Occurrence and ecotoxicological risk assessment of pharmacologically active dyes in the environmental water of Poland

The interest in the fate of pharmacologically active substances (PASs) in the aquatic environment continually increases. However, little is known about pharmacologically active dyes (PADs) as contaminants of water bodies. PADs are used in medicine, but due to their colouring properties are also applied in the textile, cosmetic and food industries. Their large-scale production and widespread applications have caused these dyes permeate to the aquatic environment. The pharmacological activity and toxicological properties of some of these dyes, caused their occurrence in water should be monitored. Up to now, PADs such as crystal violet, malachite green, methylene blue, rhodamine B, have been determined in the water of Greater China and Iran. However, there is no data on whether PADs pose an environmental problem for water bodies in Poland. Thus, different water samples were collected and analysed by the UPLC-MS/MS method allowing the determination of 20 PADs. The tests showed that dyes such as crystal violet, methyl violet 2 B and rhodamine B were found in 2 out of 36 water reservoirs (0.0122-0.0594 μgL^-1). The environmental risk assessment indicated that determined dyes for most model organisms did not pose a risk. Only the presence of methyl violet 2 B (0.0571 μgL^-1) was related to a low risk for rohu carp, and crystal violet (0.0122-0.0209 μgL^-1) showed a moderate risk for medaka fish. The occurrence of PADs was tested on a larger scale in the water samples collected from different water reservoirs in Poland. Based on obtained results, 96.3% of water samples collected from different water bodies (94.5%) were free from dyes. Thus, it could be stated that generally environmental water of Poland is contaminated with PADs at a low level. On the other hand, the presence of dyes in two samples indicates that PADs permeate the water environment, and their occurrence should be monitored.

Exposure of Lemna minor L. to gentian violet or Congo red is associated with changes in the biosynthesis pathway of biogenic amines

In the literature, there is a lack of data on the effect of gentian violet (GV) and congo red (CR) dyes on the biosynthesis pathway of biogenic amines (BAs) in Lemna minor L. (common duckweed). This plant species is an important link in the food chain. Both dyes inhibited growth, biomass yield and the biosynthesis of chlorophyll a in common duckweed. The predicted toxic units demonstrated that GV had a more toxic effect on the growth rate and biomass yield of common duckweed than CR. Decarboxylase activity in the biosynthesis of BAs in common duckweed is also a useful indicator for evaluating the toxicity of both dyes. Gentian violet also exerted more phytotoxic effects on the analyzed biochemical features of common duckweed because it changed the putrescine (Put) biosynthesis pathway, increased tyramine content 1.6 fold, inhibited the activity of S-adenosylmethionine decarboxylase by 40% and the activity of ornithine decarboxylase (ODC) by 80%. Tyrosine decarboxylase (TDC) was most active in plants exposed to the highest concentration of GV. Similarly to control plants, in common duckweed exposed to CR, Put was synthesized from ornithine; however, spermidine content was 86% higher, Put content was 51% lower, and ODC activity was 86% lower.

Exposure to Crystal Violet, Its Toxic, Genotoxic and Carcinogenic Effects on Environment and Its Degradation and Detoxification for Environmental Safety

Crystal Violet (CV), a triphenylmethane dye, has been extensively used in human and veterinary medicine as a biological stain, as a textile dye in textile processing industries and also used to provide a deep violet color to paints and printing ink. CV is also used as a mutagenic and bacteriostatic agent in medical solutions and antimicrobial agent to prevent the fungal growth in poultry feed. Inspite of its many uses, CV has been reported as a recalcitrant dye molecule that persists in environment for a long period and pose toxic effects in environment. It acts as a mitotic poison, potent carcinogen and a potent clastogene promoting tumor growth in some species of fish. Thus, CV is regarded as a biohazard substance. Although, there are several physico-chemical methods such as adsorption, coagulation and ion-pair extraction reported for the removal of CV, but these methods are insufficient for the complete removal of CV from industrial wastewaters and also produce large quantity of sludge containing secondary pollutants. However, biological methods are regarded as cost-effective and eco-friendly for the treatment of industrial wastewaters, but these methods also have certain limitations. Therefore, there is an urgent need to develop such eco-friendly and cost-effective biological treatment methods, which can effectively remove the dye from industrial wastewaters for the safety of environment, as well as human and animal health.

Decolorization of Crystal Violet by ultrasound/heterogeneous Fenton process

Activated-carbon-supported iron oxides were prepared and used as a catalyst in an integrated ultrasound/heterogeneous Fenton process for the decolorization of Crystal Violet. A synergistic effect was observed when ultrasound was combined with the heterogeneous Fenton process. The decolorization efficiency increased with the increasing power density and catalyst dosage, but decreased with the increase of initial pH value. There exists an optimal hydrogen peroxide concentration for decolorization. Catalyst stability was evaluated by measuring iron leaching in solution. The decolorization efficiency was 88% under the optimal conditions. Toxicity test with Daphnia magna showed that the acute toxicity of dye solution decreased significantly after the treatment by the heterogeneous sono-Fenton process.

Preparation of acrylic acid-modified chitin improved by an experimental design and its application in absorbing toxic organic compounds

Chitin grafted poly (acrylic acid) (chi-g-PAA) is synthesized and characterized as an adsorbent of toxic organic compounds. Chi-g-PAA copolymers are prepared using of ammonium cerium (IV) nitrate (Ce(4+)) as the initiator. The highest grafting percentage of AA in chitin obtained using the traditional technique is 163.1%. A maximum grafting percentage of 230.6% is obtained using central composite design (CCD). Experimental results are consistent with theoretical calculations. The grafted copolymer is characterized by Fourier transform Infrared spectroscopy and solid state (13)C NMR. A representative chi-g-AA copolymer is hydrolyzed to a type of sodium salt (chi-g-PANa) and used in the adsorption of malachite green (MG), methyl violet (MV), and paraquat (PQ) in aqueous. The monolayer adsorption capacities of these substances are 285.7, 357.1, and 322.6 mg/g-adsorbent, respectively. Thermodynamic calculations show that the adsorption of MG, MV, and PQ are more favored at diluted solutions. The high adsorption capacity of chi-g-PANa for toxic matter indicates its potential in the treatment of wastewater and emergency treatment of PQ-poisoned patients.

Partial degradation mechanisms of malachite green and methyl violet B by Shewanella decolorationis NTOU1 under anaerobic conditions

This work demonstrated that Shewanella decolorationis NTOU1 decolorized 200 mg l(-1) of crystal violet, malachite green, or methyl violet B within 2-11h under anaerobic conditions at 35 degrees C. The initial color removal rate of malachite green was highest, while that of methyl violet was lowest. GC/MS analyses of the intermediate compounds produced during and after decolorization of malachite green and methyl violet B suggested that biodegradation of these dyes involved reduction to leuco form, N-demethylation, and reductive splitting of the triphenyl rings. The number of N-methylated groups of these dyes might have influenced decolorization rates and the reductive splitting of the triphenyl rings of these dyes. Cytotoxicity and antimicrobial test data showed that malachite green and methyl violet B solution (100 mg l(-1)) were toxic. Toxicity of the dyes decreased after their decolorization, but further incubation resulted in increased toxicity.

Use of grape seed and its natural polyphenol extracts as a natural organic coagulant for removal of cationic dyes

Natural organic coagulants (NOCs) such as chitosan and Moringa oleifera seeds have been extensively characterized for potential application in water treatment as an alternative to metal-based coagulants. However, the action of both chitosan and M. oleifera seeds is mainly restricted to anionic organic pollutants because of their cationic functional groups affording poor cationic pollutant coagulation by electrostatic repulsion. In this study, we employed ethanolic grape seed extract (GSE) and grape seed-derived polyphenols such as tannic acid and catechin in an effort to find novel NOCs showing stable anionic forms for removal of cationic organic pollutants. The target substances tested were malachite green (MG) and crystal violet (CV), both mutagenic cationic dyes. Polyphenol treatment induced fast decolorization followed by gradual floc formation concomitant with red or blue shifts in maximum absorbance wavelengths of the cationic dyes. Liquid chromatography analysis of flocs formed by polyphenols directly showed that initial supramolecular complexes attributed mainly to electrostatic attraction between polyphenol hydroxyphenyl groups and cationic dyes further progressed into stronger aggregates, leading to precipitation of dye-polyphenol complexes. Consistent with the results obtained using catechin and tannic acid, use of GSE also resulted in effective decolorization and coagulation of soluble MG and CV in aqueous solutions. Screening of several organic GSE components for NOC activity strongly suggested that natural polyphenols are the main organic ingredients causing MG and CV removal via gradual floc formation. The treatment by natural polyphenols and GSE decreased toxicity of MG- or CV-contaminated water.

Comparison of dyes for cataract surgery. Part 1: cytotoxicity to corneal endothelial cells in a rabbit model

PURPOSE

To investigate the corneal endothelial cytotoxicity of dyes for capsule staining in cataract surgery.

SETTING

Department of Ophthalmology and Institute of Clinical Medicine, College of Medicine, National Cheng Kung University, Tainan, Taiwan.

METHODS

Cultured corneal endothelial cells of New Zealand white rabbits were exposed for 1 minute to 1 of the following dyes (various concentrations): indocyanine green (ICG), methylene blue (MB), gentian violet (GV), trypan blue (TB), and fluorescein sodium (FS). The degree of cell damage was determined by in vitro staining with TB and comparison with results in a control group. The effect of longer exposure (up to 10 minutes) to ICG 0.25% was also investigated. Structural changes in corneal endothelial cells after dye exposure were evaluated by light microscopy and transmission electron microscopy (TEM).

RESULTS

Indocyanine green 0.25%, MB 0.20%, GV 0.01%, TB 0.40%, and FS 10% did not induce significant damage to corneal endothelial cells. Significant cytotoxicity was observed with the following or higher dye concentrations: ICG 0.50%, MB 0.50%, and GV 0.10%. Exposure to ICG 0.25% for 1 to 10 minutes showed a trend toward cytotoxicity after 10 minutes. On TEM, corneal endothelial cells that had been exposed to ICG 0.50% showed remarkable organelle swelling and disruption, electron-dense granules, and cell lysis.

CONCLUSION

One minute of exposure to ICG 0.25%, MB 0.20%, GV 0.01%, TB 0.40%, and FS 10% appeared to be safe as determined by no cytotoxic effects on rabbit corneal endothelial cells in culture.

Bioremediation of crystal violet using air bubble bioreactor packed with Pseudomonas aeruginosa

Seven water and sediment samples were collected and tested for decolorizing crystal violet. Pseudomonas aeruginosa was the most effective isolate for dye decolorization. The LC(50) of the crystal violet (115 mg/l) was measured using Artemia salina as a biomarker. The effect of different heavy metals on crystal violet decolorization was investigated. Cd(2+) and Fe(3+) ions showed marginal enhancement of the decolorization process, the rate was 1.35 mg/l/h compared to 1.25 mg/l/h for the control. Phenol and m-cresol showed no effect on crystal violet decolorization, meanwhile p-cresol and p-nitrophenol reduced the decolorization rate to 1.07 and 0.01 mg/l/h, respectively. P. aeruginosa cells were immobilized by entrapment in agar-alginate beads. The beads were cultivated and reused in Erlenmeyer flask and in an air bubble column bioreactor and they enhanced the crystal violet decolorization rate to 3.33 and 7.5 mg/l/h, respectively.

Simple detection method for distinguishing dead and living yeast colonies

A rapid and simple assay was developed for detection of yeast colonies containing dying or dead cells. Methylene blue, phloxin B, rose bengal and trypan blue at concentrations of 5-10 micromol l(-1) were shown to stain non-viable cells in colonies of Saccharomyces cerevisiae, Schizosaccharomyces pombe, Candida albicans and Filobasidium capsuligenum without staining or affecting the viability of living cells of the colonies.

Ototoxicity of common topical antimycotic preparations

OBJECTIVE

To determine the ototoxic effects of five commonly used topical antimycotic agents-clotrimazole, miconazole, nystatin, tolnaftate, and gentian violet-in the guinea pig.

DESIGN

A controlled animal study in which the ototoxicity of commonly used topical antifungal agents was investigated by measurement of hair cell loss.

METHODS

Several readily available topical antimycotic preparations were instilled into the middle ears of female Hartley guinea pigs over a 1-week period. Two weeks after the last instillation, the animals were euthanized. An active control group was treated with neomycin to confirm the adequacy of the treatment in delivering a known ototoxin; an untreated control group defined the normal distribution of hair cells. The temporal bones were removed, and the cochleas were fixed and dissected. The basilar membranes were examined under the scanning electron microscope. A map of hair cell survival was made for each row in segments of each turn.

RESULTS

The untreated control animals had no discernible hair cell loss in the two lower turns. In the apical turn and sometimes the third turn, loss of hair cells was a common finding, this is a known effect of aging in this species. The animals treated with neomycin had damage consistently in the basal turn, sometimes extending into the second turn, as well as the expected hair cell loss in the apical turn. Clotrimazole, miconazole, or tolnaftate did not cause any hair cell loss in the first two turns. Hair cell loss in the third and fourth turns was similar to that of the untreated control group. Likewise, nystatin exhibited no evidence of ototoxicity. Of note, however, the preparation used in this study left a persistent residue in the round window niche. Of the first four animals treated with gentian violet, three developed pronounced behavioral signs of vestibular damage, and three demonstrated extensive middle ear inflammation and extensive new bone growth. Hair cell counts were not attempted because the extreme bone growth interfered with successful perfusion and dissection.

CONCLUSIONS

Extrapolating from guinea pigs to humans requires caution. However, it is likely that guinea pigs are, if anything, more susceptible to topical ototoxins than are humans. The specific antimycotics clotrimazole, miconazole, and tolnaftate appear to be safe. Gentian violet has the potential for severe damage. The persistent residue left by the nystatin preparation is cause for concern and is a reminder that both the active ingredient and vehicle must be considered in evaluation of safety.

Effect of molecular structure on the performance of triarylmethane dyes as therapeutic agents for photochemical purging of autologous bone marrow grafts from residual tumor cells

Extensively conjugated cationic molecules with appropriate structural features naturally accumulate into the mitochondria of living cells, a phenomenon typically more prominent in tumor than in normal cells. Because a variety of tumor cells also retain pertinent cationic structures for longer periods of time compared with normal cells, mitochondrial targeting has been proposed as a selective therapeutic strategy of relevance for both chemotherapy and photochemotherapy of neoplastic diseases. Here we report that the triarylmethane dye crystal violet stains cell mitochondria with efficiency and selectivity, and is a promising candidate for photochemotherapy applications. Crystal violet exhibits pronounced phototoxicity toward L1210 leukemia cells but comparatively small toxic effects toward normal hematopoietic cells (murine granulocyte-macrophage progenitors, CFU-GM). On the basis of a comparative examination of chemical, photochemical, and phototoxic properties of crystal violet and other triarylmethane dyes, we have identified interdependencies between molecular structure, and selective phototoxicity toward tumor cells. These structure-activity relationships represent useful guidelines for the development of novel purging protocols to promote selective elimination of residual tumor cells from autologous bone marrow grafts with minimum toxicity to normal hematopoietic stem cells.

Experimental staining of the anterior lens capsule in albino rabbits

PURPOSE

To study the value and safety of staining the anterior lens capsule in albino rabbits.

SETTING

Ophthalmology Department, Cairo University, and Ophthalmic Pathology Department, Research Institute of Ophthalmology, Cairo, Egypt.

METHODS

The experiment was divided into 3 stages. First, the capacity of different concentrations of crystal violet solution to stain the anterior lens capsule of postmortem albino rabbit eyes was tested. The toxicity of different concentrations of the dye (2% to 0.25%) was then tested to determine the highest concentration that was nontoxic to the cornea and trabecular meshwork. The third step was to detect possible toxicity of lower concentrations (0.1% to 0.05%). Different dye concentrations were injected into the anterior chamber of the rabbit eyes. The eyes were examined after 1 and 3 days, 1 week, and 1 month using light microscopy and scanning and transmission electron microscopy.

RESULTS

Different concentrations of crystal violet stained the anterior lens capsule, allowing for easy capsulorhexis. The use of the 2% and 1% concentrations was accompanied with irreversible damage to all corneal layers. The use of the 0.5% concentration caused damage to stromal keratocytes and endothelium. The use of the 0.25% concentration did not damage any corneal layer or the trabecular meshwork. Lower concentrations of 0.1% and 0.05% also stained the capsule, providing good visibility for successful capsulorhexis, and were less toxic to the corneal endothelium.

CONCLUSION

Staining the anterior lens capsule with 0.25% to 0.05% concentrations of crystal violet solution caused no injury to the cornea or trabecular meshwork in albino rabbit eyes.

[Pathological changes following retrograde infusion of methyl violet in the parotid gland of the miniature pig]

OBJECTIVE

To investigate the pathologic changes induced by infusion of 1% methyl violet in the parotid gland of the miniature pig (minipig).

METHODS

Methyl violet (either 0.6 ml, 1.0 ml, or 4.0 ml) was injected into parotid glands of fifteen minipigs. The parotid glands were harvested for gross and histopathologic study after 1 week, 2 weeks, 1 month, 3 months and 6 months.

RESULTS

The pathological changes induced by retrograde injection of methyl violet included necrosis or atrophy of acinar cells and fibrosis of the gland. The ductal system underwent atrophic changes, and thrombotic obliteration of main duct.

CONCLUSION

Retrograde infusion of 1% methyl violet results in complete atrophy and fibrosis of the parotid gland in the minipig.

[Experimental study of parotid gland injected with gentian violet]

OBJECTIVE

The Gentian Violet was used for treating the chronic parotitis since 1960's, but the dosage and the histologic changes of the tissues were undefined until now. We try to study the histologic changes of the salivary glands, heart, liver and kidneys after large volume of gentian violet was injected into the parotid gland through the duct.

METHODS

5 ml of Gentian Violet was injected to each side of 6 dogs. The macropathologic and histologic examination of the salivary glands, heart, liver and kidneys were performed at 30 min, 60 min, 120 min, 21 days and 9 months separately after the perfusion.

RESULTS

Local swelling was obvious in two or three days after infusion and subsided in one week in most of the dogs. Degeneration of the gland took place after 20 days. After 9 months, the parotid gland tissues were replaced by the connective tissues. On the other hand, no histologic change was observed in heart, liver and kidney in the investigation.

CONCLUSION

The Gentian Violet can cause degeneration of the parotid gland including the duct and replaced by connective tissues later. There is no obvious changes were noted in other organs.

Biodegradation of triphenylmethane dyes

Biodegradation of triphenylmethane dyes by bacteria, actinomycetes, yeasts, and fungi are discussed in detail. The disadvantages of physical and chemical treatment processes of dye wastewater are also discussed. Biological treatment processes have many advantages over the chemical and physical treatment processes such as possibility of degradation of dye molecules to carbon dioxide and water and formation of less sludge in addition to being environmentally friendly. This group of dyes is toxic depending on the concentration used. Toxicity of triphenylmethane dyes is discussed with respect to different organisms. Some aspects of biodegradative products of this group of dyes are also mentioned.

Heterogeneity in chemical mutagen-induced chromosome damage after G2 phase exposure to bleomycin, ara-C and gentian violet in cultured lymphocytes of beta-thalassaemia traits

Chemical mutagen-induced chromosome damage was analysed in cultured peripheral blood lymphocytes from beta-thalassaemia traits and healthy individuals. This was promoted by the fact that beta-thalassaemia trait is present in 1-17% of different population groups in India. To study mutagen-induced chromosome instability, G2 lymphocytes were exposed to bleomycin, ara-C or gentian violet in 48-h cultures. Spontaneous chromosome aberration frequencies in lymphocytes from beta-thalassaemia traits were found to be in the normal range. In all three clastogen-treated lymphocytes from beta-thalassaemia traits, there is a degree of hypersensitivity, when the results are averaged over a number of individuals, but some individuals overlap within the normal range. The heterogeneity in chemical mutagen sensitivity observed in beta-thalassaemia traits is discussed in terms of the oxidative damage consequent on the genetic and biochemical features peculiar to the beta-thalassaemia trait cell.

The mitochondrion of Trypanosoma cruzi is a target of crystal violet toxicity

The first morphological alteration observed in Trypanosoma cruzi different stages upon incubation with crystal violet was mitochondrial swelling. The use of digitonin to solubilize T. cruzi plasma membrane allowed the demonstration of an uncoupling action of crystal violet on epimastigote mitochondria in situ. Low concentrations of crystal violet (20-50 microM) or carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP; 0.5 microM) uncoupled the respiratory control mechanism. The inhibition of State 3 respiration by oligomycin was released by crystal violet or FFCCP. Crystal violet released respiratory control, and enhanced ATPase activity of digitonin-permeabilized epimastigotes. Higher concentrations of crystal violet inhibited mitochondrial respiration. The uncoupled effect of crystal violet was stimulated by inorganic phosphate. In addition, crystal violet inhibited endongenous and glucose-stimulated respiration of the intact epimastigotes, and inhibited the Mg2+-ATPase in the epimastigote mitochondrial fractions. The inhibition of this Mg2+-ATPase increased up to pH 9.0 and decreased with increasing protein concentration. These data indicate that the T. cruzi mitochondrion is apparently the main target of crystal violet toxicity.

Chronic toxicity/carcinogenicity studies of gentian violet in Fischer 344 rats: two-generation exposure

A chronic feeding study was carried out in the F1a generation of dosed Fischer 344 rats of both sexes with gentian violet (GV). The test substance was administered in the diet to 570 male and 570 female rats at dose levels of 0 (control), 100, 300 and 600 ppm for 24 months. Rats were killed and necropsied after 12, 18 and 24 months of continuous dosing. Measurements of body weights, food consumption (and dose rate) and mortality and the results of histopathological examination were analysed statistically. Male and female rats fed 600 ppm GV for 24 months showed a decrease in body weights. Average food consumption based on g food/kg average body weight was essentially equal in all groups. Mortality at the end of the study (24 months) was approximately 33% in the controls for both males and females and approximately 66% in females of the high-dose group and 48 and 39% in males of the mid- and high-dose groups, respectively. All dose-related neoplastic pathology was noted at the final necropsy. Following 24 months of dosing, there was a significant difference from the controls in the incidence of follicular cell adenocarcinoma of the thyroid gland for both males (600 ppm GV) and females (300 and 600 ppm GV). Although the incidences were very low, statistical analysis showed a significant difference from the controls for hepatocellular adenomas in the mid-dose group of the females and the mid- and high-dose groups of the males. A dose-time-related incidence of mononuclear cell leukaemia was also noted in the females. There was high background incidence of the leukaemia. Several non-neoplastic dose-related lesions were observed in both males and females, principally in the 18- and 24-month necropsies. Almost all of these lesions were focal changes in the liver, many of which were probably related to the mononuclear cell leukaemia.

Factors in formation and prevention of bandlike gastric lesions in the rat

The etiology of the deep bandlike necrotic gastric mucosal lesions induced by the oral administration of corrosive agents in the rat is unclear. An understanding of why the lesions are so precisely localized and how they develop should increase our understanding of the mechanisms by which the prostaglandins prevent them. This study utilizes an innocuous dye to demonstrate that the initial mucosal contact by orally administered agents is restricted to the crests of mucosal folds. A sequential study of lesion development at the fold crest indicates that coagulative necrosis occurs on contact and that the vascular defects, hemorrhage and congestion, are secondary to deep corrosion injury. Exogenous prostaglandin and 0.35 N HCl were found to abolish mucosal folding and hence prevent the fold-related lesions. Inhibition of prostaglandin synthesis was found to sensitize the mucosal fold crest to injury by 0.35 N HCl, and hence the use of indomethacin as a proof that endogenous prostaglandin synthesis plays a role in preventing bandlike lesions by such agents is questioned. It is concluded that the gastric mucosal fold plays a major role in localizing mucosal injury to parallel bands and that the obliteration of these sensitive sites may explain the protective effect of an ever-expanding number of agents. As lesions genesis appears to be the result of a contact artifact, the use of this model in the study of the physiological role played by gastric prostaglandins is seriously questioned.(ABSTRACT TRUNCATED AT 250 WORDS)

Enhancement of the cytotoxicity of crystal violet against Trypanosoma cruzi in the blood by ascorbate

Blood transfusion is the second most important mechanism of transmission of Chagas' disease, and crystal violet is currently used in blood banks in endemic areas in attempts to eliminate such transmission. A photodynamic action of crystal violet against Trypanosoma cruzi trypomastigotes in blood has been detected. This action was enhanced by addition of sodium ascorbate. Photoirradiation of whole blood containing crystal violet increased the concentration of ascorbyl radical and the generation of superoxide anion. Similar results were observed in incubations containing ascorbate and crystal violet in the absence of blood. Hydrogen peroxide generation was also detected in these incubations, thus confirming redox cycling of crystal violet under aerobic conditions. Since photoirradiation and addition of sodium ascorbate reduces significantly the effective dose and time of contact of crystal violet with T. cruzi-infected blood, a possible practical application of these findings is envisaged.

The effect of acrylamide on hepatocellular DNA repair

Acrylamide has recently been reported to induce tumors in laboratory animals. The effect of acrylamide on unscheduled DNA synthesis using the hepatocyte primary culture (HPC)/DNA repair test was examined. Isolated hepatocytes were exposed to acrylamide and [3H]thymidine ( [3H]TdR) for 18 hr. Incorporation of [3H]TdR into DNA was determined by autoradiography. No DNA repair was observed at acrylamide concentrations up to 10(-2) M. These findings were confirmed using density gradients. Acrylamide concentrations exceeding 10(-2) M were cytotoxic to hepatocytes. Because both autoradiography and density gradients measure DNA repair as an endpoint, the ability of acrylamide to inhibit these repair processes was also determined. Acrylamide had no effect on the repair of UV-damaged DNA. These results show that acrylamide is not genotoxic in isolated hepatocytes.

Chronic toxicity and carcinogenicity studies of gentian violet in mice

Gentian violet is a dye belonging to a chemical class known as the di- and triaminophenylmethanes. Although it has been used for many years for the control of fungal and intestinal parasites, for various uses in veterinary medicine, and as an additive to the feed of chickens to inhibit propagation of mold and fungus, very few long-term toxicity data are available. A life span dosing study of gentian violet in the diet of 720 males and 720 females of B6C3F1 mice (C57BL/6 X C3H) at dose levels of 0, 100, 300, and 600 ppm was done to determine its toxicity and carcinogenicity. Sacrifices were conducted after 12, 18, and 24 months of continuous dosing. There was no effect on food consumption or body weight gain; however, a dose effect was noted for mortality rates. Mortality (adjusted for sacrifices) in the controls of both sexes was less than 15% at 24 months, but was approximately 64% in the females and 23% in the males given the high dose. Females appeared to be more susceptible than males. A positive dose response for hepatocellular carcinoma was noted in males at 24 months and in females at 18 and 24 months. Statistical tests for dose-related trends with respect to mortality due to liver neoplasms, prevalence of liver neoplasms, and time to onset of liver neoplasms showed positive trends in both males and females. Other dose-related toxicological responses, particularly in the female mice, included erythropoiesis in the spleen, atrophy of the ovaries, adenoma of the Harderian gland, and the presence of type A reticulum cell sarcomas in the urinary bladder, uterus, ovaries, and vagina. The estimation of risk of 10(-6) over background for malignant liver neoplasms using linear extrapolations showed a lower bound on the virtually safe dose (VSD) to be 2 ppb for the female mice and 1 ppb for the male mice. For benign and malignant liver tumors together, the lower bound on the VSD was essentially the same as for malignant liver neoplasm alone. Under the conditions of the experiment described above, gentian violet appears to be a carcinogen in mice at several different organ sites.

Microsomal reduction of gentian violet. Evidence for cytochrome P-450-catalyzed free radical formation

The triarylmethane dye, gentian violet, is shown to undergo a one-electron reduction by the cytochrome P-450 monooxygenase system to produce a carbon-centered free radical as demonstrated by direct electron spin resonance techniques. The formation of this species is inhibited by carbon monoxide and metyrapone, suggesting the involvement of cytochrome P-450. Either NADPH or NADH can serve as a source of reducing equivalents for the production of this free radical. Related triarylmethane dyes are also shown to be reduced by the monooxygenase system to form free radicals.

Further study of the genetic toxicity of gentian violet

The genetic toxicity of gentian violet was studied with the Ames and the Rosenkranz bacterial assays as well as the cytogenetic assays (Chinese hamster ovary cells in vitro in the presence of rat-liver S-9 fractions, the chicken-embryo and mouse-bone-marrow cells in vivo). Gentian violet was found to be toxic but not mutagenic in the Ames assay. However, it was active in the Rosenkranz assay causing reparable DNA damage. The presence of S-9 in the in vitro cytogenetic assay and in the bacterial assays showed that the activity of gentian violet could be reduced or eliminated. In the in vivo assays, gentian violet was not clastogenic and failed to induce sister-chromatid exchanges. However, gentian violet proved to be highly toxic to growing chick embryos at high dosage and depressed mitotic activities in mouse bone marrow after prolonged treatment. Our study suggested that gentian violet can be inactivated by the liver detoxification system. However, it is potentially hazardous to cells that are exposed to the dye directly (e.g. skin epithelium and cell lining of the gastrointestinal tract).

Safety evaluation of gentian violet for breeder chickens

Four treatment levels (1.0, 2.5, 5.0 and 10.0 x the recommended use level) of a gentian violet premix (Dye-Gen) were compared with non-medicated controls for breeder chickens during a 168-day study. There were no treatment effects up to and including 10 x the recommended use level on: average daily feed consumption, feed/dozen eggs, hatchability of fertile eggs, or mortality. Fertility was higher for the birds receiving 2.5 x the recommended use level than for the non-medicated controls. Egg production was higher (P less than .05) for the non-medicated controls and 10x groups than for the birds receiving the gentian violet premix at 2.5 x the recommended use level. Semen of breeder males was observed for % abnormal sperm, % dead sperm, % motility, vigor, and semen volume. There was no treatment effect on any of the semen characteristics evaluated. It can be concluded from these data that the gentian violet premix is safe for breeder chickens under the conditions of this study.