Potentiation of hypoxic injury in cultured rabbit hepatocytes by the quinoxalinone anxiolytic, panadiplon

Potentiation of hypoxic injury in cultured rabbit hepatocytes by the quinoxalinone anxiolytic, panadiplon

The quinoxalinone anxiolytic, panadiplon, produces hepatic metabolic inhibition (mitochondrial impairment), microvesicular steatosis and centrilobular necrosis in rabbits. Metabolic inhibition occurs in cultured hepatocytes without cytotoxicity, suggesting that hepatic injury is influenced by additi...

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Bibliographic Details
Published in:Toxicology (Amsterdam) Vol. 108; no. 1; pp. 9 - 16
Main Authors: Bacon, James A., Cramer, Clay T., Petrella, Diane K., Sun, Elena L., Ulrich, Roger G.
Format: Journal Article
Language:English
Published: Shannon Elsevier Ireland Ltd 15-04-1996
Amsterdam Elsevier Science
Subjects:
Adenosine Triphosphate - metabolism
Animals
Anti-Anxiety Agents - toxicity
Anxiolytic
Biological and medical sciences
Cell Death
Cell Hypoxia
Cells, Cultured
Dihydroxyacetone - pharmacology
Drug Synergism
Drug toxicity and drugs side effects treatment
Female
Glycogen
Glycogen - metabolism
Hepatocyte
Hypoxia
L-Lactate Dehydrogenase - metabolism
Liver - cytology
Liver - drug effects
Liver - metabolism
Medical sciences
Mitochondria
Oxadiazoles - toxicity
Oxygen - metabolism
Panadiplon
Pharmacology. Drug treatments
Pyruvates - pharmacology
Pyruvic Acid
Quinoxalines - toxicity
Rabbits
Toxicity: digestive system
Hypoxia
Mitochondria
Panadiplon
Hepatocyte
Glycogen
Anxiolytic
Quinoxaline derivatives
Toxicity
Rabbit
Hepatic disease
Lagomorpha
In vitro
Vertebrata
Mammalia
Tranquillizer
Cell death
Animal
Digestive diseases
ATP
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Summary:The quinoxalinone anxiolytic, panadiplon, produces hepatic metabolic inhibition (mitochondrial impairment), microvesicular steatosis and centrilobular necrosis in rabbits. Metabolic inhibition occurs in cultured hepatocytes without cytotoxicity, suggesting that hepatic injury is influenced by additional factors. The present experiments were conducted to determine if metabolic inhibition by panadiplon predisposed hepatocytes to hypoxic injury. Injury (cell death) was evaluated by lactate dehydrogenase (LDH) release from cells; ATP and glycogen levels were also evaluated. Under hypoxic conditions, control cultures showed a 6.5-fold increase in LDH release compared to normoxic controls, with a coincident 80% decrease in ATP and 50% decrease in glycogen levels. Under normoxic conditions, 10 μg/ml panadiplon treatment for 48 h reduced ATP and glycogen levels by 40% but did not cause an increase in LDH leakage. Cells treated with panadiplon, then exposed to hypoxia conditions, showed a significant level of injury compared to normoxic control cultures, and a further reduction in ATP. No additional decrease in glycogen was observed. In an attempt to prevent panadiplon-mediated injury, glycolytic substrates (dihydroxyacetone or pyruvate) were included during normoxic and hypoxic incubations. Both cotreatments reduced the level of LDH leakage produced by panadiplon during hypoxia. Cotreatment did not generally increase ATP or glycogen levels (compared to panadiplon treatment groups) during hypoxia, though individual experiments showed a slight increase in ATP levels. During normoxia both cotreatments with panadiplon resulted in significantly higher glycogen levels than in panadiplon cultures alone. These results suggest that cellular glycogen and subsequently ATP levels are reduced during panadiplon exposure, metabolically predisposing hepatocytes to hypoxic injury.
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ISSN:0300-483X
1879-3185
DOI:10.1016/S0300-483X(95)03265-H