononuclear cells adjacent to the bone surface. In the osteoclasts and most of the ACP-positive mononuclear cells, autoradiography showed calcitonin binding. Decalcification with EDTA did not affect the staining for ACP activity in bones treated with cyanuric chloride. It was possible to simultaneously identify ACP and osteoid matrix in a decalcified section. In soft tissues without treatment with cyanuric chloride, both ACP and TRAP were detected in splenic macrophages, alveolar macrophages, and proximal convoluted ducts in kidney. Neither ACP nor TRAP was found in these cell types in the tissues treated with cyanuric chloride. This procedure provides a new, simple method to identify a more restricted population in the osteoclastic lineage than that detected by TRAP staining.     

Osteopontin is histochemically detected by the AgNOR acid-silver staining

Silver nitrate staining of decalcified bone sections is known to reveal osteocyte canaliculi and cement lines. Nucleolar Organising Regions (NOR) are part of the nucleolus, containing argyrophilic proteins (nucleoclin/C23, nucleophosmin/B23) that can be identified by silver staining at low pH. The aim of this study was to clarify the mechanism explaining why AgNOR staining also reveals osteocyte canaliculi. Human bone and kidney sections were processed for silver staining at light and electron microscopy with a modified method used to identify AgNOR. Sections were processed in parallel for immunohistochemistry with an antibody direct against osteopontin. Protein extraction was done in the renal cortex and decalcified bone and the proteins were separated by western blotting. Purified hOPN was also used as a control. Proteins were electro-transferred on polyvinylidene difluoride membranes and stained for AgNOR proteins. In bone, Ag staining identified AgNOR in cell nuclei, as well as in osteocyte canaliculi, cement and resting lines. In the distal convoluted tubules of the kidney, silver deposits were also observed in cytoplasmic granules on the apical side of the cells. Immunolocalization of osteopontin closely matched with all these locations in bone and kidney. Ag staining of membranes at low pH revealed bands for NOR proteins and 56 KDa (kidney), 60KDa (purified hOPN) and 75 KDa (bone) bands that corresponded to osteopontin. NOR proteins and osteopontin are proteins containing aspartic acid rich regions that can bind Ag. Staining protocols using silver nitrate at low pH can identify these proteins on histological sections or membranes.     

Improved Procedure for Histological Identification of Osteoid Matrix in Decalcified Bone

Several improvements on the original method of Yoshiki and coworkers for histological identification of osteoid matrix in decalcified bone are described in this report. The first, fixation of bone with neutral buffered formalin, a popular and stable fixative, should produce better tissue morphology and ensure easy handling in any laboratory. The second is a simple test for aged cyanuric chloride. Aged reagents show poor or no solubility in methanol and have almost no effect on differential staining of osteoid matrix. The third is an application of an organic acid solution in place of neutral EDTA for bone decalcification. Reduced decalcification time with the acid results in rapid preparation of bone sections. Neutral formalin fixation, immersion in the cyanuric chloride solution, decalcification with an organic acid, and hematoxylin and eosin staining, all quite routine laboratory procedures, yield high quality results for identification of osteoid matrix in bone sections.     

Modified Tetrachrome Method for Osteoid and Defectively Mineralized Bone in Paraffin Sections

A new modification of the tetrachrome method for bone osteoid in paraffin sections has been designed. The modified tetrachrome method suitable for routine use in any histology laboratory retains the simplicity of the original method and gives good results on the freshly fixed, decalcified, paraffin embedded material. Osteoid tissue is stained deep blue and normally mineralized bone is stained red. Defectively mineralized bone stains pale blue or pink and the cellular population is clearly identifiable. The ability to distinguish the osteoid tissue from mineralized bone and connective tissue and cartilage makes diagnosis of osteomalacia or osteoid producing tumors or assessment of ossification process straightforward, without the need for un-decalcified sections. By displaying simultaneously irregularities in the mineralized matrix and morphology of bone cells, the method also permits the diagnosis of conditions recently described in patients with osteoporotic fractures, such as osteocytic degeneration and bone tissue defects.     

Improved procedure for histological identification of osteoid matrix in decalcified bone

Several improvements on the original method of Yoshiki and coworkers for histological identification of osteoid matrix in decalcified bone are described in this report. The first, fixation of bone with neutral buffered formalin, a popular and stable fixative, should produce better tissue morphology and ensure easy handling in any laboratory. The second is a simple test for aged cyanuric chloride. Aged reagents show poor or no solubility in methanol and have almost no effect on differential staining of osteoid matrix. The third is an application of an organic acid solution in place of neutral EDTA for bone decalcification. Reduced decalcification time with the acid results in rapid preparation of bone sections. Neutral formalin fixation, immersion in the cyanuric chloride solution, decalcification with an organic acid, and hematoxylin and eosin staining, all quite routine laboratory procedures, yield high quality results for identification of osteoid matrix in bone sections.     

Further Considerations on a Simple Histological, Method for Identification of Osteoid Matrix

The authors have proposed fixation in cyanuric chloride as a means of inducing marked differences in acidophilia between mineralized bone matrix and osteoid. The effects of cyanuric chloride fixation are investigated in more detail here. Dye-extinction tests performed on sections from decalcified rachitic rat calvariae fixed with cyanuric chloride demonstrated a much higher isoelectric point in osteoid matrix than in mineralized matrix. Cyanuric chloride fixation resulted in high isoelectric points for fixed un mineralized proteins in general. Micro radiography revealed no decalcification in bone during fixation in cyanuric chloride.     

Tensile damage and its effects on cortical bone

Plexiform bovine bone samples are repeatedly loaded in tension along their longitudinal axis. In order to induce damage in the bone tissue, bone samples are loaded past their yield point. Half of the bone samples from the damaged group were stored in saline to allow for viscoelastic recovery while the others were decalcified. Tensile tests were conducted on these samples to characterize the effects of damage on the mechanical behavior of the organic matrix (decalcified samples) as well as on bone tissue (stored in saline). The ultimate strain of the damaged decalcified bone is 29% higher compared to that of non-damaged decalcified (control) bone. The ultimate stresses as well as the elastic moduli are similar in both decalcified groups. This phenomenon is also observed in other collagenous tissue (tendon and ligament). This may suggest that damage in bone is caused by shear failure of the organic matrix; transverse separation of the collagen molecules or microfibrils from each other. In contrast, there is a trend towards lowered ultimate strains in damaged bone, which is soaked in saline, with respect to control bone samples (not damaged). The damaged bone tissue exhibits a bi-linear behavior in contrast to the mechanical behavior of non-damaged bone. The initial elastic modulus (below 55 MPa) and ultimate strength of damaged bone are similar to that in non-damaged bone.     

Effects of fixation and decalcification on the immunohistochemical localization of bone matrix proteins in fresh-frozen bone sections

To examine the stability of bone matrix proteins for crystal dislocation, the immunolocalization of type I collagen, bone sialoprotein, and osteopontin was investigated during different stages of fixation and decalcification. Four-week-old rat femurs were rapidly frozen, and were sectioned without fixation or decalcification. Thereafter, following or bypassing fixation in 4% paraformaldehyde, these sections were decalcified in 5% EDTA for 0-5 min. Before decalcification, marked radiopacity of bone matrix was observed in contact microradiography (CMR) images, and electron probe microanalysis (EPMA) demonstrated intense localization for phosphorus and calcium. In fixed and unfixed sections without decalcification, immunolocalization of bone matrix proteins were almost restricted to osteoid. After 1 min of decalcification, reduced radiopacity was apparent in the CMR images, and less phosphorus and calcium was observed by EPMA, which completely disappeared by 5 min decalcification. After 3-5 min of decalcification, unfixed sections showed that these proteins were immunolocalized in bone matrix, but were not detectable in osteoid. However, fixed sections demonstrated that these were found in both bone matrix and osteoid. The present findings suggest that bone matrix proteins are embedded in calcified matrix which is separated from the aqueous environment and that they hardly move, probably due to firm bonding with each other. In contrast, matrix proteins in osteoid are subject to loss after decalcification because they may be bound to scattered apatite crystals, not to each other.     

Organic Chelating Agents for Decalcification of Bones and Teeth

Lower jaws of adult guinea pigs were fixed in 10% neutral formalin 24 hours following intra-arterial and intra-man-dibular injection of the same fluid. They were then decalcified 3 weeks by 3 changes of Versene or Sequestrene (ethylene diamine tetracetic acid, disodium salt). Examination of the sections revealed complete decalcification, excellent fixation and selective staining of bone, cartilage, tooth and other tissues. Comparison with acid-decalcified preparations leads us to conclude that chelate-decalcification is at least as good if not superior to acid-decalcification in the preparation of such hard tissues.     

An effective reactivation of alkaline phosphatase in hard tissues completely decalcified for light and electron microscopy

Summary An effective procedure for reactivating alkaline phosphatase in tissues decalcified completely for light and electron microscopy was presented. It was indicated that an Mg ion supply as reactivator in the decalcified sections before, not during, incubation for demonstration of the enzyme was important. In addition, choice of buffer solutions as Mg ion solvent and as rinsing solution for the sections after reactivation were also important. Cacodylate buffer should not have been used as an Mg solvent because the reactivation effect of the Mg ion was seriously reduced. But it should have been used for rinsing reactivated sections in order to obtain reaction products at all sites of enzyme activity throughout thick sections used for electron microscopy.     

Validation of bromodeoxyuridine immunohistochemistry for localization of S-phase cells in decalcified tissues. A comparative study with tritiated thymidine autoradiography

Summary Immunohistochemical detection of the thymidine analogue 5-bromo-2-deoxyuridine (BrdUrd), which is incorporated by S-phase cells, offers a convenient way of studying the proliferation kinetics of cells in normal skeletal tissues and in bone containing/derived tumours. To assess the validity of using this approach on decalcified, paraffin embedded tissues, the BrdUrd method was compared with tritiated thymidine (³H-TdR) autoradiography, using rat tibiae labelled with both³H-TdR and BrdUrd, fixed in Carnoy's fluid and decalcified in EDTA, prior to routine paraffin embedding. The distribution of BrdUrd-labelled cells correlated with the sites of cell proliferation in the growing rat tibia.Independent studies with each method on paired serial sections of double-labelled tissue, showed a highly significant correlation (r=0.81, p<0.0003) in the numbers of labelled cells seen in autoradiographs and immunostained sections from the proximal tibial growth plate. Combined BrdUrd immunohistochemistry and³H-TdR autoradiography showed that the majority of labelled cells in cartilage, bone marrow, and fibrous perichondrium and periosteum had incorporated both labels. These results show that BrdUrd immunohistochemistry is a valid technique for the study of dividing cells in mineralized tissues after decalcification.     

Immunohistochemical investigation on the presence of chondroitin sulfate in calcification nodules of epiphyseal cartilage.

Chondroitin sulfate localization in mouse epiphyseal cartilage was studied using CS-56 monoclonal antibody immunospecific for the glycosaminoglycan portion of the molecule. For light and fluorescence microscopy, decalcified specimens were embedded in paraffin, Lowicryl, or were frozen and cryostat-sectioned, and the antigen-antibody reaction was demonstrated by treating sections with IgM-peroxidase, IgM-alkaline phosphatase, or IgM-fluorescein conjugates. For electron microscopy, decalcified and undecalcified specimens were embedded in Lowicryl; ultrathin sections from undecalcified specimens were decalcified by flotation on EDTA; sections from both types of specimens were treated with IgM-immunogold conjugate for demonstration of CS-56 reaction. Before immunoreaction, part of all decalcified sections were digested with Streptomyces or testicular hyaluronidase. Control sections were treated with either mouse and goat non-immune serum, or mouse monoclonal antiserum to human dendritic reticulum cells. Both light and electron microscopy show CS-56 reaction with cytoplasmic components of maturing and hypertrophic chondrocytes. Under the light microscope, immunoreaction was not visible in calcified matrix, and was visible in uncalcified matrix only after hyaluronidase digestion. Under the electron microscope, it was evident both in uncalcified and calcified matrix, although the latter showed few immunogold particles, usually placed on areas which appeared incompletely calcified. Gold particles were chiefly distributed at the periphery of calcification nodules and fully calcified matrix. These results show that CS-56, besides reacting with cytoplasm of maturing and hypertrophic chondrocytes, binds to crystal ghosts and other components of cartilage matrix, immunoreactivity decreasing as calcification increases. This suggests that chondroitin sulfate molecules are either degraded during calcification, or segregated into macromolecular complexes, or both degraded and segregated. The second possibility is supported by the increase of immunosensitivity induced by hyaluronidase digestion.     

Comparison of verdeluz orange G and modified Gallego stains

Tumors of the oral cavity include combinations of hard and soft tissues that may be difficult to identify using routine hematoxylin and eosin (H & E) staining. Although combination stains can demonstrate hard and soft tissues, trichrome stains, such as VanGieson and Masson, cannot differentiate dental hard tissues, such as dentin, cementum and osteoid. Modified Gallegos (MGS) and verdeluz orange G-acid fuchsin (VOF) stains can differentiate components of teeth. We used 10 tissue sections of decalcified bone and 10 pathologic tissue sections that contained different calcified tissues including peripheral ossifying fibroma, odontoma, central ossifying fibroma and cemento-ossifying fibroma. Sections were stained with H & E, VOF or MGS. H and E stained both hard tissues pink. VOF stained bone purple-red, cementum red and collagen blue. MGS stained bone green-blue, cementum red and collagen blue. VOF staining intensity and differentiation was better than MGS staining. VOF staining demonstrated hard tissue components distinctly and exhibited good contrast with the surrounding connective tissue. VOF also is a simple, single step, rapid staining procedure.     

A method for preparing 2- to 50-µm-thick fresh-frozen sections of large samples and undecalcified hard tissues

This article describes a method for preparing 2- to 50-micron-thick fresh-frozen sections from large samples and completely calcified tissue samples. In order to perform the more routine work involved, a tungsten carbide disposable blade was installed to a heavy-duty sledge cryomicrotome. An entire 10-day-old rat and bone and tooth samples from a 7-month-old rat were rapidly frozen. The frozen samples were attached to the cryomicrotome stage. The cutting surface of the samples was covered with a polyvinylidene chloride film coated with synthetic rubber cement and cut at -25 degrees C. The soft tissues and the hard tissues were satisfactorily preserved and all tissue cells were easily identifiable. Enzymatic activity in the fresh sections was much stronger than that in chemically fixed and/or decalcified sections. The sections permitted histological and histochemical studies without trouble. In addition, the sections can be used for multiple experiments such as immunohistochemistry, in situ hybridization, and electron microprobe X-ray micro-analysis. This method can be used with conventional cryomicrotome equipment.