A new technique for staining mast cells using ferroin.

We describe here a new method for specific staining of mast cells using ferroin. Different hamster tissues were fixed in 4% formalin and processed for paraffin embedding. Sections were stained with hematoxylin followed by ferroin acidified with 2.5 N sulfuric acid to pH 4.0. Mast cells stained an intense orange color that contrasted markedly with bluish violet nuclei. High contrast was also observed when ferroin colored sections were counterstained with light green instead of hematoxylin. To evaluate the specificity of the stain, hamster cheek pouch sections were stained with toluidine blue, alcian blue-safranin O, and ferroin. Quantitative evaluation of mast cells stained with the three techniques showed no statistical difference. The simplicity and selectivity of this method is sufficient for image analysis of mast cells.

Modified silver staining of nucleolar organizer regions to improve the accuracy of image analysis.

Silver staining of nucleolar organizer regions (NORs) and their subsequent quantification by image analysis are used increasingly in human pathological specimens and experimental models. Because certain conditions determined by the type of tissue and/or its fixation render AgNOR segmentation for image analysis difficult due to insufficient contrast or nonspecific silver precipitation, we propose three improvements to the original technique to overcome these difficulties. Pretreatment with 7% nitric acid produced very distinct dark brown images of AgNORs on a yellow background. The gradient of background colors allowed easy discrimination of nucleolar, nuclear and cytoplasmic structures. Seven morphometric parameters related to number, size and shape of AgNORs were evaluated quantitatively by image analysis on sections pretreated with nitric acid and on adjacent sections treated with citrate buffer in a wet autoclave according to the most widely accepted method for image analysis of AgNOR. Both methods yielded similar results. A second improvement was achieved by coating the slides with 7% celloidin solution in ethyl alcohol-ether prior to AgNOR staining and acid pretreatment. This coating prevented nonspecific silver deposition on argyrophilic bacteria and other tissue debris in human vaginal smears that could make visualizing AgNOR sites difficult. Finally, placing sections face down on the staining solution prevents the formation of nonspecific silver precipitates. These procedures can be applied together or separately according to the requirements of the material to be evaluated.

Photographic microdensitometry for evaluation of acid phosphatase activity at the electron microscope level.

The dry mass of reaction products in ultrathin sections was determined using electron micrographs of polystyrene spheres of known weight deposited on Formvar membranes and evaluating the negatives photometrically. This method was applied to the quantification of the final reaction product of the acid phosphatase reaction in a model system in which enzyme was incorporated in gelatin. The enzyme activity was demonstrated by the lead precipitation method and quantified by direct microphotometry at the light microscope level. Models were then embedded and sectioned for electron microscopy. Microphotometric values afforded by the electron negatives were in linear correlation with incubation times and enzyme concentration. Section thickness and its possible variations due to deformation or contamination under the electron beam were also evaluated. Measurements of lysosomal acid phosphatase activity in rat kidney sections served to illustrate the application of the technique.