The Use of Salicylic Acid as a Fixative

The following salicylic acid-containing fixatives are useful for cytological studies in plants. The first, here designated HFC, is recommended for studies on somatic mitosis and chromosome individuality. The second, denoted HFP, is recommended for studies on plastids.

HFC is made up in two solutions. Sol. A: 100 cc. sat. aq. sol. salicylic acid, slight excess copper hydroxide, 20 cc. formaldehyde, 30 cc. normal ortho-phosphoric acid, 200 cc. water, 1 g. saponin; pH 1.8 to 1.9. Fix in Sol. A 15 to 30 minutes in partial vacuum of 35 cms. Then add Sol. B: 1% aq. chromic acid in equal parts. Continue fixation for period of 18 to 24 hours.

HFP is also made up in two solutions which are used in equal parts. Sol. A: 100 cc. sat. aq. sol. salicylic acid, slight excess copper hydroxide, 10 cc. normal ortho-phosphoric acid, 1/2 g. saponin. Sol. B: 187.5 cc. 1% aq. chromic acid, 50 cc. 2% osmic acid. Fixation technic as HFC.

Dehydrate and infiltrate with paraffin after Zirkle. Stain with crystal-violet-iodine.     

Cytological Methods for Crepis Species

Root tips of Crepis species are fixed in La Cour's “2BE” and dehydrated thru a butyl alcohol series. They are stained in 1% crystal violet for 1 hour, with chromic acid and iodine as pre-and post-staining mordants, respectively, and passed thru dehydrating alcohols containing picric acid and ammonium hydroxide. Differentiation is done in clove oil. The method is rapid; the chromosomes are dark purple; the centromere is not stained; and the cytoplasm is clear. By further controlled destaining the hetero-chromatic segments within the chromosomes may be located.

Pollen mother cells are fixed in acetic alcohol (1:4) and squashed in aceto-carmine. A method is described for making semi-permanent preparations mounted in diaphane.

Pollen grains are mounted in lacto-phenol with acid fuchsin or anilin blue W. S. as the dye.     

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.     

Demonstration Of Golgi Zones By Three Technics For Carbohydrates

The carbohydrate of the Golgi apparatus of several organs of rats, rabbits, and frogs was selected as the principal test material for the behavior of three different technics: 1) periodic acid with colored fuchsin; 2) “direct” chromic acid piperazine silver; 3) periodic acid with leucofuchsin.

Parallel sections of organs in which positive reactions were observed, were treated before staining with a series of reagents to characterize them as glycoprotein.

The results obtained by the three technics under any constant set of conditions were essentially identical in all cases. It is concluded that discrepancies that may have been noted up to now are due to several factors, probably the most important being the tissue's physiological status and the influence of fixation. The study shows that HIO₄, -fuchsinl and chromic acid silver methods are, at least empirically, as valid as HIO₄, -leucofuchsin technics.

Considering the differences in the oxidative mechanism of chromic and periodic acids and other data, the possibility of two different chemical pathways leading to the same final result is discussed.

It has been found that colored fuchsin, as well as its leuco form, can be used in the histochemical demonstration of aldehydes after periodic acid treatment (Arzac, 1948). In a later report (Amc, 1950), a series of reactions were obtained with colored fuchsin which differed in several ways from the results of others using Hotchkiss' method. For example, Gersh (1949) reported the presence of probable glycoproteic granules in the Golgi apparatus of rabbit and guinea pig's intestine. Leblond (1950) also found positive Golgi reactions in different cells of male excretory ducts and in other organs of the rat. Such reactions had not been observed with the colored fuchsin technic in any of the two above-mentioned occasions.

Since the latter investigators used different fixatives, which might have caused the discrepancies, the experiment described below was undertaken to study: (a) the influence of fixation on the final re-actions elicited by HI04-fuchsin (colored and leuco-form) and chromic acid piperazine silver methods; (b) the results obtained in the demonstration of Golgi zones of several rat's, rabbit's and frog's organs by these methods.     

Injection of Lymphatics: With Colored Cedar Oil; With Plastic

(1) The oil mass consists of: cedar oil, 1; color in oil (a paint pigment, e.g., Prussian blue), 1; and toluene, 2, parts by volume. To use, add 1 ml of diethyl ether to each 10 ml of mass, mix thoroughly and inject into the fresh organ with a very fine glass or metallic needle. Heat the organ in water at 50-60° C before starting the injection, massage gently after injection, then fix. For macroscopic studies, fix 5 days in 5% formalin, and dissect. For microscopic studies, fix at least 5 days in: formalin, 10 ml; Al₂(SO₄)₃, 2 gm; ZnSO₄, 2 gm; acetic acid, 4 ml; and distilled water, 90 ml. Dehydrate with dioxane, embed in paraffin and section at 10-20 μ. Stain with hematoxylin-eosin or with one of the following modifications of Van Gieson's formula: 1. 1% acid fuchsin, 10; picric acid (sat. aq.), 50; and 5% ZnSO₄, 40 volumes. 2. 1% acid fuchsin, 20; picric acid (sat. aq.), 80; and 5% CoSO₄, 40 volumes.

(2) The plastic mass consists of a 5-10% solution of Rhodopas (a vinyl copolymer) in acetone. Injection is made as with the oil mass except that a plastic squeeze-bottle and glass needle is preferable to a syringe. Indirect injection is used for both procedures, i.e., into the organ substance; not into a cannulated lymphatic vessel. After the plastic has hardened (24 hr), the unfixed tissue is subjected to corrosion by 5-10% NaOH in water.     

A Simplified Method of Preparation of Di-Ammine-Silver Hydroxide for Reticulum Impregnation; Comments on the Nature of the So-Called Sensitization Before Impregnation

A satisfactory di-ammine-silver hydroxide solution may be repeatedly and consistently prepared by adding 9 or 10 volumes of 10% silver nitrate solution to 1 volume of 28% ammonia water, running in the first 6 or 7 volumes rapidly and proceeding cautiously from then on, shaking until clear after each addition, until a faint permanent turbidity is reached.

The essential nature of Gomori's iron alum treatment and of Wilder's uranyl nitrate step following the Weigert permanganate-oxalic-acid sequence appears to be an oxidation, since the same results may be achieved with chromic acid, hydrogen peroxide, sodium iodate and elemental iodine, and since this step is better omitted on previously chromated material.     

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.     

Feulgen's Reaction Applied to Protozoa and Small Worms, Mounted In Toto in Venetian Turpentine

Permanent mounts of certain protozoa and small worms are obtained as follows: kill suspensions of the organisms with Feulgen's fixative (6% HgCl₂ in 2% aqu. acetic acid) for 3 to 24 hours. After pipetting off the fixative, add successively: 70% iodized alcohol; ditto, 30 minutes later; 50%, then 35% alcohol; 2 baths distilled water; normal HCl. Transfer to cold water and heat to 60°C for 4 to 5 minutes or longer. Cool under running water; and wash in distilled water.

Stain 1 to 3 hours in Feulgen's fuchsin sulfurous acid (1 g. of a suitable basic fuchsin, e. g. rosanilin hydrochloride, boiled in 200 cc. water, cooled, and allowed to stand 24 hours after adding 20 cc. normal HCl and 1 g. sodium bisulfite). Pass thru 3 baths of 200 cc. distilled water with 10 cc. normal HCl and 1 g. sodium bisulfite. Transfer to water and then to 35%, 70%, and 95% alcohols successively. Counterstain with fast green FCF, orange G or eosin Y in 95% alcohol. Pass thru two changes of absolute alcohol.

Transfer to 10% Venetian turpentine and place in a dessicator; mount after the turpentine has become concentrated.

If sections instead of total mounts are desired, the material should go from absolute alcohol, thru alcohol-xylol and xylol to paraffin (or preferably paraffin of M. P. 56°C with 3% bees-wax). The paraffin may be added to the material in the test tube, and cooled after the organisms have settled. Then break the tube, trim a block, and cut.     

Marchi's Staining Method: Studies of Some of the Underlying Mechanisms Involved

Spinal cord of cat and rabbit was stained, after experimental lesions, by variations of Marchi's method. The following conclusions were drawn:

1. The presence of an oxidizing agent (K₂Cr₂O₇, NaIO₃, or KCIO₃) in the osmic acid solution is of primary importance and a preliminary oxidation in Mueller's fluid is unnecessary or even detrimental.

2. Acetic acid added to Marchi's fluid, accentuates the action of the oxidizing agent in restraining the staining of normal myelin.

3. Too high concentration of oxidizing agent or of acid may inhibit staining of degenerating myelin.

4. Marchi's and Busch's methods have been modified as follows: Fix one day in 10% formalin and transfer without washing to the staining mixture, either A or B. Staining mixture A: Marchi's fluid plus 1 to 3% glacial acetic acid. B: An aqueous solution containing KCIO₃ 0.25%, osmic acid 0.33%, and acetic acid 1%. Stain about one week. These methods worked on spinal cord and medulla, but cannot be recommended for brain.

5. The detrimental effects of long post mortem autolysis or of prolonged fixation in formalin may be counteracted to some degree by increasing the concentration of the acid in Marchi's fluid up to 5% or of the KCIO₃ up to 0.4% in the modified Busch's fluid.     

Copper--ligand interactions and the physiological free radical processes. Part 3. Influence of histidine, salicylic acid and anthranilic acid on copper-driven Fenton chemistry in vitro

With a view to the possible use of copper(II)-^·OH inactivating ligand (OIL) complexes as regulators of inflammation, the reactivity of the copper(II)-ascorbate system with hydrogen peroxide has been investigated in the presence of three key substances: histidine (the main copper(II) low molecular mass ligand in extracellular fluid), salicylic acid (the well-known non-steroidal antiinflammatory drug, previously shown to be potentiated by copper(II) in animal models of inflammation), and anthranilic acid (an inactive substance by itself, known to be activated by copper(II) in the same models) at physiological pH (7.4) and inflammatory pH (5.5).

Such substances may affect the amount of TBARS detected in solution following copper-mediated Fenton-like reactions through three distinct mechanisms: (i) by decreasing the Cu(II)/Cu(I) redox potential, i.e. at the expense of ^·OH radical production, (ii) by scavenging ^·OH radicals in the body of the solution, and/or (iii) by acting as a true OIL, i.e. at the expense of ^·OH detection. Redox potential measurements of initial solutions have been performed in parallel to TBARS determinations to help discriminate between different ligand influences. Computer-aided speciation has been used to understand the role of copper(II) distribution on the ligand effects characterised.

Contrary to previous interpretations, histidine has been found to mainly affect ^·OH production by lowering the redox potential of the Cu(II)/Cu(I) couple. Salicylate, which has no effect on ^·OH production, has been confirmed to mainly scavenge ^·OH radicals in the body of the solution. Anthranilate, which both increases ^·OH production and decreases ^·OH detection, behaves as a potential OIL.

These results tend to confirm our previous hypothesis that copper potentiation of antiinflammatory substances is indirect, i.e. independent of any interaction between metal and drug, whereas copper activation of substances that are inactive by themselves results from specific metal-substance interactions taking place at inflammatory sites.     

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.     

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%.     

Copper-Ligand Interactions and Physiological Free Radical Processes. pH-Dependent Influence of Cu2+ Ions on Fe2+-Driven OH- Generation

Prior to comparative studies on the reactivity of various copper complexes with respect to OH radicals, the influence of free Cu²⁺ ions on the superoxide-independent generation of OH radicals through Fenton assays and water gamma radiolysis has been tested in the present work.

Cu²⁺ ions have been shown to behave in a distinct manner towards each of these two production systems. As was logically expected from the noninvolvement of copper in OH^- radical production through gamma radioiysis, no influence of Cu²⁺ ions has been observed on the amount of radicals detected in that case. In contrast, Cu²⁺ ions do influence OH^- radical generation through iron-driven Fenton reactions, but differently depending on copper concentration.

When present in high concentrations, Cu²⁺ ions significantly contribute to OH^- radical production, which confirms previous observations on the reactivity of these in the presence of hydrogen peroxide. At lower levels corresponding to copper/iron ratios below unity on the contrary, Cu²⁺ ions behave as inhibitors of the OH^- production in a pH-dependent manner over the 1-6 range investigated: the lower the pH, the greater the inhibition.

The possible origin of this previously unreported inhibitory effect is discussed.     

Hematein-its Advantages for General Laboratory Usage

The advantages of hematein over hematoxylin are that it is easy to prepare, easy to use, and saves time; while it gives equally good results. The writer has been employing for some time a pre-war imported hematein and until within the last few months has been unable to locate a satisfactory product of recent manufacture, either domestic or foreign. At the request of the Biological Stain Commission, however, an American manufacturer has at last put on the market a C. P. hematein which gives splendid results. The technic is as follows:

Paraffin or celloidin sections of Bouin or Zenker-formol material are run down to water and stained about 5 minutes in Mayer's hemalum (0.5 g. hematein ground up in a glass mortar with 10 cc. 95% alcohol and added to 500 cc. of 5% aqu. sol. potassium alum.) Rinse 1 to 3 seconds in tap water. Dip 1 to 3 seconds in eosin B (1 part 0.5% sol. in 20% alc. added to 2 pats dist. water; filtered from time to time). Wash several minutes in running water or in several changes of tap water. Dehydrate and mount; with unattached celloidin sections this may be done by running up to 95% alcohol, spreading on slide, blotting, wetting with absolute alcohol, draining and mounting in euparal.     

The Fixation of Tissues Vitally Stained with Trypan Blue

The following fixative is recommended for tissues vitally stained with trypan blue: Chloroform, 2 parts; absolute ethyl alcohol, 2 parts; glacial acetic acid, 1 part; mercuric chloride to the point of saturation.

The tissue should be fixed 1 to 2 hours; transferred to 95% ethyl alcohol for 12 hours; to absolute alcohol for 12 to 24 hours; to a mixture of absolute alcohol and xylol for 1/2 hour, and finally to xylol, before embedding in paraffin. Cedar oil may be used for clearing in the place of xylol; in that case the tissues should be transferred from absolute alcohol to a mixture of absolute alcohol and cedar oil for 24 hours before placing in cedar oil alone.

Various counterstains can be used; Mayer's carmalum is excellent.     

Brilliant Cresyl Blue as a Stain for Plant Chromosomes

Methods are proposed for staining plant chromosomes with the dye brilliant cresyl blue, and for making these stained preparations permanent by using polyvinyl alcohol mounting medium.

The stain, which is composed of 2% brilliant cresyl blue in 45% aqueous acetic or propionic acid, is used with fixed material in making smear preparations. The technics for staining are similar to those employed in the aceto-carmine method.

The mounting medium is made by mixing 56% polyvinyl alcohol, which is diluted in water to the consistency of thick molasses, with 22% lactic acid and 22% phenol by volume. The permanent slides are made by floating off the cover slip of the temporary slide in 70% alcohol, then applying the mounting medium and replacing the cover slip.

The chief advantages of the methods described are:

1)The preparation of the stain is rapid and simple. The batch of stain will be good with the first try.

2)The staining procedure in some instances is shorter than when using aceto-carmine.

3)The stain shows a high degree of specificity for nuclear structures and gives better results than aceto-carmine when used on certain plant tissues.

4)A minimum number of cells is lost in making the slides permanent when using polyvinyl alcohol mounting medium as the slide and cover slip are run through only one solution prior to mounting.

5)The mounting medium dries rapidly and this shortens the time required before critical examination of the permanent mounts can be made.     

A Controllable Carmine Technic for Plants with Small Chromosomes

Anthers of small chromosome plants (Antirrhinum, Brassica, Capsicum etc.) were fixed 12 hours or longer at 0-3° C. in: ferric acetate in glacial acetic acid (sat. soln.), 1 part; absolute alcohol, 3 parts. They were transferred to: ferric acetate (sat. soln.) in 45% acetic acid, 3 parts; 45% acetic acid, 5 parts; 1% formalin (aq.), 2 parts, and allowed to remain 5-15 minutes at room temperature for mordanting. The amount of iron introduced into the specimens was controllable by the time in the mordanting fluid. After rinsing the specimen in 45% acetic acid and macerating in a drop of Belling's acetocarmine on a slide, a cover slip was applied followed by warming and pressing with blotting paper to flatten the pollen mother cells and expel excess stain. Preparations stored temporarily by sealing the edges of the cover slip with rubber solution were best made permanent by removing the cover slip after 1-2 days, dehydrating and mounting in euparal.     

Permanent Stained Preparations of Thick Blood Films

Fixing thick films in alcoholic solution of dye after the usual staining-and-laking procedure preserves the appearance of parasites and blood elements very similar to that of the usual thick films (not fixed) for the diagnosis of malaria and relapsing fever.

Procedure recommended: Films are stained and laked for 15 minutes in diluted Giemsa—1 to 3 drops of stock solution (0.4 g. in 60 ml. equal parts absolute methyl alcohol and glycerin) per ml. distilled water; rinsed in water and allowed to dry. They are then immersed in, or flooded with, May-Griinwald's stain (0.5% in absolute methyl alcohol) for 30 seconds, rinsed in water and allowed to dry. Solutions of MacNeal's tetrachrome stain in methyl alcohol and glycerin may be substituted for Giemsa and a solution in methyl alcohol may be substituted for May-Griinwald. With slight modification of the procedure, both thick and thin films on the same slide may be stained together.

Films stained and fixed as described, and mounted in Diaphane, have shown no evidence of fading in 3 years.     

Mechanisms of Hemolysis Induced by Copper

An excess of copper is the cause of hemolysis in a number of clinical conditions. Incubation of human erythrocyte (RBC) suspensions with copper (II) causes the formation of methemoglobin, lipid peroxidation and hemolysis.

A new variant of the thiobarbituric acid (TBA) method, which minimizes the formation of interfering chromophores, was used to detect lipid peroxidation. Lipid peroxidation precedes hemolysis and the antioxidant vitamins C and E, which inhibit lipid peroxidation, also inhibit hemolysis. Consequently lipid peroxidation appears to be the cause of RBC destruction. Lipid peroxidation arises mostly from the oxidation of oxyhemoglobin by copper as it is inhibited in RBCs with carbon monoxyhemoglobin or methemoglobin. A direct interaction of copper with the red cell membrane seems to play only a minor role. Copper effects depend on the presence of free SH groups. Lipid peroxidation is probably initiated by activated forms of oxygen as it is increased by an inhibitor of catalase and reduced by hydroxyl radical scavengers. With higher copper concentrations hemolysis is greater: its mechanism appears different as lipid peroxidation is smaller but hemoglobin alterations, namely precipitation, are more pronounced.