Effects of repeated exposures of hydrogen sulphide on rat hippocampal EEG.

Exposure to high levels of hydrogen sulphide (H2S) in humans has been associated with a number of respiratory and neurological symptoms. Acute toxicity following exposure to high concentrations is well-documented, however, there is little scientific information concerning the effects of exposure to low concentrations. The effects of low levels of H2S on electroencephalographic (EEG) activity in the hippocampus and neocortex were investigated on the freely moving rat (Sprague-Dawley).

Uniform characterization of potentiation in simple and complex situations when agents bind to different molecular sites.

There is general agreement about potentiation in dose-response studies, characterized by a left shift of the dose-response curve of A by a fixed dose of B when B is causing no effect by itself (simple situation). When B causes an effect similar to A (complex situation) by binding to different molecular sites, we propose an analogous analysis. This approach is based on comparison of experimental effects of A and B in combination with theoretical, independent effects, representing an effect of A that is not affected by B.

Quantitative estimation of potentiation and antagonism by dose ratios corrected for slopes of dose-response curves deviating from one.

A shift of dose-response curves of a receptor agonist A by a receptor antagonist B to the right is frequently expressed or quantitated by calculating the dose ratio (DR) from the ED50 values obtained in the absence and presence of B. A comparison of ED50 values or a DR is also used in a more general way to express the effects of other antagonists or of potentiators. For this situation, where B is not competing with A for a binding site, slope-values may often deviate from one.

Alteration of the morphology and neurochemistry of the developing mammalian nervous system by hydrogen sulphide.

1. Hydrogen sulphide (H2S) is a broad spectrum toxicant that occurs widely in nature and is also released by a variety of industrial activities and processes. 2.

Sulfide-induced perturbations of the neuronal mechanisms controlling breathing in rats.

The effects of sulfide on neonatal rat respiration were studied. Two in vitro experimental models were utilized: the isolated brain stem-spinal cord preparation and the medullary slice preparation containing respiratory rhythm-generating regions from neonatal rats. Plethysmographic measurements of the effects of sulfide on the breathing patterns of unanesthetized neonatal rats were also made to compare the sensitivities of neonatal and adult rats to sulfide toxicity.

The actions of hydrogen sulfide on dorsal raphe serotonergic neurons in vitro.

1. The actions of hydrogen sulfide (HS-) on membrane and synaptic properties of dorsal raphe (DR) serotonergic cells were studied in the in vitro brain stem slice preparation, using intracellular sharp microelectrode and whole-cell recording techniques. 2.

Toxicology of hydrogen sulfide.

Significant progress has been made in determining the action of sulfide on the primary target organs. It is reasonably clear that sulfide causes both K(+)-channel-mediated hyperpolarization of neurons and potentiation of other inhibitory mechanisms. It is not clear whether these processes are similar to those that occur in anoxia.

Evaluation of experimental combined toxicity by use of dose-frequency curves: comparison with theoretical additivity as well as independence.

Dose-frequency curves of toxic effects of a substance A were evaluated in the absence and in the presence of a fixed dose of a second substance B. Data were fitted by the curve-fitting program ALLFIT. Observed combined frequencies of A + B were compared statistically with the expected frequencies of additivity and (or) independence by the phi 2-square goodness-of-fit test.

Application of the isobologram technique for the analysis of combined effects with respect to additivity as well as independence.

Combined actions of two substances with similar effects are frequently expressed by pairs of doses that produce a fixed response, usually 50%, in so-called isobolograms (ED50 isobolograms). In addition to the dose scales in such graphs we propose the addition of effect scales, where possible, to indicate the effect at certain doses, e.g.

Stress-induced increases in brainstem amino acid levels are prevented by chronic sodium hydrosulfide treatment.

Neurotransmitter amino acid levels were measured in select brain regions of rats and mice after chronic treatment with sublethal doses of sodium hydrosulfide (NaHS). Brainstem aspartate, glutamate, glutamine, taurine and GABA levels increased in chronically but not acutely saline-treated rats. These increases may have been due to stress from frequent handling, and were prevented by chronic NaHS treatment (7.

Dithiothreitol liberates non-acid labile sulfide from brain tissue of H2S-poisoned animals.

Acid-labile sulfide measured by conventional gas dialysis and ion chromatography with electrochemical detection accounts for only a proportion of the total sulfide present in brain tissue after poisoning with NaHS, an H2S precursor. Dithiothreitol (DTT) displaced additional measurable sulfide not detectable by the conventional techniques from NaHS-poisoned brain tissue. Sulfide liberation by DTT was dose-dependent and maximal at higher DTT concentration (10 and 30 mM) and was thought to represent non-acid labile sulfide.

Brain sulfide levels in anaesthesia: a comparison with hydrogen sulfide intoxication.

Although sublethal concentrations of hydrogen sulfide produce a state not unlike anaesthesia, measurement of rat brain sulfide levels by gas dialysis and IC with electrochemical detection after either 1.5 g/kg urethane or 42 mg/kg pentobarbital failed to demonstrate any changes as compared with endogenous brain sulfide levels of saline-injected controls. This suggests that the mechanisms underlying anaesthesia are not directly linked to endogenous cerebral sulfide levels.

Acute hydrogen sulfide poisoning. Demonstration of selective uptake of sulfide by the brainstem by measurement of brain sulfide levels.

The possibility of measuring sulfide levels in the central nervous system (CNS) opens up many avenues for exploration. In acute hydrogen sulfide (H2S) poisoning, death results from loss of central respiratory drive. To date, however, measurement of brain sulfide has not been possible.

Determination of sulfide in brain tissue by gas dialysis/ion chromatography: postmortem studies and two case reports.

An analytical method for the determination of sulfide in human and rat brain is described. It utilizes a continuous flow gas dialysis pretreatment and quantitation by ion chromatography with electrochemical detection. Rat brain sulfide levels were reliably measured after fatal intoxication by intraperitoneal injection of NaHS.

Peracute toxic effects of inhaled hydrogen sulfide and injected sodium hydrosulfide on the lungs of rats.

This study was designed to test whether intraperitoneally injected sodium hydrosulfide (NaHS) would mimic the pulmonary alterations induced by lethal peracute exposure to an atmosphere containing hydrogen sulfide. Groups of five Sprague-Dawley rats were exposed to an atmosphere of either 2317.6 +/- 547.

Monoamine oxidase inhibition as a sequel of hydrogen sulfide intoxication: increases in brain catecholamine and 5-hydroxytryptamine levels.

Administration of sodium hydrosulfide (NaHS), an alkali salt of hydrogen sulfide (H2S) at doses of 10 and 30 mg/kg, corresponding to sublethal and lethal doses (0.66 and 2.0 X LD50) resulted in significant increases in regional catecholamine levels of the rat brain only after the dose of 2.

Hydrogen sulfide in combination with taurine or cysteic acid reversibly abolishes sodium currents in neuroblastoma cells.

Patch clamp studies of neuroblastoma cells have shown that in the presence of sodium hydrogen sulfide (NaHS; the in vitro precursor of H2S), addition of the sulfonated amino acids, taurine or cysteic acid resulted in reversible abolition of the inward sodium currents. This effect could also be demonstrated by preincubating cells for 3-20 min with 5-10 mM NaHS followed by replacement of the solution with taurine or cysteic acid in sulfide-free saline. Neither NaHS, taurine nor cysteic acid alone had any effect.

Effects of acute intoxication with hydrogen sulfide on central amino acid transmitter systems.

The acute effects of hydrogen sulfide (H2S) on brain amino acid levels were examined in five regions of the rat brain following administration of either saline (controls), or 10 or 30 mg/kg i.p. of sodium hydrosulfide (NaHS).

Increased levels of amino acid neurotransmitters in the inferior colliculus of the genetically epilepsy-prone rat.

Previous studies have shown an increase in the number of GABAergic and total neurons in the inferior colliculus (IC) of the genetically epilepsy-prone rat (GEPR). Amino acid analysis of the central nucleus of the IC, as well as cerebellum, sensorimotor, temporal, and occipital cerebral cortices of GEPRs with high pressure liquid chromatography showed significant increases in the levels of GABA, taurine and glutamate. The IC of GEPR displayed a 2.

Interaction between flurazepam and ethanol.

The interaction of a representative benzodiazepine, flurazepam, and ethanol has been assessed in ICR albino mice. Tests done included loss of "rotarod" performance, light sedation, deep sedation, loss of righting reflex, anesthesia, and lethality. LD50 and ED50s were plotted as isobolograms (plots of equieffective dose combinations).

Lack of effect of antagonists on serotonin-induced inhibition in rat hippocampus.

Four putative central nervous system 5-hydroxytryptamine antagonists, methysergide, cyproheptadine, metergoline, and ketanserin and also lysergic acid diethylamide were applied by iontophoresis to firing CA1 hippocampal pyramidal cells to test their action on the inhibition produced by 5-hydroxytryptamine. In contrast to a previous report, none of these peripherally active 5-hydroxytryptamine antagonists altered the inhibitory response to submaximal doses of 5-hydroxytryptamine, but they did block after-excitations that followed the inhibitions. All the antagonists and lysergic acid diethylamide produced a depression of firing.

Possible involvement of serotonin receptors in the facilitatory effect of a hallucinogenic phenethylamine on single facial motoneurons.

2,5-Dimethoxy-4-methylamphetamine (DOM, "STP") is a potent hallucinogen, proposed to be a serotonin receptor agonist. Its effects have not previously been tested upon central neurons where serotonin is excitatory and serotonin antagonists are effective. Extracellular single unit recordings were obtained from facial motoneurons in anaesthetized rats, and drugs were applied from five-barrelled micropipettes by iontophoresis.

Direct comparison of hallucinogenic phenethylamines and D-amphetamine on dorsal raphe neurons.

We compared the effects of the hallucinogens 2,5-dimethoxy-4-methylamphetamine (DOM), mescaline and the simulant D-amphetamine, applied by microiontophoresis to rat dorsal raphe (DR) units. DR neuron firing rate was relatively insensitive to DOM and unaffected by mescaline, but was clearly inhibited by D-amphetamine. Intravenous DOM usually inhibited, but this effect was correlated with blood pressure changes; i.

Comparison of the effects of amphetamine and a fluorinated analogue on locomotion and exploratory activity in the mouse.

(+)-Amphetamine (AM) and its fluorinated analogue (+)-2-amino-3-fluoro-1-phenylpropane (fluoroamphetamine, FAM) were compared with regard to their effects on locomotor and exploratory activity in mice. Both drugs caused a reduction in spontaneous exploration, but this effect was more marked with FAM than with AM at 1 h after injection. Both compounds increased locomotor activity 10 min after injection, but FAM had sedative effects after 1 h, while AM continued to be stimulatory.