Differential Staining of Calcified Tissues in Plastic Embedded Microtome Sections by A Modification of Movat's Pentachrome Stain

Movat's pentachrome I stain has been adapted and modified as a stain for Undecalcified bone sections. After embedding in methyl methacrylate, this procedure yields consistently good results, with an excellent and colorful contrast between mineralized and unmineralized compartments of both cartilage and bone. in addition, osteoblats, osteoclasts, and other cells and tissue components can easily be differentiated. the staining properties of the lacunar wall surrounding the osteocytes are considered to reflect various states of osteocytic activity. the method is especially useful for the study of bone growth and bone repair, and as a stain for conventional histomorphometry and computer-assisted image analysis in bone biopsies.     

Differentiation of bone and soft tissues in formalin-fixed, paraffin-embedded tissue by using methylene blue/acid fuchsin stain

OBJECTIVE: To find a staining method for formalin-fixed, paraffin-embedded tissue that would distinguish bone from surrounding soft tissues, including muscle, periosteal tissue and bone marrow. STUDY DESIGN: A variety of stains were tested and compared with hematoxylin-eosin. The potential value of any given stain was evaluated based on its ability to stain bone and soft tissues different colors or shades that could be readily identified in photomicrographs. Stains were evaluated using both endochondral (tibia) and intramembranous bone (calvaria) samples. RESULTS: In contrast to standard hematoxylin-eosin stain, which stains both bone and soft tissues pink, the methylene blue/acid fuchsin stain demonstrates remarkable contrast between bone and other tissues. Methylene blue/acid fuchsin stained bone bright pink and the surrounding soft tissues blue-purple. CONCLUSION: In addition to the superior staining properties of methylene blue/acid fuchsin, other benefits of this stain include its stability, ease of use and low cost. This stain has many potential applications in the study of erosive bone disease in humans and also in animal models for research.     

Large Specimen Bone Embedment and Cement Line Staining

Undecalcified embedment of large bone specimens is often challenging. A method is presented here that is suitable for methacrylate embedment of sections of canine vertebrae while retaining the ability to localize tartrate-resistant acid phosphatase and alkaline phosphatase activity. Specimens also retained tetracycline labelling, and sectioned preparations were readily stained with routine bone procedures. A modification of the Bodian silver stain, used for examining the nerves and spinal cord in these specimens, provided a useful stain for canaliculi and cement lines in trabecular and cortical bone. This stain is advantageous when both bone and nerve tissue are of interest, as in spinal fusion studies.     

Softening Hair with Dithiothreitol (Cleland's Reagent) for Histological Sectioning in Paraffin

Undecalcified embedment of large bone specimens is often challenging. A method is presented here that is suitable for methacrylate embedment of sections of canine vertebrae while retaining the ability to localize tartrate-resistant acid phosphatase and alkaline phosphatase activity. Specimens also retained tetracycline labelling, and sectioned preparations were readily stained with routine bone procedures. A modification of the Bodian silver stain, used for examining the nerves and spinal cord in these specimens, provided a useful stain for canaliculi and cement lines in trabecular and cortical bone. This stain is advantageous when both bone and nerve tissue are of interest, as in spinal fusion studies.     

Adaptations of Goldner's Masson Trichrome Stain for the Study of Undecalcified Plastic Embedded Bone

Specialized adaptations for application of Goldner's Masson trichrome stain to plastic embedded undecalcified bone specimens are presented. This stain can be used successfully on methyl-glycol methacrylate, glycol methacrylate and Spurr embedded bones. The stain affords the advantage of good cellular staining due to the hematoxylin component with concomitant sharp discrimination of mature bone matrix which stains green, immature new bone matrix which stains red, and calcified cartilage which stains very pale green. Use of red filters during photomicrography aids in bone-osteoid discrimination in black and white photographs.     

Staining Aspirated Human Bone Marrow with Domestic Wright Stain

The method employs the domestic Wright stain for the staining of aspirated human bone marrow. Freshly distilled water, pH 6.0 to 6.4, is used. Wright stain, 0.5 cc, is placed upon the air-dried preparation and permitted to act for two minutes. The stain is then diluted with 2 cc. distilled water and permitted to act for from 5 to 10 minutes. After washing off the stain with distilled water, the preparation is placed into a decolorizer (acetone 0.5 cc, pure methyl alcohol 5.0 cc, and 100 cc. distilled water, pH 6.0 to 6.4) for differentiation from 1 to 5 seconds, rinsed, washed under running water and permitted to air-dry. A well stained and differentiated preparation shows the “Romanovsky effect”, and the sharpness of minute structures obtained compares favorably with control preparations stained with German dyes.

The bone marrow should be prepared as described. The Wright stain marketed by the National Aniline and Chemical Co., N. Y. was found to be reliable as regards staining quality of registered batches. One photomicrograph, showing bone marrow cells from pernicious anemia, is included.     

Differential in Toto Staining of Bone, Cartilage and Soft Tissues

The following method for staining bone and cartilage allows study of the gross cleared specimen and does not injure the tissues for subsequent microscopic study: Fix in 10% neutral formalin; bleach thoroughly in 3% H₂O₂ in sunlight. Wash in distilled water. Stain bone 24 hours in 0.01 g. of Biebrich scarlet in 100 ml. of distilled water. Destain in 95% alcohol until soft tissues and cartilage are colorless. Stain cartilage 24 hours in a pH2 buffer solution of 2.1g. of citric acid per 100 ml. of water with 0.001 g. of methylene blue. Destain in pH2 buffer solution until soft tissues are pale. Dehydrate in two changes of 95% alcohol in preparation for clearing. (This completes the destaining and may remove too much stain from the cartilage if destaining in the pH2 solution has been carried too far.) Place in Groat's clearing fluid and cover loosely so that the alcohol may evaporate, or remove the alcohol in vacuo. Groat's Mixture No. 19 is usually satisfactory.

For a combined stain, first stain bone, as above, and then apply the cartilage stain.

Seal jars with an ordinary liquid wood glue such as LePage's.     

A two-color acid-free cartilage and bone stain for zebrafish larvae

Traditionally, cartilage is stained by alcian blue using acidic conditions to differentiate tissue staining. The acidic conditions are problematic when one wishes to stain the same specimen for mineralized bone with alizarin red, because acid demineralizes bone, which negatively affects bone staining. We have developed an acid-free method to stain cartilage and bone simultaneously in zebrafish larvae. This method has the additional advantage that PCR genotyping of stained specimens is possible.     

C. I. Acid Red 52: A New Stain for Cells of Granulocytic Origin

Using the xanthene dye C.I. acid red 52 (CI. 45100) as a single agent stain applied to coverslip preparations of blood and bone marrow, primary and secondary granules in cells of neutrophilic origin stained brilliant pink. In eosinophils, granules stained dark red. In leukemic myeloblasts that also stained with Sudan black B and demonstrated myeloperoxidase and specific esterase activity, a few bright red staining granules were visualized with acid red 52- In some leukemic promyelocytes, Auer rods stained bright red. In leukemic lymphoblasts, no red granules were seen. Of a wide variety of dyes tested so far, acid red 52 is the most sensitive stain for primary and secondary granules of granulocytes in blood and bone marrow.     

在海藻酸钠凝胶上诱导骨髓间充质干细胞分化为成骨细胞

通过在海藻酸钠凝胶上诱导bMSCs向成骨细胞分化,探讨其对骨髓间充质干细胞（bone mesenchymal stem cells, bMSCs）的生物学效应。采用MTT、甲苯胺蓝染色、von Kossa染色和RT-PCR分别检测细胞的增殖、生长形态、诱导后细胞的钙化结节和成骨相关基因的表达。实验组bMSCs生长状况良好、细胞增殖迅速,与对照组的增殖无差异;bMSCs成集落样生长明显,集落中央细胞重叠生长形成钙化结节;培养至12d,实验组和对照组的成骨相关基因,包括碱性磷酸酶、I型胶原和骨钙素,均为阳性表达,但实验组的表达量高于对照组。海藻酸钠凝胶能够促进bMSCs向成骨细胞的分化,是良好的骨组织工程支架材料。     

C. I. acid red 52: a new stain for cells of granulocytic origin

Using the xanthene dye C.I. acid red 52 (C.I. 45100) as a single agent stain applied to coverslip preparations of blood and bone marrow, primary and secondary granules in cells of neutrophilic origin stained brilliant pink. In eosinophils, granules stained dark red. In leukemic myeloblasts that also stained with Sudan black B and demonstrated myeloperoxidase and specific esterase activity, a few bright red staining granules were visualized with acid red 52. In some leukemic promyelocytes, Auer rods stained bright red. In leukemic lymphoblasts, no red granules were seen. Of a wide variety of dyes tested so far, acid red 52 is the most sensitive stain for primary and secondary granules of granulocytes in blood and bone marrow.     

An Air Distributer for use in the Drop Method of Dehydration

A staining method is described using thionin, for undecalcified deacrylated bone sections. RNA is stained purplish violet, allowing still active osteoblasts to be distinguished from lining cells. Staining intensity of mineralized bone is related to the degree of mineralization. Mineralizing fronts and cement lines are visualized clearly. Lamellae show an alternate pattern. Histomorphometric parameters such as osteon thickness and interstitial bone thickness can be measured without using polarized light. The mineralizing front can be assessed and expressed as a percentage of the osteoblast-covered interface between osteoid and mineralized bone. The stain is also useful for qualitative assessment of metabolic bone disease. Thionin stained sections can be kept for at least one year when stored hi the dark at 7 C.     

A Versatile New Mineralized Bone Stain for Simultaneous Assessment of Tetracycline and Osteoid Seams

A versatile mineralized bone stain (MIBS) for demonstrating osteoid seams and tetracycline fluorescence simultaneously in thin or thick undecalcified sections has been developed. Bone specimens are fixed in 70% ethanol, but 10% buffered formalin is permissible. Depending upon one's preference, these specimens can be left unstained or be prestained before plastic embedding. Osteoid seams are stained green to jade green, or light to dark purple. Mineralized bone matrix is unstained or green. Osteoblast and osteoclast nuclei are light to dark purple, cytoplasm varies from slightly gray to pink. The identification of osteoid seams by this method agrees closely with identification by in vivo tetracycline uptake using the same section from the same biopsy. The method demonstrates halo volumes, an abnormal, lacunar, low density bone around viable osteocytes in purple. This phenomenon is commonly seen in vitamin D-resistant rickets, fluorosis, renal osteodystrophy, hyperparathyroidism, and is sometimes seen in fluoride treated osteoporotic patients. In osteomalacic bone, most osteoid seams are irregularly stained as indicated by the presence of unmineralized osteoid between mineralized lamellae. The method has been used effectively in staining new bone formation in hydroxyapatite implants and bone grafts. Old, unstained, plastic embedded undecalcified sections are stained as well as fresh sections after removal of the coverslip. This stain also promises to be valuable in the study of different metabolic bone diseases from the point of view of remodeling, histomorphometry, and pathology.     

Comparison of absorption measurements of DNA stain content by utilizing video and scanning image cytometers

After staining with the Feulgen reaction, the DNA stain contents of 155 mouse bone marrow cells and 22 adjacent chicken erythrocytes were measured by absorption image cytometry by utilizing two different systems--a scanning cytometer and a video cytometer. In the scanning cytometer (M85 microdensitometer, Vickers Instruments, Malden, MA), a spot of light was scanned across the cell. In the video cytometer (TAS Plus, E. Leitz, Rockleigh, NJ), the microscope field, which may contain several nuclei, was imaged onto a Plumbicon video camera. With each system, cells were scanned, digitized into their elementary pixels, and analyzed to determine their integrated absorbance. Comparison of the DNA stain contents of the same G0/G1 bone marrow cells and chicken erythrocytes, as measured by video and scanning cytometry, showed that both techniques gave comparable results; scanning cytometry is more precise. The coefficients of variation of the measurements for the G0/G1 bone marrow cells and for the chicken erythrocytes were 5.9% and 7.0%, respectively, when measured by video cytometry at the absorption peak (584 nm), compared to 4.1% and 3.5%, respectively, for the same cells when measured by scanning cytometry off the absorption peak (615 nm). The video-based measurements were relatively lower than the scanning measurements for darkly stained cells; this suggests that glare and other optical errors which increase with stain darkness caused greater systematic errors in the video cytometer than they did in the scanning cytometer.     

Simultaneous Differential Staining of Cartilage and Bone in Rodent Fetuses: an Alcian Blue and Alizarin Red S Procedure without Glacial Acetic Acid

Differential staining of cartilage and bone has several applications including developmental toxicology studies of new chemical candidates for pharmaceutical, industrial, and environmental use. It has been more common to stain fetal bone only using the dye alizarin red S: however, failure to evaluate the cartilaginous portion of the skeleton may result in the failure to identify toxicologically important alterations in skeletal morphology. Previously, differential staining of fetal cartilage and bone was best achieved by combining alizarin red S for staining bone with alcian blue to stain cartilage in glacial acetic acid solution: however, occupational hazards posed by the use of glacial acetic acid make these methods undesirable. Replacement of the glacial acetic acid with potassium hydrogen phthalate eliminates these hazards without compromising the quality of the stained specimen.     

A Thionin Stain for Visualizing Bone Cells, Mineralizing Fronts and Cement Lines in Undecalcified Bone Sections

A staining method is described using thionin, for undecalcified deacrylated bone sections. RNA is stained purplish violet, allowing still active osteoblasts to be distinguished from lining cells. Staining intensity of mineralized bone is related to the degree of mineralization. Mineralizing fronts and cement lines are visualized clearly. Lamellae show an alternate pattern. Histomorphometric parameters such as osteon thickness and interstitial bone thickness can be measured without using polarized light. The mineralizing front can be assessed and expressed as a percentage of the osteoblast-covered interface between osteoid and mineralized bone. The stain is also useful for qualitative assessment of metabolic bone disease. Thionin stained sections can be kept for at least one year when stored hi the dark at 7 C.     

A procedure for differential staining of cartilage and bone in whole formalin-fixed vertebrates.

This paper describes a modification of the Simons and Van Horn (1971) procedure for rendering cartilage blue, bone red, and soft tissue translucent or transparent in whole vertebrate specimens. Alcian blue and alizarin red S are used to stain cartilage and bone respectively. In our procedure formalin is used as a fixative. This is a significant modification because formalin is the common fixative for museum specimens. This clearing and staining procedure is thus readily applicable to comparative studies in anatomy, embryology and systematic zoology.     

Nanoscale Examination of Microdamage in Sheep Cortical Bone Using Synchrotron Radiation Transmission X-Ray Microscopy

Microdamage occurs in bone through repeated and excessive loading. Accumulation of microdamage weakens bone, leading to a loss of strength, stiffness and energy dissipation in the tissue. Imaging techniques used to examine microdamage have typically been limited to the microscale. In the current study microdamage was examined at the nanoscale using transmission x-ray microscopy with an x-ray negative stain, lead-uranyl acetate. Microdamage was generated in notched and unnotched beams of sheep cortical bone (2×2×20 mm), with monotonic and fatigue loading. Bulk sections were removed from beams and stained with lead-uranyl acetate to identify microdamage. Samples were sectioned to 50 microns and imaged using transmission x-ray microscopy producing projection images of microdamage with nanoscale resolution. Staining indicated microdamage occurred in both the tensile and compressive regions. A comparison between monotonic and fatigue loading indicated a statistically significant greater amount of stain present in fatigue loaded sections. Microdamage occurred in three forms: staining to existing bone structures, cross hatch damage and a single crack extending from the notch tip. Comparison to microcomputed tomography demonstrated differences in damage morphology and total damage between the microscale and nanoscale. This method has future applications for understanding the underlying mechanisms for microdamage formation as well as three-dimensional nanoscale examination of microdamage.     

Staining and Histomorphometry of Microcracks in the Human Femoral Head

We developed staining techniques that permit identification and histomorphometric analysis of microcracks in the human femoral head 1) from thick, ground bone sections (100 μm) by prestaining with the Villanueva mineralized bone stain (MIBS), and 2) from plastic embedded, undecalcified thin bone sections (5-15 μm) by staining in gallocyanin chrome alum-Villanueva blood stain methods. Both methods represent a significant improvement in the stainability of the microcracks, cellular and tissue elements, and the simultaneous assessment of osteoid seams and tetracycline markers by histomorphometry. Shrinkage and other artifacts were minimized, which helped to clarify some of the uncertainties arising from artifacts resulting from some bone staining methods. Histomorphometric analyses of microcracks were conducted on thick, ground sections of subchondral and trabecular bone. Microcracks were more prevalent in the subchondral bone and osteochondral junction than in the more distant trabeculae. We have consistently localized microcrack areas in bone tissues prepared in these ways.     

A histochemical comparison of methylene-blue/acid fuchsin with hematoxylin and eosin for differentiating calcification of stromal tissue

Benign and malignant connective tissue tumors consist of a fibrous component that contains varying amounts of one or more types of bone or other calcified tissue. Diagnosis of these connective tissue tumors often poses challenges for pathologists, because it is difficult to differentiate the organic matrix of osteoid from hyalinized stroma. To establish a definitive diagnosis, it sometimes is advantageous to demonstrate histologically by special staining either the type of calcification or the presence or absence of calcification. We compared the efficacy of methylene blue-acid fuchsin (MB-AF) to hematoxylin and eosin (H-E) for connective tissue tumors suspected to contain calcifications and to devise an optimal staining technique for calcification that would be specific, simple, and cost- and time-effective. We examined 50 benign and 45 malignant connective tissue tumors that were suspected to contain calcifications. Sections were stained with H-E and MB-AF and evaluated. MB-AF stained bone pink, which contrasted with blue soft tissue. After MB-AF staining, osteoid was faint pink in a blue stromal background. Osteoid was not visualized in H-E stained sections; it was stained the same shade of pink as stromal tissue. Dystrophic calcification and cementum could be identified equally well using either staining technique, but contrast was better after H-E staining. MB-AF staining of bone was comparable to H-E staining and could be used effectively to stain bone and osteoid. MB-AF is a simple, single step procedure. It also stains cementum blue with faint blue rimming and dystrophic calcification bluish-pink, but it cannot be used as a specific stain for types of calcification other than bone and osteoid.