Transplacental pharmacokinetics and fetal distribution of 2', 3'-didehydro-3'-deoxythymidine (d4T) and its metabolites in late-term rhesus macaques.

BACKGROUND: The overall goal of human immunodeficiency virus (HIV) therapy during pregnancy is to maintain maternal health and reduce the probability of vertical transmission during gestation and delivery, while keeping toxicity risks low. Azidothymidine (AZT) is currently recommended for pregnant women infected with HIV; however, many pregnant women are unable to tolerate AZT because of toxicity. In the present study, the placental transfer and fetal accumulation of the anti-HIV compound 2',3'-didehydro-3'-deoxythymidine (d4T) and its active (triphosphorylated) and inactive (thymine and beta-aminoisobutyric acid) metabolites were examined at steady state in late-term rhesus macaques. METHODS: On the day of the hysterotomy, the mother was administered an intravenous loading dose of d4T, followed by a 3-hr steady-state intravenous infusion that also included [(3)H]d4T as a tracer. After 3 hr of infusion, the fetus was delivered by cesarean section under halothane/N(2)O anesthesia. Plasma, amniotic fluid, and tissues were analyzed for d4T and its inactive metabolites by HPLC; tissue samples were analyzed for d4T and active (phosphorylated) metabolites by strong anion-exchange HPLC. RESULTS: Maternal steady-state plasma concentrations of d4T were 1-2 microg/ml, with a fetal-to-maternal plasma ratio of 0.85 +/- 0.09. The fetal tissue distribution of radioactivity was highest in the kidney and lowest in the brain. D4T, thymine, and beta-aminoisobutyric acid were detected in all fetal tissues examined. CONCLUSIONS: Our data indicate that d4T readily crosses the placenta and is present in the fetus as parent compound or its inactive metabolites after maternal infusion. Although fetal plasma concentrations of d4T were similar to clinical d4T concentrations, no phosphorylated metabolites were detected. Teratology 62:93-99, 2000. Published 2000 Wiley-Liss, Inc.

Effect of manganese on the concentration of amino acids in different regions of the rat brain.

The present study was designed to determine if chronic exposure of weanlings and adult rats to Mn produces significant alterations in amino acid concentrations in different regions of the rat brain. Weanling (30 day old) and adult (90 day old) male rats were exposed to 10 and 20 mg Mn/kg body weight per day, by gavage, for 30 days. Forty-eight hours after the last dose, animals were sacrificed by decapitation and brains were dissected into different regions to determine the concentration of amino acids by HPLC/EC. A dose dependent decrease in body weight gain was found in the adult, but not in the weanling rats. Significant increases occurred in concentrations of aspartate, glutamate, glutamine, taurine and gamma-aminobutyric acid (GABA) in the cerebellum of the adult rats dosed with 20 mg/kg per day, Mn. A significant decrease in the concentration of glutamine was observed in caudate nucleus and hippocampus of weanling rats dosed with 10 mg/kg, Mn. These data suggest that chronic Mn exposure can produce a decrease in body weight gain in adult rats and alterations in amino acids in different regions of weanling and adult rat brains.

Transplacental pharmacokinetics and fetal distribution of azidothymidine, its glucuronide, and phosphorylated metabolites in late-term rhesus macaques after maternal infusion.

3'-Azido-3'-deoxythymidine (AZT) is currently prescribed to pregnant women infected with human immunodeficiency virus to reduce the risk of vertical transmission of the virus to the fetus. Consequently, more information is needed concerning the placental transfer and tissue distribution of AZT and its metabolites. In the present study, the placental transfer and fetal accumulation of AZT, its glucuronide metabolite [3'-azido-3'-deoxythymidine-beta-D-glucuronide (AZTG)], and phosphorylated metabolites were examined at steady-state in near-term rhesus macaques. One to 2 weeks before a chronic infusion, an intravenous bolus of 8 mg/kg AZT was administered to pregnant animals to determine the dose of AZT needed to reach steady-state plasma concentrations. On the day of hysterotomy, the mother was administered an intravenous loading dose of AZT, followed by a 3-hr steady-state intravenous infusion that also included a trace of [3H]AZT. After 3 hr of infusion, the mother was anesthetized, and the fetus was delivered. Plasma and amniotic fluid were analyzed for AZT and AZTG by HPLC, and tissue samples were analyzed for AZT, AZTG, and phosphorylated metabolites by strong anion exchange HPLC. Maternal steady-state plasma concentrations were 1.3-2.2 micrograms/ml for AZT and 2.3-8.0 micrograms/ml for AZTG. Fetal AZT and AZTG plasma concentrations were both lower (0.98-2.3 micrograms/ml and 1.3-5.4 micrograms/ml, respectively) than maternal concentrations, with fetal-to-maternal plasma ratios of 0.63-1.0 for AZT. Fetal tissue distribution of tritium was highest in the kidney and lowest in the brain. Although the active triphosphorylated metabolite was not detected in the fetus, the AZT-monophosphate was detected in almost all fetal tissues examined. Our data indicate that AZT is rapidly converted to the glucuronide and monophosphate metabolites in the fetus after maternal infusion.

Distribution of 2,4-dichlorophenoxyacetic acid (2,4-D) in maternal and fetal rabbits.

The distribution of 2,4-dichlorophenoxyacetic acid (2,4-D) was examined in maternal and fetal rabbits. Pregnant New Zealand rabbits (28-30 d gestational age) were anesthetized with ketamine/xylazine and the femoral vein and artery were catheterized for compound administration and sampling. Dams received iv [14C]2,4-D (12.5 microCi/kg) with unlabeled sodium 2,4-D (1, 10, or 40 mg/kg) in saline. Blood and tissue were collected up to 2 h after dosing. Fetal to maternal plasma AUC ratios were 0.09, 0.07, and 0.16 after the 1, 10, or 40 mg/kg dose, respectively. Extraplasma AUCs were greatest in maternal kidney and uterus and lowest in maternal and fetal brain. A greater than fourfold elevation in fetal AUC was found when the dose was increased from 10 to 40 mg/kg, suggesting saturation of maternal plasma binding of 2,4-D. Although the in vitro fetal brain tissue to incubation media ratio was unity (1.03 +/- 0.1, mean +/- SD), fetal brain AUCs were 10% or less of the fetal plasma AUCs, indicating the brain barrier system to 2,4-D is functioning in the late-gestation fetal rabbit. However, its development may not be complete due to the higher brain tissue to plasma ratios in the fetus compared to the dam.

Manganese-induced reactive oxygen species: comparison between Mn+2 and Mn+3.

Manganese (Mn) is an essential element, the deficiency or excess of which is known to cause neurotoxicity in experimental animals and man. The mechanism of action of Mn neurotoxicity is still unclear. The present study was designed to evaluate whether in vitro or in vivo exposure to Mn produced reactive oxygen species (ROS). We also sought to determine if a single injection of Mn produces changes in monoamines concentration in different regions of rat brain. Adult Sprague-Dawley rats were dosed with 0, 50 or 100 mg/kg, ip with either MnCl2 (Mn+2) or MnOAc (Mn+3) and were sacrificed 1 h after the dose was administered. Brains were quickly removed and dissected for neurochemical analysis. ROS were measured by a molecular probe, 2',7'-dichlorofluorescein diacetate (DCFH-DA), and monoamines and their metabolites were measured by HPLC/EC. In vitro exposure to MnCl2 (1-1000 microM) produced dose-dependent increases of ROS in striatum whereas MnOAc produced similar increases at much lower concentrations (1-100 microM). In vivo exposure to MnOAc (Mn+3) produced significant increases of ROS in caudate nucleus and hippocampus, whereas MnCl2 (Mn+2) produced significant effects only in hippocampus. Concentrations of dopamine, serotonin and their metabolites (DOPAC, HVA and 5-HIAA) were not altered with acute injections of either MnCl2 or MnOAc. These data suggest that both divalent and trivalent manganese induce ROS, however, Mn+3 is an order of magnitude more potent than Mn+2.

Comparison of glutamine-enhanced glutamate release from slices and primary cultures of rat brain.

Increased extracellular glutamate has been associated with a wide range of effects including production of neurotoxicity. Glutamine has previously been shown to cause increased release of glutamate from a variety of preparations. Extracellular central nervous system (CNS) glutamine levels are known to increase with neurotoxin exposures, hepatic failure, renal failure, head trauma or stroke. However, the action of glutamine to enhance the release of glutamate under nondepolarizing conditions has not been well studied. Since glutamine-mediated increases in extracellular glutamate are potentially of significance in cellular damage as a result of CNS insult, further examination of this phenomenon is important. Striatal and hippocampal slices or virtually neuron-free primary striatal glial cultures were employed in studies to further elucidate the mechanism(s) of glutamine-enhanced glutamate release. Elevated extracellular glutamine caused increased glutamate release in all three preparations. In hippocampal and striatal slices elevated glutamine caused an enhancement of N-methyl-D-aspartate (NMDA) receptor-mediated [3H]catecholamine release equivalent to that produced by high concentrations (up to 100 microM) of exogenous glutamate. In both striatal slices and primary cultures kynurenate increased glutamate release in the presence of 500 microM glutamine, while kainate either had no effect or decreased glutamate levels in the presence of glutamine. Since several presynaptic modulators of release did not affect the glutamate release produced by glutamine in slices, vesicular release of glutamate from nerve terminals was probably not involved in the effects of the exogenous glutamine. The similarities between striatal slices and primary striatal cultures indicate that enzymatic conversion of glutamine to glutamate within glia may be an important factor in the glutamine-mediated elevation of extracellular glutamate levels.

Effects of a cold environment or age on methamphetamine-induced dopamine release in the caudate putamen of female rats.

Extracellular levels of dopamine (DA) and metabolites as well as serotonin [5-hydroxytryptamine (5-HT)] and 5-hydroxyindoleacetic acid (5-HIAA) were determined in the caudate putamen (CPU) of either 6- or 12-month-old female rats using microdialysis and high-performance liquid chromatography with electrochemical detection (HPLC-ED) before, during, and after four consecutive injections (given at 2-h intervals) of methamphetamine (METH). In 6-month-old rats administered 4 x 5 mg/kg METH at an environmental temperature (ET) of 23 degrees C, peak extracellular DA levels (between 50 and 150 rho g/10 microliters) were attained 30-45 min after each dose of METH while dihydroxyphenylacetic acid (DOPAC) decreased steadily after the first doses of METH until it reached a plateau at 50% of control (550-700 pg/10 microliters) levels. Increases in 5-HT levels during METH administrations paralleled DA increases while 5-HIAA decreases paralleled DOPAC decreases. The total CPU DA and 5-HT content of these rats was about 65% of control at 3 days post-METH. Reducing the ET to 4 degrees C during dosing decreased the peak and average DA levels attained during the 4 x 5 mg/kg METH administration to about 50% of that observed at a 23 degrees C ET. Increasing the dose to 4 x 10 mg/kg METH (4 degrees C ET) increased peak and average CPU DA levels to 200% that observed during 4 x 5 mg/kg METH at a 23 degrees C ET. However, no significant decreases in total CPU DA content of any rats dosed with METH at a 4 degrees C ET were observed 3 days post-METH. In 12-month-old rats dosed with 4 x 5 mg/kg METH (23 degrees C ET), the peak and average extracellular DA levels were only 30-60% that of 6-month-old rats. However, the CPU DA content of older rats was significantly decreased both 3 (30% control) and 14 (60% control) days post-METH. In summary, METH toxicity may not be predicted solely by the extracellular levels of DA attained during METH administration; age and ET also greatly influence METH neurotoxicity.

A further evaluation of the effects of K+ depolarization on glutamate-evoked [3H]dopamine release from striatal slices.

Exogenous glutamate will evoke dopamine (DA) release from striatal slices in vitro. To further characterize glutamate-evoked DA release from striatal slices, experiments were designed to: 1) determine if sufficient endogenous glutamate can be released in vitro to presynaptically mediate [3H]DA release in the absence of Mg++ and 2) reevaluate how K+ depolarization affects glutamate-evoked [3H]DA release. Removal of Mg++ to potentiate N-methyl-D-aspartate (NMDA) receptor-mediated DA release increased 15 mM K(+)-evoked [3H]DA release to about 200% of control. The potentiation of this release was probably not mediated by NMDA receptors because it was not blocked by the glutamate receptor antagonists MK-801, 6,7-dinitroquinoxalinedione (DNQX) or kynurenate. Furthermore, the removal of Mg++ increased DA release substantially (200%) in the presence of 5 microM sulpiride and 10 microM nomifensine, indicating that DA reuptake and DA D2 autoreceptors are not primarily responsible for increased DA release. In the absence of Mg++, depolarization produced by 20 mM or greater [K+] inhibited DA released by exogenous glutamate, whereas a much higher [K+] was necessary to evoke endogenous glutamate release. In the presence of 1.5 mM Mg++, a reduction of the "Mg++ blockade" of NMDA receptors by 15 mM K+ depolarization during glutamate-evoked DA release was evaluated with and without the DA reuptake inhibitor nomifensine and the DA D2 antagonist sulpiride. DA released by K+ depolarization (Mg++ present) was markedly increased by 1 mM glutamate, but this effect was only partially reversed by kynurenate or high concentrations of either MK-801 (25 microM) or DNQX (100 microM).(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of methyl bromide on regional brain glutathione, glutathione-S-transferases, monoamines, and amino acids in F344 rats.

Both metabolic and neurotransmitter changes have been implicated in the pathogenesis of monohalomethane neurotoxicity in rodents. This study in male and female F344 rats examined the effects of methyl bromide (MeBr) on regional brain glutathione-S-transferase (GST) activities and concentrations of glutathione (GSH), monoamines, and amino acid. Inhalation exposure to 150 ppm MeBr (6 hr/day x 5 days) yielded no histologic evidence of brain lesions but resulted in a number of biochemical changes. GSH depletion and GST inhibition were detected in the frontal cortex, caudate nucleus, hippocampus (examined for GSH only), brain stem, and cerebellum from animals of both sexes. Differences between sexes were detected for GSH depletion. Simultaneous treatment of rats with the inhibitor of monohalomethane toxicity, BW 755C (3-amino-1-[m-(trifluoromethyl)phenyl]-2-pyrazoline; 10 mg/kg bw ip, 1 hr pre- and 1 hr postexposure) completely protected against GST inhibition in all brain regions of both sexes. Partial protection by BW 755C against GSH depletion was observed in the cerebral cortex and in the cerebellum only. In males, MeBr exposure had no effect on the regional concentrations of the monoamines dopamine and serotonin and the amino acids glutamate, glutamine, taurine, and gamma-aminobutyric acid. Regional increases of brain aspartate and glycine levels were observed after exposure of males to MeBr but BW 755C had no effect on these changes induced by MeBr. Thus, of all the parameters studied, only GST, and in some brain areas GSH, correlated with inhibition of toxicity. It is concluded that, in contrast to the monoamines and the amino acids, GST and GSH are sensitive and potentially relevant indicators of MeBr neurotoxicity which could explain sex and regional differences in response to the monohalomethanes.

Effect of trimethyltin on amino acid concentrations in different regions of the mouse brain.

Trimethyltin (TMT) is a neurotoxic compound known to cause marked alterations in brain chemistry. We have previously demonstrated that a single oral dose of TMT produced a dose-dependent decrease in muscarinic cholinergic receptors in mouse brain and significantly elevated glutamine in several regions of the rat brain. This study was designed to determine if TMT produced dose- and time-related alterations in amino acid concentrations in the adult male C57BL/6N mouse brain and in peripheral organs and plasma. In the dose-response study, TMT was administered orally as a single dose of 0, 0.5, 1.0, 3.0 or 5.0 mg/kg and animals were sacrificed 24 hr after treatment. In the time-course study, mice were dosed with TMT at 3.0 mg/kg and sacrificed 4, 12, 24, 48 or 96 hr after dosing. Amino acid concentrations were quantified by HPLC/EC following precolumn derivatization with o-phthalaldehyde-tert-butylthiol. TMT produced dose-dependent increases in aspartate, glutamine and glycine in the caudate nucleus (CN), frontal cortex (FC) and hippocampus (HIP) at 3.0 and 5.0 mg/kg. TMT at 3.0 mg/kg produced significant increases of aspartate in FC and HIP after 48 hr. Glutamine concentrations were significantly increased at 24 and 48 hr in HIP and at 48 hr in CN. Glycine and GABA concentrations were significantly increased at 48 and 96 hr respectively in the HIP. Glutamine was increased in plasma at 4 and 12 hr and in liver at 24 hr. Hyperammonemia occurred in plasma after 8 hr and continued through 24 hr and was accompanied by an increase in serum urea nitrogen.(ABSTRACT TRUNCATED AT 250 WORDS)

Interactions of MK-801 with glutamate-, glutamine- and methamphetamine-evoked release of [3H]dopamine from striatal slices.

The interactions of MK-801 [(+)-5-methyl-10,11-dihydro-5H-dibenzo[a,d] cyclohepten-5,10-imine], glutamate and glutamine with methamphetamine (METH)-evoked release of [3H]dopamine were assessed in vitro to determine whether MK-801 inhibition of METH neurotoxicity might be mediated presynaptically, and to evaluate the effects of glutamatergic stimulation on METH-evoked dopamine release. MK-801 inhibition of glutamate- or METH-evoked dopamine release might reduce synaptic dopamine levels during METH exposure and decrease the formation of 6-hydroxydopamine or other related neurotoxins. Without Mg++ present, 40 microM and 1 mM glutamate evoked a N-methyl-D-aspartate receptor-mediated [3H]dopamine and [3H]metabolite (tritium) release of 3 to 6 and 12 to 16% of total tritium stores, respectively, from striatal slices. With 1.50 mM Mg++ present, 10 mM glutamate alone or in combination with the dopamine uptake blocker nomifensine released only 2.1 or 4.2%, respectively, of total tritium stores, and release was only partially dependent on N-methyl-D-aspartate-type glutamate receptors. With or without 1.50 mM Mg++ present, 0.5 or 5 microM METH evoked a substantial release of tritium (5-8 or 12-21% of total stores, respectively). METH-evoked dopamine release was not affected by 5 microM MK-801 but METH-evoked release was additive with glutamate-evoked release. Without Mg++ present, 1 mM glutamine increased glutamate release and induced the release of [3H]dopamine and metabolites. Both 0.5 and 5 microM METH also increased tritium release with 1 mM glutamine present. When striatal slices were exposed to 5 microM METH this glutamine-evoked release of glutamate was increased more than 50%.(ABSTRACT TRUNCATED AT 250 WORDS)

Thallium intoxication produces neurochemical alterations in rat brain.

Thallium, a rodenticide, has been shown to produce several neurological symptoms including motor weakness, ataxia, tremor, convulsion, coma and death. The present study was designed to evaluate the effects of acute or subacute exposure to thallium on several neurochemical biomarkers in rat brain. In the acute study, adult male CD rats were treated with 0 or 20 mg thallium/kg intraperitoneally (ip) and sacrificed 2, 6, or 24 hr after exposure. In the subacute study, animals were treated with 0 or 5 mg thallium/kg ip daily for 10 days and sacrificed 24 hr after the last dose. Acute injections of thallium produced in the frontal cortex significant increases in glutamine concentration after 6 hr and in taurine after 6 and 24 hr. In hippocampus, significant decreases in aspartic acid and taurine concentrations were found after 6 hr. Subacute exposure to thallium produced significant increases of dopamine (DA), 3,4-dihydroxyphenylacetic acid (DOPAC) and serotonin (5-HT) in amygdala and increases in 5-HT concentration in hypothalamus. DA or muscarinic cholinergic (MCh) receptor binding did not show any significant alterations in caudate nucleus or frontal cortex after acute or subacute exposure to thallium. However, when membranes prepared from control caudate nuclei were incubated with thallium (1-100 microM) in vitro, we observed a dose-dependent decrease in DA and MCh receptor binding. These data suggest that the neurotoxicity produced by thallium exposure may be associated with changes in the concentrations of amino acids and other neurotransmitters in various regions of the rat brain.

Pharmacokinetics of doxylamine, a component of Bendectin, in the rhesus monkey.

The elimination of doxylamine and metabolites was determined after iv administration of [14C]doxylamine succinate at 0.7 and 13.3 mg/kg to the adult female rhesus monkey. Although the total recovery of radioactivity was the same for the low- and high-dose studies (90.2%), the rate of plasma elimination of doxylamine and its demethylated metabolite (desmethyldoxylamine) was slower for the high dose group. The 24 hr urinary excretion of doxylamine metabolites, desmethyl- and didesmethyldoxylamine, was significantly increased and the polar doxylamine metabolites were significantly decreased as the iv doxylamine succinate dose was increased. The plasma elimination of gas chromatograph (GC)-detected doxylamine was determined after oral administration of Bendectin (doxylamine succinate and pyridoxine hydrochloride) at 7, 13.3, and 27 mg/kg to adult female rhesus monkeys. As the dose increased, the clearance of doxylamine decreased. A statistically evaluated fit of the oral data to a single-compartment, parallel first-order elimination model and a single-compartment, parallel first- and second-order (Michaelis-Menten) elimination model indicated that the more complex model containing the second-order process was most consistent with the observed elimination data.

Influence of inducers and inhibitors on the metabolism in vitro and neurochemical effects in vivo of MDMA.

(S)-(+)- and (R)-(-)-3,4-methylenedioxymethamphetamine (MDMA) were metabolized in vitro by rat liver microsomes via N-demethylation to 3,4-methylenedioxyamphetamine (MDA). Whereas no difference was found in the biotransformation of the two enantiomers in the male rat or in the phenobarbital (PB) treated animals of either sex, more than twice as much MDA was formed from (S)-(+)- than from (R)-(-)-MDMA in the untreated female rat. Although 3-methylcholanthrene (3MC) pretreated rat liver microsomes were less active than those from the untreated rats of the same sex, they formed more MDA from (+)- than from (-)-MDMA. The enantioselective metabolism thus appears to be associated with the relative abundance of individual cytochrome P-450 isozymes. (S)-(+)- and (R)-(-)-MDMA.HCl (20 mg/kg) were about equipotent in depleting serotonin (5-HT) levels in the frontal cortex at 3 hrs and 1 wk following oral administration to female rats. Pretreatment of rats with SKF-525A attenuated and that with PB enhanced the 5-HT depleting potential of either isomer at 3 hrs. The 5-HT depleting potency of (+)-MDMA was significantly greater than that of its (-)-antipode at 3 hr in PB pretreated, but not in SKF-525A pretreated animals. The results suggest that the neurochemical effects of MDMA are caused by the formation of an active metabolite in vivo, and since both enantiomers were N-demethylated in vitro to approximately the same extent by PB pretreated rat liver microsomes, the active metabolite may be other than MDA.

Enhancement of estradiol potency by the 17 beta-hydroxysteroid dehydrogenase inhibitor, 16-methylene E2 in vivo.

The ability of 16-methylene E2, a 17 beta-hydroxysteroid dehydrogenase inhibitor, to enhance estradiol 17 beta (E2) potency was assayed by 24-hr weight gain in the immature rat uterus. Initial studies demonstrated that 16-methylene E2 (1-100 micrograms s.c.) did not produce significant uterine weight gain 24 hr after administration, whereas E2 (0.1-10 micrograms s.c.) produced a significant uterine weight gain under the same experimental conditions. A subthreshold dose of E2 (0.01 microgram s.c.) when administered in combination with 100 micrograms (s.c.) of 16-methylene E2 produced a significant uterine weight gain. When rats were predosed with 16-methylene E2 at 72, 48, 24, 6 or 0 hr before the administration of 0.01 microgram of E2, the magnitude of the 24-hr uterine weight gain increased and attained maximal values for the 6-hr pretreatment time point. A subsequent dose-response study of 16-methylene E2 (1-100 micrograms s.c.) administered 6 hr before 0.01 microgram of E2 revealed that the 10, 50 and 100 microgram 16-methylene E2 dose significantly increased uterine weight gain in a dose-dependent manner. These results indicate that 16-methylene E2 is not a direct acting estrogen but acts synergistically with E2 to produce an enhanced uterine response. In a separate set of monkey experiments: 1) A trace dose of [3H]E2 was perfused through the in situ, term rhesus monkey placenta via the umbilical arteries and samples were collected from the umbilical vein of this open system.(ABSTRACT TRUNCATED AT 250 WORDS)

Determination of amino acids in different regions of the rat brain. Application to the acute effects of tetrahydrocannabinol (THC) and trimethyltin (TMT).

A modified HPLC method is described for the determination of amino acids [aspartic acid, glutamic acid, glutamine, glycine, taurine, and gamma-aminobutyric acid (GABA)] in brain tissue utilizing precolumn derivatization with o-phthalaldehyde (OPA)-tert-butyl-thiol and electrochemical detection. A simple extraction procedure was employed and DL-homoserine used as internal standard. A neurotoxin previously shown to affect brain amino acids (trimethyltin, TMT) and a psychoactive compound hypothesized to act on these neurochemicals (delta-9-tetrahydrocannabinol, THC) were administered to adult male rats and amino acids were measured. Results revealed a gradient of distribution of most amino acids, with lowest levels posteriorly in the brain stem and increasing to the highest values in anterior cortical regions. TMT increased glutamine significantly in all brain regions examined, but increased glycine and decreased taurine only in the frontal cortex and hippocampus. No significant changes in any amino acid were found in hippocampus after THC treatment. The results establish the validity and usefulness of this HPLC method for detecting neurotoxicity-related changes in brain amino acid metabolism.

Neuropathological evaluation by combined immunohistochemistry and degeneration-specific methods: application to methylenedioxymethamphetamine.

To best interpret the significance of neurological alterations produced by chemicals, the changes in morphological as well as neurochemical parameters must be measured and compared to each other. We have devised an approach to readily label microscopic sections for multiple antigens (neurotransmitters, enzymes, peptides, etc.) as well as for the demonstration of degenerating structures by silver impregnation. Here, we applied silver-staining together with immunolabelling of 5-HT and tyrosine hydroxylase (the rate-limiting enzyme for dopamine synthesis) to study neurohistological alterations produced by methylenedioxymethamphetamine (MDMA), a hallucinogenic stimulant previously used as an adjunct to psychotherapy and now a popular recreational drug ("Ecstasy"). Single oral doses of 40 or 80 mg/kg MDMA doubled the density of silver-impregnated (degenerating) fiber terminals in the caudate nucleus compared to controls, when rats were sacrificed 18 hours after treatment. Four months after two 40 mg/kg oral doses per day for four days, rats had a reduced neurochemical content of 5-HT in the hippocampus, and fewer immunostainable 5-HT axons per unit area in the hippocampal stratum lacunosum but no change in brain-stem neurochemical 5-HT content or in the numeric density of 5-HT-positive cell bodies in the dorsal raphe nucleus. The neurohistology suggests interpreting the changes in neurochemical content of serotonin produced by MDMA as due to degeneration followed by subsequent loss of 5-HT axons, rather than a decrease in the rate of neuronal 5-HT synthesis or a toxicity directed toward 5-HT cell bodies. The combination of neurohistological and neurochemical evaluation will continue to prove useful in comprehensive evaluation of the neurological effects of chemical exposure.

Metabolism of 14C-labeled doxylamine succinate (Bendectin) in the rhesus monkey (Macaca mulatta).

The time-course of the metabolic fate of [14C]doxylamine was determined after the p.o. administration of 13 mg/kg doxylamine succinate as Bendectin plus [14C]doxylamine succinate to the rhesus monkey. Urine and plasma samples were analyzed by reversed-phase high performance liquid chromatography (HPLC), chemical derivatization, and mass spectrometry. The cumulative 48-hr urinary metabolic profile contained 81% of the administered radiolabeled dose and consisted of at least six radiolabeled peaks. They were peak 1: unknown polar metabolites (8% of dose); peak 2: 2-[1-phenyl-1-(2-pyridinyl)ethoxy] acetic acid, 1-[1-phenyl-1(2-pyridinyl)ethoxy] methanol, and another minor metabolite(s) (31%); peak 3: doxylamine-N-oxide (1%); peak 4a: N,N-didesmethyldoxylamine (17%); peak 4b: doxylamine (4%); and peak 5: N-desmethyldoxylamine (20%). The plasma metabolic profile was the same as the urinary profile except for the absence of doxylamine-N-oxide. The maximum plasma concentrations and elapsed time to attain these concentrations were as follows. Peak 1: 540 ng/mL, 4 hr; peak 2: 1700 ng/mL, 1 hr; peak 4a: 430 ng/mL, 4 hr; peak 4b: 930 ng/mL, 2 hr; and peak 5: 790 ng/mL, 2 hr. These data suggest that in the monkey, doxylamine metabolism follows at least four pathways: a minor pathway to the N-oxide; a minor pathway to unknown polar metabolites; a major pathway to mono- and didesmethyldoxylamine via successive N-demethylation; and a major pathway to side-chain cleavage products (peak 2) via direct side-chain oxidation and/or deamination.