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

Bromotrichloromethane Hepatotoxicity. The Role of Stimulated Hepatocellular Regeneration in Recovery: Biochemical and Histopathological Studies in Control and Chlordecone Pretreated Male Rats

It has been shown that BrCCl3 is a more potent hepatotoxin than CCl4. Pretreatment with nontoxic dietary levels of chlordecone (CD) results in amplification of BrCCl3 hepatotoxicity. The objective of this research was to investigate and compare the histopathological alterations during a time course after a low dose of BrCCl3 alone and in combination with dietary CD. Male Sprague-Dawley rats were maintained on 10 ppm dietary CD or normal diet for 15 days. On day 16, they received a single ip dose (30 μ1/kg) of BrCCl3 in corn oil (CO) vehicle or corn oil alone. Blood and liver samples were collected at 0, 3, 6, 12, 24, 36, 48, 72, 96, and 120 hr for serum enzymes and histopathological examination, respectively. Serum enzymes (SDH, ALT, AST) were significantly ( p < 0.05) elevated in rats receiving the CD + BrCCl3 combination in comparison to BrCCl3 alone. For 48 hr, a continuous increase in serum enzyme activities was detected in rats treated with CD + BrCCl3 combination, but not in the rats receiving other treatments (ND + BrCCl3, ND + CO, or CD + CO). The most extensive hepatolobular necrosis was observed in rats treated with the CD + BrCCl3 combination. Thirty-six hr after the administration of BrCCl3 to rats maintained on normal diet, high mitotic activity was observed, which continued through 72 hr resulting in complete restoration of hepatolobular structure. In contrast, rats receiving the combination of CD + BrCCl3 exhibited minimal and belated hepatomitotic activity for a short period of time, resulting in progressive hepatic failure, culminating in animal death. In conclusion, hepatotoxicity of a low dose of BrCCl3 alone appeared to be overcome via stimulated hepatocellular regeneration and hepatolobular restoration. CD appears to amplify BrCCl3 hepatotoxicity via interference with this hormetic mechanism, permitting a progressive and continued hepatic injury leading to complete hepatic failure, culminating in animal death.

Preventive effect of D-002, a mixture of long-chain alcohols from beeswax, on the liver damage induced with CCl4 in rats

D-002 is a mixture of higher aliphatic primary alcohols purified from beeswax with antioxidant effects. Acute hepatotoxicity induced with CCl4 in rats has been related to increased hepatic lipid peroxidation and prevented with some antioxidants. This study investigated whether D-002 could prevent the acute CCl4-induced hepatotoxicity in rats. Animals were randomly distributed into four groups: a negative control treated orally with the vehicle and three groups injected with CCl4 (1 mL/kg) and treated orally either with the vehicle (positive control) or with D-002 (25 and 100 mg/kg). Eighteen hours after CCl4 dosing, rats were anesthetized, and livers were removed for histopathological studies. Some portions were taken and homogenized for assessing malondialdehyde (MDA) concentrations. Positive, but not negative, controls showed ballooned cells, swollen hepatocytes, and lipid-included hepatocytes, as well as necrotic areas and inflammatory infiltrates. D-002 (25 and 100 mg/kg) dose-dependently and significantly (P < .01) decreased the frequency of all abnormal liver cell types and increased that of normal hepatocytes compared with the positive controls, not showing necrotic areas or inflammatory infiltrates. D-002 dose-dependently decreased hepatic MDA levels, but only in the highest dose group were these levels significantly lower than in the positive control. In conclusion, D-002 effectively prevented the histological liver disturbances and lowered MDA levels, a marker of cellular lipid peroxidation, in rats treated with CCl4. Since increased liver lipid peroxidation has been postulated as a cause of CCl4-induced liver damage in rats, the preventive effects of D-002 could be due to its antioxidant action, but such a proposal still requires further research.

Lack of protective effect of D-003, a mixture of high-molecular-weight primary acids from sugar cane wax, on liver damage induced by galactosamine in rats

D-003 is a mixture of very-high-molecular-weight aliphatic primary acids purified from sugar cane wax, wherein octacosanoic acid is the most abundant. Experimental and clinical studies have shown that D-003 lowers cholesterol and prevents plasma lipoprotein peroxidation (LP). D-003 has protected against the histological changes characteristic of CCl4- and paracetamol-induced hepatic injury in rats, in which LP plays a pivotal role for explaining the resulting hepatotoxicity. Galactosamine induces hepatotoxicity associated with depressed RNA and protein synthesis, not with LP. The aim of this study was to evaluate whether D-003 could prevent hepatoxicity induced by mechanisms others than increased LP. We investigated the effects on galactosamine hepatotoxicity in rats distributed into five groups: a negative control group, a positive control group, and three groups treated with galactosamine and D-003 (5, 25, and 100 mg/kg). To induce liver damage, galactosamine (800 mg/kg) was injected intraperitoneally 30 minutes after dosing with vehicle or D-003. Twenty-four hours later, rats were sacrificed, and livers were immediately removed for histopathological studies. Livers from positive controls showed the characteristic pattern of galactosamine-induced damage. Galactosamine significantly reduced the percentage of normal hepatocytes, increasing both necrotic or lipid-rich hepatocytes compared with negative controls. D-003, however, did not increase the percentage of normal hepatocytes compared with positive controls, indicating that treatment was not effective for preventing the hepatic injury induced with galactosamine. Likewise, D-003 failed to change the content of necrotic and lipid-rich hepatocytes relative to positive controls. It is concluded that D-003 did not protect against the histological changes of galactosamine-induced hepatotoxicity.

Hepatotoxicity and mechanism of action of haloalkanes: carbon tetrachloride as a toxicological model

The use of many halogenated alkanes such as carbon tetrachloride (CCl4), chloroform (CHCl3) or iodoform (CHI3), has been banned or severely restricted because of their distinct toxicity. Yet CCl4 continues to provide an important service today as a model substance to elucidate the mechanisms of action of hepatotoxic effects such as fatty degeneration, fibrosis, hepatocellular death, and carcinogenicity. In a matter of dose,exposure time, presence of potentiating agents, or age of the affected organism, regeneration can take place and lead to full recovery from liver damage. CCl4 is activated by cytochrome (CYP)2E1, CYP2B1 or CYP2B2, and possibly CYP3A, to form the trichloromethyl radical, CCl3*. This radical can bind to cellular molecules (nucleic acid, protein, lipid), impairing crucial cellular processes such as lipid metabolism, with the potential outcome of fatty degeneration (steatosis). Adduct formation between CCl3* and DNA is thought to function as initiator of hepatic cancer. This radical can also react with oxygen to form the trichloromethylperoxy radical CCl3OO*, a highly reactive species. CCl3OO* initiates the chain reaction of lipid peroxidation, which attacks and destroys polyunsaturated fatty acids, in particular those associated with phospholipids. This affects the permeabilities of mitochondrial, endoplasmic reticulum, and plasma membranes, resulting in the loss of cellular calcium sequestration and homeostasis, which can contribute heavily to subsequent cell damage. Among the degradation products of fatty acids are reactive aldehydes, especially 4-hydroxynonenal, which bind easily to functional groups of proteins and inhibit important enzyme activities. CCl4 intoxication also leads to hypomethylation of cellular components; in the case of RNA the outcome is thought to be inhibition of protein synthesis, in the case of phospholipids it plays a role in the inhibition of lipoprotein secretion. None of these processes per se is considered the ultimate cause of CCl4-induced cell death; it is by cooperation that they achieve a fatal outcome, provided the toxicant acts in a high single dose, or over longer periods of time at low doses. At the molecular level CCl4 activates tumor necrosis factor (TNF)alpha, nitric oxide (NO), and transforming growth factors (TGF)-alpha and -beta in the cell, processes that appear to direct the cell primarily toward (self-)destruction or fibrosis. TNFalpha pushes toward apoptosis, whereas the TGFs appear to direct toward fibrosis. Interleukin (IL)-6, although induced by TNFalpha, has a clearly antiapoptotic effect, and IL-10 also counteracts TNFalpha action. Thus, both interleukins have the potential to initiate recovery of the CCl4-damaged hepatocyte. Several of the above-mentioned toxication processes can be specifically interrupted with the use of antioxidants and mitogens, respectively, by restoring cellular methylation, or by preserving calcium sequestration. Chemicals that induce cytochromes that metabolize CCl4, or delay tissue regeneration when co-administered with CCl4 will potentiate its toxicity thoroughly, while appropriate CYP450 inhibitors will alleviate much of the toxicity. Oxygen partial pressure can also direct the course of CCl4 hepatotoxicity. Pressures between 5 and 35 mmHg favor lipid peroxidation, whereas absence of oxygen, as well as a partial pressure above 100 mmHg, both prevent lipid peroxidation entirely. Consequently, the location of CCl4-induced damage mirrors the oxygen gradient across the liver lobule. Mixed halogenated methanes and ethanes, found as so-called disinfection byproducts at low concentration in drinking water, elicit symptoms of toxicity very similar to carbon tetrachloride, including carcinogenicity.

Effect of policosanol on carbon tetrachloride-induced acute liver damage in Sprague-Dawley rats

BACKGROUND

Policosanol is a cholesterol-lowering drug purified from sugarcane (Saccharum officinarum, L.) wax. Beneficial pleiotropic effects of policosanol, such as inhibition of the susceptibility of low density lipoprotein to lipid peroxidation, have been shown. Policosanol has a good safety profile and well tolerated and, to date, no drug-related adverse effects have been demonstrated. Specifically, policosanol has not been shown to affect liver function or to increase liver enzyme levels in experimental or clinical studies.

AIM

This study was conducted to determine whether policosanol prevents liver damage induced by carbon tetrachloride (CCl4) in rats, since this model has been associated with an increased rate of lipid peroxidation.

METHODS

Male Sprague-Dawley rats were randomised to four experimental groups: negative controls (no CCl4 or policosanol, group 1); positive controls (CCl4 but no policosanol, group 2); policosanol 25 mg/kg (group 3) and policosanol 100 mg/kg (group 4). Acute liver injury was induced in groups 2, 3 and 4 by CCl4 suspended in olive oil and administered at a dose of 1590 mg/kg via intraperitoneal injection. Eighteen hours after CCl4 dosing, the rats were anaesthetised and their livers removed for histopathological studies.

RESULTS

Policosanol 25 and 100 mg/kg dose dependently and significantly (p < 0.01) decreased the percentage of ballooned cells and hepatocytes with lipid inclusions and increased the percentage of normal hepatocytes compared with positive controls. The percentage inhibition of the occurrence of ballooned cells and hepatocytes with lipids was marked, reaching 71 and 49%, respectively, with the higher dose (100 mg/kg). The percentage of swollen hepatocytes was unchanged by policosanol compared with positive controls. No histological alterations in liver sections were found in the negative control group. Necrotic areas and inflammatory infiltrates were observed in the liver of seven of eight (87.5%) animals in the positive control group. However, only one of eight (12.5%) animals treated with policosanol 25 mg/kg and none (0%) treated with the higher dose (100 mg/kg) showed such a pattern.

CONCLUSIONS

Policosanol protected against the histological changes characteristic of CCl(4)-induced hepatic injury in rats, a model of hepatotoxicity in which the process of lipid peroxidation plays a role. Further studies aimed at demonstrating the connection between such hepatoprotective and antioxidant effects of policosanol must be initiated.

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.

The hepatic interaction of aliphatic alcohols with halogenated hydrocarbons

As has been noted, advancement in understanding of chemical interactions requires an integrated approach. Given the large number of binary mixtures of aliphatic alcohols and halogenated hydrocarbons that can be formulated, and because limitations of time and resources make it impossible to test them all, careful thought should be given to selection of pairs for laboratory experimentation. For any given pair of chemicals, the type of interaction (addition, synergism, antagonism, potentiation) should be determined and described by appropriate experimental designs and statistical methodology. This has been done for various alcohol-halocarbon mixtures. Work to expand our understanding of the mechanism(s) underlying the interaction of aliphatic alcohols and halogenated hydrocarbons would be particularly useful, as an improved mechanistic understanding would improve our ability to extrapolate across dose levels (from high laboratory exposure concentrations to typical human environmental exposure concentrations) and across species (from laboratory animals to humans).

Potentiation of halomethane hepatotoxicity by chlordecone: a hypothesis for the mechanism

A major toxicological issue today is the possibility of unusual toxicity due to interaction of toxic chemicals upon environmental or occupational exposures to two or more chemicals, at ordinarily harmless levels individually. While some laboratory models exist for such interactions for the simplest case of only two chemicals, progress in this area has suffered for want of a model where the two interactants are individually nontoxic. One such model is available, where prior exposure to nontoxic levels of the pesticide Kepone (chlordecone) results in a 67-fold amplication of CCl4 lethality in rats. Extensive hepatotoxicity observed in this interaction is characterized by histopathological alterations, perturbation of related biochemical parameters and is followed by complete hepatic failure. This propensity for chlordecone to potentiate hepatotoxicity of halomethanes such as CCl4, CHCl3, and BrCCl3 has been a subject of intense study to unravel the underlying mechanism. Mechanisms such as induction of microsomal cytochrome P-450 by chlordecone and greater lipid peroxidation are inadequate to explain the remarkably powerful potentiation of halomethane toxicity. Compelling experimental evidence supports the hypothesis that hepatocellular division during early time points after the administration of CCl4 is an important determinant of the progression (or repair of it) of the liver injury and consequent destruction (or restoration) of the hepatolobular architecture and function. This paper advances a hypothesis for the mechanism of hepatotoxic and lethal effect of CCl4 as being primarily related to the accelerated progression of liver injury due to suppressed hepatocellular regeneration and hepatolobular restoration. This is in contrast to the widely accepted putative mechanism, one which invokes only bioactivation followed by runaway lipid peroxidation as the events determining the course of the progressive phase of liver injury. The concept being advanced in this paper accepts bioactivation (and perhaps lipid peroxidation) as the primary initiating events of cell injury, but maintains that they are not the determinants of the progressive phase of liver injury. The biological issue of whether the cells are incapacitated from regenerating is the determinant of the progression of liver injury, and therefore, the ultimate outcome of hepatotoxicity and lethality.

Bromotrichloromethane hepatotoxicity. The role of stimulated hepatocellular regeneration in recovery: biochemical and histopathological studies in control and chlordecone pretreated male rats

It has been shown that BrCCl3 is a more potent hepatotoxin than CCl4. Pretreatment with nontoxic dietary levels of chlordecone (CD) results in amplification of BrCCl3 hepatotoxicity. The objective of this research was to investigate and compare the histopathological alterations during a time course after a low dose of BrCCl3 alone and in combination with dietary CD. Male Sprague-Dawley rats were maintained on 10 ppm dietary CD or normal diet for 15 days. On day 16, they received a single ip dose (30 microliters/kg) of BrCCl3 in corn oil (CO) vehicle or corn oil alone. Blood and liver samples were collected at 0, 3, 6, 12, 24, 36, 48, 72, 96, and 120 hr for serum enzymes and histopathological examination, respectively. Serum enzymes (SDH, ALT, AST) were significantly (p less than 0.05) elevated in rats receiving the CD + BrCCl3 combination in comparison to BrCCl3 alone. For 48 hr, a continuous increase in serum enzyme activities was detected in rats treated with CD + BrCCl3 combination, but not in the rats receiving other treatments (ND + BrCCl3, ND + CO, or CD + CO). The most extensive hepatolobular necrosis was observed in rats treated with the CD + BrCCl3 combination. Thirty-six hr after the administration of BrCCl3 to rats maintained on normal diet, high mitotic activity was observed, which continued through 72 hr resulting in complete restoration of hepatolobular structure. In contrast, rats receiving the combination of CD + BrCCl3 exhibited minimal and belated hepatomitotic activity for a short period of time, resulting in progressive hepatic failure, culminating in animal death. In conclusion, hepatotoxicity of a low dose of BrCCl3 alone appeared to be overcome via stimulated hepatocellular regeneration and hepatolobular restoration. CD appears to amplify BrCCl3 hepatotoxicity via interference with this hormetic mechanism, permitting a progressive and continued hepatic injury leading to complete hepatic failure, culminating in animal death.

Mechanism of the lethal interaction of chlordecone and CCl4 at non-toxic doses

There is significant interest in the possibility of unusual toxicity due to interaction of toxic chemicals upon environmental or occupational exposures even though such exposures may involve levels ordinarily considered harmless individually. While many laboratory and experimental models exist for such interactions, progress in this area of toxicology has suffered for want of a model where the interactants are individually non-toxic. We developed such a model where prior exposure to non-toxic levels of the pesticide Kepone (chlordecone) results in a 67-fold amplification of CCl4 lethality in experimental animals. The mechanism(s) by which chlordecone amplifies the hepatotoxicity of halomethanes such as CCl4, CHCl3, and BrCCl3 has been a subject of intense study. The biological effects of this interaction include extensive hepatotoxicity characterized by histopathological alterations, hepatic dysfunction, and perturbation of related biochemical parameters. Close structural analogs of chlordecone such as mirex and photomirex do not share the propensity of chlordecone to potentiate halomethane toxicity. Mechanisms such as induction of microsomal cytochrome P-450 by chlordecone and greater lipid peroxidation are inadequate to explain the remarkably powerful potentiation of toxicity and lethality. Time-course studies in which liver tissue was examined 1-36 h after CCl4 administration were conducted. While animals receiving a normally nontoxic dose of CCl4 alone show limited hepatocellular necrosis by 6 h, proceeding to greater injury after 12 h, recovery phase ensues as revealed by greatly increased number of mitotic figures. Such regeneration and hepatic tissue repair processes are totally suppressed in animals exposed to chlordecone prior to CCl4. Thus, the arrested hepatocellular repair and renovation play a key role in the potentiation of CCl4 liver injury by chlordecone. These findings have allowed us to propose a novel hypothesis for the mechanism of chlordecone amplification of halomethane toxicity and lethality. While limited injury is initiated by the low dose of CCl4 by bioactivation followed by lipid peroxidation, this normally recoverable injury permissively progresses due to arrested hepatocellular regeneration and tissue repair processes. Recent studies designed to test this hypothesis have provided additional supporting evidence. Hepatocellular regeneration stimulated by partial hepatectomy was unaffected by 10 ppm dietary chlordecone, while these animals were protected from the hepatotoxic and lethal actions of CCl4 if administered at the time of maximal hepatocellular regeneration. The protection was abolished when CCl4 was administered upon cessation of hepatocellular regeneration.

Histological and histometrical changes of liver damage in rats after treatment with ethanol and carbon tetrachloride

A pretreatment of 30 to 52 weeks with a 10% (v/v) solution of ethanol did not bring about any distinct changes but increased the damaging effects on liver caused by an acute dose of carbon tetrachloride in rats. This was shown by the semiquantitative assessment of histological changes and by the measurement of hepatocyte nuclei. The results of both investigations are complementary to each other and show a correlation.

Potentiation of CCl4-induced liver injury by ketonic and ketogenic compounds: role of the CCl4 dose

Potentiation of haloalkane hepatotoxicity by ketones and ketogenic agents is a well-known phenomenon. The importance of the CCl4 dosage in these combinations, however, has not been explored. Its influence was investigated in male Sprague-Dawley rats. Dose-effect curves for potentiation were generated using 1,3-butanediol, methyl n-butyl ketone or methyl isobutyl ketone as potentiation agents. Animals were orally treated with these compounds prior to a challenge of CCl4 (0 to 0.5 ml/kg, ip). Liver injury was assessed by monitoring plasma ALT activity and bilirubin concentrations after CCl4 treatment. The minimal effective dosage (MED) for each potentiator was used as the criterion of comparison for each combination. The MED values were determined from the plasma ALT data. Results showed that when the CCl4 dosage was increased from 0.01 to 0.10 ml/kg, the MED of each potentiator decreased 10-fold. For a given potentiator, the product of the CCl4 dosage (H, "hepatotoxicant") by the corresponding MED value (P, "potentiator") remained the same in this range of CCL4 dosages. The severity of the liver injury was similar. These findings suggest that a given level of liver injury induced by a ketone/haloalkane combination could be evaluated on the basis of the [P X H] product.

Ethanol oxidation and toxicity: role of alcohol P-450 oxygenase

The isolation and characterization of ethanol-inducible rabbit liver microsomal cytochrome P-450, termed P-450 3a or P-450ALC, has provided definitive evidence for the role of this enzyme in alcohol oxidation. From findings on the distribution, substrate specificity, and mechanism of action of P-450ALC we have suggested "alcohol P-450 oxygenase" as a more biochemically accurate name than "microsomal ethanol-oxidizing system." The present review is concerned with studies in this and other laboratories on activities and inducers associated with this versatile enzyme. Numerous xenobiotics, including alcohols and ketones, nitrosamines, aromatic compounds, and halogenated alkanes, alkenes, and ethers, are known to undergo increased microsomal metabolism after chronic exposure of various species to ethanol. Diverse compounds and treatments may induce P-450ALC, including the administration of ten or more chemically different compounds, fasting, or the diabetic state. Whether a common mechanism of induction is involved is unknown at this time. As direct evidence that P-450ALC catalyzes numerous metabolic reactions, the purified rabbit enzyme has been used in a reconstituted system to demonstrate various metabolic transformations, including the oxidation of various alcohols, acetone, acetol, p-nitrophenol, and aniline, the dealkylation of substituted nitrosamines, the reductive dechlorination of carbon tetrachloride, carbon tetrachloride-induced lipid peroxidation, and acetaminophen activation to form the glutathione conjugate.

Effect of endrin and endrin derivatives on hepatobiliary function and carbon tetrachloride-induced hepatotoxicity in male and female rats

The effects of the cyclodiene pesticide, endrin, and its aldehyde and ketone metabolites on hepatobiliary function and CCl4-induced hepatotoxicity were investigated in Sprague-Dawley rats. The rats were given control diet or diets containing 5 or 10 ppm endrin, 10 ppm endrin aldehyde or 5 ppm endrin ketone for 15 days. Three to six rats from each treatment group were given a single ip dose (100 microliter/kg body weight) of CCl4 in corn oil (1 ml/kg) on day 15. Levels of serum glutamic-oxalacetic transaminase (SGOT), glutamic-pyruvic transaminase (SGPT), isocitrate dehydrogenase and ornithine-carbamyl transferase, bile flow and biliary excretion of an anionic model compound, phenolphthalein glucuronide (PG), were measured on day 16. Dietary treatment with endrin at either dose level did not significantly elevate serum enzyme levels, while endrin aldehyde produced a slight increase in SGOT and SGPT and endrin ketone produced a small elevation in SGPT levels. Treatment with endrin aldehyde or endrin ketone did not result in significant alterations of bile flow or biliary PG excretion. Treatment with 5 ppm endrin produced a significant reduction in bile flow and a corresponding reduction in PG excretion by male rats, whereas treatment with 10 ppm endrin reduced only the PG excretion by male rats. Female rats treated with 5 or 10 ppm endrin showed a dose-dependent choleretic effect with a commensurate increase in PG excretion. With the exception of a further slight reduction in PG excretion by male rats, treatment with the endrin or endrin derivative did not potentiate CCl4-induced alterations in hepatobiliary functions. Although the levels of some serum enzymes of rats given endrin or endrin derivatives plus CCl4 were elevated over those of rats given CCl4 alone, the increases were not of the magnitude of those that have been reported previously for chlordecone. Generally, female rats challenged with CCl4 or endrin/CCl4 exhibited greater increases in serum enzyme levels than did male rats given corresponding treatments.