Drug Contamination ; Staining and Labeling ; methods

Biopsy ; Humans ; Kidney ; pathology ; Staining and Labeling ; methods

Axons ; chemistry ; Myelin Sheath ; chemistry ; Staining and Labeling ; methods

Animals ; Humans ; Parasites ; Parasitic Diseases ; pathology ; Staining and Labeling ; methods

OBJECTIVETo study the histochemical staining in the diagnosis of osteosarcoma.

METHODSTo compare the effectiveness of picrosirius red, improved Ponceau trichrome and Masson trichrome staining methods on bone formation tissues in conventional osteosarcoma, paraosteal osteosarcoma, periosteal osteosarcoma, extraskeletal osteosarcoma, inflammatory myofibroblastic tumour, malignant fibrohistiocytoma, chondrosarcoma, fibrosis with ossification and calcification.

RESULTSWith modified Ponceau trichrome staining, bone formation tissues showed a homogenous, orange-red interblended with blue in color. From osteoid to mature bone the color changed from orange-red, light blue to dark blue. Fibrotic tissue was stained blue in color with striated appearance. Cartilage was not stained. Picrosirius red method gave bone formation tissues homogenous staining. Along with bone maturation, from osteoid tissue to mineralized bones, the color showed changes from light red, yellow, orange-red, red to dark purple. The cartilage demonstrated homogenous light red in color. Fibrous tissue stained red interblended with yellow in color, striated in shape. With Masson trichrome staining osteoid displayed pale blue and mineralized bone showed dark blue in color. Fibrotic tissue showed a striated blue staining.

CONCLUSIONThe modified Ponceau trichrome and Picrosirius red staining methods are better than Masson trichrome to demonstrate bone formation tissue in osteosarcoma. The former two methods could be also used in study on bone formation.

OBJECTIVE: To optimize the method for embedding multiple undecalcified mouse tibias in plastic blocks, improve the efficiency and stability of plastic embedding and reduce the detachment rate of plastic slides. METHODS: Thirty undecalcified tibias from 15 B6 mice were used for plastic embedding after calcein labeling, fixation, dehydration and infiltration. The tibias were embedded in cylindrical plastic blocks with a diameter of 4 mm. For each bone, the 1/4 proximal tibia was cut off, and the remaining 3/4 was used for re-embedding. Five bones were embedded in a single block with each bone standing closely on the surface of a flat plate. The samples were randomized into control and experimental groups in all the processes of embedding, sectioning and staining. In the 3 groups with modified embedment, flowing CO was added into the embedding solution, embedding solution was applied to the section surface, and the slides were heated at 95 ℃ for 15 min. The polymerization time, slide detachment rate, bone formation and osteoblast parameters were analyzed. RESULTS: We prepared 6 plastic blocks, each containing 5 tibias, whose cross sections were on the same plane. The blocks were completely polymerized and suitable for sectioning. Flowing CO into the embedding solution reduced the polymerization time and increased the rate of complete polymerization. Application of the embedding solution on the section surface significantly reduced the detachment rate of the sections ( < 0.05) without affecting bone formation analysis ( > 0.05). Heating the slides significantly lowered the detachment rate of the sections ( < 0.05) without affecting osteoblast analysis ( > 0.05). CONCLUSIONS The optimized method allows effective embedding of multiple undecalcified mice tibias in the same block and can be an ideal method for histological analysis of undecalcified bones.
Animals ; Mice ; Plastics ; Staining and Labeling ; Tibia ; Tissue Embedding ; methods

In forensic traumatic pathology practice, immunohistochemistry and special staining technique play an important role in wound age estimation and complications of traumatic complication identification. They even play an important role in the identification of special cases, such as snakebites and insulin killings. This article reviews the application and value of immunohistochemistry and special staining techniques in forensic traumatic pathology based on the cases of forensic practice reported in literature.
Forensic Medicine ; Forensic Pathology/methods* ; Immunohistochemistry ; Staining and Labeling

Histocytochemistry ; methods ; Humans ; Pathology, Clinical ; methods ; Specimen Handling ; methods ; Staining and Labeling ; methods

With the help of computer image analysis system, we used the method of average positive stained area percentage APSAP to evaluate the slice immunohistochemistry result. Then we compared the evaluation result with the result of manual counting. Conformity between the two methods was verified. These data indicated that the method of was in accord with manual counting to a great extent. Moreover, the theory basis, advantages and disadvantages of the method were discussed in this paper.
Humans ; Image Interpretation, Computer-Assisted ; methods ; Immunohistochemistry ; methods ; Staining and Labeling ; methods ; Stomach Neoplasms ; chemistry ; pathology

Coloring Agents ; Frozen Sections ; methods ; Humans ; Neoplasms ; pathology ; Staining and Labeling ; methods