These data suggest that ZP123 significantly attenuates gap junction closure during acidosis. Preservation of intercellular coupling diminished CV slowing and heterogeneous repolarization, eliminating arrhythmogenic substrates.
Human butyrylcholinesterase (HuBChE) has previously been shown to protect mice, rats, and monkeys against multiple lethal toxic doses of organophosphorus (OP) anticholinesterases that were challenged by i.v. bolus injections. This study examines the concept of using a cholinesterase scavenger as a prophylactic measure against inhalation toxicity, which is the more realistic simulation of exposure to volatile OPs. HuBChE-treated awake guinea pigs were exposed to controlled concentration of soman vapors ranging from 417 to 430 micrograms/liter, for 45 to 70 s. The correlation between the inhibition of circulating HuBChE and the dose of soman administered by sequential i.v. injections and by respiratory exposure indicated that the fraction of the inhaled dose of soman that reached the blood was 0.29. HuBChE to soman molar ratio of 0.11 was sufficient to prevent the manifestation of toxic signs in guinea pigs following exposure to 2.17x the inhaled LD50 dose of soman (ILD50, 101 micrograms/kg). A slight increase in HuBChE:soman ratio (0.15) produced sign-free animals after two sequential respiratory exposures with a cumulative dose of 4.5x ILD50. Protection was exceptionally high and far superior to the currently used traditional approach that consisted of pretreatment with pyridostigmine and postexposure combined administration of atropine, benactyzine, and an oxime reactivator. Quantitative analysis of the results suggests that in vivo sequestration of soman, and presumably other OPs, by exogenously administered HuBChE, is independent of the species used or the route of challenge entry. This assuring conclusion significantly expands the database of the bioscavenger strategy that now offers a dependable extrapolation from animals to human.
Previous studies have shown that myocardium of the diabetic rat has impaired myoplasmic calcium metabolism. Delayed afterdepolarizations and triggered activity are potentiated by conditions believed to increase intracellular calcium concentration therefore, we performed this study to investigate the possibility that myocardium of the diabetic rat is more susceptible than normal tissue to develop afterdepolarizations and triggered activity. We used standard microelectrode techniques to record the electrical activity of papillary muscles from hearts of control rats and rats made diabetic with streptozotocin. We compared the response of control and diabetic preparations to conditions presumed to create progressively more severe degrees of myoplasmic calcium loading, viz. perfusion with solutions containing ouabain (5 X 10(-5) M) and increasing concentrations of calcium (2.4, 4.8, 7.2, and 9.6 mM). Our results showed the following. Ventricular muscle from diabetic rats was more prone than normal myocardium to develop delayed afterdepolarizations and triggered activity under conditions believed to cause myoplasmic calcium overload. The external calcium concentration correlated with the incidence but not the magnitude or coupling interval of the delayed afterdepolarizations in fibers of diabetic rats. The action potentials in fibers of diabetic rats decreased markedly in duration after exposure to ouabain, whereas normal action potentials were not affected significantly; as external calcium was increased with ouabain still present, the action potential duration in diabetic fibers decreased slightly more, whereas the action potential duration in normal fibers did not change significantly.(ABSTRACT TRUNCATED AT 250 WORDS)
We studied the effects of thyroid hormone on the action potential and membrane currents recorded from enzymatically dissociated guinea pig ventricular myocytes, by means of the whole-cell recording technique. Hypothyroidism was associated with an increase in action potential duration, whereas hyperthyroidism was associated with a decrease in duration. These effects are similar to those reported in multicellular preparations. Hypo- and hyperthyroidism were also associated with a decrease and an increase, respectively, in the slope of the action potential plateau. Resting potential and action potential amplitude were unaffected by the alterations in the thyroid state. The voltage-clamp experiments revealed that as compared with euthyroid myocytes, the peak calcium current was bigger in hyperthyroid myocytes and smaller in hypothyroid myocytes. The potassium outward current (at a membrane potential = 50 mV) was of similar amplitude in hypo- and euthyroid myocytes and bigger in hyperthyroid myocytes. Our major conclusion is that thyroid hormones regulate the amplitude of the calcium current and that this effect may be responsible in part for the modulation of myocardial contractility by thyroid hormones.
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