Marchi's Staining Method: II. Fixation

Following experimental lesions, spinal cords of cats and rabbits were fixed with acid, neutral, and alkaline solutions. Staining was limited to a chromate-osmic (Marchi's) solution and a chlorate-osmic solution. The following conclusions were drawn:

The presence of an acid in the fixative caused normal myelin sheaths to stain. This effect was reduced by washing tissues before staining, by adding acetic acid to the stain, or by employing a non-formalin fixative. It was, however, at no time entirely obviated.

A study was made of the granular deposits which occur in nearly all Marchi preparations and which are especially confusing if very light backgrounds are obtained.

The staining reactions of the granular deposits were very similar to those of degenerating myelin but some suppression of the granules was obtained by adding KCIO₃ to the formalin fixative.     

Acid Versus Neutral Formalin Solution as a Neurological Fixative

The fixing action of 10% formalin solution alone and with formic, acetic, propionic, butyric, lactic, monochloracetic, dichloracetic, or trichloracetic acid was studied by means of stains with silver, osmic acid and cresyl violet. The following conclusions were reached:

1. In general, better fixation and staining was obtained with acid than without.

2. Less difference was seen in comparing one acid with another than was expected before the experiments were made.

3. Propionic, butyric, and dichloracetic showed no promise of having practical value.

4. Formic and monochloracetic acids as modifiers gave superior stains with osmic acid, while silver and cresyl violet stains of the same material were about equal to those made from formalin-acetic fixed material.

5. Lactic acid caused somewhat more distortion of tissue elements than the others but was compatible with good staining.

6. Acetic acid was most effective in concentrations of 3 to 5% while the stronger acids such as formic, monochloracetic, lactic and trichloracetic were effective in concentrations of 0.5 to 1%.     

The Fixing and Staining of Liriodendron Tulepifera Root Tips and their Mycorrehizal Fungus

Root tips of Liriodendron Tulipifera forming with a fungus of the Mycelium Radicis group an endotrophic mycorrhiza, were subjected to several different fixations in which the action of cationic chromium and anionic chromium were compared. Anionic chromium in the form of chromic acid was combined with several substituted benzene compounds while cationic chromium in the form of chromic sulfate (Cr₂(SO₄)₃·15 H₂O) in 4% formaldehyde (HCHO) was used with the same ring compounds. In addition, several fixatives not containing chromium were tested.

Five percent chromic sulfate (Cr₂(SO₄)₂·15 H₂O) in 4% formaldehyde (HCHO) or in 1% osmic acid with saturated aqueous salicylic and/or picric acid preserved the histological and cytological details of the mycorrhiza, as was clearly demonstrated when followed by staining in 3% acetic acid saturated with orseillin BB and counterstained with 1% crystal violet in clove oil.

Two percent ferric chloride (Fe Cl₃) in 4% formaldehyde showed the relationship of the tannin contents of the cells to the invading hyphae when followed by suitable staining.

Cationic chromium appeared to be superior to anionic chromium in preserving cell walls as well as the general histologic features of the material investigated.     

An Improvement in Staining Technic for Protozoa

A modification of Donaldson's iodine-eosin stain for staining intestinal protozoa is presented. This modification consists of using high dilutions of colloidal iodine (Chandler)² instead of Lugol's solution as well as high dilutions of eosin. A better resolution of the external and internal structures is brought about by the new method.

The procedure is as follows: A portion of the fecal material to be examined is suspended in a 0.6% salt solution; the suspension should be of a consistency so that one drop will make a satisfactory microscope mount under a cover glass. To ten parts of this suspension, in a test tube, is added one part of the stain which is prepared as follows:—

10 parts of distilled water

6 parts of a suspension of colloidal iodine (Chandler) containing 4% iodine—20% iodine suspensoid, Merck

1 part of a 10% water solution of anilin red, Merck (eosin yellowish)

Technicians will find, because iodine in the form of colloidal iodine is readily released to the organisms, that the use of this material is far superior to Lugol's solution hi carrying out the technic for staining intestinal protozoa in the study of fresh mount preparations. Not only are organisms more deeply stained with iodine but by eosin as well, even when employed in high dilutions.     

Reactions of Hemoglobiniferous Cells to Aced and Basic Dyes under Varying Conditions of H-Ion Activity

1. An attempt has been made to apply Loeb's concept of the amphoteric nature of proteins for the discrimination of suspected hemoglobiniferous substances from known hemoglobiniferous substances according to their reactions to acid and basic dyes with reference to the isoelectric point of hemoglobin (pH 6.8).

2. The substances in the cytoplasm of known hemoglobiniferous cells (red blood corpuscles, normoblasts and erythroblasts) of the lymph nodes, spleen and bone marrow of the albino rat, when suspended in buffered dye-sucrose solutions, retain eosin on the acid side of pH 7.0, but the substances of the Russell bodies, suspected of being hemoglobiniferous, do not retain eosin at all; and the cytoplasm of the plasma cells, also alleged to be slightly hemoglobiniferous, only retains eosin on the acid side of pH 6.4.

3. The only basic dye used which did not precipitate in buffer solutions was methylene blue. This did not react with hemoglobin in accordance with Loeb's concept, because it did not penetrate mature red blood corpuscles and in those immature erythrocytes which it did penetrate it was precipitated by the reticulum.

4. Therefore, from the results obtained with the acid dye, it is tentatively concluded that the substance in the Russell bodies and in the cytoplasm of the plasma cells are not hemoglobiniferous because they do not react as do the substances in known hemoglobiniferous cells with reference to the isoelectric point of hemoglobin.

5. More investigation, however, must be carried out on both fresh and fixed material before a final unequivocal answer can be made to this problem.     

A New Methylene Blue Technic for Permanent Preparations

1. Tissues stained intra vitam with methylene blue are fixed in a 10% ammonium molybdate solution in physiological saline (or sea water if the tissue is from a marine animal). Fixation time is kept to a minimum. Washing also is reduced to a minimum.

2. Excess fluids are removed from tissues by blotting with a paper or cloth towel before they are put into the succeeding solution. Tissues are taken from the wash water, blotted and placed in a mixture of equal parts of absolute ethyl alcohol and n-butyl alcohol for 30 minutes. They are then blotted and transferred to n-butyl alcohol for 30 minutes. After blotting they are placed in a mixture of one part methyl salicylate and four parts xylene until cleared. Tissues may be mounted whole or prepared for sectioning by embedding in paraffin in the usual way.

3. Tissues fixed, washed, dehydrated and cleared as described retain nearly all of the stain; the time required is greatly reduced; there is no need to chill the dehydrating solutions; cell distortion is much reduced.     

Staining Methods For Studying Ingredient Distribution In Baked Cakes

A method is described for preparing cake crumb for sectioning and staining. Previous to embedding, the fat was stained and fixed by exposing small blocks of cake to the fumes from a 5%, freshly-prepared, aqueous solution of osmic acid (OsO₄). This was followed by dehydration in ethyl alcohol and tertiary butyl alcohol, removal of air under vacuum and infiltration with paraffin.

Sections were cut 20 and 9Op thick and mounted with water.

Wax was removed by immersion in xylene. The sections were rehydrated in a series of ethyl alcohol dilutions, from concentrated to dilute, then transferred to distilled water.

Protein was then stained pink by immersion of the slides in an acidified 0.04% water solution of eosin Y, or starch was stained blue with a dilute aqueous solution of iodine. Ten grams iodine and 10 g. KI were dissolved in 25 ml. distilled water. This stock solution was diluted for use one to two hundred times.

The relationship between protein and starch was demonstrated by staining the sections with eosin, differentiating in 50% alcohol and staining with iodine.

When slides of cake crumb were prepared in this way, the fat was stained black, the protein bright pink and the starch granules a dark blue.     

Block Staining of Nervous Tissue with Silver IV. Embryos

Procedures having enhanced reliability over older methods for both Bielschowsky and Cajal types of stain are described.

Fixation of embryos in a solution containing 4% formaldehyde and 0.5% trichloracetic acid greatly improved the staining of neural elements by Bielschowsky's method.

Among the variations of Cajal's type of staining tried, a modification of Ranson's pyridin-silver method gave the most complete staining of neurofibrillar elements. Washing for 0.5 to 1 hour after silver impregnation and shortening of the reduction time from 24 to 4 hours corrected the tendency of the method to overstain.     

A Rapid Silver-on-the-Slide Method for Nervous Tissue

A progressive silver staining method is described, which permits microscopic examination of the sections during the staining process. After formaldehyde fixation, dehydration and embedding in paraffin or celloidin, fine fibers and synaptic endings may be demonstrated. After formaldehyde fixation and mordanting in 3% K₂Cr₂O₇, myelinated fibers and mitochondria are specifically stained.

The unique feature of this method is, that the silver solution (0.5% protargol) is mixed with the reducing solution: 1.6% Rochelle salts, containing traces of Ag NO₃, MgSO₄, and K₂S (U.S.P.). The sections are placed directly into this mixture, which is then warmed to 45-55° C. Sections are removed when progressive staining is completed, washed in water, dehydrated and mounted.

In the fiber stain, nerve fibers and synaptic endings are dark brown or black, and nuclear chromatin is deep brown, against a pale yellow background. When the myelin sheath procedure is followed, the fiber bundles are deep brown, and the intensity of the staining remains the same for specific tracts, aiding in their identification.     

Impregnation of Oligodendroglia in Nervous Tissue Kept in Formalin for Many Years

A method for impregnating oligodendroglia in nervous tissue (monkey) fixed and preserved in formalin for many years is described. This tissue is reconditioned by placing 12 to 30μ frozen sections of it in concentrated ammonia (sp. gr. 0.90) and by washing them slowly for 24 hours with a 1 mm. stream of water. The fluid is then poured off the sections; the jar is refilled with concentrated ammonia; and washing is repeated for another 24 hours. The sections are then plunged into concentrated ammonia for 7 minutes.

After treatment in ammonia, the sections are incubated for one hour at 38^oC. in Globus' 5% hydrobromic acid solution. They are washed again, in distilled water, and then impregnated in a “medium” strength ammoniacal silver carbonate solution (5 ml. of 10% AgNO₃ added to 15 ml. of 5% Na₂CO₃. The precipitate is dissolved in concentrated ammonia and diluted to SO ml. with distilled water). Impregnation is followed by reduction in 1% formalin without agitation; fixation in 5% Na₂S₂O₃; dehydration, and mounting in clarite.

Typical oligodendroglia (Fig. 1) were made visible by use of the method outlined in this paper.     

Differential in Toto Staining of Bone, Cartilage and Soft Tissues

The following method for staining bone and cartilage allows study of the gross cleared specimen and does not injure the tissues for subsequent microscopic study: Fix in 10% neutral formalin; bleach thoroughly in 3% H₂O₂ in sunlight. Wash in distilled water. Stain bone 24 hours in 0.01 g. of Biebrich scarlet in 100 ml. of distilled water. Destain in 95% alcohol until soft tissues and cartilage are colorless. Stain cartilage 24 hours in a pH2 buffer solution of 2.1g. of citric acid per 100 ml. of water with 0.001 g. of methylene blue. Destain in pH2 buffer solution until soft tissues are pale. Dehydrate in two changes of 95% alcohol in preparation for clearing. (This completes the destaining and may remove too much stain from the cartilage if destaining in the pH2 solution has been carried too far.) Place in Groat's clearing fluid and cover loosely so that the alcohol may evaporate, or remove the alcohol in vacuo. Groat's Mixture No. 19 is usually satisfactory.

For a combined stain, first stain bone, as above, and then apply the cartilage stain.

Seal jars with an ordinary liquid wood glue such as LePage's.     

Book Review

LEGGETT, W. F. Ancient and Medieval Dyes. 5 × 8 in. 96 pp. Cloth. Chemical Publishing Co., Brooklyn, N. Y. 1944. $2.25.

Microtechnic In General. McCARTNEY, J. E. A new immersion oil “polyric”. J. Path. & Bact., 56, 265-6. 1944.

NICKERSON, MARK. A dry ice freezing unit for rotary microtomes. Science, 100, 177-8. 1944.

Dyes And Thedx Biological Uses. BERGEIM, FRANK H., and BRAKER, WILLIAM. Homosulfanilamides. J. Amer. Chem. Soc., 66, 1459. 1944.

CALDWELL, W. T., TYSON, F. T., and LAUER, LOTHAR. Substituted 2-sulfonamido-5-aminopyridines. II. J. Amer. Chem. Soc., 66, 1479. 1944.

JOHNS, C. K. Dye concentration in resazurin tablets. Amer. J. Pub. Health, 34, 955-8. 1944.

SMITH, WINSLOW WHITNEY. Relative sensitivity of different phases of growth curve of Bact. salmonicida to alkaline acriflavine. Proc. Soc. Exp. Biol. & Med., 56, 240-2. 1844.

VAN ARENDONK, A. M., and SHOULE, H. A. Dialkylaminoalkyl derivatives of substituted quinolines and quinaldines. J. Amer. Chem. Soc., 66, 1284. 1944.

WHEELER, KEITH, and DEGERING, E. F. Preparation and properties of certain derivatives of sulfamide. J. Amer. Chem. Soc., 66, 1242. 1944.

Animal Microtechnic. BOARDMAN, EDWARD T. Methods for collecting ticks for study and delineation. J. Parasitology, 30, 57-9. 1944.

DICKIE, MARGARET M. A new differential stain for mouse pituitary. Science, 100, 297-8. 1944.

GOVAN, A. D. TELFORD. Fat staining by Sudan dyes suspended in watery media. J. Path. & Bact., 56, 262-4. 1944.

LILLIE, R. D., and ASHBURN, L. L. Supersaturated solutions of fat stains in dilute isopropanol for demonstration of acute fatty degenerations not shown by Herxheimer technic. Arch. Path., 36, 432. 1943.

MULLEN, J. P. A convenient and rapid method for staining glycogen in paraffin sections with Best's carmine stain. Amer. J. Clin. Path., Tech. Sect., 8, 9-10. 1944.

NYKA, W. A method for staining the rickettsiae of typhns in histological sections. J. Path. & Bact., 56, 264. 1944.

POPPER, HANS, GYORGY, PAUL, and GOLDBLATT, H. Fluorescent material (ceroid) in experimental nutritional cirrhosis. Arch. Path., 37, 161. 1944.

SMALL, C. S., and SCHULTZ, M. A. Sustaining faded tissue sections. Amer. J. Clin. Path., Tech. Sect., 7, 66-7. 1943.

YOFFEY, J. M., and PARNELL, J. The lymphocyte content of rabbit bone marrow. J. Anat., 78, 109-12. 1944.

ZIEGLER, E. E. Hematoxylin-eosin tissue stain. An improved, rapid, and uniform technic. Arch. Path., 37, 68. 1044.

Plant Microtechnic. HAASIS, FERDINAND W. Staining rubber in ground or milled plant tissues. Ind. and Eng. Chem., Anal. Ed., 16, 480. 1944.

PARRIS, G. K. A simple nuclear stain and staining technique for Helminthosporia. Phytopathology, 34, 700. 1944.

Microorganisms. DARZINS, E. Rickettsienstudien. Zentbl. Bakl., Abt. I, Orig., 151, 18-20. 1943.

GOHAR, M. A. A staining method for Corynebacterium diphtheriae. J. Bact., 47, 575. 1944.

GRAY, P. H. H. Two-stain method for direct bacteria count. J. Milk Techn., 6, 76. 1943.     

Improvement of the Golgi Method by pH Control

Experiments were made to test the influence of the pH of the fixing fluid (ranging from 1.0-8.1) and that of the chromating fluid (1.65-7.8) on subsequent silver impregnation. Brains of adult monkeys, cats, dogs, rabbits, guinea pigs, rats and mice were fixed by the pulsating-perfusion method of Haushalter and Bertram (1955), after first washing out the blood with saline-acacia solution of the same pH as that of the 10% formol-saline-acacia used for fixation. The brains were sliced to 3 mm thickness and the slices further fixed 1-2 days in 10% formalin with its pH adjusted to that of the preceding fixing fluid. Chromation for 1 day followed, with acidified ZnCrO₄ at pH 1.65-5.9 and buffered Na₂CrO₄ at pH 7.8. Silvering for 2 days in 0.75% AgNO₃ solution effected the staining. Dehydration, paraffin embedding and sectioning completed the process.

From these experiments, it was found that fixation at pH 7.0-7.2 followed by chromation at pH 3.1 in a mixture of ZnCrO₄, 60 gm and formic acid, 35 ml, diluted to 1000 ml with distilled water, was optimum for best impregnation of nerve cells and their processes. Human brain and that of newborn mammals, although not perfused, responded well to the controlled-pH procedure. The advantages of the technic are the staining of nerve cells in regions refractory to previous methods and the relatively short time needed for its completion.     

Control of the Ferric Ion Concentration in Iron-Aceto-Carmine Staining

The Fe⁺⁺⁺ concentration is controlled by adjusting the FeCl₃ normality of the iron-aceto-carmine staining solutions. Two stock mordant solutions are prepared by dissolving ferric chloride (FeCl₃·6H₂O; m. w. =270.31) in 45% glacial acetic acid, the normality of one being N/1, and of the other N/10. By combining aceto-carmine (preferably prepared from Merck's carmine No. 40 N. F., or from the Coleman and Bell product) and one or the other of the stock mordant solutions, a series of iron-aceto-carmine solutions is made up, each solution being of different normality for FeCl₃, depending on the proportions combined. Trial series: N/50, N/100, N/500, N/1000 and 0 N.

Tissue (spermatogenic) from one specimen is fixed in Carnoy-2, divided equally among the five iron-aceto-carmine solutions for staining, then squashed, dehydrated and mounted as usual. Subsequently the trial series may be retained or adjusted. Advantages of the method: 1) discloses quickly the optimum stain for a particular tissue type; 2) automatically gives an optimum stain to cells in different maturational stages; 3) results are reproducible in subsequent operations.

Tables and equations are provided for a number of other normalities and quantities of stain.     

Possible uses of Dioxan in Botanical Microtechnic

Dioxan has been well established as an advantageous dehydrating agent for plant tissues. It dehydrates equally well after fixatives containing formalin, acetic acid, chromic acid, chromates, mercuric chloride, osmic acid, and alcohol. Better infiltration of paraffin after dehydration may be obtained by passing the material thru (1) a cold bath composed of 30 cc. of dioxan, 5 cc. of xylol and 20 cc. of melted soft paraffin and, (2) a warm bath of 50 cc. of dioxan, 50 cc. of paraffin, and 10 cc. of xylol. Transfer from (2) to soft paraffin. A dioxan fixative consisting of dioxan 50 cc., formalin 6 cc., acetic acid 5 cc., water 50 cc. was devised for delicate subjects. The fixed material is transferred directly into dioxan and mounted in dioxan-diaphane or dioxan-balsam. Very delicate objects require dioxan dilution of the balsam and slow concentration of the mounting medium by evaporation.

Entire plant parts or epidermal peelings are fixed in any desired fixative, washed if necessary, transferred to dioxan and mounted in diluted dioxan-balsam or diaphane. Dioxan may be used to mount hyalin objects whose refractive indexes approach those of balsam in media of higher index than balsam. It may be used in place of alcohol in finishing parafin sections, and since it exhibits different stain solubilities than alcohol it offers an important new tool in obtaining and maintaining stain balances.     

A Colloidal Silver Method for Nerve Cells and Processes, Neuroglia and Microglia

A method is described whereby nerve cells and processes, neuroglia and microglia may be stained using colloidal silver solutions (argyrol, silvol, 10% and 20%).

Fresh, unfixed brain tissue is stained in bulk in argyrol or silvol, and then dehydrated, embedded in low viscosity nitrocellulose, and sectioned. Before reduction the sections are treated with gold chloride to replace the silver. Sections are reduced in a formalin hydroquinone solution, fixed in sodium thiosulfate, dehydrated, and mounted in euparal. A method is described for removing the nitrocellulose before mounting.

No variation in the method was found to be necessary for the various species tested (rat, guinea pig, rabbit, and dog).     

Observations on the Kinetics of Uranyl Acetate and Phosphotungstic Acid Staining of Chromatin in thin Sections for Electron Microscopy

When thin sections of spermatogenic chromatin are fixed with either glutaraldehyde alone or postfixed with osmium tetroxide (OsO₄) and stained with uranyl acetate (UAc) for increasing times, even after as little as 1 min, stain uptake is proportional to section thickness. Greater UAc uptake is observed in chromatin fixed with gutaraldehyde only, but stain uptake is reduced following a long wash with distilled water to a level similar to that seen with postfixed chromatin. Lead citrate poststaining of chromatin fixed with either glutaraldehyde or postfixed with OsO₄ increases UAc uptake by a factor of about 3.

The staining of thin sections of spermatogenic chromatin with ethanolic phosphotungstic acid (PTA) shows a region where stain uptake is proportional to section thickness followed by a plateau. This staining pattern is seen in chromatin fixed with glutaraldehyde alone or postfixed with OsO₄; similar levels for final PTA uptake are also observed.

An increase in the resin content of embedded chromatin postfixed with OsO₄ is proposed to explain the decrease and increase in the rate of migration of UAc and ethanolic PTA staining solutions, respectively.     

Is homocysteine a pro-oxidant?

High plasma homocysteine concentrations have been found to be associated with atherosclerosis and thrombosis of arteries and deep veins. The oxidative damage mediated by hydrogen peroxide production during the metal-catalyzed oxidation of homocysteine is to date considered to be one of the major pathophysiological mechanisms for this association.

In this work, a very sensitive and accurate method was employed to measure the effective production of H₂O₂ during homocysteine oxidation. Furthermore, the interaction of homocysteine with powerful oxidizing species (hypochlorite, peroxynitrite, ferrylmyoglobin) was evaluated in order to ascertain the putative pro-oxidant role of homocysteine.

Our findings indicate that homocysteine does not produce H₂O₂ in a significant amount (1/4000 mole/mole ratio of H₂O₂ to homocysteine). Moreover, homocysteine strongly inhibits the oxidation of luminol and dihydrorhodamine by hypochlorite or peroxynitrite and rapidly reduces back ferrylmyoglobin, the oxidizing species, to metmyoglobin.

All these results should, in our opinion, lead to a rethinking of the commonly held view that homocysteine oxidation is one of the main causative mechanisms of cardiovascular damage.     

Preliminary Notes on Chromic Fixation in Alcoholic Media

In Note I are pointed out certain chemical difficulties which stand in the way of experiments on chromium fixation in alcoholic media; also a procedure is described by means of which these difficulties may be avoided in the preparation of a chrome-alcohol stock solution.

In Note II it is suggested that the properties of OsO₄ most important in the quick-killing effect conferred by this adjuvant upon aqueous chromic reagents are probably, in addition to its high toxicity, its volatility and its oxidant action. Volatile, toxic oxidants which do not attack alcohol are therefore discussed briefly, with reference especially to their use as quick-killing adjuvants in chrome-alcohol reagents. Iodine is noted as probably the most important inorganic possibility. Reasons are stated for considering the quinones the most promising of numerous possible organic compounds.

Results of fixations of Vicia faba root tips in nine variations of the proportions of acetic acid and iodine in a chrome-alcohol-aceticiodine combination are described. The chrome-alcohol-iodine reagents which proved best proportioned for V. faba root tips preserved some details of the chromosomes better than does Bouin's solution, but did not make certain details of the early prophase as clear as does Benda's modification of the Flemming reagent, according to a comparison with Sharp's figures of Bouin and Benda preparations of root tips of the same species.