Decalcification for electron microscopy with L-ascorbic acid

L-Ascorbic acid decalcification was used for electron microscopy of mammalian tooth germs and bone after fixation in a glutaraldehyde-paraformaldehyde mixture. The recommended decalcifying solution is 2% with respect to L-ascorbic acid and 0.9% with respect to sodium chloride. The method has the advantage that decalcification is complete within a quarter of the time required with EDTA. The fine structure of ameloblasts and hard tissue is preserved as well as with EDTA.     

Routine acid decalcification of bone marrow samples can preserve DNA for FISH and CGH studies in metastatic prostate cancer.

Production of paraffin-section material from tissue samples that contain bone requires decalcification. Techniques such as acidic decalcification or EDTA chelation are suitable methods. Acid decalcification is generally quicker than EDTA chelation but studies have suggested that it may result in hydrolysis of DNA. Here we show that limited acid decalcification (less than 24 hr) in 5% formic acid can preserve DNA sufficient for fluorescent in situ hybridization (FISH) or comparative genomic hybridization (CGH) and that prolonged 10% formic acid decalcification results in failure of FISH and only limited retrieval of DNA for CGH studies.     

Effects of various decalcification protocols on detection of DNA strand breaks by terminal dUTP nick end labelling

To analyse DNA strand breaks by terminal deoxy(d)-UTP nick-end labelling (TUNEL) in calcified tissues including bones and teeth, it is important to decalcify the tissues first. However, the effects of decalcifying reagents on the integrity of DNA are largely unknown. In the present study, we evaluated the usefulness of various decalcifying reagents including 10% EDTA (pH 7.4), 5% trichloroacetic acid (TCA), 5% formic acid, 5% HCl, 10% nitric acid, Plank–Rychlo's solution, Morse's solution and K-CX solution in TUNEL staining. Mouse maxilla was selected as the experimental system. Apoptotic cells naturally occurring in the epithelium were analysed. Tissues were assessed by soft X-ray imaging to confirm complete decalcification. The time required for decalcification of the tissue was 7 days with 10% EDTA and 2 days with other decalcifiers. Decalcified tissues were stained with Methyl/Green–Pyronine Y or 4, 6-diamidino-2-phenylindole for assessment of DNA integrity. Nuclei of epithelial cells were strongly positive for both dyes after decalcification with 10% EDTA, 5% TCA, Morse's solution and 5% formic acid. The other reagents failed to retain DNA. Our results demonstrated good TUNEL staining of the maxilla treated with 10% EDTA or 5% TCA . Based on the required time for processing and the signal-noise ratio, we recommend 5% TCA as the decalcifying reagent to analyse for DNA strand breaks.     

Infra-red spectroscopic study for decalcification in the dentine

Summary A study was made of spectra of decalcified human dentine being treated with five decalcifying agents to investigate the differences of infrared spectra of decalcified dentine.Solutions of 20% 4-Na-EDTA, 5% HNO₃, 10% sulfosalicylic acid, 10% CCl₃COOH and 10% lithium lactate were used as decalcifying agents. Infrared absorption spectra between 1800 and 650 cm^–1 were obtained for the investigation of the absorption strength at 1033,1095; 1412–1414 to 1450–1455; 875–870; 1649 and 1550 cm^–1 before and after decalcification.The specimens following decalcification with EDTA and HNO₃ showed almost no influences to the absorption strength at 1649 and 1550 cm^–1 of amides. Such absorption spectra were relatively slight in CCl₃COOH and sulfosalicylic acid. The absorption strength at 1033 and 1095 cm^–1 bands of PO ₄ ^––– may indicate a standard of decalcification. Quick and complete decalcification of dentine was performed by HNO₃, CCl₃COOH and sulfosalicylic acid but slower and more incomplete decalcification resulted with EDTA and lithium lactate.     

Fixation and decalcification of adult zebrafish for histological, immunocytochemical, and genotypic analysis

To facilitate the molecular analysis of tissues in adult zebrafish, we tested eight different fixation and decalcification conditions for the ability to yield DNA suitable for PCR and tissue immunoreactivity, following paraffin embedding and sectioning. Although all conditions resulted in good tissue histology and immunocytochemistry, only two conditions left the DNA intact as seen by PCR. The results indicate that zebrafish fixed in either 10% neutral buffered formalin or 4% paraformaldehyde, followed by decalcification in 0.5 M EDTA, is an easy and reliable method that allows molecular experiments and histology to be performed on the same specimen. The fixation and decalcification by Dietrich's solution permitted the PCR amplification of DNA fragments of 250 but not 1000 bp. Therefore, a protocol of formalin or paraformaldehyde fixation followed by decalcification with EDTA is broadly applicable to a variety of vertebrate tissues when excellent histological, immunocytochemical, and genotypic analyses may be simultaneously required.     

Decalcification for histochemical demonstration of hydrolytic and oxidative enzymes

Summary A method for histochemical demonstration of hydrolytic and oxidative enzymes following decalcification was described in mature bone and tooth by neutral EDTA decalcifying solution.The decalcifying solution, 0.5 M EDTA tetrasodium salt was adjusted to neutral pH with 5 M citric acid, obtained the most sufficient results for demonstration of enzymes in decalcified tissue. The hard tissue decalcified in 30 to 40 days at 4° C exhibited a good preservation of hydrolytic and oxidative enzymes histochemically, but a few structural destruction in a long term decalcification was found in soft tissues and certain organs.     

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.     

The effects of different decalcification protocols on TUNEL and general cartilage staining.

Apoptosis is characterized by DNA strand breaks with a 3'-OH terminus, which are analyzed by terminal deoxy(d)-UTP nick end labeling (TUNEL). Proteinase K digestion is thought to be an essential step in the TUNEL procedure. The effects of decalcifying reagents on general staining and the TUNEL assay for cartilage sections are largely unknown. The effects of these reagents on retention and integrity of DNA in chondrocytes have not been described until now. We evaluated the effects of various decalcifying solutions, including 10% EDTA, 10% citric acid, 5% trichloroacetic acid, 5% acetic acid and a commercial hydrochloric acid-based reagent, on general cartilage staining and the TUNEL assay for cartilage. The effects of proteinase K on nucleus preservation were also examined. Decalcification with 10% EDTA gave the best result for general cartilage staining. Chondrocyte DNA was retained and intact after using this reagent. Decalcification with 10% EDTA is also the safest method of decalcification if the TUNEL assay is applied to cartilage. Proteinase K digestion may have adverse effects on nucleus preservation in cartilage. Awareness of these effects is important whenever the TUNEL assay is applied.     

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.     

The effects of different decalcification protocols on TUNEL and general cartilage staining

Apoptosis is characterized by DNA strand breaks with a 3'-OH terminus, which are analyzed by terminal deoxy(d)-UTP nick end labeling (TUNEL). Proteinase K digestion is thought to be an essential step in the TUNEL procedure. The effects of decalcifying reagents on general staining and the TUNEL assay for cartilage sections are largely unknown. The effects of these reagents on retention and integrity of DNA in chondrocytes have not been described until now. We evaluated the effects of various decalcifying solutions, including 10% EDTA, 10% citric acid, 5% trichloroacetic acid, 5% acetic acid and a commercial hydrochloric acid-based reagent, on general cartilage staining and the TUNEL assay for cartilage. The effects of proteinase K on nucleus preservation were also examined. Decalcification with 10% EDTA gave the best result for general cartilage staining. Chondrocyte DNA was retained and intact after using this reagent. Decalcification with 10% EDTA is also the safest method of decalcification if the TUNEL assay is applied to cartilage. Proteinase K digestion may have adverse effects on nucleus preservation in cartilage. Awareness of these effects is important whenever the TUNEL assay is applied.     

A Technique for Decalcification and Demonstration of Substance P-Like Immunoreactivity

Substance P-like immunoreactivity (SPLI) was demonstrated in mouse spinal cord by an indirect immunofluorescence method after decalcification of the vertebra with a mixture of EDTA and Zamboni's fixative. SPLI was observed mainly in the gray matter of the spinal cord, especially the superficial layers of the dorsal horn; the distribution was the same as in the control spinal cord. No diffusion and depletion of SPLI were recognized after decalcification and no specific fluorescence was observed. The findings reported here indicate that decalcification with a mixture of EDTA and Zamboni's fixative is a useful method for examining SPLI in nervous tissue surrounded in situ by calcified tissues.     

A technique for decalcification and demonstration of substance P-like immunoreactivity

Substance P-like immunoreactivity (SPLI) was demonstrated in mouse spinal cord by an indirect immunofluorescence method after decalcification of the vertebra with a mixture of EDTA and Zamboni's fixative. SPLI was observed mainly in the gray matter of the spinal cord, especially the superficial layers of the dorsal horn; the distribution was the same as in the control spinal cord. No diffusion and depletion of SPLI were recognized after decalcification and no specific fluorescence was observed. The findings reported here indicate that decalcification with a mixture of EDTA and Zamboni's fixative is a useful method for examining SPLI in nervous tissue surrounded in situ by calcified tissues.     

Golgi-Cox Impregnation of Peripheral Zone after Coating Tissue with Egg Yolk

Conventional methods of decalcification using acids depolymerize nucleic acids. This is a serious handicap for microspectrophotometric studies on the DNA content of calcified tissues. in the investigation reported here we have evaluated different decalcifying agents for this purpose. Liver, spleen, and maxillae of adult Wistar rats were exposed to the action of nitric acid, picric acid, and EDTA.     

The Effect of Decalcification on the Microspectrophotometric Determination of Dna

Conventional methods of decalcification using acids depolymerize nucleic acids. This is a serious handicap for microspectrophotometric studies on the DNA content of calcified tissues. in the investigation reported here we have evaluated different decalcifying agents for this purpose. Liver, spleen, and maxillae of adult Wistar rats were exposed to the action of nitric acid, picric acid, and EDTA.     

Ethylenediaminetetraacetic Acid in Ammonium Hydroxide for Reducing Decalcification Time

Ethylenediaminetetraacetic acid (EDTA) solution is used to decalcify bone specimens for histological examination. Sodium hydroxide (NaOH) has been used to dissolve EDTA and to bring EDTA solutions to neutral pH. This solution, however, requires several weeks to decalcify bone specimens. We investigated a new de-calcification fluid using concentrated ammonium hydroxide (NH₄OH) to dissolve EDTA and to adjust the pH to neutral. Decalcification was performed using a magnetic stirrer with and without vacuum, or with a sonic cleaner. Decalcification end point was confirmed using both the weight loss and X-ray methods. After decalcification, specimens were processed through paraffin and sections were stained with hematoxylin and eosin. Decalcification employing NH₄OH required an average of six days. Light microscopy indicated good retention of cellular detail.     

Stain Solubilities Part III

Ethylenediaminetetraacetic acid (EDTA) solution is used to decalcify bone specimens for histological examination. Sodium hydroxide (NaOH) has been used to dissolve EDTA and to bring EDTA solutions to neutral pH. This solution, however, requires several weeks to decalcify bone specimens. We investigated a new de-calcification fluid using concentrated ammonium hydroxide (NH₄OH) to dissolve EDTA and to adjust the pH to neutral. Decalcification was performed using a magnetic stirrer with and without vacuum, or with a sonic cleaner. Decalcification end point was confirmed using both the weight loss and X-ray methods. After decalcification, specimens were processed through paraffin and sections were stained with hematoxylin and eosin. Decalcification employing NH₄OH required an average of six days. Light microscopy indicated good retention of cellular detail.     

A method to determine the end point of decalcification of hard tissue and bone

A method for decalcification end point determination of mineralized tissue is described. The calcium content of the decalcification solution was determined colorimetrically with a "continuous automatic analyzer" with a high degree of accuracy. The end point method used has been tested on two decalcification methods, 5% nitric acid with or without ultrasonic treatment. The results suggest it is possible to quantitate the decalcification process.     

An Improved Method of Decalcification

Following several experimental investigations, an improved method of decalcification has been devised. The principle of this decalcification method is to obtain complete decalcification by a mixture of as high pH as possible without diminishing the stainability of the Nissl-granules (with Einarson's progressive staining method by means of gallocyanin). This is accomplished by the help of a buffer solution of equal parts of 8 N formic acid and 1 N sodium formate (pH 2.2). After-treatment consists only in rinsing in flowing water for 24 hours. Dehydration is in alcohol (70%, 96%, 100%); cedar oil; ligroin. Embedding in paraffin follows.     

A Method to Determine the end Point of Decalcification of Hard Tissue and Bone

A method for decalcification end point determination of mineralized tissue is described. The calcium content of the decalcification solution was determined colorimetrically with a “continuous automatic analyzer” with a high degree of accuracy. The end point method used has been tested on two decalcification methods, 5% nitric acid with or without ultrasonic treatment. The results suggest it is possible to quantitate the decalcification process.     

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.