Free Radicals Appear to Affect Survival of Hepatocytes at 4°C

1) Rat hepatocytes, stored in a simple salts medium for 24 h at 4°C, retain more than 80% of their capacity to synthesize glucose from lactate.

2) The combination of NH₄Cl with oleate is cytotoxic during storage and during subsequent incubation of hepatocytes from 48 h starved rats, but not to hepatocytes from fed rats.

3) Protection against cytotoxicity is afforded by albumin and by a number of other compounds, notably polyols and glycerol.

4) These compounds appear to exert their effects by scavenging free radicals and, in the case of polyols and glycerol, by supplying reducing equivalents to maintain the redox state of the cell in the face of increased flux through glutathione peroxidase.     

A Controllable Silver Stain for Nerve Fibers and Nerve Endings

A paraffin section method is described with a yellow-brown-black color range comparable to that of Ranson's pyridine silver block stain. After impregnation with activated protargol and reduction with a fine grain photographic developer, silver nitrate impregnation and reduction are repeated as often as necessary. The procedure is as follows:

Place hydrated sections of tissue fixed in chloral hydrate (25 g. in 100 ml. of 50% alcohol) in 1% aqueous protargol (Winthrop Chemical Co.) containing 5-6 g. metallic copper for 12-24 hours. After rinsing in 2 changes of distilled water, reduce 5 to 10 minutes in: Elon (Eastman Kodak Co.) 0.2 g., Na₂SO₃, dessicated, 10 g., hydroquinone 0.5 g., sodium borate powder 0.1 g., distilled water 100 ml. Wash thoroly in 4 or 5 changes of distilled water and place in 1% aqueous AgNO₃ for 10-20 minutes at 28°-50° C. Rinse in 2 or 3 changes of distilled water and reduce in the elon-hydroquinone solution. After thoroly washing in 4 or 5 changes of distilled water, examine under microscope.

If too pale, treat again in silver nitrate for 10-20 minutes, rinse, reduce 5-10 minutes and wash thoroly until nerve fibers show distinct microscopic differentiation, then dehydrate, clear and mount.     

Locating Iodine in Tissues Autographically, Especially after Fixation by Freezing and Drying

The ability of radioactive elements to affect photographic emulsions enables the detection of radioactive iodine in the thyroid. By placing unstained histological sections of a thyroid (from an animal treated with radioactive iodine) in contact with the gelatin side of medium lantern slide plates, each accumulation of radioactive iodine in the section affects the photographic plate. After exposures prolonged for several days to several weeks depending on the amount of radioactivity in the tissues, the plate is developed and fixed by routine photographic methods. The histological section is stained and may be compared under the microscope to the reactions on the plate or “autographs”.

In an attempt to detect the location of the inorganic iodine which is displaced during fixation and embedding by ordinary methods because of its solubility, a simplified freezing-drying technic for fixation was devised which, at least with the thyroid, yielded well fixed sections. The quick freezing was obtained with acetone-dry-ice mixtures; and the drying was performed at -25° to -30° C. Preliminary addition of paraffin to the tube in which the drying was performed made possible the inclusion in vacuum by heating the tube when drying was completed. The tissue could then be sectioned at 10ju on the microtome. The slides were placed on photographic plates for detection of radioactive iodine as indicated above. Before staining, the sections were treated with absolute alcohol for denaturation of the proteins.     

Specific Staining of Nucleolar Substance with Aceto-Carmine

A method is described for staining nucleoli intensely by treating tissues with formaldehyde, hydrolysing in normal HC1 at 60°C. and staining with aceto-carmine. With correct hydrolysis time, chromosomes and cytoplasm are almost colorless.

Formaldehyde increases the acidity of cell parts, especially the nucleolus, presumably by neutralizing the basic protein groups, and increases the resistance to hydrolysis, perhaps by protecting the phospholipoprotein complexes which are most abundant in the nucleolus.

Hydrolysis reduces the acidity of cell parts, chiefly by removal of nucleic acids.

Aceto-carmine stains cell structures which are weakly acid in character (about pH 4-5) probably by precipitating as large dye aggregates.

The technic appears to be highly specific for nucleoli and related cell bodies.     

An Ice-Solvent Method of Drying Frozen Tissue for Plant Cytology

A freeze-dry method where cold absolute ethanol is used as a dehydrating agent in place of vacuum dehydration has been applied to various plant materials with good cytological results. The method involves: (a) freezing rapidly small pieces of tissue 1 cubic mm or less in partly frozen isopentane cooled with liquid nitrogen, (b) transferring quickly to vials of cold absolute ethanol at -41° to -45°C, and (c) holding within this temperature range for 3 days to dissolve the ice. A simply constructed cryostat is used to maintain the vials of absolute alcohol and tissue at the cold temperature. This consists of a semi-frozen constant temperature bath of either 65% ethanol or pure diethyl oxalate in a tightly covered beaker which fits within a large dewar flask half filled with dry ice. The bath is arranged so that it will be on top of and in contact with the dry ice but properly insulated to prevent freezing completely.

The resulting dried tissue is very unstable in either water or hot absolute ethanol; therefore, to prevent loss of cytological detail during further processing, the tissue must be treated to render the proteins insoluble. Either (a) replace the cold absolute ethanol in the tissue vials with cold (approx. -40°C) 75% ethanol, warm slowly to 60°C, and hold for 1 hour, or (b) replace with cold acidulated 95% ethanol (100 ml. of 95% ethanol + 0.30 ml. of glacial acetic acid), warm to room temperature, and hold for 30 minutes. Following either treatment the tissues are dehydrated to absolute alcohol and embedded in paraffin by the usual technics. Sections are attached to slides by flattening over warm water and drying.

When epidermis from onion bulbs was used as a basis of comparison of fixed and living material with the phase-contrast microscope, the mitochondria, plastids, and other fine structures in fixed preparations appear to be nearly identical with the living. Fat droplets disappear. With larger tissues such as onion root tips, thin freehand sections must be prepared before freezing to obtain good cytological results. The application of the method to cytochemical studies is discussed and in many ways it seems to be as useful as the freeze vacuum-dry method.     

Staining Residual Lipids in Ultrathin Sections of Tissues Embedded in Polyester Resin

Rat suprarenal glands fixed in Palade's 1% OsO₄, buffered at pH 7.7 with veronal-acetate, to which 0.1% MgCl₂ was added, were embedded in Vestopal-W and sectioned at 0.2-1 µ. The sections were attached to slides by floating on water, without adhesive, and drying at 60-80° C, placed in acetone for 1 min and then treated with the following staining procedure: Place the preparation in a filtered solution of oil red O, 1 gm; 70% alcohol, 50 ml; and acetone, C.P., 50 ml; for 0.5-1 hr. Rinse in absolute ethyl alcohol; drain; counterstain with 0.5% aqueous thionin for 5 min; rinse in distilled water; drain; stain in 0.2% azure B in phosphate buffer at pH 9, for 5 min. Dry and apply a drop of immersion oil directly on the section. The preparations are temporary. Ciaccio-positive lipids, rendered insoluble by OsO, fixation, stained red to ochre.     

Further Experiments with the Masson Trichrome Modification of Mallory's Connective Tissue Stain

Several dyes, notably ponceau 2R, azofuchsin 3B, nitrazine yellow, and Biebrich scarlet may replace imported “ponceau de xylidin” in the Masson ponceau acid fuchsin mixture. Of these Biebrich scarlet appears to be the best and may be used without acid fuchsin.

A mixture of equal parts of 5% solutions of phosphomolybdic and phosphotungstic acids is much superior to either acid alone and gives adequate mordanting in 1 minute at 22°C.

With the fast green modification, times in plasma and fiber stains can be reduced to 2 minutes each. With anilin blue a 4-minute plasma stain is required. One-minute final differentiation in 1% acetic acid is adequate.

Primary mordanting of formalin material may be accomplished by 5 minutes in saturated aqueous mercuric chloride or 2 minutes in saturated alcoholic picric acid. Three minutes washing in running water is required after these mordants.     

Grinding Thin Sections of Plastic-Embedded Bone

The method describes an adaptation of a metallurgical procedure whereby dry, calcined bone may be simultaneously infiltrated and embedded in a transparent plastic, Transoptic, and then ground to the desired thinness for microscopic observation with transmitted light. A 2 mm.-thick specimen of bone, ground smooth on one side, is placed ground side up in a 1' mold assembly of a metallurgical specimen mount press. About 5 ml. of the plastic medium is added, the temperature raised to 130° C, and the pressure raised to 100 pounds. When 130° C. is reached, the heater is disconnected, the pressure immediately raised to 3500 pounds and maintained at that level until the mold cools to 68° C. The pressure is then released and the 5 mm.-thick plastic disc, with the embedded specimen therein, expressed from the mold. Grinding, as well as polishing, is dry; abrasives in fluid media are not used. The disc and specimen are coarse ground on #340 grit dry silicon carbide paper until histological details begin to appear. Final fine grinding is done on #600 grit dry silicon carbide paper. The disc is then polished and may be mounted on a 1 × 3 Plexiglas slide.     

The Plastic Ethyl Methacrylate in Routine Laboratory Technic

The use of ethyl methacrylate as a permanent, transparent, colorless medium for mounting in toto invertebrate and vertebrate embryos and small adults is demonstrated.

The liquid monomer is partially polymerized by heating over a hot-plate, the reaction being aided by the use of benzoyl peroxide as a catalyst. The object to be mounted is fixed, stained, dehydrated, and cleared in the usual manner, and is then infiltrated with the partially polymerized ethyl methacrylate. It is oriented on a hardened base in a glass or porcelain dish, and the mold is then allowed to harden (polymerize) completely at a temperature of 38-40° C. under a 250-watt infra-red, ultra-violet bulb. After the block is removed from the dish it may be polished by the ordinary metallurgical methods. More than 40 species of animals have been satisfactorily treated in this manner.     

Enzymatic and Non-Enzymatic Esterification of long Polyunsaturated Fatty Acids and Lysophosphatidylcholine in Isooctane

Phosphatidylcholine containing large amounts of long polyunsaturated fatty acid, eicosapentaenoic acid (C20:5) and docosahexaenoic acid (C22:6), was synthesized in isooctane. Immobilized phospholipase A₂ was used as a catalyst. A parallel non-enzymatic esterification reaction was investigated in separate experiments.

The concentrations of lyso-phosphatidylcholine, polyunsaturated fatty acids, water and the enzyme were varied over wide ranges as were the temperature and the reaction time. The type of enzyme, carrier and immobilization procedure were held constant.

The yield of phosphatidylcholine was relatively high (about 21%) when the concentration of polyunsaturated fatty acids was high (300 mg/g of reaction mixture) and the water content was low (below 30% of the dry immobilized enzyme). The highest yield of phosphatidylcholine was found at 80 hours and 75°C. However, at this temperature an extensive non-enzymatic reaction between polyunsaturated fatty acids and lyso-phosphatidylcholine occurred. At 80°C the polyunsaturated fatty acids were partly oxidized. Therefore, a temperature of 45°C to 65°C is probably the optimum temperature for the reaction.     

The Dry Preservation of Fixed Plant Material

A method for the dry-preservation of fixed plant material, root tips and buds, is described. The method seems to be advantageous on long expeditions and when material has to be sent away.

The material is transferred from the fixative to 70% alcohol (3 changes, 1/2 hour in the last). It is dried on blotting-paper. The dried material may be preserved a long time. Material kept dry for 4 1/2 years has proved to be quite satisfactory. Drying has been tried after fixation with CRAF-solutions (Webber and Randolph modifications) and fixatives containing osmic acid (Fleming-Benda and 2BD).

The dry material is swollen by keeping for 2 days in 10% alcohol. It is embedded in paraffin according to the usual method. A satisfactory staining has been obtained after these fixatives using iodine-gentian-violet and Feulgen stainings. In addition to chromosome counts dry material may be used for chromosome morphology studies.

Dried material fixed in aceto-alcohol (1:3) has not turned out to be specially suitable for squash preparations owing to the fragility of the chromosomes. If strong pressure is not applied, satisfactory results may, however, be obtained.     

Histochemical Demonstration of Carbonic Anhydrase Activity

Fresh tissue slices fixed in chilled acetone for 1 hour and washed in distilled water for 10-30 minutes were incubated for 30-45 minutes at 37°C. in the freshly prepared incubating mixture: filtrate of a mixture of 8% sodium bicarbonate, 100 ml., and MnCl₂·4H₂O, 1 g. After washing in distilled water for 1 hour, they were dehydrated and embedded in paraffin. Sections were cut 15-20μU, deparaffinized, rinsed in absolute alcohol and placed in a 0.1% solution of potassium periodate for 48 hours at 37°C. The mounted sections were counterstained (if desired), dehydrated in alcohol, cleared in xylene (not carbol-xylene) and mounted in balsam. Many brown granules were produced on the sites of enzyme activity by this procedure. The results obtained seem to be in good agreement with previous findings by biochemical determinations.     

The Processing of Mammalian Haemopoietic Cells in Thin Layer Agar Cultures for Electron Microscopy

Human and mouse haemopoietic cells cultured by the thin layer agar technique have been studied with the electron microscope. To process colonies of haemopoietic cells or individual cells which appeared in these colonies, a special technique had to be developed. The technique presented covers methods of selection, isolation, and sectioning that were devised for this purpose.

Haemopoietic cells are cultured in small plastic Petri dishes containing a culture system with 0.25% agar. Cell colonies and individual cells intended for light as well as for electron microscopic study are examined and selected microscopically with the aid of a numbered grid which is placed under the closed Petri dish.

Cells in the agar gel are fixed with glutaraldehyde which is pipetted directly onto the cultures. In order to facilitate their removal from the medium, the consistency of the agar solution is increased by evaporating liquid with controlled mild warming.

Pieces of agar containing colonies or single cells are cut out with a fine trephine and postfixed in osmium tetroxide. Agar pieces are embedded cell side up in a thin layer of Epon. After polymerization, the Epon-embedded pieces of agar are appropriately oriented at the head of flat embedding molds filled with fresh Epon. After another polymerization procedure, the top of the Epon blocks containing the cells are trimmed to a smooth surface with a glass knife.

The exact distance between the smooth surface of the blocks and the cells is measured by use of the vertical micrometer of a standard light microscope. The Epon layer around the specimen is trimmed away to expose selected cells for subsequent semi-thick and ultrathin sectioning. Sections are stained and examined microscopically.

With minor modifications the technique described also enables the processing of extremely small quantities of biological materials derived from other experiments for both light and electron microscopic observation.     

2-Heptanone Production by Spores of Penicillium roquefortii in a Water-Organic Solvent Two-Phase System

The production of 2-heptanone from octanoic acid may be performed by free and entrapped spores of Penicillium roquefortii in a water-organic solvent two phase system.

An industrial, isoparafflnic solvent, i.e. Hydrosol IP 230 O.S., which may be considered as tetradecane, is well suited for the process. Activities nearly double those achieved with aqueous systems are observed using an initial fatty acid content in the organic layer close to 100 mM and a ratio of the volume of the organic phase to the total volume of the medium of 0.88. The presence of the solvent allows a better recovery of the metabolite by lowering its activity coefficient.

Fed-batch experiments performed in an aerated, stirred reactor show that the bioconversion may proceed in the two-phase system for at least 300 h. These conditions allow conversion of 750 mM (108 g · 1^-1) fatty acid, and production of 600 mM (68.5 g · 1^-1) 2-heptanone.     

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).     

Methacrylate Embedding and Sectioning of Calcified Bone

Twenty-five milliliter aliquots of ethyl-butyl (1:1) methacrylate were polymerized at 6 or 7 initiator concentrations using 3 polymerization temperatures, both in air and in a water bath. Duplicate series were polymerized with and without vibration, pre-polymerization, and exclusion of oxygen. Hardening times and maximum temperatures reached within the samples were recorded. Vibration and the exclusion of oxygen had no effect. Prepolymerization, increasing polymerization temperature and increasing initiator concentration all decreased the hardening time and increased the maximum temperature. Polymerizing in a water bath rather than in air reduced the maximum temperature by 25-40°C and lengthened the hardening time about 1 hr. An initiator concentration of 0.4% Luperco CDB in ethyl-butyl methacrylate and a water-bath temperature of 45°C were selected for tissue embedding. The hardening time was 8 hr and the maximum temperature during polymerization was about 60°C.

Split rat femora and tibiae were freeze-dried and vacuum-infiltrated with acetone, absolute alcohol or monomer. The acetone or alcohol-fixed specimens were subsequently infiltrated with monomer. The specimens were transferred to 1 oz bottles, prepolymerized syrup added, and polymerized. No consistent differences between specimens treated by these methods were noted. Five-micron serial sections could be cut using a Leitz sledge microtome with a modified knife if the block was coated with paraffin between sections.     

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.     

Influence of Igepal reverse micellar and micellar systems on activity and stability of heme peroxidases

The activities of horseradish peroxidase (HRP) and lactoperoxidase (LPO) entrapped in reverse micelles of Igepal CO-520 in cyclohexane were studied. When the molar ratio of water to surfactant, w ₀ was ≥13, the activity of HRP encapsulated in the water pool of the reverse micelle was comparable with that measured in buffer. For LPO, however, lower activity was observed after its incorporation into the same system.

The activity of the investigated peroxidases was also measured in an aqueous solution of Igepal CO-720 or after incubation with this surfactant. The enzymes became inactivated in an aqueous micellar solution of Igepal CO-720, although this process was reversible.

The stability of HRP and LPO at 37 or 50°C was lower in the micellar systems than in buffer with the exception for HRP in reverse micelles at 50°C.     

Evaluation of high sensitive C-reactive protein and 5-10 methylenetetrahydrofolate reductase genotype in Japanese young adults

Primary objective: To carry out a preliminary evaluation of subclinical inflammation and its genetic background in young adults.

Research design: Fifty-five healthy Japanese young adults aged 19-27 years (37 males and 18 females, mean age: 22.3 years), and 58 healthy Japanese adults aged 40 to 60 years (21 males and 37 females, mean age: 51.5 years) were included in this study.

Methods and procedures: We measured plasma high-sensitive C-reactive protein (hs-CRP) levels and screened for the C677T polymorphism of the 5-10 methylenetetrahydrofolate reductase gene (MTHFR), which is considered a genetic risk factor for atherosclerosis, by HinfI digestion.

Main outcomes and results: Hs-CRP levels of the young adult group were significantly lower than the levels of the middle aged group (0.014±0.030 mg/dl vs. 0.031±0.040 mg/dl, p=0.005). The levels were significantly higher in males than in females (0.028±0.019 mg/dl vs. 0.013±0.010 mg/dl, p=0.008) among young adults. Furthermore, we evaluated the relationship of the C677T genotype and hs-CRP values, but found no association between them.

Conclusions: Although the sample size is limited, our preliminary study demonstrated the profiles of hs-CRP in Japanese young adults. Further investigation will be needed to establish the guidelines for customized school health education using sensitive laboratory and genetic markers.