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.     

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.     

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.     

Maillet's Oso4-ZnI2 Fixative and Alcian Blue Staining in the Study of Neurosecretion; Invertebrates

Maillet's OsO₄-ZnI₂ fixation staining can be combined with a subsequent counterstaining by Alcian blue or aldehyde fuchsin to demonstrate neurosecretory cells in addition to cytological details of the nerve tissue. This technic has been applied to various annelids: Eisenia foetida (Oligochaeta), Erpobdella octoculata (Achaeta) and Nereis diversicolor (Polychaeta). The material is fixed in a 1:4 mixture of 2% OsO₄ and 3% ZnI₂ for 15 nr, embedded in paraffin, sectioned at 5 μ and the sections alternatively mounted on two glass slides. One of these is oxidized by a solution of 0.3% KMnO₄ acidified by 0.6% H₂SO₄ and counterstained with 1% Alcian blue, pH 0.2, the other one is mounted in balsam. The two preparations may then be compared to locate the neurosecretory cells among the other neurons shown on a slide treated only by the OsO₄-ZnI₂. Secretory cells are not stained by Maillet's reagent; except for their Golgi bodies and their cellular and nuclear membranes. The zone of grains which is generally strongly stained by the Alcian blue takes a yellowish hue from the OsO₄-ZnI₂ fixation. This method could be successfully applied to the histological controls in regeneration experiments. In these last ones, we must simultaneously observe the regeneration of the nervous fibres and the possibility of intervention of neurosecretory elements.     

Specific Staining of Sialic Acid Components on Sodium Dodecyl Sulfate Polyacrylamide Gel

Specific staining of sialic acid components after sodium dodecyl sulfate polyacrylamide gel electrophoresis can be carried out as follows: 1) extract glycoprotein of erythrocyte membranes or serum by the phenol-saline method, 2) electrophorese the extract on 5% polyacrylamide gel containing 0.1% sodium dodecyl sulfate at constant current, 3) treat the gel with chilled 0.04 M HIO₄ for 45 minutes, 4) replace the periodic acid solution with one containing resorcinol 0.6 g, cone. HCl 50 ml, 0.1 M CuSO₄ 0.5 ml and H₂O 50 ml, 5) warm the container in boiling water until blue violet sialic acid bands become clear, 6) replace the staining solution with a mixture of equal parts water and concentrated HCl and observe at once.     

Differentiating Type i and Type ii Alveolar Cells in Rat Lung by OsO4NaI Staining

The fixing-staining mixture consisted of 1 part of 2% aqueous OsO₄ and 3 parts of 3% Nal in distilled water. Fresh lungs were cut into 2 mm slices and immersed in this solution for 24 hr at room temperature. Controls were fixed in buffered OsO₄ alone. Selective staining of type II alveolar cells was shown by the OsO_t-NaI mixture but was absent in the controls. No additional staining of the sections was required, and the selectivity was readily observable in either paraffin or Araldite sections by light microscopy and in Araldite sections by electron microscopy     

Methylene Violet (Bernthsen), by Zinc-Alkali-Chlorate Hydrolysis of Methylene Blue

Though Bernthsen's methylene violet (MV) is a common constituent of polychrome methylene blue, the hydrolytic oxydation of methylene blue to yield azure-free MV has been considered a difficult chemical reaction since the time of Bernthsen, who used Ag₂O in the hydrolysis. MV is qualitatively distinguished from azures by Bernthsen's criteria and the author's new tests: (1) light-excited isomeric change, (2) reactivity to acidity, (3) reaction with KCIO, and (4) reaction with Na₂SO₃ of azures in CHCI₃, while MV gives none. But MV shows (5) indicator properties at pH 4, while azures do not. For practical hydrolysis, treat methylene blue (10 parts by weight) and KCIO₃ (1 part) with 1-2 N NaOH to convert methylene blue to a mixture of MV and azures. Then dilute the solution, add a Zn salt and NaHCO₃ in excess of the amount needed to convert the NaOH to Na₂CO₃. Boil the solution gently for 1-2 hr. The end point of the reaction is found by pipetting a drop of reactant into 3% acetic acid in a test tube, adding CHC1₃ and extracting. The acetic layer should then be almost colorless while the CHC1₃ is colored intensely cherry red. After cooling, the precipitated dye is filtered and dried. This procedure gives good yields of a dye which meets the criteria given by Bernhsen. The peak of the absorption curve in solution, pH 4-11, is at 624 mμ (Bernthsen 625 mμ) and in acid solution, pH 0-4, 588 mμ (Biological Stains, 1953; 580 μ). The dye contains so little azures, that purification of the MV fraction obtained from the reaction mixture is unnecessary when it is used in the Wright-type Romanowsky stain. The remarkable staining effect of MV is its power to bring out red azurophil granules of monocytes and lymphocytes when used with eosinated thiazins in Wright's stain.     

Practical Methods for the Control of Hydrogenion Concentration in Staining Procedures—The Use of “Buffers”

Data are given for the simple preparation of dry chemical mixtures to be used in the easy preparation of buffer solutions for use in the control of stain procedures. Two of these mixtures of special value in practical staining operations are the following: 4.539 g. KH₂PO₄, 5.940 g. Na₂.HPO₄.2H₂O. (pH=6.8); 7.262 g. KH₂PO₄, 2.376 g Na₂HPO₄.2H₂O (pH = 7.4). Hydrogen-ion control has been found to be essential to consistent results with the compound blood and tissue stains such as Wright's and Giemsa preparations. The more general use of a pre-determined pH in staining procedures is indicated; several possible methods of application are suggested.     

Acceleration of Mallory's Phosphotungstic Acid-Hematoxylin Staining for Skeletal Muscle Fixed in Formalin

The staining time for mammalian skeletal muscle fixed in neutral phosphate-buffered formalin was shortened from 12-24 hr to 10-30 min. The permanganate-oxalate sequence was omitted although oxidation by periodic acid or with iodine was found to be necessary. The material was embedded in paraffin and cut 6 μ or less. Deparaffinized sections were treated with 1% alcoholic iodine for 10 rain followed by 5% Na₂S₂O₃ for 2 min and placed in an oven at 60 C for 10-30 min to stain in a preheated mixture of 50 ml of ripened Mallory's phosphotungstic acid-hematoxylin and 1 ml of 2% phosphomolybdic acid. Experiments with fixation showed that the staining procedure followed Zenker's fluid successfully but not Bouin's fluid. Oxidation by KMnO₄ was effective only after Zenker fixation; oxidation by CrO₃ was unsuccessful.     

A Copper Sulfate-Silver Nitrate Method for Nerve Fibers of Planarians

For staining in toto, planarians are fixed in a mixture of 10 ml of commercial formalin, 45 ml of 95% ethanol and 2 ml of glacial acetic acid. After treatment with 70% ethanol 3-10 days, they are washed in distilled water and immersed in 10% CuSO₄. 5H₂O for 3 hr at 50° C, transferred without washing to 1% AgNO₃ for 1.0-1.5 hr at 50° C; and then developed in: 10 ml of 1% pyrogallol, 100 ml of 56% ethanol and 1 ml of 0.2% nitric acid. Gold toning, 5% Na₂S₂O₃ and dehydration follow as usual. For staining sections, material is fixed in the same fixative, embedded in paraffin and sectioned at 10 μ. After bringing sections to water, they are immersed in 20% CuSO₄. 5H₂O for 48 hr at 37° C; then rinsed briefly in distilled water and placed in 7% AgNO₃ for 24 hr at 37° C. They are washed briefly in distilled water and reduced in: hydroquincne, 1 gm; Na₂SO₃, 5 gm and distilled water 100 ml. Gold toning, followed by 5% Na₂S₂O₃ and dehydration completes the process. Any counterstaining may follow.     

A Chlorate-Formaldehyde Modification of the Golgi Method

Pieces of fresh nervous tissue 3-5 mm thick are put into a mixture of: 6% K₂Cr₂O₇, 40 ml; 5% KClO₃, 20 ml; 20% chloral hydrate, 30 ml; and concentrated formalin (38% HCHO), 10 ml; allowed to fix 3 days, with a daily change of fluid; transferred to 3% K₂Cr₂O₇ for 3 days, with twice daily changes; then to 1% AgNO₃ for 3 days at 20-25° C. Frozen sections are cut, dehydrated, cleared and mounted in Permount with a cover glass. The method gives good results for microglia and oligodendroglia in addition to the usual staining of nerve cells and their processes.     

Pyronin Y in the Methyl-Green-Pyronin Histological Stain

Two samples of pyronin Y were found which, with the exception of eosinophilic granules and osteoid, stained only nucleic acids in animal tissues. Good differentiation was obtained. with n-butyl alcohol. It was therefore possible to prepare a differentially staining mixture of either of these pyronins combined with methyl green. This mixture stains polymerized desoxyribose nucleic acid (DNA) clear green, depolymerized DNA and ribonucleic acid red. The red staining of eosinophilic granules and osteoid is readily distinguished by its persistence after ribonuclease or warm-buffer extraction. The staining mixture consists of: (1) pyronin Y (Edward Gurr or G. T. Gurr), CHCl₃ extracted, 2% aq, 12.5 ml; (2) methyl green, CHCl₃ extracted, 2% aq, 7.5 ml; (3) distilled water, 30 ml. The staining procedure is as follows. (1) Immerse slides 6 min in the dye mixture. (2) Blot with filter paper. (3) Immerse in 2 changes of n-butyl alcohol, 5 min each. (4) Xylene, 5 min. (5) Cedar oil, 5 min. (6) Apply Permount and cover.     

A Rhodocyan Technic for Staining the Anterior Pituitary

A reproducible, one-step, differential staining technic which uses routine formalin-fixed tissue and gives brilliantly contrasting results is produced by incubating sections for 1 hr in a 60° C oven in the following dye mixture: 1% eosin B (CI#771), 8 ml; 1% anilin blue (CI#707), 2 ml; and buffer solution (0.1M citric acid, 1.1 ml; 0.2M Na₂HPO₄, 0.9 ml; distilled water, 28.0 ml) at pH 4.5. No differentiation is necessary. The method can be modified for duodenal enterochromaffin cells and alpha cells of pancreatic islets by adjusting the buffer to pH 3.6 and staining for only 3 min at 60° C.     

自组装短肽R2I4R2对皮肤创伤快速修复过程的研究

研究探索自组装短肽R₂I₄R₂在人皮肤成纤维细胞体外三维培养的应用效果与对创伤修复过程的作用。通过圆二色谱仪分析不同时间、温度和离子条件对其二级结构的影响;刚果红染色宏观检测短肽自组装情况;体外培养人皮肤成纤维细胞探索细胞在R₂I₄R₂形成的纳米纤维网络中的生长状态及凋亡情况;建立SD大鼠皮肤创伤模型,HE染色与免疫组织化学检测其对皮肤创伤修复的病理变化。结果表明,R₂I₄R₂在不同条件下均可形成较为稳定的二级结构;自组装24h后可形成均一稳定的膜片状结构,为细胞三维培养提供支架;人皮肤成纤维细胞可在R₂I₄R₂形成的纳米纤维网络三维环境中生长且状态良好;动物实验表明,短肽R₂I₄R₂可减少炎症、促进新生血管生成、加速皮肤创伤修复过程。自组装短肽R₂I₄R₂作为新的纳米支架材料,可用于细胞三维培养与皮肤创伤修复。     

Handling Germinated Pollen on Millipore Membrane During the Feulgen and Autoradiographic Procedures

To prevent loss of pollen during the Feulgen's procedure, the pollen was grown on an autoclaved membrane filter (Millipore AA WP 025 00) in contact with a sterilized medium containing agar 0.5-1%, sucrose according to the genus (Malus 0.3-0.5 M; Persica and Tulipa 0.4 M), and H₃BO₃, 0.01%. To fix the germinated pollen of most species, the membrane was placed for 2 hr to overnight at 2-4 C on filter paper wet with the following mixture: OsO₄, 1 gm; CrO₃, 1.66 gm; and distilled water, 233 ml. To fix Persica pollen, 10% of glacial acetic acid had to be added to the fixative. Washing with distilled water and bleaching with a mixture of 3% H₂O₂ and sat. aq. ammonium oxalate, 1:1, were performed also on filter paper. Similarly, the preparation was processed for Feulgen staining by use of pieces of filter paper wet with the required fluids. Hydrolysis preceding the Schiff's reagent was performed at room temperature with 5 N HCl for 18 min. The differentiation after the Schiff's action was with 2% K₂S₂O₅ buffered to pH 2.3 with 9 ml of phosphate buffer (KH₂PO₄, 1.4 gm; conc. HCl, 0.35 ml and distilled water to make 100 ml). The stained pollen was floated off the membrane with a drop of glacial acetic acid to a gelatinized or an albumenized slide, and squashed. When the coverslip is removed the preparation may be either dehydrated and mounted or coated with autoradiographic film.     

Effects of Inorganic Oxides, Sulfides, Chlorides, and Acid Chlorides on Metachromasia and Other Staining Properties

The ability of 17 inorganic compounds (POCl₃, PSC1₃, PC1₃, P₂O₅, P₂S₅, P₄S₃, P₄S₇, PC1₅, Sb₂O₅, As₂O₅, BiOC1₂, SeOC1₂, SO₂C1₂, Sb₂S₅, VOC1₂, SiC1₄ and CrO₂Cl₂) dissolved in pyridine or 2,2,4-trimethyl pentane, to enhance subsequent staining of tissue components with toluidine blue, phosphotungstic acid-hematoxylin (PTAH), leukofuchsin, and dihydroxydinaphthyl-disulfide (DDD) was studied. Eight of these compounds were also tested for ability to enhance staining with Alcian blue 8GN and Luxol fast blue MBS. Nine of the 17 compounds produced increased staining of certain tissue components with leukofuchsin, 13 with toluidine blue, 16 with PTAH, and 16 with DDD. The results suggest additional approaches to identification of tissue entities by induced metachromatic basophilia and leukofuchsin positivity as well as by the other stains studied, and also suggest a number of hitherto unstudied modes of reaction between the dyes used and reactive groups of tissue components. Many reactions of the compounds tested, with reactive groups known to be present in tissue components, are basecatalyzed, so that choice of solvent can influence the results obtained.     

Removal of Ribonucleic Acid from Bacterial Cells by Dilute Salt Solutions

Bacterial cells were impressed upon a clean glass slide, fixed in ethyl alcohol and immersed at 37°C in either of the following two salt solutions: (A) NaCl, 7.8 gm; KCl, 0.7 gm; distilled water, 1000 ml; adjusted to pH 7.0; or (B) 0.1M NaH₂PO₄, 400 ml; 0.1M Na₂HPO₄, 600 ml; KCl, 0.7 gm. After 1-5 hr soaking to remove ribonucleic acid, the slide was stained by Giemsa's method as usual. The staining revealed slender chromatinic bodies with reasonable clarity extending the whole diameter of the moderately swollen cell. The results of this method seemed to be much like those obtained after ribonuclease digestion.     

Demonstration of Pulmonary Surfactant by Tracheal Injection of Tricomplex Salt Mixture: Electron Microscopy

Laboratory animals were perfused with glutaraldehyde through the right ventricle before filling the whole lung intratracheally with a solution of 0.05 N Pb(NO₃)₂ and K₃Fe(CN)₆ and incubating it at 37 C for 30 min. An electron-dense reaction product on the surface of epithelial cells and in certain well-localized regions of the alveolar septa results. Nonspecific, intracellular, precipitates do not occur. Lungs which are sliced before glutaraldehyde fixation and immersed in the tricomplex salt mixture show patchy localization of reaction product. Diffuse, electron-dense deposits measuring 100-2000 mμ in diameter are seen in the cytoplasm of epithelial, endothelial and interstitial cells although occasionally there is localization on the surface of the epithelial cells and in specific sites within cells. Injection of the whole lung with tricomplex salt mixture after fixation with glutaraldehyde by vascular perfusion is a better method for the ultrastructural demonstration of pulmonary surfactant than immersion fixation and staining.     

Processing Pollen and Spore Exines for Electron Microscopy

A resin mixture containing Araldite M, 15 ml; Epon 812, 25 ml; dodecenyl succinic anhydride, 55 ml; and dibutyl phthlate, 2 ml, was found to be the optimal embedding resin for both fresh and acetylated pollen exines. Diamond knives greatly facilitated sectioning. Exine fine structure, and stratification patterns in fresh pollen were most clearly revealed by section staining of glutaraldehyde-fixed (2 hr), OsO₄-stained (2 hr) specimens. Acetylated exines (acetic anhydride-H₂SO₄ 9:1; 100 C, 5 min) did not require additional treatment prior to embedding, but section staining of exines so treated greatly enhanced stain differentiation of exine subunits. Successfully used section stains included Reynold's lead hydroxide, Millonig's lead citrate and aqueous KMnO₄. Additional procedures were tried but were found to have serious disadvantages, e. g. exines treated with KMnO₄ before embedding shattered badly during sectioning.     

The Quantitative Determination of Osmium Tetroxide in Fixatives

This rapid spectrophotometric method for determining the OsO₄ concentration in fixative and stock solutions is based on the reduction of OsO₄ by acidified KI to the blue species of OsI₆ =, which is then determined at 649 mµ. The salt K₂OsI₆ has been isolated from the reaction mixture and characterized. Method: A I ml aliquot of the solution, containing up to 3% OsO₄, is diluted to 100 ml with distilled water. To 1 ml of the diluted solution is added, in order: distilled water, 2 ml; 1 M HCI, 1 ml; and 1 M KI, 1 ml. Optical density at 649 mµ is read from 10-120 min thereafter. OsO₄ concentration is calculated from the measured molecular extinction coefficient of OsI₆ =, 4400 liter/mole cm.