Modulatory effects of metanil yellow on immunity in rodents.

Pathomorphological and immunological studies were carried out on rodents following oral administration of 0, 0.1, 0.25 and 0.5% (w/w) metanil yellow, mixed in diet, for 30 days. No significant change in hematologic parameters and histologic architecture of liver, kidney, mesenteric lymph node, thymus and urinary bladder was observed except for mild desquamation of intestinal villi and moderate changes in Peyer's patches of small intestine with higher doses. Among immunological parameters, significant enhancement in the primary humoral immune response (anti-SRBC IgM plaque forming cells of spleen) was observed with the lowest dose of metanil yellow while higher doses produced opposing effects. An elevated cutaneous delayed type hypersensitivity (DTH) reaction to SRBC was seen in 0.1% metanil yellow treated animals but higher doses did not influence the reaction. The treatment also caused changes in functional capabilities of macrophages. Although these immune alterations could hardly influence the local immunity of gut, as measured by the capacity of animals to cause rejection of Nippostrongylus brasiliensis parasite, the potential to modulate the immunity in general by metanil yellow however assumes considerable biological significance.     

Utilization of 15N-urea administered into the sheep small intestine.

The retention and excretion of intrajejunally administered 15N-urea was studied in four experiments on two sheep with a permanently fistulated small intestine. In the first 7 days after the administration of 2 g 15N-urea, 18.26% was excreted in the faeces and 19% in the urine; 62.74% was retained in the organism. Urinary excretion took place mainly on the first day and from the 3rd to the 7th day no 15N was present in the urine. The rate of 15N excretion in the faeces was roughly the same for the first 4 days and then fell; on the 7th day there was no 15N in the faeces. The proportion of 15N-urea retained in the organism and excreted in the urine was 81% showing that urea in the ruminant gastrointestinal tract is largely linked up into metabolic circulation as part of the general exchange of nitrogenous compounds.     

Effects of certain food dyes on chromosomes of Allium cepa

The effects of 4 permitted food dyes, i.e., fast green FCF, indigo carmine, orange G and tartrazine, and the non-permitted dye metanil yellow on chromosomes of Allium cepa are reported. A significant increase in polyploid cells was observed in all cases. High doses of these dyes induced chromosome breaks and micronucleus formation. Although all dyes produced mitotic aberrations, metanil yellow and fast green FCF showed comparatively stronger clastogenic activity.     

Sulphate recycling and metabolism in sheep and cattle.

Merino wethers and Brahman x Shorthorn steers, offered lucerne or spear grass hay, were used to study the movements of sulphate through pools in plasma and ruminal liquor. The irreversible loss of sulphate from ruminal liquor was 60 and 76% of sulphur ingested for both species fed lucerne and spear grass respectively. The irreversible loss of sulphate from the plasma averaged 67 and 56% of sulphur ingested for animals fed lucerne and spear grass respectively. Daily recycling of sulphate to the rumen of sheep was 98 mg sulphur on the lucerne diet and 3.9 mg sulphur on the spear grass diet. Sulphate recycling in cattle fed lucerne was 533 mg sulphur; in cattle fed spear grass the value was 234 mg sulphur. Over 6 days following an intravenous injection of [35S]sulphate into sheep and cattle fed lucerne, 5-10% of the dose was excreted in the faeces and c. 10% was retained. Corresponding values for animals fed spear grass were 23-31% in faeces and 40-51% of the dose retained. After intraruminal injections of [35S]sulphate, animals fed lucerne excreted 15-18% of the dose in the faeces and retained 25-30% of the dose over 6 days. Values for animals fed spear grass were 22-26% in faeces and 62-70% retained. It was concluded that sulphate recycling to the rumen is a limiting factor in microbial synthesis for sheep fed low-quality roughage, and that secretion of endogenous sulphur into the postruminal tract of ruminants is of importance in the metabolism of sulphate.     

Differential dichrome staining of tissue culture monolayers: alternate dyes and possible mechanism.

A polyacid-dependent dichrome has been devised which will differentiate epithelial from mesenchymal cells in young dividing primary cultures. Epithelial cells and colonies and nuclei are stained with metanil yellow, the stain is fixed and differentiated with phosphotungstic acid, and the mesenchymal elements are stained with toluidine blue. Several other dyes are tested for substitution in this method. Biebrich scarlet and aniline blue could be substituted for the metanil yellow; Bismarck brown T, Janus green B, crystal violet, and neutral red could be substituted for the basic dye.     

The metabolism of arylazoisoxazolones by rats and dogs

1. When rats were given a single oral dose of the lipid-soluble fungicide 4-(2-chlorophenylhydrazono)-3-methyl[4-(14)C]isoxazol-5-one ([(14)C]drazoxolon), about 75% of the label was excreted in the urine and 13% in the faeces in 96hr. An additional 7% of the radioactivity was recovered as (14)CO(2) in 48hr. 2. About 8% of the label was excreted by rats in the bile in 0-24hr. and an additional 6% was excreted by the same route in 24-48hr. 3. When dogs were given a single oral dose of [(14)C]drazoxolon about 35% of the label was excreted in the urine and a similar amount was excreted in the faeces in 96hr. 4. The major metabolites in the urine of the rat and the dog were identified as 2-(2-chloro-4-hydroxyphenylhydrazono)acetoacetic acid (dog, 14%), the corresponding ether glucosiduronic acid (dog, 12%; rat, 13%) and ester sulphate (rat, 65%). 5. When rats were given a single oral dose of 3-methyl-4-([U-(14)C]phenylhydrazono)isoxazol-5-one about 75% of the label was excreted in the urine and 15% in the faeces in 96hr. The major metabolite in the urine was identified as the ester sulphate conjugate of 2-(4-hydroxyphenylhydrazono)-acetoacetic acid. 6. Reduction of the azo link was of minor quantitative significance. 7. These results are discussed in their relation to species differences in the toxicity of these compounds.     

The metabolism and excretion of methylglucamine (N-methyl-D-glucamine) in the rat

Methylglucamine is a commonly used cation in radiocontrast media. The present study sheds light on its fate in the rat. When administered intraperitoneally, 93% of the compound was excreted unchanged in the urine in 24 hr. When administered orally, about 15% of the dose was found in the urine, about 40% in the faeces and 20% in expired air in 24 hr. When administered orally to rats whose gut flora had been depleted by treatment with neomycin sulphate, 19% was excreted in the urine, 69% in the faeces and 3% in expired air in 72 hr. This indicated that the gut flora played a role in the degradation of the compound and its eventual loss as expired carbon dioxide.     

Long-term low-dose mutation studies in human cells: metanil yellow and orange II

We tested the mutagenic effects of two commonly used fold colors, metanil yellow and orange II, in AHH-1 human lymphoblast cells. The cell line, which is competent for oxidative metabolism of various chemicals, was exposed to both compounds in high-dose x short-term (3 day) or high-dose x long-term (10-day) and low-dose x long-term (20-day) treatments. Concentrations of metanil yellow and orange II as low as 22 nM and 12 nM, respectively, were sufficient to induce mutation rates which were equal to twice the spontaneous mutation rate at the HPRT locus in AHH-1 cells.     

Differential Dichrome Staining of Tissue Culture Monolayers: Alternate Dyes and Possible Mechanism

A polyacid-dependent dichrome has been devised which will differentiate epithelial from mesenchymal cells in young dividing primary cultures. Epithelial cells and colonies and nuclei are stained with metanil yellow, the stain is fixed and differentiated with phosphotungstic acid, and the mesenchymal elements are stained with toluidine blue. Several other dyes are tested for substitution in this method. Biebrich scarlet and aniline blue could be substituted for the metanil yellow; Bismarck brown T, Janus green B, crystal violet, and neutral red could be substituted for the basic dye.     

Absorption,metabolism and excretion of 3-acetyl don in pigs

The absorption, metabolism and excretion of 3-acetyldeoxynivalenol (3-aDON) in pigs were studied. Pigs with a faecal microflora known to be able to de-epoxidate trichothecenes were used in the experiment. The pigs were fed a commercial diet with 3-aDON added in a concentration of 2.5 mg/kg feed for 2.5 days. No traces of 3-aDON or its de-epoxide metabolite were found in plasma, urine or faeces. Deoxynivalenol (DON) was detected in plasma as soon as 20 min after start of the feeding. The maximum concentration of DON in plasma was reached after 3 h and decreased rapidly thereafter. Only low concentrations close to the detection limit were found in plasma 8 h after start of the feeding. A significant part of the DON in plasma was in a glucuronide-conjugated form (42 ± 7%). No accumulation of DON occurred in plasma during the 60 h of exposure. The excretion of DON was mainly in urine (45 ± 26% of the toxin ingested by the pigs) and only low amounts of metabolites of 3-aDON (2 ± 0.4%) were recovered in faeces. De-epoxide DON constituted 52 ± 15% of the total amount of 3-aDON-metabolites detected in faeces. The remaining part in faeces was DON. DON was still present in the urine and faeces at the end of the sampling period 48 h after the last exposure. The results show that no de-epoxides are found in plasma or urine in pigs after trichothecene exposure, even in pigs having a faecal microflora with a de-epoxidation activity. The acetylated form of the toxin is deacetylated in vivo. Furthermore, the experiment shows that the main part of DON is rapidly excreted and does not accumulate in plasma, but a minor part of the toxin is retained and slowly excreted from the pigs.     

Metabolism of [14C]methamphetamine in man, the guinea pig and the rat

1. The metabolites of (+/-)-2-methylamino-1-phenyl[1-(14)C]propane ([(14)C]methamphetamine) in urine were examined in man, rat and guinea pig. 2. In two male human subjects receiving the drug orally (20mg per person) about 90% of the (14)C was excreted in the urine in 4 days. The urine of the first day was examined for metabolites, and the main metabolites were the unchanged drug (22% of the dose) and 4-hydroxymethamphetamine (15%). Minor metabolites were hippuric acid, norephedrine, 4-hydroxyamphetamine, 4-hydroxynorephedrine and an acid-labile precursor of benzyl methyl ketone. 3. In the rat some 82% of the dose of (14)C (45mg/kg) was excreted in the urine and 2-3% in the faeces in 3-4 days. In 2 days the main metabolites in the urine were 4-hydroxymethamphetamine (31% of dose), 4-hydroxynorephedrine (16%) and unchanged drug (11%). Minor metabolites were amphetamine, 4-hydroxyamphetamine and benzoic acid. 4. The guinea pig was injected intraperitoneally with the drug at two doses, 10 and 45mg/kg. In both cases nearly 90% of the (14)C was excreted, mainly in the urine after the lower dose, but in the urine (69%) and faeces (18%) after the higher dose. The main metabolites in the guinea pig were benzoic acid and its conjugates. Minor metabolites were unchanged drug, amphetamine, norephedrine, an acid-labile precursor of benzyl methyl ketone and an unknown weakly acidic metabolite. The output of norephedrine was dose-dependent, being about 19% on the higher dose and about 1% on the lower dose. 5. Marked species differences in the metabolism of methamphetamine were observed. The main reaction in the rat was aromatic hydroxylation, in the guinea pig demethylation and deamination, whereas in man much of the drug, possibly one-half, was excreted unchanged.     

The metabolism of 2,6-di-tert.-butyl-4-hydroxymethylphenol (Ionox 100) in the dog and rat

1. A single oral dose of [(14)C]Ionox 100 to rats is almost entirely eliminated in 11 days: 89.1-107.2% of the (14)C is excreted and 0.29+/-0.02% of the dose is present in the carcass plus viscera after removal of the gut. Rats exhibit an individual variation in the elimination pattern, 15.6-70.8% of (14)C being excreted in the urine and 75.2-27.0% in the faeces during 11 days. 2. After the oral administration of [(14)C]Ionox 100 to dogs, 87.1-90.3% of the (14)C is excreted in the faeces and urine during 4 days. 3. Dogs and rats do not show a species difference in this pattern of elimination. 4. The rate of elimination from dogs and rats given a single dose of Ionox 100 is not affected by the size of the dose and the presence of triglyceride fat in the diet. 5. Ionox 100 is completely metabolized in dogs and rats: unchanged Ionox 100 is absent from the urine and faeces, and from the carcass when elimination is complete. In rats, 3,5-di-tert.-butyl-4-hydroxybenzoic acid accounts for 50-85% of a dose of Ionox 100 and (3,5-di-tert.-butyl-4-hydroxybenzoyl beta-d-glucopyranosid)uronic acid for 47-10%; in dogs, the unconjugated acid accounts for 85% and the ester glucuronide for 10-12%. 3,5-Di-tert.-butyl-4-hydroxyhippuric acid is not formed. Other metabolites, which have been detected in small quantity in the faeces and urine of animals dosed with Ionox 100, have not been identified. 6. 3,5-Di-tert.-butyl-4-hydroxybenzoic acid and (3,5-di-tert.-butyl-4-hydroxybenzoyl beta-d-glucopyranosid)uronic acid are also the major metabolites of Ionol (2,6-di-tert.-butyl-p-cresol) in rats. 7. The elimination of Ionox 100 metabolites from rats is faster than that of Ionol and its metabolites. Unlike Ionol, unchanged Ionox 100 could not be detected in the bodies of these animals.     

Enhancement of Histological Detail Using Metanil Yellow as Counterstain in Periodic Acid Schiff's Hematoxylin Staining of Glycol Methacrylate Tissue Sections

Histological detail in sections from tissues embedded in glycol methacrylate was improved by counterstaining PAS/iron-hematoxylin stained sections with a dilute solution of metanil yellow. The addition of the counterstain increases contrast in tissue sections and highlights PAS-positive entities. The staining protocol provides sharp definition of tissue morphology, differentiates cell types and other tissue components and does not produce background staining.     

The metabolism of benzyl isothiocyanate and its cysteine conjugate.

1. The corresponding cysteine conjugate was formed when the GSH (reduced glutathione) or cysteinylglycine conjugates of benzyl isothiocyanate were incubated with rat liver or kidney homogenates. When the cysteine conjugate of benzyl isothiocyanate was similarly incubated in the presence of acetyl-CoA, the corresponding N-acetylcysteine conjugate (mercapturic acid) was formed. 2. The non-enzymic reaction of GSH with benzyl isothiocyanate was rapid and was catalysed by rat liver cytosol. 3. The mercapturic acid was excreted in the urine of rats dosed with benzyl isothiocyanate or its GSH, cysteinyl-glycine or cysteine conjugate, and was isolated as the dicyclohexylamine salt. 4. An oral dose of the cysteine conjugate of [14C]benzyl isothiocyanate was rapidly absorbed and excreted by rats and dogs. After 3 days, rats had excreted a mean of 92.4 and 5.6% of the dose in the urine and faeces respectively, and dogs had excreted a mean of 86.3 and 13.2% respectively. 5. After an oral dose of the cystein conjugate of [C]benzyl isothiocyanate, the major 14C-labelled metabolite in rat urine was the corresponding mercapturic acid (62% of the dose), whereas in dog urine it was hippuric acid (40% of the dose). 5. Mercapturic acid biosynthesis may be an important route of metabolism of certain isothiocyanates in some mammalian species.     

Excretion of corticosteroid metabolites in urine and faeces of rats.

Stress enhances the production of corticosteroids by the adrenal cortex, resulting in the increased excretion of their metabolites in urine and faeces. An intraperitoneal injection of radioactive corticosterone was applied to adult, male Sprague-Dawley rats to monitor the route and delay of excreted metabolites in urine and faeces. Peak concentrations appeared in urine after 3.2 +/- 1.9 h and in faeces after 16.7 +/- 4.3 h. Altogether about 20% of the recovered metabolites were found in urine and about 80% in faeces. Using high-performance liquid chromatography (HPLC), several peaks of radioactive metabolites were found. Some metabolites were detected by enzyme immunoassay (EIA) using two different antibodies (corticosterone, 11beta-OH-aetiocholanolone). There was a marked diurnal variation with low levels of faecal corticosterone metabolites in the evening and higher values in the morning. This diurnal variation was influenced neither by the intraperitoneal injection of isotonic saline nor by ACTH. However, the administration of dexamethasone eliminated the morning peak for 2 days.     

Gallocyanin as a Nuclear Stain in Autoradiography

In autoradiography, staining sections with gallocyanin and counterstaining with metanil yellow produces clear autoradiograms and avoids the staining of the emulsion encountered by using hematoxylin. Gallocyanin is a gradually progressive stain and by appropriate timing the intensity of staining is readily controlled. It is unnecessary to subject the plates to differentiating solutions.     

The Anomeric Equilibrium of Glucose in Acidic and Basic Media

In order to elucidate the nature of malodor from piggery wastes, volatile compounds in fresh faeces, fresh urine, rotten urine, and rotten mixtures of faeces and urine were isolated by freeze vacuum distillation and continuous extraction and identified by gas chromatography-mass spectrometry. Many alcohols were detected not in fresh urine, but in faeces. Various fatty acids were determined at high concentrations in all samples, but their abundance was different in faeces and urine. Large amounts of phenols came from urine. Aromatic carboxylic acids were detected only in urine and decreased rapidly during digestion. Indole and 3-methylindole which were present only in faeces showed a reverse change of concentration during digestion.     

Decolorization of Fast red by metabolizing cells of <Emphasis Type="Italic">Oenococcus oeni</Emphasis> ML34

Three different azo dyes such as Fast red, metanil yellow and Fast orange were examined for their decolorization by O. oeni ML34. Fast red (FR) was decolorized by 68%, whereas the other dyes were removed by only about 30%. The effects of glucose addition, substrate (dye) concentration and environmental factors (temperature, pH) on decolorization were investigated by two-level factorial design. The statistical analyses revealed that glucose specifically increases the extent of FR decolorization. A glucose level of 5 g/l was the optimum concentration for removal of, FR reaching a decolorization percentage of up to 93%.     

Determination of ochratoxin A in urine and faeces of swine by high-performance liquid chromatography

Sensitive methods for the determination of ochratoxin A in urine and faeces of swine are described. The samples were extracted with chloroform at pH <2, and the extracts were cleaned up by a combination of solid-phase extraction and liquid—liquid partition. High-performance liquid chromatography with fluorescence detection was used for detection and determination. The detection limits were 0.3 ng/ml for urine and 1.5 ng/g for faeces. Recoveries of ochratoxin A from spiked samples of urine and faeces were 93% and 60%, respectively. Because of the low detection limit and the fast and relatively easy performance, the method for the determination of ochratoxin A in urine proved suitable for the estimation of possible contamination of live animals.     

Hexachlorobenzene porphyria and hexachlorobenzene catabolism in rats

Gas-chromatographic examinations were made on the amounts of hexachlorobenzene accumulating in the liver and fatty tissue of rats chronically poisoned with a diet containing 0.2 % hexachlorobenzene, and on the amounts of hexachlorobenzene and pentachlorophenol excreted with the urine and the faeces in the course of the poisoning. The results indicated a constant rise in the hexachlorobenzene levels in these tissues. Pentachlorophenol formed in the catabolism of hexachlorobenzene appeared in increasing concentration in both the urine and the faeces from the commencement of the poisoning. After the 5th–6th week of poisoning, the presence of other apolar and polar products in the excretions was also markedly enhanced. After a single dose of hexachlorobenzene /0.2 g/animal/, of all the decomposition products only pentachlorophenol was produced in high concentration, showing that this is a primary catabolite. A hypothesis is put forward as to the possibility of a role being played in the mechanism of action of hexachlorobenzene by a membrane permeability change.