Acute alteration of chloroform-induced hepato- and nephrotoxicity by n-hexane, methyl n-butyl ketone, and 2,5-hexanedione

Organism and molecular-level responses of superoxide dismutase interaction with 2-pentanone

2-Pentanone is an excellent organic solvent and extractant, which is widely used in industrial production. 2-Pentanone is harmful to soil organisms when it enters the soil. However, current studies have not clarified the response of the antioxidant enzyme superoxide dismutase (SOD) to 2-Pentanone and its mechanism. In this study, the response of earthworm antioxidant enzyme SOD to 2-Pentanone and its molecular mechanism was investigated at organism molecular levels. The results showed that the SOD activity of earthworms under 2-Pentanone stress was significantly inhibited, and the inability of superoxide anion radicals (·O₂^-) to be scavenged in time might be one of the reasons for the increase of lipid peroxidation. Under 2-Pentanone exposure conditions, catalase (CAT), an antioxidant enzyme closely related to SOD, and the total antioxidant capacity (T-AOC) of earthworms were activated to resist oxidative damage. On the other hand, the observation of earthworm microstructure provided evidence of a direct risk of 2-Pentanone on earthworm body wall tissues. Molecular-level assays have shown that 2-pentanone altered the secondary structure of SOD, which further led to the loosening of the SOD backbone structure and the extension of the polypeptide chain. On the other hand, 2-pentanone quenched the endogenous fluorescence of SOD in the form of static quenching and formed the 2-pentanone/SOD complex. Molecular simulation results suggested that 2-pentanone tended to bind on the surface of SOD rather than close to the active site, and it is speculated that the alteration of SOD structure is the key reason for the change in its activity. This study enriches the toxicological data of 2-Pentanone on soil organisms, thus responding to the current concerns about its ecological risk.

Poly(ethylene glycol)s With a Single Cinnamaldehyde Acetal Unit for Fabricating Acid-Degradable Hydrogel

A synthetic route to prepare a poly(ethylene glycol) with a single cinnamaldehyde acetal unit in the polymer chain, was successfully established using a newly synthesized cinnamaldehyde acetal diethylene glycol (CADEG) as initiator. This HO-PEG(ca)-OH is non-toxic and would be degraded into a cinnamaldehyde and two PEG diols in acid environment. A whole polyethylene glycol based hydrogel was easily fabricated by thiol-ene “click” reaction in alkalescence aqueous solution using acrylate-PEG(ca)-acrylate and 4-arm PEG-SH as raw materials at room temperature. The gel time was dependent on the pH of the solution and its alkalinity can promote gel. The hydrogel can be degradable in acidic conditions and the stronger the acidity, the faster the degradation. This HO-PEG(ca)-OH also can be used in synthesis of cinnamaldehyde containing PEG derivatives, block copolymers or other acid degradable materials.

Chlorinated methanes and liver injury: highlights of the past 50 years

The chlorinated methanes, particularly carbon tetrachloride and chloroform, are classic models of liver injury and have developed into important experimental hepatoxicants over the past 50 years. Hepatocellular steatosis and necrosis are features of the acute lesion. Mitochondria and the endoplasmic reticulum as target sites are discussed. The sympathetic nervous system, hepatic hemodynamic alterations, and role of free radicals and biotransformation are considered. With carbon tetrachloride, lipid peroxidation and covalent binding to hepatic constituents have been dominant themes over the years. Potentiation of chlorinated methane-induced liver injury by alcohols, aliphatic ketones, ketogenic compounds, and the pesticide chlordecone is discussed. A search for explanations for the potentiation phenomenon has led to the discovery of the role of tissue repair in the overall outcome of liver injury. Some final thoughts about future research are also presented.

Toxicokinetics of organic solvents: a review of modifying factors

This article reviews, with an emphasis on human experimental data, factors known or suspected to cause changes in the toxicokinetics of organic solvents. Such changes in the toxicokinetic pattern alters the relation between external exposure and target dose and thus may explain some of the observed individual variability in susceptibility to toxic effects. Factors shown to modify the uptake, distribution, biotransformation, or excretion of solvent include physical activity (work load), body composition, age, sex, genetic polymorphism of the biotransformation, ethnicity, diet, smoking, drug treatment, and coexposure to ethanol and other solvents. A better understanding of modifying factors is needed for several reasons. First, it may help in identifying important potential confounders and eliminating negligible ones. Second, the risk assessment process may be improved if different sources of variability between external exposures and target doses can be quantitatively assessed. Third, biological exposure monitoring may be also improved for the same reason.

Effect of dosing vehicle on the hepatotoxicity of CCl4 and nephrotoxicity of CHCl3 in rats

There are conflicting results in the literature concerning the effect of gavage vehicle, corn oil (CO) versus aqueous suspension, on the toxicity of haloalkanes. The purpose of our study was to assess the influence of oral dosing vehicle on the acute hepatotoxicity of CCl4 and nephrotoxicity of CHCl3. Male Sprague-Dawley rats, fed ad libitum, were treated (po) with single doses of CCl4 or CHCl3 using corn oil (CO), or an aqueous preparation (5%) of Emulphor (EL620) or Tween-85 (Tw-85) as vehicle (10 ml/kg). Rats were killed 48 h after treatment. Blood was collected for plasma alanine aminotransferase (ALT) determination and renal cortical slices were prepared for p-aminohippuric acid (PAH) incorporation. The comparison, between gavage vehicles, of the slopes and ED50 of the dose-response curves, although not significantly different, indicated clear trends for enhanced potency with CO for CHCl3 nephrotoxicity but not for CCl4 hepatotoxicity. However, ALT values, a measure of the severity of effect for CCl4, also indicated that CO, when compared to EL620 and Tw-85, tended to enhance CCl4 hepatotoxicity at low toxicity incidence. Furthermore, CO clearly enhanced the severity of effect for CHCl3 nephrotoxicity, as measured by the slice-to-medium PAH ratios, at high dosage. The greater severity of the lesion produced by exposure to these chemicals, when administered in CO, is consistent with the trends observed for their potency (dose-response curves). Our results agree with an increased toxicity of haloalkanes by the gavage vehicle CO reported in the literature. Thus, CO should be considered a potential confounder in hepato- and nephrotoxicity assays.

Ketone potentiation of haloalkane-induced hepato- and nephrotoxicity. I. Dose-response relationships

Carbon tetrachloride (CCl4) induced hepatotoxicity and chloroform (CHCl3) induced nephrotoxicity were evaluated in male Sprague-Dawley rats pretreated with acetone (A), methyl ethyl ketone (MEK), and methyl isobutyl ketone (MiBK). Dose-response relationships for A, MEK, and MiBK potentiation of CCl4-induced hepatotoxicity and CHCl3-induced nephrotoxicity were compared. A, MEK, and MiBK pretreatment at a dosage of 6.8 mmol/kg, given daily for 3 d, markedly potentiated CCl4-induced liver toxicity as indicated by a decrease in the CCl4 ED50 to 3.4, 4.6, and 1.8 mmol/kg, respectively, compared to vehicle-pretreated rats (17.1 mmol/kg). Similarly, pretreatment with these ketones (13.6 mmol/kg) potentiated CHCl3 kidney toxicity but to a lesser degree; CHCl3 ED50 values for vehicle-, A-, MEK-, and MiBK-pretreated rats were 3.4, 1.6, 2.1, and 2.2 mmol/kg, respectively. Our results indicate a potency ranking profile for the potentiation of CCl4 hepatotoxicity of MiBK > A > MEK and of A > MEK > or = MiBK for CHCl3 nephrotoxicity. These dissimilar ranking profiles could be due to differences in mechanisms of action for the two target sites.

Tissue concentrations of methyl isobutyl ketone, methyl n-butyl ketone and their metabolites after oral or inhalation exposure

Quantitative relationships between plasma, liver and lung methyl isobutyl ketone (MiBK) and methyl n-butyl ketone (MnBK) concentrations after oral or inhalation exposure were established. Their respective metabolites (4-methyl-2-pentanol, 4-hydroxy-methyl isobutyl ketone, 2-hexanol, and 2,5-hexanedione) were also quantified. Male Sprague-Dawley rats were exposed for 3 days to MiBK or MnBK vapors (4 h/day) or treated orally for 3 days with a MiBK- or MnBK-corn oil solution. Both ketones and their respective metabolites in plasma or tissue concentrations were determined by gas chromatography. MiBK and MnBK plasma and tissue concentrations increased in a dose-related manner with the administered dose irrespective of the route of administration. Metabolite concentrations, however, were influenced by the route of administration.

Toxicology studies of a chemical mixture of 25 groundwater contaminants: hepatic and renal assessment, response to carbon tetrachloride challenge, and influence of treatment-induced water restriction

Because groundwater contamination is an important environmental concern, we examined the hepatic and renal effects of repeated exposure to a mixture of 25 chemicals frequently found in groundwater near hazardous-waste disposal sites and the effect of such exposure on carbon tetrachloride (CCI4) toxicity. Adult male F-344 rats received ad libitum deionized water and feed (Ad Lib Water) or ad libitum 10% MIX (referring to 10% of a technically achievable stock mixture) and feed for 14 d. Because exposure to the 25-chemical mixture via the drinking water resulted in decreased water and feed consumption, restricted deionized water and feed controls (Restricted Water) were included. On d 14, rats were gavaged with 0, 0.0375, 0.05, 0.075 or 0.15 ml CCl4/kg, and hepatic and renal toxicity assessed 24 h later. Little or no hepatic and renal toxicity was observed in rats exposed to 10% MIX alone. No hepatic or renal lesions occurred that could be attributed to 10% MIX alone. Slight but statistically significant alterations, of uncertain biological significance, resulted from the water treatments: 10% MIX increased alanine aminotransferase, urea nitrogen (BUN), and BUN/creatinine ratio; Restricted Water increased 5'-nucleotidase and decreased alkaline phosphatase. Relative kidney weight was increased by both 10% MIX and Restricted Water. CCI4 resulted in significant dosage-dependent hepatotoxicity in all three water treatment groups but had little or no effect on renal indicators of toxicity. Relative to Ad Lib Water, significantly greater hepatotoxicity occurred in both 10% MIX and Restricted Water rats. The response to CCI4 in the Restricted Water rats was similar to that of 10% MIX rats, indicating that a substantial portion of the effect of 10% MIX on CCI4 hepatotoxicity is due to decreased water and feed intake.

Dichloroacetic acid and trichloroacetic acid increase chloroform toxicity

Dichloro- and trichloroacetic acids (DCA and TCA) and chloroform are formed during chlorination disinfection of drinking water. The effects of DCA and TCA treatment on CHCl3 toxicity were assessed in these studies. Male and female rats were gavaged with DCA or TCA (0.92 and 2.45 mmol/kg administered 3 times over 24 h). Three hours after the last dose CHCl3 was injected ip (0.75 mg/kg). Male rats experienced some weight loss (15%) and slight increases of ALT and BUN, but there were no effects of either DCA or TCA on any of these responses. In females, CHCl3 increased plasma ALT and this response was greater (up to threefold) in the DCA group, compared to saline controls. Similarly, BUN was increased by CHCl3 and this was more severe (up to threefold) in both the DCA and TCA pretreated groups. These results show that CHCl3 toxicity is increased by DCA and TCA, and this effect is gender-specific, occurring only in females. DCA increases both liver and kidney toxicity, whereas TCA affects only kidney toxicity.

Potentiation of lithocholic-acid-induced cholestasis by methyl isobutyl ketone

Methyl isobutyl ketone was found to potentiate intrahepatic cholestasis induced by taurolithocholate and the combination of manganese-bilirubin. The aim of this study was to elucidate the mechanism of this potentiation using the lithocholate-induced cholestasis model. Male rats were given methyl isobutyl ketone 7.5 mumol/kg body wt. daily for 3 days. The effect of this treatment on lithocholate-induced cholestasis, bile formation and taurocholic acid transport was examined. The data showed that methyl isobutyl ketone treatment potentiated lithocholate-induced cholestasis and reduced significantly bile salt, phospholipid and cholesterol secretion rates as well as the transport maximum of taurocholic acid. It is suggested that methyl isobutyl ketone potentiates lithocholate-induced cholestasis by reducing the bile salt pool and interfering with the haptic secretion rate of bile salts.

Immunochemical detection of cytochrome P450 isozymes induced in rat liver by n-hexane, 2-hexanone and acetonyl acetone

Cytochrome P450 isozymes induced in rat liver by treatment with n-hexane, 2-hexanone and acetonyl acetone (given intraperitoneally 5 mmol/kg for 4 days) were investigated using enzyme assays (benzene, toluene, 7-ethoxyresorufin and 7-pentoxyresorufin metabolism) and monoclonal antibodies (anti-P450IA1/2, anti-P450IIB1/2, anti-P450IIC11/6, anti-P450IIE1(91) and anti-P450IIE1(98)). n-Hexane treatment enhanced the activities of low-Km benzene aromatic hydroxylase and toluene side-chain oxidase, but not 7-ethoxyresorufin O-deethylase or 7-pentoxyresorufin O-depentylase. 2-Hexanone or acetonyl acetone treatment enhanced the activities of low- and high-Km benzene aromatic hydroxylases, toluene side-chain oxidase and 7-pentoxyresorufin O-depentylase, but not of 7-ethoxyresorufin O-deethylase. Immunoblot analysis showed that anti-P450IA1/2 did not bind liver microsomal protein from either control and treated rats in the region of cytochrome P450s, whereas with anti-P450IIE1(98) a clear-cut band was seen in liver microsomes from control and treated rats, with intensities in the following order: 2-hexanone = acetonyl acetone greater than or equal to n-hexane greater than control greater than phenobarbital. With anti-P450IIB1/2, a band was detected in microsomes from phenobarbital-treated rats, and to a lesser extent, in microsomes from 2-hexanone- and acetonyl acetone-treated rats. Like the immunoblot analysis, anti-P450IIE1(91) inhibited toluene side-chain hydroxylase activity in all microsomes, except in preparations from phenobarbital-treated rats and anti-P450IIB1 in microsomes from phenobarbital-, 2-hexanone- and acetonyl acetone-treated rats.(ABSTRACT TRUNCATED AT 250 WORDS)

Morphological and biochemical analyses of trichloroethylene hepatotoxicity: differences in ethanol- and phenobarbital-pretreated rats

The histological and biochemical differences between ethanol- and phenobarbital (PB)-potentiated hepatotoxicity of trichloroethylene (TRI) in Wistar strain male rats were investigated. Both ethanol (2 g in daily liquid diet for 3 weeks) and PB (80 mg/kg/day for 4 days, ip) pretreatments enhanced TRI (inhalation exposures of 500 ppm for 8 hr, 2000 ppm for 2 or 8 hr, and 8000 ppm for 2 hr)-induced hepatic damage as judged by increases in plasma transaminase activities. Livers from PB-treated rats exposed to TRI displayed centrilobular necrosis, whereas livers from ethanol-treated rats exposed to TRI were characterized by ballooning degeneration mainly in midzonal areas. TRI exposure decreased the in vitro metabolism of TRI, high-Km benzene aromatic hydroxylase (BAH) activity, and cytochrome P450 content in livers of PB-treated rats with severe hepatic damage. In ethanol-treated rats, TRI exposure increased both the in vitro metabolism of TRI and the low-Km BAH activity but did not cause an apparent decrease in cytochrome P450 content even in animals with severe hepatic damage. These results suggest that TRI caused necrosis of centrilobular hepatocytes in PB-pretreated rats, which was accompanied by loss of xenobiotic metabolizing functions, whereas ballooning degeneration of hepatocytes mainly in midzonal areas occurred in ethanol-pretreated rats without loss of xenobiotic metabolizing functions.

Critical review of the toxicity of methyl n-butyl ketone: risk from occupational exposure

Methyl n-butyl ketone (MBK) was considered rather harmless until an outbreak of peripheral neuropathy occurred in 1973 among workers exposed to MBK. MBK easily penetrates the skin; pulmonary retention is approximately 80-85% in man. Distribution is widespread with highest levels in blood and liver; MBK also reaches the fetal tissues. MBK metabolism probably depends on the route of exposure, and is very similar to that of n-hexane. The critical organ is the nervous system. These effects find expression as peripheral neuropathy, with potential for serious effects of the central nervous system. From the viewpoint of neurotoxicity, 2,5-hexanedione is the most important metabolite. The neurotoxicity is potentiated by several compounds, while MBK itself potentiates the toxicity of other chemicals. From animal experiments, a no-adverse-effect level (NAEL) could not be established. Peripheral neuropathy may develop in workers exposed to only a few ppm of MBK. The difference in the Occupational Exposure Limits for MBK and n-hexane, as established by several organizations, is questioned in view of the neurotoxic effects of these substances.

Effects of acetone and methyl n-butyl ketone on hepatic mixed-function oxidase

The administration of ketones potentiates CCl4 hepatotoxicity; however, the potencies of the ketones differ. The aim of the present study was to assess potential differences between acetone and methyl n-butyl ketone (MnBK) on cytochrome P-450. The effects of single and repetitive doses of acetone and MnBK were determined in male rats by estimating the rate of metabolite formation of three substrates and the hepatic content of cytochrome P-450. A single treatment with acetone (13.5 mmol/kg or greater) enhanced the oxidation of aniline and 7-ethoxycoumarin, whereas repetitive treatments also increased aminopyrine demethylation and cytochrome P-450 content. Single and repetitive treatments of MnBK (15 mmol/kg) augmented the oxidation of all three substrates and increased cytochrome P-450 content. The effects of the ketones on cytochrome P-450 isozymes were characterized using sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Acetone and MnBK increased the 52.1 and 54.1 kD forms and, in addition, MnBK tended to increase the 50.6 kD species. The data indicate that ketones differ in the type of isozymes induced and in the degree of induction. The higher potency of MnBK, compared to acetone, is probably associated with the fact that MnBK affects a greater number of isozymes than acetone.

Hepatotoxic effects elicited by n-hexane or n-heptane

Hepatotoxic effects of n-hexane and n-heptane administered i.p. (1 ml/kg body wt) were studied in albino rats after 1, 2, 7 and 45 days of treatment. Hepatic protein content decreased with n-heptane and total sulphydryl content showed a significant decrease in the rats exposed to either solvent. A significant increase in lipid peroxidation was observed after 24 h and 48 h exposure to n-hexane or n-heptane. A marked decrease in drug metabolizing activity and an increase in pentabarbitone sleeping time was also observed. Hepatic glucose-6-phosphatase, a microsomal marker enzyme, showed a significant decrease.

Amplification of chloroform hepatotoxicity and lethality by dietary chlordecone (kepone) in mice

Male Swiss Webster mice (25-30 g) maintained on powdered control diet, or on diets containing chlordecone (CD, 10 ppm), mirex (M, 10 ppm), or phenobarbital (PB, 225 ppm) were used in this study. At these low levels, chlorinated hydrocarbon pesticides are not toxic, they neither affect food or water consumption, nor the body weight of mice. After a 15-day dietary protocol, a single challenge dose of CHCl3 (0.1 ml/kg) was administered intraperitoneally in corn oil vehicle. Liver damage was assessed 24 hours later using serum aspartate aminotransferase (AST) and alanine aminotransferase (ALT) activities, histopathology, and lethality. For comparison, serum enzymes were measured in a separate group of mice receiving a high dose of CHCl3 (1.0 ml/kg) alone. None of the dietary treatments alone affected any of the serum transaminases. The serum enzymes were remarkably elevated in the mice treated with CD and CHCl3. A high dose of CHCl3 (1.0 ml/kg) elevated the serum enzymes more than 10-fold over those in the mice fed normal diet receiving only the corn oil vehicle. The histopathology of the liver indicated midzonal necrosis typical of liver injury from CHCl3 and depletion of PAS positive glycogen deposits. These effects were not evident in mice treated with 0.1 ml/kg CHCl3 alone. Additional histological alterations in the livers of the CD + CHCl3 group include the degenerated cells, loss of basophilic staining characteristics, and an increased degree of cytoplasmic vacuolation. The amplification of CHCl3 hepatotoxicity by CD was also reflected by a 4.2-fold increase in lethality determined by 48-hour LD50.(ABSTRACT TRUNCATED AT 250 WORDS)

Potentiation by methyl isobutyl ketone of the cholestasis induced in rats by a manganese-bilirubin combination or manganese alone

Haloalkane-induced hepatonecrogenesis can be potentiated by the prior administration of methyl isobutyl ketone (MIBK). In a previous study, MIBK was shown to potentiate the cholestasis induced by taurolithocholate in rats. We investigated the possibility that this ketone could potentiate the cholestasis induced by a combination of manganese and bilirubin (Mn-BR) or by manganese alone in rats. Dosages varying from 1.88 to 15 mmol/kg MIBK were administered once, 18 hr prior to the administration of the cholestatic Mn-BR combination. The cholestatic effect of the manganese-bilirubin combination is enhanced with dosages of MIBK of 3.75 mmol/kg and more. Daily ketone pretreatment for 3 days resulted in an increased response to the cholestatic challenges of either Mn-BR or Mn alone. MIBK per se is devoid of cholestatic properties, since the bile flow measured prior to the cholestatic challenge is not decreased and in some cases is significantly greater than that from vehicle-pretreated animals. These results show that MIBK can potentiate cholestatic as well as necrogenic forms of hepatotoxicity.

Correlation between acetone-potentiated CCl4-induced liver injury and blood concentrations after inhalation or oral administration

In studies of acetone-potentiated liver injury induced by haloalkanes, acetone is usually given by gavage, whereas industrial exposure to acetone normally occurs by inhalation. It was of interest to verify if the route of administration influences the potentiation. Male Sprague-Dawley rats were exposed for 4 hr to acetone vapors or treated orally with acetone; the minimal effective dose (MED) levels for potentiating CCl4-induced liver injury were estimated to be 2500 ppm and 0.25 ml/kg, respectively. Groups were treated with acetone using 0.4, 1, 2, 4, or 6 times the MED. Half of each group was killed at various time intervals after treatment for blood acetone measurements by gas chromatography; the other half was challenged with CCl4 (0.1 ml/kg, ip) 18 hr after acetone, and killed 24 hr later. Plasma alanine aminotransferase (ALT) activity and bilirubin concentrations were measured. Inhalation and oral administration of acetone both potentiated CCl4 toxicity. Rats exposed repetitively to acetone vapors (10 daily exposures) and subsequently challenged with CCl4 exhibited liver toxicity that was not significantly different from that of rats subjected to a single exposure. Correlations between ALT activities and maximal blood acetone concentrations were found to be linear (positive) and significant for both routes. For a given blood acetone concentration, however, toxicity was least severe following acetone exposure by inhalation. When the concept of threshold concentrations was applied to the data, the severity of the toxic response was dependent on the blood acetone concentration above the threshold, irrespective of the route of administration.

Renal and hepatic interactions between 2-hexanone and carbon tetrachloride in F-344 rats

Fisher-344 rats were pretreated with 2-hexanone (HX) and challenged with carbon tetrachloride (CCl4) in a replicated 3 X 4 factorial experiment to determine if HX potentiated CCL4-induced renal and hepatic damage. Rats given both HX and CCl4 demonstrated more severe hepatic injury at 24 and 48 h than did controls. However, in contrast to our experience with chloroform (CHCl3), CCl4-induced renal injury in HX-pretreated rats was only slightly greater than in vehicle-pretreated controls.

Taurolithocholate-induced intrahepatic cholestasis: potentiation by methyl isobutyl ketone and methyl n-butyl ketone in rats

Haloalkane-induced hepatonecrogenesis can be potentiated by the prior administration of methyl isobutyl ketone (MIBK) and methyl n-butyl ketone (MBK). We investigated the possibility that these ketones could potentiate the cholestasis induced by taurolithocholate (TLC) in rats. Daily ketone pretreatment for 3 or 7 days resulted in an enhancement of the diminution in bile flow observed after TLC challenge. When the ketones were administered without TLC challenge, cholestasis was not observed; in fact, slight increases in bile flow did occur. The data suggest that MIBK may be more effective than MBK as a potentiator. Preliminary experiments with 2,5-hexanedione (HD), a metabolite of MBK and a potent potentiator of haloalkane hepatonecrosis, were included in the study. HD appeared to be a less potent potentiator of TLC-induced cholestasis. Although some ketones can potentiate cholestatic as well as hepatonecrogenic reactions, different mechanisms of action appear to be involved in these two phenomena.

The joint neurotoxic action of inhaled methyl butyl ketone vapor and dermally applied O-ethyl O-4-nitrophenyl phenylphosphonothioate in hens: potentiating effect

The neurotoxic action of inhaled technical grade methyl butyl ketone and dermally applied (O-ethyl O-4-nitrophenyl phenylphosphonothioate (EPN) was studied. Three groups of five hens each were treated 5 days/week for 90 days with a dermal dose of 1.0 mg/kg of EPN (85%) on the unprotected back of the neck. These groups were exposed simultaneously to 10, 50, or 100 ppm of technical methyl butyl ketone (MBK; methyl n-butyl ketone:methyl isobutyl ketone, 7:3) in inhalation chambers. A fourth group was treated only with the dose of EPN and a fifth group with only 100 ppm MBK. The control consisted of a group of five hens treated with a dose of 0.1 ml acetone. Treatment was followed by a 30-day observation period. Simultaneous exposure to EPN and MBK greatly enhanced the neurotoxicity produced when compared to the neurotoxicity produced by either chemical when applied alone. Continued exposure to EPN and MBK resulted in earlier onset and more severe signs of neurotoxicity than exposure to either individual compound. The severity and characteristics of histopathologic lesions in hens given the same daily dermal dose of EPN in combination with inhaled MBK depended on the MBK concentration. Histopathologic changes were more severe and prevalent in the 100 ppm MBK:1 mg/kg EPN group than in the others. In this group, Wallerian-type degeneration was seen along with paranodal axonal swellings. The morphology and distribution of these lesions were characteristic of those induced by MBK. In the 50 ppm MBK:1 mg/kg EPN group axonal swelling was evident but not clearly identifiable as paranodal. Hens treated with 10 ppm MBK:1 mg/kg EPN had minimal lesions with low incidence of axonal swellings. These were not as large as those seen in MBK neurotoxicity, but instead resembled the histopathologic lesions caused by EPN. The results indicate that the combined treatment gave a value for neurotoxicity coefficient which was two times the additive neurotoxic effect of each treatment alone. Pretreatment with three daily ip doses of 5 mmol/kg technical grade MBK or methyl n-butyl ketone (MnBK), equally increased chicken hepatic microsomal cytochrome P-450 content. Also, hepatic microsomes from MBK-treated hens metabolized [14C]EPN in vitro to [14C]EPN oxon to a much greater extent than those from control hens. These results suggest that MBK potentiates the neurotoxic effect of EPN, at least in part, by increasing the metabolic activation of EPN to the more neurotoxic metabolite EPN oxon.(ABSTRACT TRUNCATED AT 400 WORDS)

Role of intrarenal biotransformation in chloroform-induced nephrotoxicity in rats

Various ketonic agents potentiate the hepatic and renal toxicity of halogenated solvents in mice and rats. Characteristics of CHCl3 nephrotoxicity and of 2-hexanone potentiation were evaluated in adult male Fischer 344 rats pretreated with vehicle (oil, 10 ml/kg, po) or 2-hexanone (10 mmol/kg, po) 18 hr prior to CHCl3 exposure. In contrast to the liver, little metabolism of 14CHCl3 by renal cortical microsomes from vehicle- or 2-hexanone-pretreated rats was detected. However, CHCl3 produced a concentration-related dysfunction when added to renal cortical slices from Fischer 344 or Sprague-Dawley rats. The degree of CHCl3 toxicity in vitro was not altered when renal cortical slices were preincubated with CHCl3 (8.5 microliter) under an atmosphere of carbon monoxide. In renal cortical slices, deuterated-CHCl3 was less toxic than CHCl3. Although 2-hexanone pretreatment increased renal slice metabolism of 14CHCl3 twofold, this increase was not associated with an increase in nephrotoxicity after direct exposure of slices to CHCl3 (0 to 10 microliter) in vitro. CHCl3 (0.5 ml/kg, ip) did not alter renal cortical glutathione concentrations in vehicle or 2-hexanone pretreated rats. The association of 14CHCl3-derived radiolabel was increased over control by 2-hexanone pretreatment in protein, lipid, and acid soluble fractions from the renal cortex by approximately two-, two-, and fivefold, respectively. In conclusion, renal cytochrome P-450 did not appear to mediate CHCl3 metabolism and nephrotoxicity in the rat to the extent observed previously in mice. 2-Hexanone appeared to potentiate nephrotoxicity by a mechanism different than that observed in rat liver.

Temporal analysis of rat liver injury following potentiation of carbon tetrachloride hepatotoxicity with ketonic or ketogenic compounds

The administration of some ketonic or ketogenic compounds prior to a challenging dose of CCl4 potentiates the hepatic damage induced by this haloalkane. However, nothing is known about the recovery from the liver injury in these cases of chemically induced potentiation. To investigate this problem, we performed a temporal analysis of the hepatotoxic response of male Sprague-Dawley rats to CCl4 following a single pretreatment (p.o.) with: n-hexane, 2-hexanone, 2,5-hexanedione (15 mmol/kg in corn oil), isopropanol, acetone (33 and 34 mmol/kg in water, respectively); or the vehicle alone (10 ml/kg). They received, 18 h later, an i.p. injection of CCl4 (0.1, 0.75 or 1.0 ml/kg) and were killed 24-120 h later. Liver damage was assessed biochemically (ALT, OCT) and morphologically. A good correlation between biochemical and morphological results was observed. The ketonic or ketogenic compounds studied potentiated the liver injury produced by 0.1 ml/kg CCl4. Relative ranking orders regarding severity of maximal hepatic damage induced and time needed for complete recovery of liver injury were established; time of recovery was dependent on the maximal severity of the lesion, regardless of the potentiation. The results show that the temporal evolution of CCl4-induced liver injury is not markedly influenced by the administration of ketonic or ketogenic compounds as pretreatments, but rather depends on the severity of the maximal damage induced by the overall treatment.

Dose-response relationships in ketone-induced potentiation of chloroform hepato- and nephrotoxicity

Chloroform (CHCl3)-induced hepato- and nephrotoxicity was evaluated in male, Fischer 344 rats pretreated with various dosages (1.0 to 15.0 mmol/kg, po) of acetone (Ac), 2-butanone (Bu), 2-pentanone (Pn), 2-hexanone (Hx), or 2-heptanone (Hp). The CHCl3 challenge dosage (0.5 ml/kg, ip) produced slight centrilobular hydropic degeneration and patchy degeneration and necrosis in the proximal tubules of corn oil-pretreated rats. Each of the ketones studied produced a dose-related potentiation of CHCl3 liver and kidney injury. CHCl3 produced extensive tubular and centrilobular necrosis when administered to ketone-pretreated rats. The relationship between ketone dosage and the magnitude of the potentiated response was nonlinear. Maximum potentiation of CHCl3 toxicity occurred in the dosage range of 5.0 to 10.0 mmol ketone/kg. Ketone dosages greater than 10.0 mmol/kg were associated with a reduction in the degree of CHCl3 injury. At the lowest ketone dosage (1.0 mmol/kg), potentiating capacity appeared to be related to ketone carbon skeleton length. No differences in potentiating capacity were discernable between the ketones at dosages of 5.0 to 10.0 mmol/kg. Thus, whether or not there is a relationship with carbon chain length and potentiation depends upon the dosage of the ketone.

Uptake, distribution, metabolism, and elimination of styrene in man. A comparison between single exposure and co-exposure with acetone

Six male subjects were exposed for two hours during light physical exercise to 2.81 mmol/m3 (293 mg/m3) of styrene on one occasion and to a mixture of 2.89 mmol/m3 (301 mg/m3) of styrene and 21.3 mmol/m3 (1240 mg/m3) of acetone on another (combination study). About 68% of the dose (somewhat more than 4 mmol) of styrene was taken up. The arterial blood concentration of styrene reached a relatively stable level after about 75 minutes of exposure of about 18 and 20 mumol/l after the single and combined exposure, respectively. Calculated values of mean blood clearance were 1.9 l/min in the styrene study and 1.6 l/min in the combination study; the half life of styrene in blood was about 40 minutes in both studies. The concentration of non-conjugated styrene glycol increased linearly during exposure and reached about 3 mumol/l at the end of exposure and was eliminated with a half life of about 70 minutes. Styrene-7,8-oxide was detected and quantified in the blood in a complementary study. The half lives for the excretion of mandelic and phenylglyoxylic acid in the urine were about four and nine hours, respectively, in both studies.

Mechanisms in 2-hexanone potentiation of chloroform hepatotoxicity

2-Hexanone (2-Hx) is known to potentiate chloroform (CHCl3) hepatotoxicity in part by increasing the bioactivation of CHCl3 to phosgene (COCl2). Treatment of rats with 2-Hx + CHCl3 in vivo did not initiate peroxidation of hepatic fatty acids as determined by formation of conjugated dienes or depletion of unsaturated fatty acids, or as determined by production of malondialdehyde (MDA) in vitro. A 5-fold decrease in the specific activity of succinate-dependent cytochrome c reductase in liver from rats treated in vivo with corn oil (vehicle) + CHCl3 and in rats treated with 2-Hx + CHCl3 indicated that a mechanism independent of CHCl3 bioactivation may add to the hepatotoxic effects which result from the metabolism of chloroform to phosgene.

Effect of chloroform on hepatic and renal DNA synthesis and ornithine decarboxylase activity in mice and rats

Chloroform administered intraperitoneally (i.p.) to male mice and rats resulted in a dose-dependent increase in hepatic ornithine decarboxylase (ODC) activity. Maximal induction of the enzyme in mice was 10-fold and occurred at 375 mg/kg chloroform; in rats it was 52-fold and occurred at 750 mg/kg chloroform. Chloroform increased in mice and decreased in rats the rate of hepatic and renal DNA synthesis. Therefore, the induction of ODC activity in rat liver was not followed with an increase in DNA synthesis. The implications of these results to the proposed nongenetic mechanism of chloroform induction of hepatocellular carcinoma in mice and renal tumors in rats are discussed.

2-hexanone potentiation of [14C]chloroform hepatotoxicity: covalent interaction of a reactive intermediate with rat liver phospholipid

Rats were treated with [14C]chloroform (14CHCl3) in corn oil (CO) or corn oil alone 18 hr following pretreatment with 2-hexanone (2-HX) in corn oil or corn oil alone. Livers were removed, homogenized 1,2, and 6 hr post-14CHCl3 administration, and glutathione (GSH) content, irreversible binding of 14CHCl3-derived radiolabel, and phospholipid composition were determined. The combination of 2-HX + CHCl3 reduced GSH content to 21% of control (CO + CO) 1 hr after CHCl3 administration. No significant rebound of GSH was observed 24 hr post-CHCl3 administration. In contrast, GSH was not altered by administration of CHCl3 to CO-pretreated rats. Although 14CHCl3-derived radiolabel was irreversibly bound to hepatic macromolecules of both CO- and 2-HX-pretreated rats, total irreversibly bound 14C was significantly enhanced in 2-HX-pretreated rats at all time points. The latter observation was consistent with the decrease in GSH of 2-HX-pretreated rats. Total 14C binding in 2-HX-pretreated rats reached a plateau 2 hr post-14CHCl3 administration and was distributed 52% in protein, 41% in lipid, and 7% in acid soluble fractions 6 hr post-14CHCl3 administration. 2-HX enhanced 14C binding to protein and lipid at each time point. Radiolabel was not detected in neutral lipids of control or 2-hexanone-treated animals, but was enhanced 33-fold in phospholipids of 2-hexanone-treated animals. Phospholipid fatty acid methyl ester derivatives did not contain 14C indicating the radiolabel was most likely associated with phospholipid polar head groups. Two dimensional thin layer chromatographic analysis of phospholipid from treated animals demonstrated that 87% of the total radiolabel was associated with a specific phospholipid (14C-PL) which had a 1:1 molar ratio of phosphate to 14C. The latter indicates that the 14C-PL was a monophospholipid derivative of 14CHCl3 reactive intermediate, generally thought to be phosgene. Concurrent decrease in phosphatidylethanolamine content from 23% of total phospholipid to 7%, accumulation of 14C-PL to 2.6% of total phospholipid, and increase in lysophosphatidylethanolamine from 1 to 7% of total phospholipid during 2-hexanone + 14CHCl3 treatment indicated that the amine moiety of phosphatidylethanolamine polar head groups was the probable target of phosgene-lipid interaction, and that a degradative pathway existed which removed the abnormal phospholipid from hepatic membranes. No phospholipid other than phosphatidylethanolamine was depleted. During models studies, 2% phosgene in toluene was reacted with liver phosphatidylethanolamine for 6 hr at 37 degrees C.(ABSTRACT TRUNCATED AT 400 WORDS)

Potentiation of the hepatotoxicity of N-nitrosodimethylamine by fasting, diabetes, acetone, and isopropanol

Previous studies indicate that pretreatment with acetone or isopropanol, fasting, and streptozotocin-induced diabetes enhance hepatic microsomal nitroso-dimethylamine (NDMA) demethylase in rats. This study demonstrates that these same treatments also potentiate the hepatotoxicity of NDMA as indicated by plasma glutamic pyruvate transaminase (GPT) levels and histologic data. Pretreatment with acetone or isopropanol (2.5 ml/kg) and 2 days of fasting caused a 2-fold potentiation of NDMA-induced plasma GPT elevation, whereas streptozotocin-induced diabetes caused a 4.6-fold potentiation. The centrilobular necrosis produced by NDMA was more severe after pretreatment with the inducers. NDMA treatment also decreased hepatic microsomal demethylase activity. These results lend support to the concept that a NDMA demethylase is responsible for the activation of NDMA in vivo to a toxic intermediate, and induction of this enzyme activity potentiates NDMA hepatotoxicity.

Chemically induced nephrotoxicity: role of metabolic activation

Renal xenobiotic metabolism can result in production of electrophiles or free radicals that may covalently bind macromolecules or initiate lipid peroxidation. The mechanisms of renal xenobiotic metabolism may vary in different anatomical regions. Kidney cortex contains a cytochrome P-450 system while medulla contains a prostaglandin endoperoxidase. Recently cysteine conjugated-lyase has been implicated in production of reactive intermediates. Metabolic activation may be amplified by accumulation of xenobiotics within renal cells due to tubular concentrating and/or secretory mechanisms. Additionally, renal xenobiotic detoxicification can occur by conjugation with glucuronide, sulfate or glutathione.

Comparison of the effects of methyl-N-butyl ketone and phenobarbital on rat liver cytochromes P-450 and the metabolism of chloroform to phosgene

It was previously shown that treatment of rats with methyl-n-butyl ketone (MBK) produced an increase in the total level of liver microsomal cytochromes P-450 and an increase in the rate of metabolism of chloroform (CHCl3) to phosgene (COCl2). In the present study it was found that MBK also produced qualitative changes in the composition of microsomal cytochromes P-450 in rat liver as determined by anion-exchange chromatography. The degree of the chromatographic changes paralleled the effect of MBK on the rate of metabolism of CHCl3 to COCl2 and CHCl3-induced hepatotoxicity, suggesting that MBK potentiated the hepatotoxicity of CHCl3, at least in part, by inducing the formation of cytochromes P-450 that metabolized CHCl3 to the hepatotoxin COCl2. In this regard, reconstitution studies with a form of cytochrome P-450 isolated from rat liver microsomes from rats treated with MBK or phenobarbital (Pb) showed unequivocally that cytochrome P-450 can metabolize CHCl3 to COCl2. Although analysis of rat liver microsomes by SDS-polyacrylamide electrophoresis and anion-exchange chromatography suggested that MBK and Pb had similar effects on the composition of cytochromes P-450, metabolism studies indicated that differences did exist.

Relationship between the carbon skeleton length of ketonic solvents and potentiation of chloroform-induced hepatotoxicity in rats

Previous studies have suggested that ketonic solvents potentiate the hepatotoxic action of CHCl3 in rats. In addition, the relative potentiating capacity of the ketones appeared to be related to the length of their carbon skeleton. To test this hypothesis CHCl3-induced liver injury was evaluated in male Sprague-Dawley rats pretreated (15 mmol/kg, p.o.) with acetone (Ac), 2-butanone (Bu), 2-pentanone (Pn), 2-hexanone (Hx) or 2-heptanone (Hp). After 18 h, a challenging dose of CHCl3, (0.50 or 0.75 ml/kg, i.p.) was given. Liver damage was evaluated 24 h after CHCl3 administration by determining elevations in plasma GPT and OCT activity. Neither Ac, Bu, Pn, Hx, Hp or the CHCl3 challenging dosages produced marked liver injury when given alone. However, each of the ketones potentiated CHCl3-induced liver damage. The severity of the potentiated hepatotoxic response was significantly (positively) correlated with the ketone carbon chain length. These observations suggest that carbon skeleton length may play a role in determining the relative potentiating capacity of ketonic solvents.

Acetone-induced potentiation of trihalomethane toxicity in male rats

The acute hepato- and nephrotoxic potentials of two trihalomethane water contaminants, bromodichloromethane (BrCHCl2) and dibromochloromethane (Br2CHCl), were determined in male Sprague-Dawley rats. Br2CHCl possessed a greater hepatotoxic and lethal potential than BrCHCl2. However, both Br2CHCl and BrCHCl2 were weak hepatotoxicants as compared to a related trihalomethane, CHCl3. Br2CHCl and BrCHCl2 did not produce liver injury until near-lethal dosages were administered. Neither trihalomethane appeared to produce appreciable kidney injury during the 24-h challenge period. Pretreatment of rats with acetone (15 mmol/kg, p.o.) markedly potentiated the hepatotoxic response to BrCHCl2 and Br2CHCl. The potentiated response observed with acetone plus BrCHCl2 or Br2CHCl was equal to or greater than that observed with acetone plus an approximately equimolar dosage of CHCl3. That is, acetone appeared to convert these weak hepatotoxicants into strong hepatotoxicants.

Dose-dependent modification of 1,1-dichloroethylene toxicity by acetone

The ability of acetone to potentiate the toxicity of 1,1-dichloroethylene (DCE) in male rats was investigated. A biphasic potentiation of DCE-induced hepatotoxicity was observed; low doses (5 and 10 mmol/kg, p.o.) of acetone were active, whereas higher doses (15 and 30 mmol/kg) were not. Nephrotoxicity was not affected.

Acetone potentiation of 1,1,2-trichloroethane hepatotoxicity

Acetone potentiation of 1,1,2-trichloroethane (TCEA) hepatotoxicity was found to be strongly dose-dependent for both acetone and TCEA. An oral dose of 0.5 ml of acetone/kg was the most effective potentiating pretreatment when administered 16 h prior to TCEA. Surprisingly, higher doses of acetone did not potentiate the hepatotoxicity of TCEA, but may have decreased the severity of this toxicity. Acetone potentiation of hepatotoxicity was most pronounced at or near the hepatotoxic threshold for TCEA. While acetone treatment alone did not affect hepatic glutathione (GSH) stores the most consistent effect produced by acetone pretreatment was a significant potentiation of TCEA-induced depletion of hepatic GSH. These findings suggest that critical doses of acetone may enhance the subsequent hepatotoxicity of TCEA via mechanisms that affect the interaction of TCEA and hepatic GSH stores.

Role of biotransformation in the potentiation of halocarbon hepatotoxicity by 2,5-hexanedione

2,5-Hexanedione (2,5-HD) pretreatment potentiated CHCl3-induced hepatotoxicity. 2,5-HD significantly increased hepatic cytochrome P-450, NADPH cytochrome c reductase, aniline hydroxylation, p-nitroanisole O-demethylation, and aminopyrine N-demethylation in both male and female mice. 2,5-HD pretreatment potentiated CHCl3-induced centrilobular necrosis and increased serum alanine amino transferase (ALT) activity by 20 times more than CHCl3 alone. Similarly, 2,5-HD pretreatment potentiated CDCl3-induced hepatotoxicity as well as CCl4-induced hepatotoxicity in male mice, but did not potentiate trichloroethylene-, 1,1,2-trichloroethane-, or perchloroethylene-induced hepatotoxicity. In female mice, 2,5-HD pretreatment potentiated CHCl3- and CDCl3-induced hepatotoxicity as well as trichloroethylene-, 1,1,2-trichloroethane-, and carbon tetrachloride-induced hepatotoxicity, but not perchloroethylene-induced hepatotoxicity. 2,5-HD pretreatment had no preferential effect on either CHCl3- or CDCl3-induced hepatotoxicity in females. However, phenobarbital pretreatment did differentiate CHCl3- and CDCl3-induced hepatotoxicity in females. 2,5-HD-induced potentiation of halocarbon hepatotoxicity is sex dependent.

Effects of xylene and xylene isomers on cytochrome P-450 and in vitro enzymatic activities in rat liver, kidney and lung

Rats were exposed for 3 days by inhalation to 2000 ppm of a xylene mixture, or the individual constituents, o-xylene, m-xylene, p-xylene and ethylbenzene. All solvents increased hepatic cytochrome P-450 concentrations and NADPH-cytochrome c reductase activity, although p-xylene did not increase the cytochrome P-450 content as much as the other compounds, showing the importance of the substitution pattern. Increases were observed in the in vitro O-deethylation of 7-ethoxyresorufin and in the hydroxylation of n-hexane and benzo[a]pyrene. The metabolite profiles obtained with these substrates and the results of gel electrophoresis in the presence of sodium dodecyl sulfate indicate that the induction is of the phenobarbital type. In kidney microsomes an increased concentration of cytochrome P-450 was obtained following exposure to a xylene mixture or to o- or m-xylene. The O-deethylation of 7-ethoxyresorufin was increased by exposure to all solvents. In lung microsomes xylene and xylene isomers but not ethylbenzene caused a decrease in cytochrome P-450 content and a reduction in n-hexane hydroxylation. However, the O-deethylation of 7-ethoxyresorufin was not affected. In general the effect of the xylene mixture reflected the content of the dominating component m-xylene. The ability of xylene and xylene isomers to modify the metabolism of other potentially toxic substances in liver, kidney and lung microsomes suggests the possibility of synergistic toxic responses.

Carcinogenicity and mutagenicity of solvents. I. Glycidyl ethers, dioxane, nitroalkanes, dimethylformamide and allyl derivatives

The carcinogenicity and/or mutagenicity as well as structural features and relationships of the glycidylethers (principally phenyl-, butyl-, allyl-, and isopropyl-), dioxane, nitroalkanes (nitro methane, ethane and propane), dimethylformamide and allyl derivatives (chloride, alcohol and amine) were examined. Additionally, considerations of the production, use patterns, estimated populations at risk, TLV's and metabolism of the above agents were discussed.