A minimally toxic dose of methylene dianiline injures biliary epithelial cells in rats.

The threshold for hepatotoxicity and cholestasis induced by methylene dianiline (DAPM) in rats is between 25 and 75 mg/kg (Bailie et al., Environ. Health Perspect., 124, 25-30, 1993). Our objectives were to determine if a minimally toxic dose of DAPM provided a model system for studies of selective injury to biliary epithelial cells (BEC) in vivo. Thus, we examined the effects of 50 mg DAPM/kg on (1) biliary constituents, (2) liver constituents likely involved in DAPM biotransformation/detoxification, and (3) early morphological and histochemical changes in the liver. Male Sprague Dawley rats had biliary cannulas positioned under pentobarbital anesthesia. After 1 h of control bile collection, rats received 50 mg DAPM/kg po in 35% ethanol or 35% ethanol only. Bile was collected for another 6 h. Histochemical, ultrastructural, and biochemical liver alterations were assessed at 3 h or at 3 and 6 h. DAPM had minimal effects on biliary bile salt and bilirubin excretion over 6 h. Biliary glucose and protein excretion were increased approximately 2-fold starting in Hour 1, while inorganic phosphate excretion was not increased until Hour 2. Biliary glutathione excretion initially increased (Hour 1) but then declined steadily for 5 h. Microsomal cytochrome P-450 activities were transiently decreased at 3 h but had returned to control values by 6 h. Liver glutathione (GSH and GSSG) was not affected by DAPM at 3 or 6 h. Necrosis of intrahepatic bile ducts was severe at 6 h with moderate injury in smaller bile ducts. Ultrastructural alterations were observed in BEC mitochondria and microvilli at 3 h with no apparent alterations in hepatocyte mitochondria or tight junctions between cells. In addition, histochemical staining of liver sections and assays of mitochondrial enzyme activities in vitro at 3 h revealed no loss of mitochondrial function in hepatocytes. These results provide strong evidence for defining DAPM as a selective bile duct toxicant.

Species differences in testicular and hepatic biotransformation of 2-methoxyethanol.

Biotransformation of 2-methoxyethanol (2-ME) by alcohol and aldehyde dehydrogenases is an established factor in the toxicity of this useful solvent. Little is known about potential capacity for 2-ME biotransformation by testis or other target tissues. We detected appreciable capacity for 2-ME biotransformation by alcohol dehydrogenase in testes from Sprague-Dawley rats. However, kinetic analysis showed a 6-fold lower affinity for 2-ME by alcohol dehydrogenase of testis compared to liver. 2-ME biotransformation was also detected in testes from Wistar rats and one strain of mice but not in testes from hamsters, guinea pigs, rabbits, dogs, cats or humans. Testes from all these species readily converted the aldehyde metabolite of 2-ME to 2-methoxyacetic acid. Hepatic capacities for 2-ME biotransformation by alcohol dehydrogenase varied from 22 to 2.5 mumol/mg prot/min with a species rank order of: hamsters >> rats = mice > guinea pigs = rabbits. There was no consistent concordance between activities for 2-ME versus ethanol, the prototype substrate for alcohol dehydrogenase, which could reflect substrate preferences of different isozymes. Species differences between rats and hamsters were also found for testicular and hepatic biotransformation of the glycol ethers, 2-ethoxyethanol and 2-butoxyethanol. Although species differences in capacity for 2-ME biotransformation were found, the observations do not provide an explanation for reported species and strain differences in susceptibility to 2-ME toxicity.

Hyperthyroidism increases covalent binding and biliary excretion of 1,1-dichloroethylene in rats.

Distribution, covalent binding, and biliary excretion of 1,1-dichloroethylene (DCE) were examined in euthyroid (EuT) and hyperthyroid (HyperT) rats, which are more vulnerable to DCE hepatotoxicity. Male Sprague-Dawley rats were made hyperthyroid by 3 sc injections of thyroxine at 48-h intervals prior to experiments; euthyroid controls received vehicle injections. A time course study monitored the circulation and excretion of 14C-DCE label for 24 h after administration of 14C-labeled DCE (50 mg/kg in mineral oil) in serial blood and urine samples. At 24 h, total and covalently bound 14C-label were measured in liver, kidney, and lung. Hepatotoxicity of DCE was enhanced in the HyperT rats, as evidenced by elevated serum activities of aminotransferase and histopathology, and was associated with increases in circulating metabolite, and in metabolite bound to red blood cells and liver but not to kidney or lung. Hyperthyroidism had little effect on in vitro capacity of hepatic microsomes to convert DCE to reactive intermediates as reflected by covalent binding. A biliary excretion study in pentobarbital-anesthetized rats showed a striking, but transient, increase in toxicant metabolite excretion in bile of HyperT rats during the first 2 h after toxicant administration (14C-DCE, 100 mg/kg). During the next 2 h, biliary metabolite excretion by HyperT rats decreased while there was a rise in circulating amounts of total and bound 14C-label. Thus, although hyperthyroidism had little effect on the total extent of DCE metabolized, this hormonal disturbance may have transiently enhanced metabolite formation and definitely was associated with a lesser ability to detoxify reactive DCE metabolites capable of injuring hepatic cell constituents by covalent binding reactions.

Methylene dianiline: acute toxicity and effects on biliary function.

4,4'-Methylene dianiline (4,4'-diaminodiphenylmethane, DAPM), which is used in the polymer industry, causes hepatobiliary damage in exposed humans. Our objectives were to characterize the acute toxicity of DAPM in liver, particularly on secretion of biliary constituents and on biliary epithelial cell gamma-glutamyl transpeptidase (GGT) activity. Biliary cannulas were positioned in Sprague-Dawley male rats under pentobarbital anesthesia. After 1 hr of control bile collection, each rat was given 250 mg DAPM/kg (50 mg/ml) po in 35% ethanol or 35% ethanol only; bile was collected for a further 4 hr. Groups of rats were also examined for liver injury and biliary function at 8 and 24 hr after DAPM. Four hours after DAPM administration, main bile duct cells were severely damaged with minimal damage to peripheral bile ductule cells. Focal periportal hepatocellular necrosis and extensive cytolysis of cortical thymocytes occurred by 24 hr. Serum indicators of liver injury were elevated by 4 hr and continued to rise through 24 hr. By 4 hr, biliary protein concentration was increased 4-fold while concentrations of biliary bile salt, bilirubin, and glutathione were decreased by approximately 80, 50, and 200%, respectively. DAPM also induced a striking effect on biliary glucose with an approximately 20-fold increase. Histochemical staining of main bile duct GGT was absent by 8 hr after DAPM. Bile flow was diminished by 40% at 4 hr; three of five rats had no bile flow by 8 hr and none had any bile flow by 24 hr. These results indicate that DAPM rapidly diminishes bile flow and alters the secretion of biliary constituents and is highly injurious to biliary epithelial cells.

Glutathione and tissue amino acid responses to light-exposed parenteral nutrients.

Effects of infusion of light-exposed (+L) or light-protected (-L) total parenteral nutrition solutions were investigated in rats. The parenteral infusions were carried out for 7 days through jugular cannulas in freely moving rats in metabolic cages. Plasma tyrosine and citrulline, hepatic methionine, valine, isoleucine, leucine and tyrosine, and biliary cystathionine were significantly greater in the -L than +L rats, whereas biliary arginine was significantly lower in the -L compared to +L rats. Bile flow, biliary inorganic phosphate and glucose were significantly lower, whereas biliary total glutathione (GSH+GSSG) was significantly greater in the -L compared to +L animals. These data suggest adverse effects on hepatobiliary function due to light exposure of parenteral nutrients. The endogenous markers used suggest that tight junction permeability, bile acid-independent flow, glutathione and amino acid homeostasis are altered by light exposure and that these changes can be minimized by light protection. The mechanisms involved in the induction of these changes need to be elucidated. The role of light exposure of parenteral nutrients during routine clinical use in the induction of hepatic dysfunction, a common metabolic complication of parenteral nutrition, needs to be considered.

Biliary endogenous inorganic phosphate, D-glucose, IgA and transferrin are differentially altered by hydrostatic pressure.

Our objective was to determine the effects of hydrostatic biliary pressure on excretion patterns of endogenous solutes which reflect various pathways of bile formation. A stable in vivo model was developed using anesthetized rats intraduodenally infused with taurocholate to maintain bile flow. Bile was collected during a 2-h basal period, a 4-h pressure period where elevation of the bile duct cannula decreased bile flow to 1/3 the basal rate, and a 2-h period after release of hydrostatic biliary pressure. During pressure treatment, bile salt concentration gradually increased approximately 3-fold, biliary inorganic phosphate concentrations rapidly rose approximately 5-fold, and biliary glucose concentration progressively rose approximately 17-fold. Concentrations of proteins in bile were affected differently with extreme decreases in IgA, moderate decreases in total protein and leucine aminopeptidase, and minimal change in transferrin. By 2 h after pressure release, only the alterations in biliary glucose and IgA persisted. The observed striking and persisting increases in biliary glucose are tentatively explained as an impaired reabsorption of glucose by the biliary tract.

Biliary function studies during multiple time periods in freely moving rats. A useful system and set of marker solutes.

Biliary output of endogenous and exogenous compounds is altered by anesthesia, depletion of bile salts, and hydrostatic pressure. The described system for bile function studies minimizes these confounding factors by substantially modifying existing methods. Experiments were conducted in freely moving rats which eliminates effects of anesthesia or restraint-induced stress. Depletion of bile salts was prevented by intraduodenal infusion of taurocholate which maintains bile volume. Bile was collected in containers taped to the rat's back which minimizes hydrostatic forces induced by lengthy or elevated biliary cannulas. Animals were prepared for hepatobiliary function studies 1 week before experiments by placement and exteriorization of a jugular cannula and a bile duct to duodenal fistula. Experiments involved monitoring biliary outputs of marker solutes for various pathways of bile formation during three sequential time periods of 120 min, that is, a basal period in the morning and two experimental periods in the afternoon. We found similar patterns of biliary output in each time period for small i.v. doses of conventional exogenous markers [3H-taurocholate, phenolphthalein glucuronide, indocyanine green, and horseradish peroxidase] and for less commonly studied endogenous markers [glucose, inorganic phosphate (Pi), total protein, and leucine aminopeptidase]. This temporal stability indicates a lack of confounding circadian variability for these markers during the course of the biliary function study. Biliary excretion patterns of these marker solutes (e.g., rapid high recoveries of phenolphthalein glucuronide and low concentrations of Pi and glucose) demonstrated that our system for bile function studies is associated with intactness of the examined pathways of bile formation. These results validate our system and set of marker solutes for in vivo biliary function studies.(ABSTRACT TRUNCATED AT 250 WORDS)