The Germicidal Effect of Staining Solutions

Gentian violet, crystal violet and carbol fuchsin applied to cover slip preparations for one minute will destroy the majority of non-spore-forming bacteria and yeasts, tho they can not be relied upon to do this consistently and in all cases.

The Gram staining procedure is more effective and non-spore-formers were never found to survive this process.

Methylene blue stains exert very little if any germicidal power and most organisms survived them readily. India ink was totally ineffective.

Several species of yeasts and yeast-like molds were killed in every instance by the Gram stain, gentian violet, crystal violet and carbol fuchsin, but survived both Loeffler's methylene blue and a plain aqueous solution of methylene blue.     

Contribution to the Staining of Neuroglia

The chemistry of Weigert's glia staining method is critically discussed. An investigation of the Heidelberger Victoria blue staining method has shown that Victoria blue may be replaced by other phenylmethane dyes as methyl violet, ethyl violet, and crystal violet. It was found that the exposure of the stained section to sunlight is an oxidation process. Artificial ultra violet rays or chemical oxidation agents give the same effect. Frozen sections fixed in formalin or alcohol may be stained in a concentrated aqueous solution of any of the above mentioned phenylmethane dyes, dried, and exposed to ultra violet rays for 30 minutes, then treated with 1/10 N. iodine solution, differentiated in xylol anilin and cleared in xylol. The glia cell body as well as the fibrils are clearly differentiated from the nervous elements and connective tissue.     

The Germicidal Effect of Staining Solutions

Gentian violet, crystal violet and carbol fuchsin applied to cover slip preparations for one minute will destroy the majority of non-spore-forming bacteria and yeasts, tho they can not be relied upon to do this consistently and in all cases.

The Gram staining procedure is more effective and non-spore-formers were never found to survive this process.

Methylene blue stains exert very little if any germicidal power and most organisms survived them readily. India ink was totally ineffective.

Several species of yeasts and yeast-like molds were killed in every instance by the Gram stain, gentian violet, crystal violet and carbol fuchsin, but survived both Loeffler's methylene blue and a plain aqueous solution of methylene blue.     

Chemical Structures and Staining Mechanisms of Weigert'S Resorcin-Fuchsin and Related Elastic Fiber Stains

Chemical properties of Weigert's resorcin-fuchsin, orcinol-new fuchsia, Sheridan's crystal violet and their resorcinol-free analogues were investigated using reverse-phase and gel filtration chromatography, electrophoresis, and visible light spectroscopy. Their staining properties were also studied. It was concluded that 1) the staining components of Weigert's resorcin-fuchsin, orcinol-new fuchsin and their resorcinol-free analogues are all indamine oligomers, 2) resorcinol is required for the production of Sheridan's crystal violet, the staining components of which consist of crystal violet substituted by varying numbers of resorcinyl substituents, 3) the staining components of all preparations are canonic (i.e., basic) dyes, 4) iron is present in staining solutions as the tetrachlorofemte anion (FeCI₄^-) and not as Fe⁺⁺⁺ or as a dye-chelate, and 5) since even the smallest Weigert's resorcin-fuchsin, orcinol-new fuchsin or Sheridan's crystal violet component has a conjugated bond number of 32, die observed staining of elastic fibers is only as expected.     

A Differential Stain Favorable to the Diagnosis of Neisserian Infection

A differential Gram stain has been evolved which incorporates the combined features of the original Gram and Pappenheim methods. National Aniline crystal violet and new methyl green and pyronin are the dyes preferred. The iodine mixture of Kopeloff and Beerman is a satisfactory mordant and Merck's pure technical acetone is an excellent differentiating agent. A system is established by means of the dyes and reagents which form a physicochemical equilibrium, provided pure dyes are employed, and the technic is carried out with precision. Gram-positive bacteria are coated by means of buffered crystal violet solution and the iodine-sodium hydroxide solution precipitates the crystal violet from other substances. The dye-iodine precipitate is readily dissolved by pure acetone. Iodine green, a pure derivative of crystal violet has the effect of noninterference in the technic and has selective action upon nuclear substance. Pyronin has affinity for Neisserian organisms primarily and acts as an inert substance upon most other proteins, (except cytoplasm of eosinophils, lymphocytes, plasma cells, and endothelial cells). The following technic is recommended:

Stain air-dry films 3 to 5 minutes in a 1% solution of crystal violet in 10 parts of Clark and Lubs' phosphate buffer of pH 6.6 to 7.0 and 90 parts water. Decant and flush with 2% iodine in N/10 NaOH. Decant and decolorize in acetone 10 seconds or less. Air dry and counterstain 1 1/2 to 2 minutes with methyl-green-pyronin (2 parts 2% aqueous methyl green National with one part 0.3% aqueous pyronin yellowish). Wash and air dry. Oil of Bergamot is preferable to xylene as a clearing agent. Best results are obtained if each slide is handled separately as for staining blood films.     

The Gram Staining Mechanism of Cat Tongue Keratin. II. The Role of Potassium Iodide-Iodine Solution

The aniline-xylene decolorizer of the Gram-Weigert staining procedure failed to remove crystal violet dye from stained sections of cat tongue without prior treatment of the sections with potassium iodide-iodine solution. The potassium iodide of the iodide-iodine solution was found to release the major part of the crystal violet dye bound by the tongue sections. Iodine appeared also to play a role in dye release, but only to a slight degree. The amount of Gram-positive staining was increased both by alkaline treatment of the tissue prior to staining, and by increasing the pH of the iodide-iodine solution.     

Gram staining and lectin binding properties of Myxosporea and Sporozoea

The staining method developed by Christian Gram was introduced as a simple and highly selective tool for demonstrating myxosporean and coccidian sporogonic stages. When using standard blood staining procedures for those enigmatic parasites it is sometimes difficult to distinguish them from fish host tissue. They clearly exhibit a partial Gram-positive reaction in histological sections, but staining is variable in air dried fish organ imprints. To visualize the Gram-negative background of different host tissue components in histological sections, the conventional safranin counterstain of the Gram protocol may be modified as follows: after application of 2% crystal violet (basic violet 3) and Lugol's solution, sections are stained with 0.1% nuclear fast red-5% aluminum sulfate and 0.35% aniline blue (acid blue 22) dissolved in saturated aqueous picric acid. Replacement of the Gram-specific dye crystal violet with 2% malachite green gave similar results in organ imprints containing myxospores or coccidia, but only in sections containing myxosporea. Staining for 1 min with an aqueous solution of 0.5% malachite green and followed 1 min washing was sufficient for rapidly demonstrating the parasite spores in organ imprints of both myxosores and oocysts. With regard to the role of acid mucopolysaccharides and other carbohydrates in the Gram reaction of spores, alcian blue 8GX staining was compared to the binding of FITC-labeled WGA, GS I and GS II. Each lectin was applied at 20 μl/ml PBS, HEPES for 1 hr. Whereas WGA yielded a nonspecific pattern like the alcian blue staining, GS II resulted in a pattern similar to the Gram staining results. This binding was weak in untreated specimens, but was significantly enhanced when digested first within trypsin overnight in a humid chamber at 37 °C. The binding of GS II to both myxosporidian and coccidian spores suggests that they are both composed of polymers containing N-acetyl-D-glucosamine residues. Furthermore, the results suggest that this hexosamine plays a key role in the Gram reaction.     

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.     

Chemical structures and staining mechanisms of Weigert's resorcin-fuchsin and related elastic fiber stains

Chemical properties of Weigert's resorcin-fuchsin, orcinol-new fuchsin, Sheridan's crystal violet and their resorcinol-free analogues were investigated using reverse-phase and gel filtration chromatography, electrophoresis, and visible light spectroscopy. Their staining properties were also studied. It was concluded that 1) the staining components of Weigert's resorcin-fuchsin, orcinol-new fuchsin and their resorcinol-free analogues are all indamine oligomers, 2) resorcinol is required for the production of Sheridan's crystal violet, the staining components of which consist of crystal violet substituted by varying numbers of resorcinyl substituents, 3) the staining components of all preparations are cationic (i.e., basic) dyes, 4) iron is present in staining solutions as the tetrachloroferrate anion (FeCl4-) and not as Fe or as a dye-chelate, and 5) since even the smallest Weigert's resorcin-fuchsin, orcinol-new fuchsin or Sheridan's crystal violet component has a conjugated bond number of 32, the observed staining of elastic fibers is only as expected.     

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.     

Studies in Gram Staining

Gram-negative bacteria stained with crystal violet are decolorized by 95% alcohol within 2 min, whereas Gram-positive bacteria require at least 3 min treatment. Aqueous solutions of safranin, neutral red, and fuchsin replace crystal violet from stained Gram-positive bacteria more quickly than alcohol alone, and alcoholic solutions of these counterstains are in most cases still more effective. Treatment of crystal viokt-stained organisms with alcoholic safranin (0.25%) for 15 scc will distinguish Gram-positive bacteria (viokt) from Gram-negative bacteria (pink).

Alcohol containing very low concentrations of iodine generally decolorizes crystal violet-stained Gram-positive bacteria more quickly than alcohol alone. Increasing concentrations of iodine in alcohol reduce the rate of decolorization of stained bacteria, but stained Gram-negative bacteria are still readily dccolorized. The addition of 0.1% iodine to alcohol increases the rate of extraction of crystal violet by alcohol from Gram-negative organisms, but delays extraction of dye from Gram-positive organisms, and this applies when counterstain is also present. A two-solution modification of Gram staining is described in which crystal violet-stained bacteria are treated with an alcoholic solution of safranin, fuchsin, and iodine.     

Staining of depolymerised DNA in mammalian tissues with methyl violet 6B and crystal violet

The paper contains an account of DNA staining with basic dyes; methyl violet 6B and crystal violet in mammalian tissue sections after RNA extraction with cold concentrated phosphoric acid. The study shows that the best staining is obtained at pHs 2.5 and 3.5. Dehydration of stained nuclei is perfect when a mixture of absolute ethanol and n-butanol is used followed by treatment of sections in isoamyl or amyl alcohol. The in situ absorption data of nuclei stained with aqueous solution of methyl violet 6B as well as with crystal violet are also presented. Possible mechanism of staining as well as an explanation for dye-leaching when sections are dehydrated through ethanol are discussed.     

Iodine131 Uptake in the Gram Staining Technic

The Hucker modification of the Gram staining technic, in which NaI¹³¹ was incorporated with the Gram's iodine solution, was performed as the basic procedure. The Gram positive test-bacteria were Staphylococcus aureus and Bacillus megaterium; the Gram negative were Escherichia coli and Pseudomonas aeruginosa. The uptake of I¹³¹ was measured after the addition of the Gram's iodine solution (NaI¹³¹) to the test-bacteria dried on a glass slide, after the decolorization process and after counterstaining. Radiation was measured by placing the slide under a GM-TGC-2 end-window counting tube after each procedure. The Gram positive test-bacteria retained approximately twice as much I¹³¹ after decolorization and counterstaining as did the Gram negative bacteria. In this, the basic technic, the uptake of I¹³¹ by the test bacteria appeared to be directly related to the crystal violet concentration in the primary staining solution. The uptake of I¹³¹ was not significantly altered by the time of application of the Hucker crystal violet staining solution (15-180 sec), or of the Gram's iodine (NaI¹³¹) solution (30-120 sec) or by the duration of the alcohol decolorization process (30-120 sec).

Variations (herein referred to as variations 2 and 3) of the basic procedure were carried out in which the primary staining solution contained crystal violet combined with NaI¹³¹ or Gram's iodine solution (NaI¹³¹). In variations 4 and 5 the effect of the order of application of the various staining reagents was investigated. In these variations (2-5) all test-bacteria were stained Gram negative. The initial uptake of I¹³¹ was decreased, though in variations 4 and 5 the percent retention of I¹³¹ was increased. In the staining of bacterial spores by different methods (variation 6), it was noted that the initial uptake and percent retention of I¹³¹ was greater than with the vegetative forms. When ovalbumin was stained by the Hucker technic and variations thereof, it was noted that the initial uptake of I¹³¹ was directly related to the protein (ovalbumin) concentration up to an ovalbumin concentration of 1%.     

Studies in gram staining.

Gram-negative bacteria stained with crystal violet are decolorized by 95% alcohol within 2 min, whereas Gram-positive bacteria require at least 3 min treatment. Aqueous solutions of safranin, neutral red, and fuschsin replace crystal violet from stained Gram-positive bacteria more quickly than alcohol alone, and alcoholic solutions of these counterstains are in most cases still more effective. Treatment of crystal violet-stained organisms with alcoholic safranin (0.25%) for 15 sec will distinguish Gram-positive bacteria (violet) from Gram-negative bacteria (pink). Alcohol containing very low concentrations of iodine generally decolorizes crystal violet-stained Gram-positive bacteria more quickly than alcohol alone. Increasing concentrations of iodine in alcohol reduce the rate of decolorization of stained bacteria, but stained Gram-negative bacteria are still readily decolorized. The addition of 0.1% iodine to alcohol increases the rate of extraction of crystal violet by alcohol from Gram-negative organisms, but delays extraction of dye from Gram-positive organisms, and this applies when counterstain is also present. A two-solution modification of Gram staining is described in which crystal violet-stained bacteria are treated with an alcoholic solution of safranin, fuchsin, and iodine.     

In vitro cytotoxicity of Acanthamoeba spp. isolated from contact lens containers in Korea by crystal violet staining and LDH release assay

In order to observe the cytotoxicity of Acanthamoeba spp., which were isolated from contact lens containers as ethiological agents for the probable amoebic keratitis in Korea, the crystal violet staining method and LDH release assay were carried out. In the crystal violet staining method, among eight contact lens container isolates, isolate 3 (Acanthamoeba KA/LS5) showed 83.6% and 81.8% of cytotoxicity, and isolate 7 (Acanthamoeba KA/LS37) showed 28.2% and 25.1% of cytotoxicity, in 1 mg/ml and 0.5 mg/ml lysate treatments, respectively. Acanthamoeba culbertsoni and A. healyi showed 84.0% and 82.8% of cytotoxicity. Similar results were observed in A. castellanii and A. hatchetti which showed 83.6% and 75.5% of cytotoxicity. Acanthamoeba royreba and A. polyphaga showed 9.0% and 1.7% of cytotoxicity. In the LDH release assay, isolate 3 (20.4%) showed higher cytotoxicity than other isolates in 1 mg/ml lysate treatment. The results provide that at least isolate 3 has the cytotoxic effect against CHO cells and seems to be the pathogenic strain.     

Rapid methods to assess sanitizing efficacy of benzalkonium chloride to Listeria monocytogenes biofilms

Different methods were used to investigate biofilm growth including crystal violet staining, ATP bioluminescence and total viable count. Seven strains of Listeria monocytogenes and 8 of their derivative strains were screened for their capacity to form biofilms. Both adaptation to benzalkonium chloride (BC) and curing of plasmids did not significantly affect biofilm-forming ability. The strains of L. monocytogenes belonging to serotype 1 formed biofilms significantly better as compared to serotype 4 (P=0.0003). To estimate the efficacy of BC for biofilm elimination the best and the poorest biofilm-formers were used (C719 and LJH 381). It was observed that, L. monocytogenes strain C719 in biofilms is at least 1000 times more resistant to BC than in planktonic form. Cells present in biofilms were shown to recover and grow after BC treatment thus providing a source of recontamination. It was shown that ATP bioluminescence provides good correlation with bacterial counts of L. monocytogenes in biofilms. Staining with crystal violet, on the contrary, did not correlate with bacterial growth in biofilms in the presence of high concentrations of BC but provided information on the concentration of bacterial cells, both live and dead, attached to the surface. ATP bioluminescence was found to be a reliable method for rapid estimation of the efficacy of sanitizers for biofilm disinfection. Crystal violet staining, on the other hand, was shown to be a suitable method to monitor removal of biofilms. Our investigation showed that for Listeria biofilms concentrations of BC higher then 10 mg/ml should be applied for at least 30 min to kill almost all the live cells in biofilms. However, this concentration was still not enough to remove biofilms from the surface of plastic.     

Basic Two-Dye Stains for Epoxy-Embedded 0.3-1 μ Sections

Dyes used in the 3 methods recommended are: I, thionin and acridine orange (T-AO); II, Janus green and Darrow red (JG-DR); III, methyl green and methyl violet (MG-MV). The first 2 methods were two-solution stains, applied in sequence; the third, required only one solution since methyl violet is present in commercial methyl green. Staining solution and timing was as follows: Method I. 0.1% thionin in a 45% ethanolic solution of 0.01 N NaOH, 5 min at 70 C; rinsing in water and followed by 1 min in a 1% aqueous solution of acridine orange made up in 0.02 N NaOH, also at 70 C, then washed, and dried on slides. Method II. 0.5% Janus green in aqueous 0.05 N NaOH, 5 min at 70 C; rinsing in water then into 0.5% Darrow red in 0.05 N NaOH (aq.), 2 min at 70 C., washing, and drying on slides. Method III. 1% methyl green (commercial, unpurified) in 1% aqueous borax for 15-20 min at 20-25 C, washing and attaching to slides. All staining was performed by floating the sections on the staining solutions, all drying at 70 C, and mounting in a resinous medium. T-AO gave blue to violet cytoplasmic structures, darker nuclei which contrasted strongly with yellow connective tissue and the secretion of goblet cells. JG-DR resembled a hematoxylineosin stain, but by shortening the staining time in DR to 0.5-1 min, collagenous and elastic tissue retained more of the green dye. MG-MV gave dark green nuclei in light green cytoplasm, with collagenous and elastic tissues in blue to violet. As with most methods for staining ultrathin sections, thicknesses of less than 1 μ required longer staining times.     

Evaluation of different staining procedures for the quantification of fibroblasts cultured in 96-well plates.

Comparison of published methods for the quantification of adherent cell numbers by the measurement of absorbance of bound stain indicates a wide variation in their sensitivity. This study aimed at comparing the sensitivities of five different staining procedures (Coomassie brilliant blue G in perchloric acid, Coomassie brilliant blue G in phosphoric acid, methylene blue, crystal violet, and toluidine blue) applied to three separate types of cultured fibroblasts (3T3 cells, Vero cells, and human gingival fibroblasts) at concentrations from 0.125 x 10(4) to 10 x 10(4) per well in 96-well microplates. Absorbance values of Coomassie blue-stained cells were measured in situ. Those of the remaining cells were measured after solubilization of the dye with 1% sodium dodecyl sulfate. All absorbance values were measured using an Elisa reader at 620 or 570 nm for crystal violet. The relationship between cell number and absorbance over the entire cell concentration range was best fitted with quadratic regression analysis, in contrast with the linear relationship described elsewhere. The order of sensitivity of the staining procedures was the same for each cell type: Coomassie blue in perchloric acid less than Coomassie blue in phosphoric acid less than methylene blue less than crystal violet less than toluidine blue. With the latter two stains absorbance values began to plateau at approximately 8 x 10(4) cells per well. However, staining with Coomassie blue in perchloric acid and methylene blue resulted in an almost linear relationship between cell number and absorbance over the entire concentration range tested.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of hypoxanthine and guanine in regulation of Salmonella typhimurium pur gene expression.

Crystal violet (hexamethyl-para-rosaniline chloride) interacts with aqueous KI-I2 during the Gram stain via a simple metathetical anion exchange to produce a chemical precipitate. There is an apparent 1:1 stoichiometry between anion (I-) and cation (hexamethyl-para-rosaniline+) during the reaction and, since the small chloride anion is replaced by the bulkier iodide, the complex formed becomes insoluble in water. It is this same precipitate which forms in the cellular substance of bacteria (both gram-positive and gram-negative types) and which initiates the Gram reaction. Potassium trichloro(eta 2-ethylene)-platinum(II), as an electronopaque marker for electron microscopy, was chemically synthesized, and it produced an anion in aqueous solution which was compatible with crystal violet for the Gram stain. It interacted with crystal violet in a similar manner as iodide to produce an insoluble complex which was chemically and physically analogous to the dye-iodide precipitate. This platinum anion therefore allows the Gram staining mechanism to be followed by electron microscopy.     

Crystal violet as an i-motif structure probe for reversible and label-free pH-driven electrochemical switch

A simple pH-induced electrochemical switch based on an i-motif structure is developed by using crystal violet as a selective electrochemical probe for the i-motif structure. Thiol-modified cytosine-rich single-strand oligonucleotide (C-rich ssDNA) can be self-assembled on the gold electrode surface via gold–sulfur interaction. Crystal violet is employed as an electrochemical probe for the i-motif structure because of its capability of binding with the i-motif structure through an end-stacking mode. In acidic aqueous solution, crystal violet may approach the electrode surface owing to the formation of the i-motif structure, resulting in an obvious signal, so-called “ON” state. Whereas in neutral or basic aqueous solution, the i-motif structure unfolds to dissociative single strand, which causes crystal violet to leave from the electrode surface, and a weak signal is obtained, so-called “OFF” state. In addition, in the range of pH 4.6–7.3, the increase in current has a good linear relationship (R = 0.989) with pH value in the testing solutions. This pH-driven electrochemical switch has the advantages of simplicity, sensitivity, high selectivity, and good reversibility. Furthermore, it provides a possible platform for pH measurement.