Halomethane-chlordecone (CD) interactive hepatotoxicity--current concepts on the mechanism.

Why is a low dose of toxic chemical nontoxic? What makes a larger dose of the same chemical toxic? Extensive work done to understand the mechanism of halomethane hepatotoxicity and its potentiation by chlorinated insecticide, chlordecone has resulted in the understanding of these basic tenets of toxicology. Studies suggest that ordinarily a small dose of halomethane causes limited liver injury which is accompanied by stimulated tissue repair enabling complete recovery from injury before manifestation. A large dose of halomethane becomes toxic due to suppressed tissue repair, which permits injury to progress in an unchecked fashion. Exposure to very low levels of chlordecone results in highly exaggerated toxicity of ordinarily nontoxic doses of halomethane because of suppressed hepatocellular regeneration and restoration, permitting the progression of liver injury ultimately resulting in liver failure and animal mortality. This concept is further supported by the observation that, while exposure to even high levels of phenobarbital and subsequent low nontoxic doses of halomethane results in greater level of initial liver injury, tissue repair is not completely suppressed; it is slightly postponed by 24 hr, but then much higher rate of tissue repair ensures and consequently enables the animals to completely recover from liver injury and survive. Thus, whether initiation of tissue repair processes occurs or not is the critical determinant in the ultimate manifestation of hepatotoxicity and its end result of either animal death or recovery and survival. Currently understood 'Mechanisms of toxicity' adequately explain only how toxic injury begins. These mechanisms do not permit us to predict the ultimate outcome of toxicity.(ABSTRACT TRUNCATED AT 250 WORDS)

Comparative evaluation of sequestration of polyamines by perfused rabbit and rat lungs.

Differences were observed in the sequestration of polyamines putrescine, spermidine and spermine by isolated, ventilated, perfused rat and rabbit lungs, former being able to accumulate more polyamines compared to the latter. Steady state equilibrium was reached earlier for spermine in rat. Isolated ventilated lungs were perfused with harmaline and ouabain, inhibitors known to inhibit the sodium pump at a maximum concentration of 1 mM for rabbit lungs and 0.4 and 0.2 mM for rat lungs, respectively. They did not affect the uptake of polyamines by rat lung but decreased the uptake of putrescine by rabbit lung. Decreased sodium (50 meq/L) in the perfusate increased the uptake of spermine and spermidine by rabbit lung but again showed no effect with rat lung. However, the uptake of polyamines by isolated ventilated rat and rabbit lungs perfused for 60 min with these compounds was linear over the entire range of high concentrations studied. These results suggest that the major uptake process of polyamines by intact lungs of both animal species is primarily by simple diffusion. HPLC analysis of the perfusate and lungs from both animal species post-perfusion indicated no detectable metabolites of the polyamines.