A rapid method for demonstrating skeletal muscle motor innervation in frozen sections.

Longitudinal 50-100 mum-thick frozen sections of muscle are picked up on slides coated with 3% EDTA and after drying are incubated to demonstrate acetylcholinesterase. Subsequent incubation in 0.5% K3Fe(CN)6 is followed by fixation for 30 minutes in formol-calcium or formol-saline. After washing, the slides are incubated in 20% aqueous AgNO3 containing 0.1% CuSO4 for 2-30 minutes at 37 C. Following development in a 1% solution of quinol (w/v) 5% with respect to NaSO3 (w/v), axons and subneural apparatus stain dark brown to black in contrast to the less well stained muscle fibers and nuclei. This procedure permits study of the pattern of neuromuscular innervation in skeletal muscle 3 1/2-4 hours after receipt of a sample, and makes possible determination of the terminal innervation ratio.     

Localization of Myoglobin in Striated Muscle of the Domestic Pig; Benzidine and NADH2-TR Reactions

Tissue blocks 1 cm³ from longissimus (white) and trapezius (red) muscles of adult pigs were fixed in phosphate-buffered 2.5% glutaraldehyde, pH 7.4, for 4 hr at about 25 C; washed 4 hr in running tap water, and immersed in 30% w/v sucrose solution for 16 hr or more. After freezing in liquid N₂, cryostat sections were cut and floated into saturated aqueous benzidine containing 0.15% H₂O₂ at 25 C for 30 min. Stained sections were washed in distilled water and mounted on slides with glycerol jelly. Three distinguishable gradiations of color intensity were found: strong, intermediate, and negative. The trapezius had a greater number of myoglobin-positive fibers than the longissimus muscle. Myoglobin-positive and myoglobin-negative staining occurred in red and white fibers, respectively; intermediates were apparently more closely related to the red than to the white fibers. The NADH₂TR reaction showed the same sites as did the benzidine reaction.     

Method for Staining Bacterial Flagella

The following method of staining bacterial flagella is ecommended for use on smears made from suspensions of 10 to 16-tour agar slant cultures, incubated 30 minutes at 37°C before spreadng on thoroly cleaned and named slides:

1. Cover with fixative (100 cc. of 1/4 sat. aqu. solution picric acid, with 5 g. tannic acid and 7.5 g. ferrous sulfate).
2. Wash with tap water, dry and cover with Fontana spirochaete stain; heat to steaming and allow to act for 1 to 2 minutes. Wash in ap water. The stain is prepared as follows: To 25 cc. 2% AgNO₃ add dilute ammonia till the precipitate which forms redissolves; then add more AgNO₃ till a faint turbidity results. A clear solution is useess.

     

Controlled Formaldehyde-Catecholamine Condensation in Cryostat Sections to Show Adrenergic Nerves by Fluorescence

Three sets of sections of freshly removed tissue are cut at 18 μ in a cryostat and dried on slides for 1.5 hr over P₂O₅. Each set of sections is incubated with a differently hydrated paraformaldehyde (prepared by storing paraformaldehyde powder over 21%, 25% or 28% aqueous H₂SO₄ for 1 wk) at 80 C for 1 hr before being mounted in glycerol and viewed with a fluorescence microscope. At least one set of specimens shows optimal fluorescence. The entire procedure from removing the tissue to observing fluorescence microscopically is accomplished readily within 4-8 hr. Adrenergic axons in the medial muscle of the cat nictitating membrane, the myometrium of the cat uterus and the adventitia of arterial vessels in rat pancreas are demonstrated.     

Techniques for Studying Adipocytes

Various fixatives as well as tissue and slide handling procedures have been evaluated in attempts to demonstrate adipocytes histochemically while maintaining cell and tissue integrity. The optimal procedure for analysis of immature adipose depots consists of the following steps: 1) fresh, unfixed tissues are frozen rapidly in isopentane quenched in a liquid nitrogen bath; 2) cryostat sections are cut, removed from the knife with a room temperature slide, and then air dried for 5-10 minutes; 3) slides can be stained directly with picro-Ponceau or toluidine blue procedures or with oil red O following fixation for 30 minutes in cold (4 C) 10% formalin-CaCl₂ (1.25%). For analysis of mature rat adipose depots steps 2 and 3 are modified as follows: 2) cryostat sections are removed from the knife with a cold slide (-20 C) and dried for 30 minutes at 4 C; 3) the mounted sections are stained with oil red O following fixation for 30 minutes in cold (4 C) 10% formalin-HgCl₂ (2.5%). When procedures described above for immature adipose depots are combined with esterase fining, adipocyte cytoplasm is clearly demonstrated. These procedures allow the routine use of fresh frozen, unfixed cryostat sections in studies of adipose cellularity.     

Hematoxylin Staining of Tissues Embedded in Epoxy Resins

Sections of 0.5-2 μ thickness are affixed to slides with albumen adhesive, thoroughly dried, and placed in xylene or toluene for 1 hr, then brought through ethanol to water. Sections of tissue fixed in O_sO₄ are treated first in 0.1% KMnO₄, then with 1.0% oxalic acid, and after rinsing, incubated at 60 C for 12-24 hr in hematoxylin (Harris's or Ehrlich's) and counterstained 10-15 min with 0.5% phloxine B. Permanent preparations are made by clearing and mounting in a synthetic resin. The method requires only easily available reagents and is suitable for routine processing of epoxy sections.     

Application of Methods for Mammalian Chromosome Spreads to the Cells of Cestodes

Tapeworm cells obtained by physical maceration between ground-glass surfaces are incubated for 3 hr in Hanks' balanced salt solution (BSS) supplemented with colchicine to a concentration of 10-⁴ M. After washing in BSS, the cells are incubated for 10 min in 1/4 strength BSS then centrifuged 10 min. Fixation of the intact button of cells (or alternatively, by squirting the cells directly into the fixative) in Carnoy's alcohol-chloroform-acetic acid (6;3:1) for 30 min follows, and cells, dispersed and washed in the fixative, are flattened by dropping the suspension on clean, water-wet slides which are then air-dried and stained with Giemsa diluted 1 ml;47 ml with distilled water to which 2 ml of buffer—M/15 KH₂PO₄, 32 ml, mixed with M/15 Na₂HPO₄, 68 ml—is added. After staining 15 min and washing in distilled water, slides are air-dried and mounted with resin. Well separated and well stained chromosomes have resulted.     

Hematoxylin-Eosin Staining of OsO4-Fixed Epon- Embedded Tissue; Prestaining Oxidation by Acidified H2O2

Successful application of hematoxylin-eosin staining to 0.5-1 μ sections of OsO₄-fixed Epon-embedded mammalian tissue is made possible by first treating the sections for approximately 1 min at 25-30 C with 10% H₂O₂ acidified with 0.1 or 0.01 N H₂SO₄ to pH 3.2. Subsequent steps are: washing; drying; Hams hematoxylin at 50 C, 1-2 min; washing; drying; 0.2-0.3% NH₄OH in 70% ethanol, 3-5 sec, drying at 50 C; 5% aqueous eosin for 3 & 45 sec at 25-30 C, washing; drying; clearing in xylene and mounting in resin. The use of acidified H₂O₂ prevents the staining of Epon and permits the characteristic staining picture to be obtained. Sections were attached to glass slides without adhesive and processed horizontally on a rack. Slides should be well drained and blotted before each drying step, to prevent formation of precipitate on the section.     

Application of the Nauta-Gygax Technic for Degenerating Axons to Mounted Sections

Frozen sections of formalin-fixed brains containing lesions were mounted on slides that had been coated first with albumen-glycerol (1:1) then 4% gelatin and blotted. The slides were placed in formaldehyde vapor at 56° C for 40-60 min, washed, and stored (optional) in 10% formalin-saline. The staining technic was as follows: after washing, soak 30-40 min in 0.5% phosphomolybdic acid, rinse; put in 0.05% potassium permanganate 9-16 min (usually 12 min); decolorize in a 1:1 mixture of 1% hydroquinone and 1% oxalic acid; wash thoroughly; soak in 1.5% AgNO₃ at about 20° C for 25-35 min; rinse; put into an ammino-silver solution (4.5% AgNO₃, 20 ml; pure ethanol, 10 ml; ammonia, sp. gr. 0.880, 2.4 ml; 2.5% NaOH, 1 ml) for 1-2 min; reduce in acidified formalin (distilled water, 400 ml; pure ethanol, 45 ml; 1 % citric acid, 13.5 ml; 10% formalin, 13.5 ml) for 1-3 min; wash; dehydrate through ascending grades of alcohol, including absolute; coat with 0.5% collodion, allow to dry slightly and harden in absolute alcohol-chloroform (2:1); rehydrate and put into 1% Na₂S₂O₃ for 1 min; dehydrate and cover.     

Irreversible blockade of sigma-1 receptors by haloperidol and its metabolites in guinea pig brain and SH-SY5Y human neuroblastoma cells

We evaluated the effect of haloperidol (HP) and its metabolites on [³H](+)-pentazocine binding to σ₁ receptors in SH-SY5Y human neuroblastoma cells and guinea pig brain P₁, P₂ and P₃ subcellular fractions. Three days after a single i.p. injection in guinea pigs of HP (but not of other σ₁ antagonists or (−)-sulpiride), [³H](+)-pentazocine binding to brain membranes was markedly decreased. Recovery of σ₁ receptor density to steady state after HP-induced inactivation required more than 30 days. HP-metabolite II (reduced HP, 4-(4-chlorophenyl)-α-(4-fluorophenyl)-4-hydroxy-1-piperidinebutanol), but not HP-metabolite I (4-(4-chlorophenyl)-4-hydroxypiperidine), irreversibly blocked σ₁ receptors in guinea pig brain homogenate and P₂ fraction in vitro . We found similar results in SH-SY5Y cells, which suggests that this process may also take place in humans. HP irreversibly inactivated σ₁ receptors when it was incubated with brain homogenate and SH-SY5Y cells, but not when incubated with P₂ fraction membranes, which suggests that HP is metabolized to inactivate σ₁ receptors. Menadione, an inhibitor of the ketone reductase activity that leads to the production of HP-metabolite II, completely prevented HP-induced inactivation of σ₁ receptors in brain homogenates. These results suggest that HP may irreversibly inactivate σ₁ receptors in guinea pig and human cells, probably after metabolism to reduced HP.     

Prestaining Oxidation by Acidified H2O2 for Revealing Schiff-Positive Sites in Epon-Embedded Sections

Reliable production and identification of Schiff-positive sites on glutaraldehyde-osmium fixed 0.5-1 μsm Epon sections is accomplished by preoxidation of sections with 10% H₂O₂ acidified with H₂SO₄ (HPSA) to pH 3.2 (Pool, C. R., Stain Techn., 44: 75-9, 1969). Light green as a counterstain is used. Steps in the procedure are: HPSA, 1-2 min at 25-30 C; washing; 1% light green 3-5 min; brief rinse; Schiff reagent 1-3 min; washing; drying; clearing in xylene and mounting in resin. The use of acidified H₂O₂ prevents the common occurrence of Schiff background staining in glutaraldehyde-fixed tissues and permits optimum penetration of staining solutions. Sections were attached to glass slides without adhesive and were processed in Coplin jars. Prior to drying, excess solutions should be drained and wiped away with lens tissue to prevent formation of precipitate on the sections.     

Application and Evaluation of the Lead-Adenosine Triphosphatase Method in Skeletal Tissue

Application and evaluation of the lead-ATPase histochemical method in skeletal tissue has demonstrated an intracellular localization of enzyme activity. The skeletal tissue was demineralized for 72 hr in cold 10% aqueous EDTA adjusted to pH 7.2. Frozen sections were cut and placed on cold albumenized slides, oriented, thawed, dried in a cool air stream, and fixed for 10 min in cold (-2 to -3 C) 10% formalin buffered with Na-acetate and adjusted to pH 7.2. The sections were washed, treated with 10% EDTA for 20 min at room temperature, rewashed, and incubated for an optimal period of 30 min at 37 C. in the lead-ATP medium of Wachstein and Meisel. Following incubation the sections were washed, treated for 1 min with 1% (NH₄)₂S, rewashed, immersed for 30 min in 10% buffered formalin, dehydrated, cleared, and mounted. Evaluation of the substrate specificity suggests that other phosphatases associated with skeletal tissue do not complicate the ATPase reaction.     

Staining Nerve Fibers After Sublimate-Acetic and After Bouin'S Fluid

A silver staining method for paraffin sections of material fixed in HgCl₂, sat. aq., with 5% acetic acid is as follows. Process the sections through the usual sequence of reagents, and including I-KI in 70% alcohol, thiosulfate (5% aq.), washing and back to 70% alcohol containing 5% of NH₄OH (conc. aq.). After 3 minutes in the ammoniated alcohol, wash through tap water and 2 changes of distilled water and silver 5-10 minutes at 25°C. in 15% AgNO₃ aq. to which 0.02 ml. of pyridine per 100 ml. has been added. Blot the slide, but not the section and do not rinse. Reduce at 45°C. in 0.1% pyrogallol in 55% alcohol, then rinse in 55% alcohol and wash in water. The remainder of the process consists of gold toning, intensifying in oxalic acid, fixing in 5% Na₂S₂O₃, washing, dehydrating, clearing and covering. When the specimen contains much smooth muscle, the I-KI solution is acidified before use by adding 2 ml. of 1N nitric acid per 100 ml., and the sections treated for 3 minutes instead of the usual 2 minutes. Formalin should not be added to sublimate-acetic, but specimens that do not contain strongly argyrophilic nonneural tissue may be fixed in formalin or, preferably, Bouin's fluid. Sections of tissue after the latter type of fixation will not require the I-KI and thiosulfate but can go from 95% alcohol to the ammoniated alcohol. The advantages of fixing in HgCl₂-acetic acid are suppression of the staining of connective tissue and intensifying the staining of nerve fibers.     

Histochemical Demonstration of Pyrophosphatase

Fresh tissue slices were fixed in 5% formalin containing 0.9% NaCl for 10-20 min and frozen sections therefrom floated for 3 hr at 37°C on an incubating mixture made as follows. Sodium pyrophosphate (Na₄P₂O₇-12H₂O), 1.088 gm was dissolved in 20-30 ml of distilled water and to this was added ferric chloride (FeCl₃-6H₂O), 0.61 gm dissolved in 10-15 ml of water. The precipitate was just dissolved by cautiously adding 5-10% aqueous Na₂CO₃ solution and the pH adjusted to 7.2 with 1N HCl. The volume was made up to 100 ml and 0.9 gm of NaCl added. Before use, 1 ml of 10% Mg(NO₃) was added. After incubation, sections were washed 10-15 min in 0.9% NaCl, then mounted on glass slides and air-dried. When dry, the slides were immersed in 0.9% NaCl containing 0.2-0.5% ammonium sulfide for 2-3 min, then dehydrated rapidly through graded alcohols, cleared, and covered in balsam. Sites of pyrophosphatase activity stained in various shades of green. Acid pyrophosphatase also was histochemically demonstrated by the same principle, excepting that the substrate solution was adjusted to pH 3.7-4.0 with acetate buffer. The pattern of distribution of pyrophosphatase and glycerophosphatase was almost identical.     

Investigations on Nickel Biosorption and its Remobilization

Immobilized preparations of the bacteria (Pseudomonas aeruginosa and Rhodopseudomonas BHU strain 1) and the cyanobacterium ( Anacystis nidulans) exhibited significant Ni adsorption in the order 91%, 72%, 75%, respectively, within 2 h contact with aqueous NiCl₂ (7·05 μg Ni/0·1 mg biomass). The immobilizing agent (Ca-alginate, 1·5%, w/v) absorbed more Ni (43%) than the exopolysaccharide of cyanobacteria, Rivularia sp. (40%) or Aphanothece sp. (30%). Ni remobilization from different adsorbed systems was maximum (84%) for Ca(NO₃)₂ over NaCl (4·3%) at equimolar concentrations (12 m , each). Extracts from forest soil (organic C, 2-3%) were more effective in Ni remobilization (22·65%) than similar preparations from garden soil (18%) with organic C in the range of 0·98-1·1%.     

Selective Staining of Neurosecretory Material in Semithin Epoxy Sections by Gomori's Aldehyde Fuchsin

The epoxy resin was removed from semithin (1 μm) sections by immersing them for 30 sec in sodium methoxide (Mayor et al., J. Biophys. Biochem. Cytol., 9: 909-10, 1961) and then processed as follows: (1) left for 1-3 hr at 60 C in a mixture of formalin, 25 ml; glacial acetic acid, 5 ml; CrO₃, 3 gm; and distilled water, 75 ml: (2) oxidized 10 min in a 1:1:6 v/v mixture of 2.5% KMnO₄, 5% H₂SO₄ and distilled water: (3) bleached in 1% oxalic acid, and (4) stained for 15 min in aldehyde fuchsin, 0.125% in 70% alcohol, or in a 1% aqueous solution of toluidine blue. The neurosecretory material is selectively stained.     

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.     

Development and evaluation of a new growth medium for Helicobacter pylori

The present study was aimed at modifying the original formulation of Commercial Eugon agar (CEA) to develop a new H. pylori growth medium. Initial studies were carried out to determine the number of H. pylori colonies recovered on in-house H. pylori agar (IHPA), IHPA without l -cysteine and sodium sulfite (IHPA-NC), IHPA without l -cysteine (IHPA-C), IHPA without sodium sulfite (IHPA-N) and CEA as the control. Significant differences ( P <0.001) in the number of colonies recovered were observed between IHPA-N, IHPA-NC and IHPA-C. Incorporation of sodium sulfite decreased the number of colonies recovered, indicating that sodium sulfite was inhibitory to H. pylori growth. Removal of l -cysteine reduced the number of colonies recovered, suggesting that l -cysteine is necessary for the growth of H. pylori . In the subsequent study, incorporation of K₂HPO₄ further increased the number of colonies recovered compared with IHPA-N ( P <0.001), and 0.25% (w/v) of K₂HPO₄ yielded the highest numbers of colonies ( P ≤0.04). Finally, thirty other H. pylori clinical isolates were evaluated for their growth in the IHPAP-N, a new medium consisting of 1.5% (w/v) pepticase, 0.5% (w/v) peptone, 0.4% (w/v) sodium chloride, 0.03% (w/v) l -cysteine, 0.55% (w/v) dextrose, 0.25% (w/v) K₂HPO₄ and 1.5% (w/v) agar. The number of colonies recovered in IHPAP-N was significantly ( P <0.005) higher than that of CEA. IHPAP-N with 0.25% K₂HPO₄ and without sodium sulfite were adequate solid media for the growth of H. pylori .     

Bromphenol Blue as A Stain for Muscle Striations

Sections from formalin-fixed muscle are stained 4-24 hr with a 0.05% solution of bromphenol blue in 2% acetic acid, rinsed with water and placed in 0.5% acetic acid for 5-10 min. They are then treated 30 sec with tap water substitute (KHCO₃, 0.2 gm; MgSO₄, 2 gm; distilled water, 100 ml), rinsed, dehydrated in alcohol, cleared in xylene and covered in a polystyrene mountant Striatums of both cardiac and skeletal muscle fibers are fully resolved under oil immersion, against the blue background of the other parts of the fibers.     

Initial and Persisting Staining power of Solutions of Iron-Hematoxylin Lake

A study was made of factors affecting the initial staining power and the stability of iron-hematoxylin lake solutions. The findings were applied to the preparation of a superior hematoxylin staining solution. This is made up as follows: in 50 ml. water dissolve, in order, 1.0 g. ferric ammonium sulfate [FeNE₄ (SO₄)₂⋅ 12H₂O], 0.8 ml. sulfuric acid, 50 ml. 95% ethyl alcohol, 0.5 g. hematoxylin. Filter the solution to remove the insoluble, white crust of the ferric ammonium sulfate. The solution stains well ten minutes after it has been made. Peak performance is attained within 5 hours, and is maintained for 4 to 8 weeks. Staining time is 3 to 30 minutes. Excess stain can be rinsed off the slide and section by immersion in water, after which destaining, if necessary, can be accomplished with a solution of 50 ml. water, 50 ml. 95% ethyl alcohol, 0.18 ml. sulfuric acid. The slides may or may not be placed next in a neutralizing solution of 50 ml. water, 50 ml. 95% ethyl alcohol, 0.5 g. sodium bicarbonate. They may then be passed through 50 ml. water, 50 ml. 95% ethyl alcohol on the way to alcoholic counterstaining solutions, or through water leading to aqueous counterstains.

The nuclear stain produced is black, intense and very sharp and has proved to be consistently excellent on a variety of animal and human tissues following a number of different fixatives.