Notes on Technic: A Device for Centering Tissue Blocks on the Porter-Blum Microtome

A method of double embedding fixed tissues in 3% low viscosity nitrocellulose and paraffin is described. Five percent phenol in 80% alcohol during dehydration and 5% glycerin in the nitrocellulose solutions enhance cutting qualities. A modified Ruyter's solution is used to flatten sections. After a section is aflixed to a slide, it is passed through chloroform and acetone to remove the paraftin and celloidin. A 1% celloidin dip insures adherence of the seaion to the slide. Slides are stored in 70% alcohol until they are to be stained. Following staining and dehydration in graded alcohols, clearing should be done in a 1: 3 mixture of terpineol and toluene.     

Double Embedding Again

A method of double embedding fixed tissues in 3% low viscosity nitrocellulose and paraffin is described. Five percent phenol in 80% alcohol during dehydration and 5% glycerin in the nitrocellulose solutions enhance cutting qualities. A modified Ruyter's solution is used to flatten sections. After a section is aflixed to a slide, it is passed through chloroform and acetone to remove the paraftin and celloidin. A 1% celloidin dip insures adherence of the seaion to the slide. Slides are stored in 70% alcohol until they are to be stained. Following staining and dehydration in graded alcohols, clearing should be done in a 1: 3 mixture of terpineol and toluene.     

Protective Paraffin Infiltration of Soft Tissues in Insects to Facilitate Softening of Hard Exoskeletons

This technique can produce serial sections as thin as 5 μ from hard chitin-covered materials of insects or other arthropods. Procedures: Fix with alcoholic Bouin's fluid for 3 hr. Henceforth subject material to partial vacuum in each step to ensure a final proper embedding. Wash with 80% ethanol 2 or 3 times for 2 hr or until the picric acid is largely removed. Dehydrate to 90% ethanol and give 2 changes of n-butanol 2 hr each, and one of a 1:1 n-butanol-paraffin mixture in 56-57° oven for 12 hr. Finally, use 2 baths of pure paraffin, 3 hr each, to complete the infiltration. After the last bath, withdraw the specimen from the paraffin, and remove the superficial paraffin, first mechanically and then with a xylene bath for 4 min. Rinse first with n-butanol, and afterwards with absolute ethanol, 2 min each. The compound eyes are protected with a paraffin covering, the specimen is hydrated with a 1% aqueous solution of detergent for 1 hr and then washed with running tap water. The material is treated with a concentrated sulfuric-nitric mixture (H₂SO₄:HNO₃) for 4 hr to eliminate the exoskeleton. After this treatment, the specimen is washed with running tap water for 12 hr, dehydrated with acetone and then bathed in a 2% solution of celloidin in ethyl acetate to form a protective artificial cuticle. This coating is hardened with 2 quick baths of chloroform, the specimen reembedded in paraffin, and the block cast for sectioning.     

A Celloidin Infiltration-Frozen Section Sequence for Enhanced Preservation of Phosphatases in Bone

The effect of the following embedding procedures on the acid and alkaline phosphatase content of decalcified mouse tibiae has been studied: embedding in 23% gelatine for 18 hr at 37° C, embedding in paraffin wax in vacuo for 1 hr at 58° C, and impregnation with 4% celloidin in diethyl ether and ethanol at 4° C for 2-3 days. Unsupported tissues were also used to demonstrate these enzymes for comparison with the above procedures. Tibiae were first fixed in 10% neutral formalin at 4° C for 15 hr, decalcified in equal volumes of 2% formic acid and 20% sodium citrate at pH 4.9 for not more than 5 days and then washed in distilled water before carrying out the embedding schedules. The celloidin-impregnated tibiae were placed in 70% ethanol to harden the celloidin and then washed in distilled water for 1-2 hr. These tibiae and those embedded in gelatine were cast in a gelatine block which was then hardened in 10% neutral formalin at 4° C for 2 hr. Sections of these and unsupported tibiae were cut at 15 μ on a freezing microtome. Decalcified tibiae embedded and blocked in paraffin wax were sectioned at 15 μ on a base sledge microtome. The enzymes were demonstrated using the coupling azo dye method given by Pearse (Histochemistry, 1st Ed. 1954). The stable diazotates of 4 benzoyl amino 2-5 diethoxyanilene, 3 nitro toluidine and o-dianisidine were used. Of the embedding procedures paraffin wax embedding produced the greatest loss of both enzymes. Gelatine embedding and infiltration with celloidin were equally good for the demonstration of acid phosphatase but for alkaline phosphatase the celloidin method was superior. The gelatine embedded material did not produce consistently good results. Celloidin-impregnated tibiae could be stored without marked deterioration of the enzyme content for longer than gelatine-embedded tibiae.     

Staining and Mounting Helminths

The following procedure is recommended: Fix ces-todes and trematodes (while held flat between glass slides) 0.5-2.0 hr. in the following mixture: formalin, 15; acetic acid (gl.), 5; glycerol, 10; 95% ethyl alcohol, 24; distilled H₂O, 46; all proportions by volume. After freeing them from the slides, wash thoroughly in running water and stain immediately thereafter. Stock staining solution: ferric ammonium alum (violet cryst.), 2 g.; distilled H₂O (cold) 100 ml.; after solution, add 2 ml. concentrated H₂SO₄, bring to a boil; add 1 g. coelestin blue B (Nat. Aniline), boil 3-5 min.; cool and add 10 ml. absolute methyl alcohol and 10 ml. glycerol. Dilute 1 vol. with 3 vol. distilled H20 for use. Stain 5-30 min., depending on size of specimens. Wash with 2 changes 0.5 hr. each of distilled H₂O, then 50% isopropyl alcohol 12-16 hr., 50% isopropyl alcohol 2 hr., followed by graded isopropyl alcohol for dehydration. Ether: ethyl alcohol (equal parts), 1 hr., is followed by embedding in celloidin in a sheet just thick enough to cover the specimens. Trim embedded specimens and dehydrate with isopropyl alcohol, 80%, 90% and absolute. Clear in beechwood creosote. Mount in balsam with cover glasses that overlap the edges of the celloidin 1-2 mm. While drying at 37°C, refill edges of mount with fresh balsam as needed. When dry, remove excess balsam and ring the edges with ordinary gloss enamel paint.     

Silver Protein Staining of Nerve Fibers in Celloidin Sections

Celloidin sections from formalin-fixed brain and spinal cord of primates are stored in 70% alcohol after cutting, soaked in 2% pyridine in 50% alcohol for 6-8 hr at 37 C, and transferred to 1% concentrated NH₄OH in 50% alcohol 15-18 hr at 20-25 C. After washing and flattening, the sections are transferred to 1% silver protein solution containing 30 ml of 0.2 M H₃BO₃/100 ml. Impregnation is accomplished in 50 ml screw-top jars, 50 mm in diameter, which are filled to a depth of 35 mm, and have 1 gm of copper foil, 0.002 inch thick added. The foil is folded in loose accordion-fashion, pierced and threaded, cleaned in 5% HNO₃, rinsed in distilled water, and suspended in the solution just above the sections by fastening the thread to the jar lid. The sections are impregnated for 24 hr at 37 C, rinsed in distilled water, reduced in a solution of 5% Na₂SO₃ and 1% hydroquinone for 10 min, washed in distilled water and toned in 0.2% gold chloride for 5 min. After rinsing in distilled water, the sections are transferred to 1% oxalic acid for 45-60 sec, washed in distilled water and placed in 5% Na₂S₂O₃ for 5 min. Sections are then washed, dehydrated to 95% alcohol, cleared in terpineol, followed by 3 changes in xylene, and mounted.     

Staining and Mounting Helminths

The following procedure is recommended: Fix ces-todes and trematodes (while held flat between glass slides) 0.5–2.0 hr. in the following mixture: formalin, 15; acetic acid (gl.), 5; glycerol, 10; 95% ethyl alcohol, 24; distilled H₂O, 46; all proportions by volume. After freeing them from the slides, wash thoroughly in running water and stain immediately thereafter. Stock staining solution: ferric ammonium alum (violet cryst.), 2 g.; distilled H₂O (cold) 100 ml.; after solution, add 2 ml. concentrated H₂SO₄, bring to a boil; add 1 g. coelestin blue B (Nat. Aniline), boil 3–5 min.; cool and add 10 ml. absolute methyl alcohol and 10 ml. glycerol. Dilute 1 vol. with 3 vol. distilled H20 for use. Stain 5–30 min., depending on size of specimens. Wash with 2 changes 0.5 hr. each of distilled H₂O, then 50% isopropyl alcohol 12–16 hr., 50% isopropyl alcohol 2 hr., followed by graded isopropyl alcohol for dehydration. Ether: ethyl alcohol (equal parts), 1 hr., is followed by embedding in celloidin in a sheet just thick enough to cover the specimens. Trim embedded specimens and dehydrate with isopropyl alcohol, 80%, 90% and absolute. Clear in beechwood creosote. Mount in balsam with cover glasses that overlap the edges of the celloidin 1–2 mm. While drying at 37°C, refill edges of mount with fresh balsam as needed. When dry, remove excess balsam and ring the edges with ordinary gloss enamel paint.     

The Histological Examination of Mummified Material

Tissue from Egyptian mummy material is extremely brittle; hence it was handled in perforated glass tubes during processing. The first (softening) fluid consisted of 96% ethyl alcohol, 30 vol; 1% aqueous formalin, 50 vol; 5% aqueous Na₂CO₃, 20 vol. It was used in a fluid to tissue volume ratio of 100:1 and allowed to act overnight. A special dehydrating sequence: 80% alcohol, 3-6 hr; 8% phenol in 96% alcohol, and absolute alcohol followed by 3 changes of amyl acetate, 6-18 hr each; 3 changes of 1 % celloidin in methyl benzoate, 24 hr each; then through benzene and embedding in paraffin completed the special technic. This allowed regular sectioning and staining to be done successfully.     

A Sensitive Myelin-Sheath Stain Particularly Useful for Small Mammals and Neonatal Cats

Staining of myelinated fibers including the delicate myelin sheaths of infantile animals is as follows: perfuse the anesthetized animal with a pH 7.4 posphate-buffered fixative, either 10% formalin, 6% gluteraldehyde or a mixture containing 3% gluteraldehyde and 2% acrolein. Dissect out the brain or spinal cord and continue fixation for at least 24 hr. Cut larger brains to 1 cm in at least one dimension. Wash in running tap water 2-3 hr and soak in 2.5% potassium dichromate in 1% acetic acid (the primary mordant) for 3-5 days in darkness. Wash at least 12 hr in running tap water. Dehydrate and embed in celloidin and store in 80% ethanol. Section at 25-60 μ into 80% ethanol. Wash 1-2 min in distilled water and then immerse in 1-2% ferric alum at 50 C for at least 1 hr (the secondary mordant). Wash in tap water and stain at least 1 hr at 50-60 C in 0.5% unripened hematoxylin in 1% acetic acid. Wash well in tap water and differentiate in a mixture containing 0.5% ferrityanide, 0.5% borax and 0.5% Na₂CO₃; 2 changes. Wash well in distilled water, then in tap water, and dehydrate, clear and mount. Myelin stains black, cell bodies stain tan, and the background is pale yellow. With minor modifications in timing, the method is applicable to frozen and to paraffin sections; the primary mordant being omitted in the freezing technique.     

A Tungstate Modification of the Golgi-Cox Method

Pieces of fresh nervous tissue 4-5 mm thick are put into the following solution: HgCl₂, 1 gm; K₂Cr₂O₇, 1 gm; K₂CrO₄, 0.8 gm; K₂WO₄ (or Na₂WO₄), 0.5 gm; distilled water 100 ml. They are kept undisturbed in the dark at room temperature for 20-30 days, then transferred to the following alkaline solution: LiOH (or NaOH), 1 gm; KNO₃, 15 gm; distilled water, 100 ml. After 12-24 hr in this solution they are washed for 12-24 hr in several changes of distilled water. (If sodium hydroxide was used, 0.5 ml of acetic acid should be added per 100 ml of wash water.) Embedding in celloidin follows dehydration. Sections are dehydrated in 3 parts of absolute alcohol and 1 part of chloroform, cleared in iodobenzene and mounted with a cover slip using a mounting medium with a refractive index around 1.61. The use of tungstate improves the general results and allows especially successful impregnations in very young animals, when the usual technic fails.     

Sectioning Insects with Sclerotized Cuticle

Adult insects of different orders including beetles were fixed in a mixture of a saturated solution of picric acid in 90% alcohol, 75 parts; formalin, 25 parts; nitric acid (cone), 8 parts, 4-6 days and even up to 10 days depending upon the hardness of the cuticle (addition of 5% mercuric chloride to this mixture is recommended when prolonged immersion is required), or in Carnoy and Lebruns' fluid 24-48 hours and then transferred to a solution of 3-6 parts of nitric acid in 100 parts of 90% alcohol (3-6 days). After dehydration in different grades of alcohol, the insects were double embedded in celloidin and paraffin, either by (1) clove oil for 1 day, then to a saturated solution of celloidin in clove oil matured for at least 2 months for 20-40 days, or (2) the conventional ether-alcohol-celloidin mixture for 7 days; followed by hardening in chloroform. The difficulty in the proper infiltration of paraffin into celloidin hardened by chloroform around the insect is avoided by keeping the block overnight in a mixture of paraffin, 1 part; chloroform, 5 parts. The rest of the technic is essentially the same as that followed in cutting sections after double embedding.     

Basic Dye Counterstaining of Sections Impregnated by the Golgi-Cox Method

Celloidin blocks of Golgi-Cox impregnated material are cut at 50 μ, the sections collected in 70% alcohol, transferred to a 3:1 mixture of absolute alcohol and chloroform for 2 min, and then stored in xylene or toluene for at least 3 min, or up to 2 wk until processed further. Mounting is done on glass slides which have been coated with fresh egg albumen diluted in 0.2% ammonia water (or a 0.5% solution of dry powdered egg albumen) and then dried at 60°C overnight. For attachment to these coated slides, sections are first soaked for 2-3 min in a freshly prepared mixture of methyl benzoate, 50 ml; benzyl alcohol, 200 ml; chloroform, 150 ml; and then transferred quickly to the slides by means of a brush. After 2-3 min the chloroform evaporates and the celloidin softens. The slides are then immersed in toluene which hardens the celloidin and anchors the sections to the slides. Alcohols of descending concentrations to 40% are followed by alkalinizations, first in: absolute alcohol, 40 ml; strong ammonia water 60 ml, for 2 min, then in: absolute alcohol, 70 ml; strong ammonia water, 30 ml, for 1 hr. Excess alkali is then removed by 70% and 40% alcohol, 2 min each, and a 10 min wash in running tap water. Bleaching in 1% Na₂S₂O₃, for 10 min and washing again in tap water for 10 min completes the process preliminary to staining. The preparations are then stained for 90 min in an aqueous solution of either 0.5% cresylecht violet, neutral red, or Darrow red, buffered at pH 3.6. Dehydration and differentiation in ascending grades of alcohol, clearing with toluene or xylene, and applying a cover glass with a mounting medium having a refractive index of about 1.61 completes the process.     

A Simplified and Convenient Method for the Double-Embedding of Tissues

A method for embedding tissues with a celloidin-paraffin combination is presented. The essential features of the process depend upon (1) a thorough infiltration of the specimen with celloidin of low concentration, and (2) the subsequent impregnation of both the specimen and the celloidin with paraffin.

The methods for sectioning, and the removal of the embedding agent are given.

The chief advantages of this method are: the preservation of all of the advantages of celloidin embedding but with a great saving of time, and greater convenience of storage; the cutting of thin sections (2μ for many types of tissues); it is useful for embedding specimens for which neither pure paraffin nor pure celloidin are entirely satisfactory, i.e. those containing tissues differing in density.     

Autoradiography of Water-Diffusible Substances in Sections of Whole Baby Rats

Rats, 7 days postnatal which had been injected with a radioactive nuclide, were quick frozen and sectioned in the frozen state. An adhesive cellulose tape (Sellotape) was used to support the section during cutting, through freeze-drying, and attaching to slides. Dehydration of the frozen sections consisted of 1 hr in a chilled desiccator containing silica gel, then at reduced pressure of 2-3 mm Hg until quite dry. The exposed side of the section was sprayed with celloidin dissolved in amyl acetate and allowed to dry. This side of the section was attached to a slide, previously coated with 1% gelatin containing 0.1% chrome alum, by means of an adhesive consisting of 4% gelatin and 5% formalin in 60% glycerol. In applying this adhesive it is mandatory that a border of about 3 mm of bare glass be left outside the adhesive, to allow intimate contact between the sticky side of the tape and the glass. The adhesive was allowed to set for 20 min, the slide immersed in water lor 50 sec, and the cellulose layer of the tape peeled off. The rubber base from the tape was removed with chloroform, the slide dried, and the exposed surface of the section coated with celloidin in amyl acetate, by dipping. After this treatment, the slides could be coated by dipping in autoradiographic emulsion without affecting water-soluble radioactive substances in the tissue.     

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.     

Staining Reticulin with Gold

This bromine-iodine-gold chloride-reduction sequence stains reticulin in formalin-fixed paraffin sections without risk of sections becoming detached. After hydration, sections are exposed to 0.2% bromine water containing 0.01% KBr for 1 hr, then rinsed and placed for 5 min in a solution consisting of KI, 2 gm; iodine crystals, 1 gm; and distilled water, 100 ml. After this the sections are well washed in distilled water, immersed for 5 min in 1% w/v aqueous solution of chloro-auric acid, again rinsed in distilled water, and the gold is reduced by placing in freshly made 3% H₂O₂ for 2-4 hr at 37 C, or in 2% oxalic acid for 1-3 hr at the same temperature.     

Affixing Polyester Wax Sections to Glass Slides by Celloidin and Cellulose Acetate Applied in Sequence

Sections cut from material embedded in polyester wax can be firmly attached as follows: One drop of a 2% solution of celloidin in amyl acetate is smeared on clean slides, and sections taken from the floatation water onto these slides are dried at room temperature. After drying the slides are immersed in a 2% solution of cellulose acetate in acetone for 1 min, transferred directly to absolute ethanol, through 50% ethanol, and into water. Sections affixed by this method and stained by either hematoxylin-eosin or toluidine blue schedules do not loosen and have negligible background staining.     

Brazilin-Toluidine Blue O and Hematoxylin-Darrow Red Methods for Brain and Spinal Cord

Tissue fixed in 10% formalin, formalin-95% ethanol 1:s CaCO₂ or phosphate buffer neutralized formalin, or methanol-chloroform 2:1, was dehydrated and embedded in paraffin or double-embedded by infiltration in 1% celloidin followed by a chloroform-paraffin sequence. Sections were attached to slides with either albumen or gelatine adhesive and processed throughout at room temperature of 24-26 C. For either method, mordanting 30-60 min in 1% iron alum was followed by a 10 min wash in 4 changes of distilled water. For brazilin-toluidne blue O, myelin was stained for 20-60 min, depending upon section thickness, in a self-differentiating solution consisting of: 0.15% Li₂CO₃ 75 ml; 6% brazilin in 95% ethanol, 25 ml; and NaIO₃ 75 mg. After a thorough washing, Nissl material was stained for 3-8 min in a solution consisting of: 0.1 M acetic acid, 90 ml; 0.1 M sodium acetate, 10 ml; and 1% toluidine blue 0, 2.5 ml. For hematoxylin-Darrow red, myelin was stained for 2-6 hr in a self-differentiating solution consisting of: 0.15% Li₂,CO₃ 95 ml; 10% hematoxylin in 95% ethanol, 5 ml; and NaIO₃ 25 mg. After a thorough washing, Nissl material was stained for 20 min or less in a solution consisting of: 0.1 M acetic acid, 90 ml; 0.1 M sodium acetate, 10 ml; Darrow red, 25 mg. This mixture was first boiled, cooled to room temperature and filtered. In both methods, washing, dehydration, clearing, and mounting completed the process. In the brazilin-toluidine blue technic, myelin sheaths were stained reddish purple; neuronal nuclei light blue with dark granules of chromatin; nucleoli dark blue; and cytoplasm blue with dark blue Nissl granules. In the hematoxylin-Darrow red procedure, myelin sheaths were blue-black; nuclei light red with dark granules of chromatin; nucleoli almost black; and cytoplasm red with bright red Nissl granules.     

Temporally-Patterned Magnetic Fields Induce Complete Fragmentation in Planaria

A tandem sequence composed of weak temporally-patterned magnetic fields was discovered that produced 100% dissolution of planarian in their home environment. After five consecutive days of 6.5 hr exposure to a frequency-modulated magnetic field (0.1 to 2 µT), immediately followed by an additional 6.5 hr exposure on the fifth day, to another complex field (0.5 to 5 µT) with exponentially increasing spectral power 100% of planarian dissolved within 24 hr. Reversal of the sequence of the fields or presentation of only one pattern for the same duration did not produce this effect. Direct video evidence showed expansion (by visual estimation ∼twice normal volume) of the planarian following the first field pattern followed by size reduction (estimated ∼1/2 of normal volume) and death upon activation of the second pattern. The contortions displayed by the planarian during the last field exposure suggest effects on contractile proteins and alterations in the cell membrane’s permeability to water.     

Divergence and evolution of homologous regions of Bombyx mori nuclear polyhedrosis virus.

Homologous regions (hrs) (hr1,hr2-left,hr2-right,hr3,hr4-left,hr 4-right, and hr5) similar to those found in the Autographa californica nuclear polyhedrosis virus (AcNPV) genome were found in the Bombyx mori NPV (BmNPV) genome. The BmNPV hrs contained two to eight repeats of a homologous nucleotide sequence which were on average about 75 bp long. All of these homologous sequence repeats contained a 26-bp-long palindrome motif with an EcoRI or EcoRI-like site at its core. The consensus sequence of the BmNPV hrs showed 95% conservation with respect to those found in AcNPV. Nucleotide sequence analysis indicated that hr2-left and hr2-right of BmNPV evolved from an ancestor similar to hr2 of AcNPV by inversion, cleavage, and ligation. The polarities of the BmNPV and AcNPV hrs were conserved except for that of hr4-left. Within hr4-right of BmNPV, four repeats of a previously underscribed palindrome motif were found. Bmhr5D, a BmNPV mutant which lacked hr5, replicated at a rate similar to that of wild-type BmNPV in BmN cells and silkworm larvae, indicating that hr5 was not essential for viral replication. After ten passages of Bmhr5D in BmN cells, no detectable changes in its genome were observed by restriction endonuclease analysis. The evolution and divergence of the BmNPV genome are also discussed.