A Chemical and Histochemical study of the Technic for acid Phosphatase

A chemical and histochemical study of Gomori's acid phosphatase technic showed that the causes of its unreliability were: (1) that fixation and other steps of histological procedure inactivate the enzyme to a great extent; (2) the enzyme may diffuse, as demonstrated in frozen sections of acetone-fixed material; and (3) some absorption of lead by the sections takes place. Much of this unreliability is avoided, however, by maintaining as low a temperature as possible during fixation and dehydration, with exposure to the temperature of the paraffin oven for the shortest possible length of time. The relative insolubility and thermo-stability of the enzyme, moreover, indicate the possibility of devising a more satisfactory technic in the future.     

A New Hematological Stain: I. Constituents and Methods of Use

The stain proposed by the author is quickly and simply prepared by mixing equal parts of the following permanent stock solutions:

The mixed stain is usable, for at least eight months, and is applicable to practically all hematological purposes: blood smears, fixed sections, frozen sections, and touch preparations. In the technics utilized to produce its action on preparations treated in different ways, the only variants are the methods for treating the cells, while the stain itself remains totally unchanged for all purposes. For blood smears fixed with methyl alcohol, the technic consists merely of pouring the stain on the slide, leaving it for 5 to 7 minutes, and then washing it off. On sections, a further process of differentiation with acid acetone is rapidly carried out. The various types of granules, including megakaryocyte and platelet granules, are clearly demonstrated. For frozen sections, the technic is extremely rapid, yet yields excellent differentiation.     

Thin Sections from Unfixed Tissues for Histochemical Staining

Sections were cut from fresh unfixed tissues by means of a microtome provided with an apparatus for the simultaneous cooling of the knife and freezing stage. These sections were of uniform thickness and were found to be very suitable for histochemical staining. Such sections were immersed while still frozen in the fluid which contained the necessary chemicals for a specific technic. After remaining in the fluid for an appropriate time, the sections were put on slides and dried in warm air. The remaining steps were carried out on the slides. Several histochemical procedures (phosphatase, esterase, glycogen) were found to give good results when this technic was used.     

A Protargol Method for Staining Nerve Fibers in Frozen or Celloidin Sections

Extensive experimentation with protargol staining of neurons in celloidin and frozen sections of organs has resulted in the following technic: Fix tissue in 10% aqueous formalin. Cut celloidin sections IS to 25 μ, frozen sections 25 to 40 μ. Place sections for 24 hours in 50% alcohol to which 1% by volume of NH₄OH has been added. Transfer the sections directly into a 1% aqueous solution of protargol, containing 0.2 to 0.3 g. of electrolytic copper foil which has been coated with a 0.5% solution of celloidin, and allow to stand for 6 to 8 hours at 37° C. Caution: In this and the succeeding step the sections must not be allowed to come in contact with the copper. From aqueous protargol, place the sections for 24 to 48 hours at 37° C. directly into a pyridinated solution of alcoholic protargol (1.0% aqueous solution protargol, 50 ml.; 95% alcohol, 50 ml.; pyridine, 0.5 to 2.0 ml.), containing 0.2 to 0.3 g. of coated copper. Rinse briefly in 50% alcohol and reduce 10 min. in an alkaline hydroquinone reducer (H₃BO₃, 1.4 g.; Na₂SO₃, anhydrous, 2.0 g.; hydroquinone, 0.3 g.; distilled water, 85 cc; acetone, 15 ml.). Wash thoroly in water and tone for 10 min. in 0.2% aqueous gold chloride, acidified with acetic acid. Wash in distilled water and reduce for 1 to 3 min. in 2% aqueous oxalic acid. Quickly rinse in distilled water and treat the sections 3 to 5 min. with 5% aqueous Na₂S₂O₃+5H₂O. Wash in water and stain overnight in Einarson's gallocyanin. Wash thoroly in water and place in 5% aqueous phosphotungstic acid for 30 min. From phosphotungstic acid transfer directly to a dilution (stock solution, 20 ml.; distilled water, 30 ml.) of the following stock staining solution: anilin blue, 0.01 g.; fast green FCF, 0.5 g.; orange G, 2.0 g.; distilled water, 92.0 ml.; glacial acetic acid, 8 ml.) and stain for 1 hour. Differentiate with 70% and 95% alcohol; pass the sections thru butyl alcohol and cedar oil; mount.     

Nile Blue Histochemical Method for Phospholipids

The technic recommended is: Fix 6-12 hr. in 10% formalin containing 1% CaCl₂. Cut frozen sections without embedding or after gelatin or carbowax. Stain 90 min. at 60°C. in saturated aqueous Nile blue sulfate, 500 ml. plus 50 ml. of 0.5% H₂SO₄, boiled 2 hr. before use. Rinse in distilled water, and place in acetone heated to 50°C. Remove the acetone from the source of heat and allow the sections to remain 30 min. Differentiate in 5% acetic acid 30 min., rinse in distilled water, and refine the differentiation in 0.5% HCl for 3 min. Wash in several changes of distilled water and mount in glycerol jelly. Results: phospholipids - blue; everything else - unstained. Counterstaining nuclei with safranin is optional, but if done, it preferably precedes the Nile blue and is then differentiated by the acetic acid. The histochemical principles on which the method is based are as follows: (1) The calcium compounds of phospholipids combine with the oxazine form of Nile blue sulfate and survive subsequent treatment; (2) neutral lipids are dissolved out by acetone; (3) proteins and other interfering substances are destained by the acetic acid and hydrochloric acid baths.     

Frozen Sections from Bouin-Fixed Material in Histopathology

It has become almost a dogma that, for obtaining satisfactory frozen sections, fixation of the tissues in formalin is necessary; formalin is exclusively recommended for this purpose in the textbooks of microscopical and pathological technic.¹ It has, however, several important disadvantages, which become the more acutely felt when fixation in more than one fixative is impossible, as happens so often in surgical pathology. When, after the preparation of the frozen sections, embedding in paraffin is necessary, formalin-fixed tissues show a marked shrinkage, especially when rapid embedding methods (e. g. dioxane) are used. This shrinkage can only be prevented by the time-consuming hardening of the blocks in K₂Cr₂O₇. The trichrome stains, the phosphotungstic-hematoxylin stain and the azan method, which are slowly superseding the hematoxylin-eosin and van Gieson stains in histopathology, give only mediocre or inferior results after formalin fixation, unless the sections are refixed.     

The Rapid Preparation of Frozen Tissue Sections

The essential feature of this procedure involves the rapid freezing of the tissue following excision and keeping it frozen until the desired chemical or fixative has been applied. For freezing, either carbon dioxide or liquid air is used, as desired. The microtome knife is thoroughly cooled by taping blocks of dry ice to its surface. The cut sections, still frozen, are manipulated by a camel's hair brush so that they lie flat upon the knife. They are then transferred to a slide by a special section lifter. This has the form of a double-bottomed scoop packed with dry ice. Thus the section remains frozen while it is transferred to a clean microscope slide held at an angle above a Coplin jar of the desired reagent. The sections must be immersed just prior to melting. They curl and do not adhere to the slide if still rigidly frozen, and are distorted if immersed after melting.

With this technic sections showing a minimum of cellular distortion may be obtained. Consequently, it facilitates the use of many cytological technics, chemical tests, and enzymatic studies, such as the Gomori technics, on a variety of tissues.     

Distribution of acid phosphatase, beta-glucuronidase, n-acetyl-beta-d-glucosaminidase and beta-galactosidase in cornea of albino rabbit.

Activities of acid phosphatase, beta-glucuronidase, N-acethyl-beta-D-glucosaminidase and acid beta-galactosidase were investigated histochemically in rabbit corneas. Frozen sections after block fixation in cold 4% formaldehyde with 1% CaCl2 followed by washing in cold physiological saline as well as cold microtome sections of corneas quenched in petroleter chilled with acetone-dry ice mixture, transferred to nonprecooled slides or semipermeable membranes were used. Standard aqueous media were employed in the case of free-floating frozen sections of fixed corneas as well as of cold mictrotome sections (postfixed in cold 4% formaldehyde). Agar media were used in connection with the technic of semipermeable membranes. Gomori method (in the case of acid phosphatase), simultaneous azocoupling methods (substrates derivated of naphthol-AS-BI with hexazonium-p-rosanilin) in the case of acid phosphatase, beta-glucuronidase and N-acetyl-beta-D-glucosaminidase and the indigogenic method in the case of acid beta-galactosidase were applied. Enzyme activities in sections of fixed corneas were minimal in comparison with those in cold microtome sections of unfixed material revealed particularly with the technic of semipermeable membranes which is to be preferred. This technic is recommended in studies concerned with lysosomal enzymes in the cornea, particularly in keratocytes. All enzymes investigated were present in corneal epithelium, keratocytes and endothelium. Acid phosphatase displayed the highest activity followed by beta-glucuronidase and acetyl-beta-D-glucosaminidase. The activity of beta-galactosidase was the lowest. For the demonstration of activities in keratocytes sections parallel to the surface are very suitable. In these sections enzyme activities were demonstrated in small granules (apparently lysosomes) present in the central part of their cytoplasm as well as in projections. Diffuse staining was also seen, being the highest in the case of acid phosphatase.     

Acid Thionin Stain for Nissl Bodies on Frozen Sections

Using a buffered acid thionin stain with carbolxylene as a clearing agent, a reliable stain for Nissl bodies may be performed on frozen sections of fresh or old formalin-fixed material in a relatively short period of time. The technic is simple: the buffering of thionin makes regressive differentiation unnecessary.     

Polarized Light Technic A Comparison with the Marchi Method

The authors compare polarized light technic for the study of degeneration of myelinated nerves with the Marchi method. While polarized light shows much the same thing, it has the advantages of being much more rapid, more sensitive, and constant. It does not depend on fixation and staining but on the chemical structure of the myelin substance. These changes in structure begin before the third hour after cutting the nerve of a rat. No further technic is involved beside the making of frozen sections. Photographs are presented to illustrate the method.     

A Durable Nissl Stain for Frozen and Paraffin Sections

Frozen sections, 25-50 /j. thick, of formalin-fixed nervous tissues are mounted following the Albrecht gelatin technic. Paraffin sections, 15 p., are deparaffinized and transferred to absolute ethanol. The slides are then coated with celloidin. Both frozen and paraffin sections subsequently follow the same steps: absolute ethanol-chloroform (equal parts) for at least 20 min, 95% ethanol, 70% ethanol (1-3 min), then rinsed in distilled water. Sections are stained in Cresylechtviolett (Chroma) 0.5% aqueous solution containing 4 drops of glacial acetic acid per 100 ml, rinsed in distilled water, agitated in 70% ethanol until excess stain leaves the slide, and rinsed in 95% ethanol. Sections are then dehydrated in absolute ethanol, followed by butanol, cleared in xylene, and enclosed in permount.     

The Weigert-Pal Technic for Staining Myelin

The writer gives a schedule for carrying out the Weigert-Pal technic by which three difficulties of the original technic are overcome: the tendency of the sections to become brittle; the difficulty of observing the extent of the reaction occurring in the permanganate solution; and the slowness with which the reaction takes place. By the method proposed as many as 300 sections may be stained and differentiated in the time it formerly took to handle 50.     

The Weigert-Pal Technic for Staining Myelin

The writer gives a schedule for carrying out the Weigert-Pal technic by which three difficulties of the original technic are overcome: the tendency of the sections to become brittle; the difficulty of observing the extent of the reaction occurring in the permanganate solution; and the slowness with which the reaction takes place. By the method proposed as many as 300 sections may be stained and differentiated in the time it formerly took to handle 50.     

Procion yellow staining of motoneurones in the frog.

Intracellular recording and subsequent staining of spinal motoneurones in the frog was made by procion-filled micropipettes. Spike discharges in response to dorsal root (DR) and ventral root (VR) volleys as well as to direct current injections were studied. Reconstruction of the dendritic tree of the cell stained after recording was made from photomicrographs taken from frozen serial sections of the spinal cord. Migration of the dye into a neighbouring unimpaled cell was observed. The advantages of the procion injection technique in studying the frog's spinal cord physiology are discussed.     

The Hortega Silver Carbonate Method for Staining Pituicytes After Paraffin Embedding

In three papers published on pituicytes, of the ox by Bucy (1930), of the human by Shanklin (1940), and of the horse by Vazquez-Lopez (1942) the pituitaries were sectioned by the freezing method and stained by the Hortega silver carbonate technic. Since that time, as a routine procedure in our laboratory, frozen sections have been replaced by paraffin which in no way interferes with the Hortega silver carbonate staining.     

The Hortega Silver Carbonate Method for Staining Pituicytes After Paraffin Embedding

In three papers published on pituicytes, of the ox by Bucy (1930), of the human by Shanklin (1940), and of the horse by Vazquez-Lopez (1942) the pituitaries were sectioned by the freezing method and stained by the Hortega silver carbonate technic. Since that time, as a routine procedure in our laboratory, frozen sections have been replaced by paraffin which in no way interferes with the Hortega silver carbonate staining.     

Use of a Silicone Rubber (Clear Seal) as a Section Adhesive Resistant to Acid, Alkali and Heat

An optically clear silicone rubber adhesive is recommended for use in histochemical procedures in which detachment of tissue sections is likely. Procedure: Cut paraffin sections and float on a 45-50 C water bath; leave frozen sections on the microtome knife in the cryostat; spread the silicone rubber thinly and evenly over 2/3 of the slide (Clear Seal—General Electric, was used); pick up paraffin sections directly from the floatation water and frozen sections from the microtome knife with a warm slide; dry for 1.5 hr at 25 C; place paraffin sections in a 60 C oven for 0.5 hr, deparaffinize through xylene and hydrate through alcohols to water. Stain sections as desired, but avoid clearing agents before mounting after strong acid or alkaline treatment, and mount rapidly if a synthetic resin is used because of the solvent effect on the silicone rubber. Of the adhesives tried, silicone rubber is the only one capable of withstanding boiling 10% HCl for any period of time without detachment of sections.     

Distortion-Free Mounting of Frozen Sections by Handling on Paper Supports

Frozen sections are cut from the specimen until the level of interest is reached. A strip of paper (bond or similar writing paper) 5 cm long and about 1 cm wider than the specimen is moistened with water, closely applied to the surface of the specimen and frozen onto it. As the section is cut, the end of the paper strip above the knife is grasped and turned backward toward the other end of the strip. The section is then applied to an albumenized glass slide, firmed and thawed by finger pressure, and the paper removed. After thorough drying, the preparation is ready for further processing. When properly performed, mounted sections whose details coincide to those of the uncut block can be obtained. If thawing on the knife is prevented by cooling the knife, the technic can be performed without a cryostat, but it is also feasible to use a cryostat if a favorable temperature is maintained. The authors obtained 30 μ serial sections, suitable for stereotaxic mapping, from rabbit brain by this method.     

Silver Impregnation of Nerve Fibers in Teeth After Decalcification With Ethylenediaminetetraacetic ACID

The difficulties in impregnating bony tissues, which occur after decalcification with acids or electrolysis are avoided by decalcification with ethylenediaminetetraacetic acid at pH 8.2-8.5. The decalcification of adult human teeth which have been cut to a thickness of 2-5 mm takes 1-2 mo. If frozen sections of the decalcified teeth are impregnated 24 hr in 20% AgNo₃, rinsed through 6 changes of 20% neutralized (CaCO₃) formalin, blotted thoroughly with a cloth and placed in an ammoniated silver solution for 15-20 min, reliable impregnation of nerve fibers is obtained. The stock ammoniated silver solution is prepared by adding concentrated NH₄OH to 10-20 ml of 20% AgNO₃ until the precipitate formed by it is dissolved and then adding a few drops of the silver solution until the first permanent opalescence of the mixture is obtained. From this 2 ml are diluted directly before use with 6 ml of distilled water and 4 drops of concentrated NH₄OH added. The diluted stock solution should be used for few (5-10) sections only. The rest of the technic is done in the routine manner.     

Hexazonium pararosaniline as a fixative for animal tissues

Hexazonium pararosaniline is a valuable reagent that has been used in enzyme activity histochemistry for 50 years. It is an aqueous solution containing the tris-diazonium ion derived from pararosaniline, an aminotriarylmethane dye, and it contains an excess of nitrous acid that was not consumed in the diazotization reaction. Other investigators have found that immersion for 2 min in an acidic (pH 3.5) 0.0015 M hexazonium pararosaniline solution can protect cryostat sections of unfixed animal tissues from the deleterious effects of aqueous reagents such as buffered solutions used in immunohistochemistry, while preserving specific affinities for antibodies. In the present investigation hexazonium pararosaniline protected lymphoid tissue and striated muscle against the damaging effects of water or saline. The same protection was conferred on unfixed sections treated with dilute nitrous or hydrochloric acid in concentrations similar to those in hexazonium pararosaniline solutions. Model tissues (solutions, gels or films containing gelatin and/or bovine albumin) responded predictably to well known cross-linking (formaldehyde) or coagulant (mercuric chloride) fixatives. Hexazonium pararosaniline solutions prevented the dissolution of protein gels in water only after 9 or more days of contact, during which time considerable swelling occurred. It is concluded that there is no evidence for a “fixative” action of hexazonium pararosaniline. The protective effect on frozen sections of unfixed tissue is attributable probably to the low pH of the solution.