Safranin and Anilin Blue with Delafield's Hematoxylin for Staining Cell Walls in Shoot Apexes

The following technic is suggested for staining cell walls in shoot apexes: After the usual preliminary steps through 50% ethyl alcohol, stain in 1 % safranin 0 for 24 hours. Rinse in tap water and place in 2% aqueous tannic acid for 2 minutes. After rinsing in tap water, stain for 2 minutes in 1 part Delafield's hematoxylin to 2 parts distilled water and rinse in tap water. Remove excess hematoxylin with acidified water (1 drop cone. HC1 in 200 ml. water), then place slides in 0.5% lithium carbonate for 5 minutes. Dehydrate through an ethyl alcohol series, then transfer from absolute alcohol to a saturated solution of anilin blue in “methyl cellosolve” for 5-10 minutes. Wash in absolute alcohol, rinse in a solution of 25% methyl salicylate, 33% xylene, 42% absolute ethyl alcohol and clear for 10 minutes in a solution of 2 parts methyl salicylate, 1 part xylene, 1 part absolute ethyl alcohol. Transfer through two changes of xylene and mount in “clarite” or suitable alternate. The resulting preparations will have clearly defined, dark-staining cell walls and will photograph well when “Super Panchro-Press, Type B” film (Eastman Kodak Co.) is used in conjunction with suitable Wratten filters.     

Safranin and Anilin Blue with Delafield's Hematoxylin for Staining Cell Walls in Shoot Apexes

The following technic is suggested for staining cell walls in shoot apexes: After the usual preliminary steps through 50% ethyl alcohol, stain in 1 % safranin 0 for 24 hours. Rinse in tap water and place in 2% aqueous tannic acid for 2 minutes. After rinsing in tap water, stain for 2 minutes in 1 part Delafield's hematoxylin to 2 parts distilled water and rinse in tap water. Remove excess hematoxylin with acidified water (1 drop cone. HC1 in 200 ml. water), then place slides in 0.5% lithium carbonate for 5 minutes. Dehydrate through an ethyl alcohol series, then transfer from absolute alcohol to a saturated solution of anilin blue in “methyl cellosolve” for 5-10 minutes. Wash in absolute alcohol, rinse in a solution of 25% methyl salicylate, 33% xylene, 42% absolute ethyl alcohol and clear for 10 minutes in a solution of 2 parts methyl salicylate, 1 part xylene, 1 part absolute ethyl alcohol. Transfer through two changes of xylene and mount in “clarite” or suitable alternate. The resulting preparations will have clearly defined, dark-staining cell walls and will photograph well when “Super Panchro-Press, Type B” film (Eastman Kodak Co.) is used in conjunction with suitable Wratten filters.     

Destaining Agents for Iron Alum Hematoxylin

Detailed directions for using various destaining agents after iron alum hematoxylin are given. A saturated aqueous solution of picric acid is recommended for bringing out nuclei in whole mounts of protozoa. Differentiation with a mixture of 1 part 30% hydrogen peroxide, and 2 parts, 95% alcohol, is useful for cytoplasmic structures. Greater reliability and precision are claimed for these methods as compared with the conventional differentiation in iron alum.     

In Toto Staining and Preservation of Peripheral Nervous Tissue

A simple quantitative modification of the in toto staining technique for nervous networks of Sihler is described. The results are demonstrated on the innervation pattern of the hard palate of the rat. Formalin fixed hard palates of rat were macerated and bleached in an aqueous solution of 3% potassium hydroxide with a few drops of 3% hydrogen peroxide added. Thereafter, the specimens were decalcified in Sinter's solution I (1 part glacial acetic acid, 1 part pure glycerin and 6 parts 1% chloral hydrate), the process being controlled by radiography. The specimens were next stained in Sutler's solution II (1 part Ehrlich's hematoxylin, 1 part pure glycerin and 6 parts 1% chloral hydrate). After staining, the non-nervous tissues were destained in Sihler'g solution I. Destaining was checked microscopically and was stopped before the finest branches of the nerves began to fade. The specimens were then washed in a weak aqueous solution of lithium carbonate and cleared in increasing concentrations of glycerin. Good visualization of nervous structures and a deep field of observation resulted; orientation of the peripheral nerves with respect to surrounding structures was readily seen and a three-dimensional image of the nervous networks was obtained.     

In toto staining and preservation of peripheral nervous tissue

A simple quantitative modification of the in toto staining technique for nervous networks of Sihler is described. The results are demonstrated on the innervation pattern of the hard palate of the rat. Formalin fixed hard palates of rat were macerated and bleached in an aqueous solution of 3% potassium hydroxide with a few drops of 3% hydrogen peroxide added. Thereafter, the specimens were decalcified in Sihler's solution I (1 part glacial acetic acid, 1 part pure glycerin and 6 parts 1% chloral hydrate), the process being controlled by radiography. The specimens were next stained in Sihler's solution II (1 part Ehrlich's hematoxylin, 1 part pure glycerin and 6 parts 1% chloral hydrate). After staining, the non-nervous tissues were destained in Sihler's solution I. Destaining was checked microscopically and was stopped before the finest branches of the nerves began to fade. The specimens were then washed in a weak aqueous solution of lithium carbonate and cleared in increasing concentrations of glycerin. Good visualization of nervous structures and a deep field of observation resulted; orientation of the peripheral nerves with respect to surrounding structures was readily seen and a three-dimensional image of the nervous networks was obtained.     

Differentiation of Two Types of Basophils In The Adenohypophysis of The Rat and The Mouse

Pituitaries are fixed for 24 hr. in Bouin's fluid containing 0.5% trichloroacetic acid instead of 5% acetic acid, or in a mixture of 9 parts SUSA and 1 part saturated aqueous solution of picric acid. They are embedded in paraffin and horizontal sections are cut at 3-4 μ. The staining method consists of 3 phases: (a) immersion in aldehyde-fuchsin for the selective demonstration of the beta cell granules, (b) staining of the nuclei with Ehrlich's hematoxylin and (c) a rapid one-step counterstain with light green and orange G dissolved in a phosphotungstic-acetic acid mixture for the differentiation of the acidophilic and the delta cell granules.     

A Single solution iron-hematoxylin Stain for Intestinal Protozoa

A single solution iron-hematoxylin stain is described for staining fecal smears rapidly and simply. The stain is prepared from the following solutions: Solution A: 1% hematoxylin in 95% alcohol, prepared by diluting a stock solution of 10% hematoxylin in 95% alcohol. Solution B: Ferric ammonium sulfate (violet crystals), 4.0 g.; glacial acetic acid, 1.0 ml.; concentrated sulfuric acid (sp. gr. 1.8),0.12 ml.; distilled water, 100 ml. Mix equal parts of Solution A and Solution B; allow to stand overnight, filter and use. For maximum length of staining life, store in full, air-tight bottles. To stain fecal smears, fix in Schaudinn's, pass through iodine alcohol to 50% alcohol, stain for three minutes, wash in running tap water 5 to 15 minutes, dehydrate and mount.     

A Single solution iron-hematoxylin Stain for Intestinal Protozoa

A single solution iron-hematoxylin stain is described for staining fecal smears rapidly and simply. The stain is prepared from the following solutions: Solution A: 1% hematoxylin in 95% alcohol, prepared by diluting a stock solution of 10% hematoxylin in 95% alcohol. Solution B: Ferric ammonium sulfate (violet crystals), 4.0 g.; glacial acetic acid, 1.0 ml.; concentrated sulfuric acid (sp. gr. 1.8),0.12 ml.; distilled water, 100 ml. Mix equal parts of Solution A and Solution B; allow to stand overnight, filter and use. For maximum length of staining life, store in full, air-tight bottles. To stain fecal smears, fix in Schaudinn's, pass through iodine alcohol to 50% alcohol, stain for three minutes, wash in running tap water 5 to 15 minutes, dehydrate and mount.     

Chelating Agents as Histological and Histochemical Decalcifiers

The alterations caused by chelating agents (disodium ethylenediaminetetraacetate) used as decalcifying solutions at pH 7.0, in histological and histochemical technics have been studied comparatively. They have been controlled by the staining with hematoxylin and eosin, Gomori's aldehyde fuchsin, periodic acid-Schiff, metachromasia, and alkaline phosphatase. Their effect on the tissues was similar to that of buffered acid decalcifying solutions, such as that of Greep, Fischer and Morse (equal parts of 2% formic acid and 20% sodium citrate).

The use of 1% sodium diethylbarbiturate for 24 hr as a reactivating agent for alkaline phosphatase in the specimens treated with chelating agents is recommended.     

Mallory's Connective Tissue Stain Following Hematoxylin

The following combination of hematoxylin with Mallory's connective tissue stain is useful in bringing out nuclei as well as in differentiating tissue:

Slightly overstain in Mayer's hematoxylin (50 g. potassium alum and 0.2 g. sodium iodate added to 1 liter 0.1% aqueous hematoxylin). Wash; and stain 30 seconds to 1 minute in 0.04% aqueous acid fuchsin-Stain 4 minutes in: 0.5 g. anilin blue and 2 g. orange G dissolved hi 100 cc. of 1% aqueous phosphomolybdic acid. Pass thru 95% alcohol to absolute; clear in xylol and mount in balsam.     

An Evaluation and Modification of Cole's Hematoxylin

Consistency in staining with an alum hematoxylin is possible by the routine use of fresh staining solutions. A modification of Cole's hematoxylin is so easily prepared that fresh staining solutions present no problem. The staining solution consists of 100 ml 1.2% aqueous KA1(SO₄)₂ .12 H₂O, 1 ml 10% alcoholic hematoxylin and 2 ml 1% iodine. Mix, place in paraffin oven overnight and stain sections 5 minutes. The three solutions can be kept as stock solutions for years.     

Detection of Batrachochytrium dendrobatidis in Eleutherodactylus fitzingeri: effects of skin sample location and histologic stain

Batrachochytrium dendrobatidis is a fungal pathogen that has been implicated in amphibian declines worldwide. Histopathologic techniques have been used to diagnose the disease, but their sensitivity has not been determined. It is also unclear whether the probability of detection varies between skin samples derived from different body parts. We examined 24 Fitzinger's rainfrogs (Eleutherodactylus fitzingeri) with chytridiomycosis. This is a common frog species with a broad range and high abundance throughout most of Costa Rica. We sampled 12 different body parts from each animal, and alternated the staining between a routinely used stain (hematoxylin and eosin [H&E]), and a more fungus-specific stain (periodic acid-Schiff [PAS]). The pelvic patch and the innermost finger of the hand were consistently the best places to detect the disease, although significant differences were found only with the gular area, the abdomen, and toes four and five. We found more positive samples using PAS than using H and E in all body parts, although significant differences were detected only in samples derived from the pelvic patch. Using the best combination of factors (stain and body part) and animals with the lightest infections (to test the sensitivity of the technique), we calculated that at least 17 sections are needed in order to reach 95% confidence that a frog is or is not infected. We conclude that the choice of stain and body part can significantly alter estimates of prevalence of B. dendrobatidis.     

K-ras Gene Mutation Related to Histological Atypias in Human Colorectal Adenomas

To investigate the relationship of oncogene analysis to morphology, we analyzed K-ras gene mutations by dot-blot hybridization with and without consideration of histological atypias in individual colorectal adenomas. Each of 54 colon polyps were divided into two parts after fixation. One part was used as a mass to assess point mutations; the remaining portion of each polyp was paraffin-embedded, stained with hematoxylin and eosin, and examined for point mutations related to histological atypias. In the first part of our study, K-ras gene mutations at codon 12 were detected in 13 cases (24%). In the second part of our study, 12 cases had distinctly different histological atypias. From each of these 12 cases, two areas, one with higher or one with lower grade atypia in the same polyp were excised to analyze for K-ras gene mutation. Two of these 12 cases (17%) had the mutation in different areas of the same tumor. These two cases contained the mutation only in the areas with higher grade atypia, and only one case added information regarding ras mutation upon microdissection when compared to the entire biopsy. These results suggest that oligonucleotide hybridization can identify the majority of cases containing ras mutations despite regional morphologic variation. Individual cases, however, may contain clonal subpopulations within adenomas with different ras sequences from other regions within the same adenoma.     

Fresh Tissue Diagnosis in the Operating Room

A polychromatic stain giving color reactions closely simulating hematoxylin and eosin, without overstaining and obscuring the finer detail of the cell, has been developed in this laboratory. It is as follows: To 4 parts of 1% aqueous azure A (azure I) which has been previously filtered, add very rapidly one part of filtered 0.5% aqueous Erie garnet B. The mixture is immediately filtered to prevent precipitation. Occasional refiltering may be necessary if the mixture has been standing a month or more. Float tissue slices from a freezing microtome directly into distilled water; pick them up with a round glass rod and immerse into the stain which has been poured into a small section dish. The staining time varies with different tissues but 10 to 15 seconds usually gives the most satisfactory results. Lift sections from the stain, still on the same glass rod, float thru two changes of distilled water, and then transfer to a clean glass slide. Place a large drop of 40% glucose on a clean cover slip and immediately invert over the section. The mounted specimen is then ready for microscopic examination. In examining the tissues under the microscope it is best to employ an intense artificial light (an ordinary 40 or 60 watt bulb is sufficient). After mounting, one-half to one minute should elapse before examining the section to allow it to clear.     

The Surface Staining of Embedded Tissues

The staining procedure is based on the theory that the freshly cut surface of embedded material will absorb stain only in the exposed tissue elements, provided that the embedding compound itself will not absorb the staining fluid. Concentrated stains are used for short intervals to insure minimum penetration. For paraffin embedded materials: (1) Cut block, preferably on microtome, to the desired tissue surface. (2) Rinse in absolute alcohol. (3) Float face down in stain. (Ripe, concentrated alum hematoxylin—Galigher's formula recommended—will stain in 10 to IS minutes. Heidenhain's iron hematoxylin works exceptionally well in some cases.) Mordant 20% alum 5 to 10 minutes, briefly rinse, and stain comparable 5 to 10 minutes in 1 to 1.5% hematoxylin. (4) Allow to become blue in tap water (for hematoxylin stains). (5) Counter-stain if desired. (6) Dehydrate in absolute alcohol for not more than 10 minutes. (7) Dry for 15 to 20 minutes. (8) Trim block to 2-3 mm. and mount between two cover glasses by use of microflame. Attach mount to slide with balsam. For celloidin embedded materials: (1) Dehydrate block with 90% alcohol, phenol-toluene, finally pure toluene. (2) Rinse cut surface with 90% alcohol, then apply stain. (3) Wash, after hematoxylin stains, counterstain if desired. (4) Dehydrate surface, 90% alcohol, phenol toluene, pure toluene, and mount in medium dissolved in toluene.

Possible applications of surface staining technic are suggested and illustrated.     

An Improved Hematoxylin-Eosin Stain for Sections of Marrow Units

The procedure recommended is: Fix “marrow units” (small functional structures of bone marrow) in 10% formol-saline solution for 1-2 hours and dehydrate in 80% alcohol, 95% alcohol and acetone 30 minutes each. Place in fresh 50° and 53°C. paraffin for 30 minutes each. Embed in fresh 53°C. paraffin. Serially section at 5μ thickness and mount with Schleicher's floating solution. Allow to dry for 1 hour in an oven and deparaffinize by passing through xylene I and II, absolute alcohol I and II, and 95% alcohol. Rinse in fresh distilled water and place in dilute Harris' hematoxylin (stock solution 50 ml., distilled water 200 ml.) for 2 to 3 minutes. Rinse well in distilled water and check staining under the microscope. Dip in acid-alcohol 5 times (1 dip to equal about 1 second). Rinse well in weak (0.02%) ammonia water and distilled water. Dip in 2% aqueous phosphotungstic acid about 3 to 5 times (equal to 3-5 seconds). Rinse in fresh distilled water and place in weak ammonia water for 1 minute. Rinse in fresh distilled water I and II. Place in 80% alcohol for 5 minutes and check under the microscope for “blueness” and nuclear differentiation. Place in dilute alcoholic eosin (0.5% alcohol-eosin stock solution 10 parts and 95% alcohol 90 parts) for 1 to 2 minutes. Rinse in 80% alcohol and place for 1 minute in 95% alcohol. Check under the microscope for staining quality. Place in absolute alcohol for 1 minute, alcohol-xylene (equal parts), 10 dips, and xylene I and II. Mount. This hematoxylin-eosin staining schedule brings out minute structural detail of bone marrow tissue heretofore not demonstrable.     

A Method for Making Aceto-Carmin Smears Permanent

Anthers are collected and placed in a solution of 1 part acetic acid to 3 parts of absolute alcohol. The contents of the anther are squeezed out on a slide in a drop of Belling's iron-aceto-carmin solution and a cover glass placed over the drop. Care should be taken to remove all anther walls and flower parts. Heat the slide over an alcohol flame for a second, repeating 4 or 5 times. Place the slide in a petri dish filled with a 10% solution of acetic acid. When the cover glass has risen away from the slide gently remove the cover glass and place in a Coplin jar containing equal parts of alcohol and acetic acid. Likewise, place the slide in this solution. Run both cover and slide thru the following solutions: 1 part acetic acid to 3 parts absolute alcohol, 1 part acetic acid to 9 parts absolute alcohol, absolute alcohol and finally equal parts of absolute alcohol and xylol. Recombine the cover and slide in xylol-balsam directly from this solution.     

A Method for Making Aceto-Carmin Smears Permanent

Anthers are collected and placed in a solution of 1 part acetic acid to 3 parts of absolute alcohol. The contents of the anther are squeezed out on a slide in a drop of Belling's iron-aceto-carmin solution and a cover glass placed over the drop. Care should be taken to remove all anther walls and flower parts. Heat the slide over an alcohol flame for a second, repeating 4 or 5 times. Place the slide in a petri dish filled with a 10% solution of acetic acid. When the cover glass has risen away from the slide gently remove the cover glass and place in a Coplin jar containing equal parts of alcohol and acetic acid. Likewise, place the slide in this solution. Run both cover and slide thru the following solutions: 1 part acetic acid to 3 parts absolute alcohol, 1 part acetic acid to 9 parts absolute alcohol, absolute alcohol and finally equal parts of absolute alcohol and xylol. Recombine the cover and slide in xylol-balsam directly from this solution.     

The Use of Buffered Solutions in Staining: Theory and Practice

The importance of pH in staining tissue is emphasized. The effect of pH upon the selectivity and intensity of staining with iron hematoxylin, malachite green, and eosin Y is considered. Many difficulties may be avoided by staining in the higher alcohols and directions are given for the preparation of buffer solutions from pH 1.2-8 in alcohol. The concentration of stains, time of staining, and order of staining are discussed for progressive and regressive staining. At pH 8 in 95% alcohol very few tissues stain with malachite green at a concentration of 1/1000 saturated. At pH 6 most cytoplasmic elements stain with malachite green at a concentration of 1/1000 saturated or with eosin Y at 1/250 saturated. As the pH is lowered more tissue elements stain until the nucleus is completely stained. This behavior is in accord with the theory of chemical combination of dyes with proteins, which states that proteins combine with basic dyes on the basic side of their isoelectric points and with acid dyes on the acid side of their isoelectric points. With hematoxylin stain the pH range is much shorter. A satisfactory hematoxylin stain is composed of 0.1% hematoxylin, 0.1% FeCl₃, and HCl to bring the pH to 1.2-1.6 in 80% alcohol. With this stain, which may be used immediately, the nuclei of most tissues begin to stain at pH 1.2 and much of the cytoplasm will be stained if the pH is raised to 1.4. The shortness of this effective pH range is thought to be due to the dissociation of the hematoxylin-iron-protein complex. The use of different dyes successively at different pH values, such as hematoxylin at 1.3, malachite green at 8, and eosin at 6, permits better differentiation of the tissue elements, and intelligent variations in the staining technic.     

K-ras Gene Mutation Related to Histological Atypias in Human Colorectal Adenomas

To investigate the relationship of oncogene analysis to morphology, we analyzed K-ras gene mutations by dot-blot hybridization with and without consideration of histological atypias in individual colorectal adenomas. Each of 54 colon polyps were divided into two parts after fixation. One part was used as a mass to assess point mutations; the remaining portion of each polyp was paraffin-embedded, stained with hematoxylin and eosin, and examined for point mutations related to histological atypias. In the first part of our study, K-ras gene mutations at codon 12 were detected in 13 cases (24%). In the second part of our study, 12 cases had distinctly different histological atypias. From each of these 12 cases, two areas, one with higher or one with lower grade atypia in the same polyp were excised to analyze for K-ras gene mutation. Two of these 12 cases (17%) had the mutation in different areas of the same tumor. These two cases contained the mutation only in the areas with higher grade atypia, and only one case added information regarding ras mutation upon microdissection when compared to the entire biopsy. These results suggest that oligonucleotide hybridization can identify the majority of cases containing ras mutations despite regional morphologic variation. Individual cases, however, may contain clonal subpopulations within adenomas with different ras sequences from other regions within the same adenoma.