The New Domestic Cresyl Echt Violet

Specimens of both vertebrate and invertebrate nerve-containing tissues were fixed 2-3 days in Bouin's fluid, soaked 2 days in alcohol containing 2% strong ammonia water, dehydrated and embedded in paraffin. The sections were mounted with gelatin adhesive according to Masson's procedure, dewaxed, passed through graded alcohols to water, then back to 2% ammoniated 80% alcohol for 12-24 hours. The slides were rinsed 3-5 seconds in distilled water, impregnated about one and a half hours in 40% AgNO₃ at increasing temperature up to 45°C. The slides were flooded with 62.5% formalin and this solution allowed to remain 3-5 minutes; they were then blotted with filter paper. A second impregnation in ammoniated silver carbonate, controlled under the microscope, was followed by a 10-minute treatment with 10% aqueous acetic acid, toning with gold chloride, then thiosulfate and finally washing. Counterstaining with ponceau red or acid fuchsin, eventually followed by aniline blue or fast green, dehydration and covering, completed the process.     

A Cresyl Fast Violet Stain for Bacteria and Fungi in Tissue

The cresyl fast violet staining method was modified to eliminate differentiation. Paraffin sections from tissues fixed in Zenker-formol were stained in a 1% aqueous solution of cresyl fast violet (Chroma), adjusted to pH 3.7 with acetic acid, washed in running tap water, dehydrated and covered. Because basophilia increases with time of fixation or storage in formalin or Kaiserling's fluid, dilution of the dye solution to 0.5-0.1% is recommended for such material. Bacteria, nuclei, Nissl substance, and lipofuscin were colored dark blue; fungi, blue to purple; and cytoplasm and muscle fibers, light blue. Collagen and reticulum fibers were only faintly stained. Thus, microorganisms were easily visible against the lightly colored background. In formalin-fixed material, bile pigment was colored olive green. Because this method does not require differentiation, it gave uniform results even in the hands of different users. Little or no fading was observed in sections stored for more than 2 yr.     

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.     

Brilliant Cresyl Blue as A Stain for Chromosome Smear Preparations

Brilliant cresyl blue is substituted for carmine in the acetocarmine technic. A mixture of one part of 1% toluidine blue and three parts 0.75% brilliant cresyl blue dissolved in 45% acetic acid gives good results. Propionic acid may be used instead of acetic acid for more rapid penetration.     

Demonstration of Lipofuscin and Nissl Bodies in Crystal Violet Stained Sections Using a Fluorescence Technique or Pyronin Y Stain

This paper presents two simple, reliable methods for identification of lipofuscin and Nissl bodies in the same section. One method shows that lipofuscin stained with crystal violet retains its ability to fluoresce and can be observed under the fluorescence microscope after the stain has faded. Fading is accompanied by a gradual increase in the intensity of the fluorescence and is complete in about 5 min. Exciting illumination from this part of the spectrum also substantially fades staining of other autofluorescing tissue elements, such as lipids. Nonfluorescing structures, such as Nissl bodies, remain stained. By changing from transillumination with tungsten light to epifluorescent illumination and vice versa, both types of structures—Nissl bodies and lipofuscin—can be identified in the same section. The second technique uses pyronin Y for staining Nissl bodies in preparations previously stained with crystal violet. Nissl bodies are stained pink but lipofuscin remains violet. Lipofuscin in these sections also remains autofluorescent after the crystal violet stain has faded under violet or near-UV light.     

Mouse Model of Intraluminal MCAO: Cerebral Infarct Evaluation by Cresyl Violet Staining

Stroke is the third cause of mortality and the leading cause of disability in the World. Ischemic stroke accounts for approximately 80% of all strokes. However, the thrombolytic tissue plasminogen activator (tPA) is the only treatment of acute ischemic stroke that exists. This led researchers to develop several ischemic stroke models in a variety of species. Two major types of rodent models have been developed: models of global cerebral ischemia or focal cerebral ischemia. To mimic ischemic stroke in patients, in whom approximately 80% thrombotic or embolic strokes occur in the territory of the middle cerebral artery (MCA), the intraluminal middle cerebral artery occlusion (MCAO) model is quite relevant for stroke studies. This model was first developed in rats by Koizumi et al. in 1986 ¹. Because of the ease of genetic manipulation in mice, these models have also been developed in this species ^2-3.Herein, we present the transient MCA occlusion procedure in C57/Bl6 mice. Previous studies have reported that physical properties of the occluder such as tip diameter, length, shape, and flexibility are critical for the reproducibility of the infarct volume ⁴. Herein, a commercial silicon coated monofilaments (Doccol Corporation) have been used. Another great advantage is that this monofilament reduces the risk to induce subarachnoid hemorrhages. Using the Zeiss stereo-microscope Stemi 2000, the silicon coated monofilament was introduced into the internal carotid artery (ICA) via a cut in the external carotid artery (ECA) until the monofilament occludes the base of the MCA. Blood flow was restored 1 hour later by removal of the monofilament to mimic the restoration of blood flow after lysis of a thromboembolic clot in humans. The extent of cerebral infarct may be evaluated first by a neurologic score and by the measurement of the infarct volume. Ischemic mice were thus analyzed for their neurologic score at different post-reperfusion times. To evaluate the infarct volume, staining with 2,3,5-triphenyltetrazolium chloride (TTC) was usually performed. Herein, we used cresyl violet staining since it offers the opportunity to test many critical markers by immunohistochemistry. In this video, we report the MCAO procedure; neurological scores and the evaluation of the infarct volume by cresyl violet staining.     

A New Method of Differentiating Gentian Violet when used as a Somatic Chromosome Stain

The addition of 0.5% of picric acid crystals to the dehydrating alcohols makes possible a much better differentiation of gentian violet than has previously been obtainable. The final differentiation occurs in clove oil. The method was especially designed for use on the root tips of plants normally growing in arid regions.     

Crystal Violet as A Nuclear Stain for Gaffkya Tetragena and Other Bacteria

A method is given to stain the nucleus of Gaffkya tetragena and other bacteria. Only water solutions of crystal violet, mercuric chloride, and nigrosin are used. While the application of heat (50°C. for 20 seconds) is not absolutely necessary, it facilitates the decolorizing process. Some of the nuclei of cells from old cultures were found in various stages of division. The nucleus of a mature cell divides, and each daughter nucleus undergoes a second division usually in a plane at right angles to that of the first division. The nuclear division indicates cell development in units of four cells each. The method was found reliable for demonstrating the nucleus at various periods and stages of growth.     

A Modification of the Cresyl Violet Technic for Staining Nerve Cells

Kill root tips in 1 part glacial acetic acid to 3 parba RB Solute alcohol for 12 or more hours. Remove from king fluid a d place for 5 to 10 minutes in a solution consisting of 1 part 95% alcohol to 1 part concentrated HC1. Transfer to Carnoy's fluid for 5 minutes or longer. Cut a small piece (0.5 mm. or less) off the tip of the root Press directly on the piece of root with a small fiat scalpel; the cells will now separate and float free in the stain. Place cover slip over the drop of stain and apply gentle pressure. Heat carefully by paseing the slide 3 or 4 times thru the flame of an alcohol lamp. Seal with heated mixture of 1 part Parowax to 1 part gum mastie. Make permanent by the McClintock permanent method. and place on a clean slide in a small drop of iron-ace-sinin.     

The Site of Action of the Crystal Violet Nuclear Stain

Enzymatic treatment of bacterial cells prior to staining revealed that the crystal violet nuclear stain reacts with protein components of the nucleus as contrasted to the desoxyribonucleic acid specificity of some nuclear stains.     

Identification of Functional Tumor Vessels by Resorcin-Crystal Violet Stain Infusion

A resorcin-crystal violet solution of low viscosity injected into the circulatory plexus supplying a tumor is used to identify and characterize functional tumor vessels. Unstained sections of tumor tissue demonstrate heavily stained vascular endothelium with no leakage of stain to extravascular tissue for intact vessels, and little or no background staining. The method is simple to apply for tumor vessel morphology and morphometry.     

A Comparison of the Crystal Violet Nuclear Stain with Other Technics

The crystal violet nuclear stain was compared with the acid Giemsa and thionin-SO₂ stains, and it was found that the three technics revealed nuclear structures which were identical. Various methods of fixation and hydrolysis were tested and it was concluded that the crystal violet gave more uniform results if used without fixation or hydrolysis. The effects of these treatments on the other technics are discussed.     

Hematoxylin as a Pituitary Stain

The accurate picture of the acidophil granules of the anterior pituitary which is provided by iron hematoxylin can be combined with the differential staining of the basophils by either the periodic acid-Schiff (PAS) or combined aldehyde-fuchsin-PAS procedures. To accomplish this the two stages of the iron hematoxylin technique are separated so that mordanting in iron alum precedes and application of hematoxylin follows the basophil procedures.     

Isohematein as a Biological Stain

The possible use of isohematein as a biological stain is considered. Certain characteristics of the dye are discussed in relation to staining technic. A preliminary series of experiments is described. The stomach of the frog, skeletal muscle of the frog, and spinal cord of the cat were used as representative tissues. The dye has greater tinctorial power than hematoxylin (hematein) but it is not so selective for nuclei. The results at hand indicate that the dye may have some value as a differential stain for nerve cell bodies. Fibrillae in smooth muscle cells and cross striatums in skeletal muscle were also brought out.     

Gomori's Hematoxylin as a cHromosome Stain

The chromic hematoxylin of Gomori (1941) can be used as an excellent chromosome stain after hydrolysis of the tissue in warm 1-N hydrochloric acid. The hydrolysis must be accurately timed for different material as in the case of the Feulgen reaction. The staining of sections can be performed at room temperature and requires about 15 minutes. For pieces of tissue and whole preparations, it is recommended to stain at 60°C. for 40 minutes. Sections stained at room temperature can be differentiated in 1% hydrochloric acid alcohol for one minute and can be counterstained with phloxine according to Gomori's formula. Whole preparations or sections stained at 60°C. must be differentiated in 45% acetic acid for half an hour or more. Tissue pieces may, after staining, be squashed and examined in the acetic acid, but the preparations can also be made permanent. The blue-black stain is very selective and has the advantage of giving high contrast, and it is nonfading, and insoluble in water and other common reagents. It proved definitely superior to other chromosome stains for difficult material such as planarians, rabbit blastocysts, and cleavage stages of sea urchins. Though both the procedure and the result of this method show some similarity to the Feulgen reaction nothing can be said with certainty about its chemical basis.     

Assessment of Demyelination in Glycol Methacrylate Sections: A New Protocol for Cresyl Fast Violet Staining

A simple staining technique for nervous tissue is described. Tissue perfused with glutaraldehyde and formaldehyde and postfixed with osmium tetroxide is embedded in glycol methacrylate. One-micrometer sections are stained with 0.05% cresyl fast violet aqueous solution at 60 C for 5 min, washed with tap water and air dried. With this method the details of all nervous tissue elements are clearly demonstrated. The technique is particularly useful for assessing demyelination because the staining of axoplasm allows demyelinated axons to be well visualized.