Neurotransmitter receptors in brain regions of acrylamide- treated rats. I: Effects of a single exposure to acrylamide

A single oral dose of acrylamide (25 or 50 mg/kg) increased the level of striatal 3H-spiroperidol binding in six week old male rats. This enhanced dopamine receptor activity was specific since treatment caused no significant changes in glycine, serotonin, and muscarinic cholinergic binding. At the highest acrylamide dose tested (100 mg/kg), elevations of the medullary glycine and frontal cortical serotonin receptors were also found. Pretreatment of animals with a blocker of hepatic mixed function oxidase (SKF 525a) or a thiol blocker (methylmercuric chloride) prevented the acrylamide-induced elevation of striatal spiroperidol binding, indicating that the causative agent was a secondary metabolite of acrylamide. Apomorphine-induced motility was significantly attenuated by 24 hr predosing with acrylamide, suggesting a change in the sensitivity of the dopamine receptor. The behavioral relevance of observed biochemical changes was thus shown by the altered response of treated animals to apomorphine.     

Four weeks of oral isotretinoin treatment causes few signs of general toxicity in male and female Sprague-Dawley rats.

Despite widespread use of isotretinoin for its anti-acne effects and its current evaluation in clinical trials as a cancer treatment, little is known about its general toxicity in adult nonpregnant animals, particularly after oral administration which mimics the human route. Here, adult male and female Sprague-Dawley rats were gavaged daily with 0 (soy oil), 7.5, or 15 mg/kg isotretinoin for 28 days during which time body weight, food/water intake, and estrous phase were measured. At sacrifice, organ weights were collected and concentrations of dopamine (DA), serotonin and metabolites were measured in frontal cortex, striatum, hippocampus, and diencephalon. Food intake was mildly decreased in both treated groups (approximately 15% in males and 7% in females); however, body weight and water consumption were unaffected. The estrous cycle appeared slightly affected (i.e., lengthened by 15 mg/kg, and both treated groups appeared to have less time in diestrus and more time in estrus). Kidney/body weight ratio was decreased by 7.5 and 15 mg/kg isotretinoin and spleen/body weight ratio was increased in the 7.5 mg/kg group. Males of the 7.5 mg/kg group exhibited significantly higher gonad/body weight ratios than did same-sex controls. Concentrations of monoamine and metabolites in the frontal cortex and diencephalon were unaffected. Nor were striatal DA and DOPAC concentrations affected; however, there were isolated effects on striatal HVA and 5-HIAA. Hippocampal DA concentrations were marginally increased. These data indicate mild effects resulting from oral isotretinoin treatment at doses which likely produce serum levels within the range of humans.     

3H-dopamine uptake and 3H-haloperidol binding in striatum after administration of methyl mercury to rats

Methyl mercury inhibits dopamine (DA) and serotonin (5-HT) uptake by brain synaptosomes and decreases antagonist binding to striatal dopaminergic D₂ receptors in vitro. To assess the effects in vivo, adult rats were given methyl mercury, either as a single dose (10 mg/kg by gavage) or a cumulative total dose of 50 mg/kg in 2 weeks. The repeated dosing decreased body weight and caused neuromuscular dysfunction. In spite of this overt toxicity, neither ³H-DA uptake nor ³H-haloperidol binding changed in striatal synaptosomes. There were no significant alterations in ³H-5-HT uptake by hypothalamic synaptosomes or ³H-flunitrazepam binding in cerebellar synaptosomes. The results suggest that monoaminergic synapses and the benzodiazepine binding sites, associated with cerebellar GABA receptors, remain functionally normal at doses of methyl mercury that are otherwise toxic. The results also emphasize the importance of due care when extrapolating cellular or biochemical data to the level of the whole organism.     

Neurotransmitter receptors in brain regions of acrylamide- treated rats. II: Effects of extended exposure to acrylamide

Acrylamide was administered orally to 6 week old male rats in ten doses, spread over a two week period. At the two lower doses (5 and 10 mg/kg, total dose 50 and 100 mg/kg) effects on neurotransmitter receptor sites appeared confined to the striatum where both the dopamine and muscarinic acetylcholine receptors exhibited enhanced binding twenty four hours after the last acrylamide dose. Other receptor sites within the frontal cortex, cerebellum, and medulla were not significantly altered. At the highest dose (20 mg/kg, given ten times), increases were also found for frontal cortical serotonin, medullary glycine, and cerebellar GABA receptor sites. The only unaffected receptor found was the cortical site for benzodiazepene. One week after the final acrylamide dose, the intensity of binding of all ligands studied was not significantly different in treated and control groups. Thus, effects appeared reversible. Since striatal membrane protein concentration was reduced by treatment of rats with acrylamide, the observed increased in activity of muscarinic receptors could be best accounted for in terms of loss of striatal non-receptor protein rather than increased binding. However, the magnitude of increased striatal 3H-spiroperidol binding in treated animals suggested an increase in overall binding capacity. An effect on dopamine neurons was also suggested by a decreased responsiveness to apomorphine in rats treated with acrylamide at 10 mg/kg for 10 successive days; however, the effect had dissipated by 8 days after the final injection of acrylamide.     

Developmental Toxicity of Amesergide Administered by Gavage to CD Rats and New Zealand White Rabbits

Amesergide is a selective serotonin 5-HT_IC/2 receptor antagonistbeing developed for the treatment of depression. The potentialdevelopmental toxicity of amesergide was evaluated in CD ratsand New Zealand white rabbits. Pregnant rats and rabbits weredosed once daily by gavage on Gestation Days 6–17 and6–18, respectively. Doses for rats were 0, 3, 10, and30 mg/kg; doses for rabbits were 0, 0.2, 2, and 15 mg/kg. Cesareansections were performed on rats and rabbits on Gestation Days20 and 28, respectively. In rats, maternal effects expressedas depression of body weight gain and food consumption wereobserved at the 30 mg/kg dose level. Fetal viability and morphologywere not affected at any dose level. Fetal weight was depressedat the 30 mg/kg dose level. The no-observed-effect level (NOEL)in the rat was 10 mg/kg. In rabbits, maternal effects expressedas a decrease in food consumption occurred at the 2 and 15 mg/kgdose levels; weight gain was depressed at 15 mg/kg. Fetal viability,weight, and morphology were not affected at any dose level.The NOELs for maternal and developmental effects in the rabbitwere 0.2 and 15 mg/kg, respectively.     

Morphine,cocaine and antidepressant induced motivational activity and midbrain dopaminergic neurotransmission

Positive motivational properties of opioids, stimulants and serotonin selective reuptake inhibitors have been reported following place preference conditioning. The possibility that these effects are associated with changes in dopamine concentration in the nucleus accumbens or striatum was investigated. Male Wistar rats were place conditioned in a three compartment model to vehicle or drug (morphine 2.5 mg/kg, cocaine 5 mg/kg, sertraline 5 mg/kg or paroxetine 15 mg/kg) alternately for 8 days using a 30 min pre-treatment time. Control animals received saline only. Nucleus accumbens and striatal tissue were dissected 72 h after final drug dose, and the concentration of dopamine and its metabolites determined using high performance liquid chromatography (HPLC). Striatal dopamine D1-like receptor density was also determined through radioligand binding. Significant place preference (P<0.05) was observed with morphine, cocaine and sertraline. Morphine treated subjects showed a significant decrease (P<0.05) in striatal dopamine concentration, whilst cocaine and sertraline treatment resulted in a significant increase in striatal dopamine levels. Nucleus accumbens concentrations of dopamine, and striatal dopamine D1-like receptor density remained unchanged. The changes in striatal dopamine concentrations are consistent with withdrawal from opioid and stimulant compounds, and suggest that place preference conditioning may, in part, result from negative motivational or aversive effects.     

Morphometric analysis of osteosclerotic bone resulting from hexachlorobenzene exposure

Hexachlorobenzene (HCB) exposure has been shown to induce hyperparathyroidism and osteosclerosis in rats. Experiments were undertaken to investigate the effects of HCB-induced hyperparathyroidism and osteosclerosis on femur morphometry as well as femur breaking strength. Fischer 344 rats were dosed 5 d/wk for 15 wk with 0, 0.1, 1, 10, or 25 mg HCB/kg body weight. Hyperparathyroidism was produced in the two higher dose groups as reported previously (Andrews et al., 1989). Femur weight was significantly increased in the rats receiving 0.1, 1, and 25 mg HCB/kg body weight, whereas density was increased significantly at 1, 10, and 25 mg HCB/kg dose levels. Bone strength was also significantly increased at the three higher dose levels. Cross-sectional area of the midpoint of the femur was significantly increased at the 1 mg/kg HCB dose level. Cortical area and the proportion of the total area of the bone that the cortex occupied were significantly increased at the three higher dose levels. Medullary cavity area was significantly increased at the 0.1 mg/kg dose level but significantly decreased at the 2 higher dose levels of HCB. The right femur was significantly predominant to the left femur in weight, volume, and density through all dosing regimens. HCB exposure significantly altered bone morphometry and strength characteristics in the Fischer 344 rat.     

Dopamine transporter binding in the rat striatum is increased by gestational, perinatal, and adolescent exposure to heptachlor.

Heptachlor is a persistent cyclodiene pesticide that affects GABAergic function. Recent reports indicate that heptachlor exposure also alters dopamine transporter (DAT) expression and function in adult mice. The aim of this study was to determine whether gestational, perinatal, and/or adolescent heptachlor exposure in rats altered dopamine-receptor and DAT binding. Adolescent exposure to dieldrin was included to evaluate the generality of the findings. Sprague-Dawley rats received doses (po) ranging from 0 to 8.4 mg/kg/day of heptachlor, or dieldrin, 3 mg/kg/day, during different developmental periods. There were dose-related decreases in maternal weight gain and pup survival, as well as delayed righting reflex, at heptachlor doses > or =3 mg/kg/day. There were no changes in striatal dopamine receptor-D1 ([(3)H]SCH-23390) and -D2 ([(3)H]spiperone) binding in preweanling pups exposed perinatally to heptachlor, and no differences in the response of adult rats to the motor activity-increasing effects of d-amphetamine. However, there were significant (27-64%) increases in striatal DAT binding of [(3)H]mazindol in preweanling rats exposed only gestationally. In rats exposed perinatally and/or during adolescence, there were also increases (34-65%) in striatal DAT binding at postnatal days (PND) 22, 43, and 128. Adolescent exposure to dieldrin also increased DAT binding. In other rats exposed perinatally and throughout adolescence, even the lowest dose of heptachlor 0.3 mg/kg/d increased DAT binding on PND 130. The DAT affinity for mazindol was unchanged in heptachlor-exposed striata. In vitro binding studies indicated that heptachlor (> or =10 microM) displaced mazindol binding. Thus, gestational, perinatal, and/or adolescent exposure to heptachlor produced an increase in DAT binding as early as PND 10, and this change persisted into adulthood.     

Acute and subacute oral toxicity assessment of dry encapsulated and non-encapsulated green coffee fruit extracts

The coffee fruit is a high source of bioactive compounds such as phenolic acids and methylxanthines, comprising chlorogenic acids and caffeine, respectively. Extract from this matrix may be used as supplement or active ingredient of functional foods, energy drinks, cosmetics or drugs. Safety of caffeine- and chlorogenic acid-rich encapsulated and non-encapsulated hydroethanolic extracts from green coffee fruit (GCFE) was assessed by acute and subacute toxicity tests. In the acute test, oral single dosage until 1000 mg/kg per body weight (bw) did not show any adverse effect on both female and male mice according to the Hippocratic screening and clinical parameters for a period of 14 days. While the oral median lethal dose of non-encapsulated GCFE was 5000 mg/kg bw/day, that of encapsulated GCFE was not detectable likely due to the delayed release of caffeine and other compounds from GCFE. Non-encapsulated GCFE displayed a stimulating effect at a dose of 1000 mg/kg bw/day after 30 min of oral administration, but not after 60 min. Daily consumption of encapsulated GCFE for 30 days showed no adverse effect in male rats even at the highest dose. Extrapolating this value of no-observed-adverse-effect level (1000 mg/kg bw/day) to human consumption, a human equivalent dose of 189 mg/kg bw/day or 11.34 g/day could be estimated for encapsulated GCFE considering a 60 kg adult body weight.     

Isolation and striatal (3H) serotonin uptake: role in the voluntary intake of ethanol by rats

Ethanol preferring rats were selected and showed a constant voluntary intake of a 12 percent ethanol solution during 14 days (about 5 g/kg body weight daily). Analysis of 3H serotonin uptake by striatal synaptosomes showed that steady state 3H serotonin synaptosomal levels were lower in alcohol preferring rats. Grouping these rats (5 per cage) reduced both voluntary intake of ethanol and synaptosomal 3H serotonin uptake. Furthermore, blocking the serotonin uptake by clomipramine 5 mg X kg-1 or 10 mg X kg-1 also reduces voluntary intake of ethanol. These data are in agreement with the hypothesis of a modulation of the voluntary intake of ethanol both by chemical and housing stimulation of striatal receptors for serotonin.     

Chronic toxicity study with the serotonin antagonist amesergide administered nasogastrically to rhesus monkeys for one year

The chronic toxicity of amesergide, a selective (5HT₂/5HT_1c) serotonin antagonist, was evaluated in rhesus monkeys given daily nasogastric doses of 0, 5, 10, or 22.5 mg/kg for 1 year. An initial high dose of 25 mg/kg was reduced after approximately 1 week of dosing due to severe behavioral effects, including lethargy, a trance-like appearance, and rigidity, that interfered with the animal's ability to eat and drink. The behavioral effects, although still present at the new high dose of 22.5 mg/kg were less intense and subsided prior to subsequent daily dosing. All animals survived the treatment period. Clinical signs associated primarily with early treatment at the 25-mg/kg dose level resulted in reductions of body weights and food consumption. After the high dose was reduced from 25 mg/kg to 22.5 mg/kg, there were no significant effects on body weight gain or food consumption when compared to controls. Plasma concentrations of amesergide and its metabolites increased in a dose-dependent fashion. Areas under the plasma concentration-time curve (AUC) and peak plasma concentrations (Cmax) decreased substantially as the study progressed. Stress-related decreases occurred in leukocytic and erythrocytic parameters of high-dose males, but values returned to near pretest by study termination. Organ weights as well as gross and histological examination of tissues from animals of all treatment groups revealed no treatment-related lesions. No adverse effects occurred at daily doses of 5 or 10 mg/kg. © 1994 Wiley-Liss, Inc.     

Sigma (σ) receptor ligand, AC927 (N-phenethylpiperidine oxalate), attenuates methamphetamine-induced hyperthermia and serotonin damage in mice

Methamphetamine interacts with sigma (σ) receptors and AC927, a selective σ receptor ligand, protects against methamphetamine-induced dopaminergic neurotoxicity. In the present study, the effects of AC927 on methamphetamine-induced hyperthermia and striatal serotonergic neurotoxicity were evaluated. Male, Swiss Webster mice were injected (i.p.) every 2 h, for a total of four times, with one of the following treatments: Saline + Saline; Saline + Methamphetamine (5 mg/kg); AC927 (5, 10, 20 mg/kg) + Methamphetamine (5 mg/kg); or AC927 (5, 10, 20 mg/kg) + Saline. Pretreatment with AC927 (10 mg/kg) significantly attenuated methamphetamine-induced striatal serotonin depletions, striatal serotonin transporter reductions, and hyperthermia. At the doses tested, AC927 itself had no significant effects on serotonin levels, serotonin transporter expression, or body temperature. To evaluate the effects of higher ambient temperature on methamphetamine-induced neurotoxicity, groups of mice were treated at 37 °C. Overall, there was an inverse correlation between the body temperature of the animals and striatal serotonin levels. Together, the data suggest that AC927 (10 mg/kg) protects against methamphetamine-induced neurotoxicity. The reduction of methamphetamine-induced hyperthermia by AC927 may contribute to the observed neuroprotection in vivo.     

Neurochemical effects of chronic co-administration of ritanserin and haloperidol: comparison with clozapine effects

The effects of chronic treatment with clozapine (20 mg/kg per day), ritanserin (0.5 mg/kg per day), haloperidol (0.5 mg/kg per day), or the combination of haloperidol and ritanserin, on dopamine (DA) and serotonin (5-HT) metabolism were studied. Chronic haloperidol treatment decreased DA metabolism in nucleus caudatus. Chronic ritanserin treatment failed to alter striatal or mesolimbic DA metabolism but decreased the concentrations of 5-HT and 5-hydroxyindoleacetic acid in the nucleus raphe dorsalis. The effects of chronic haloperidol were not altered by concomitant ritanserin administration. In comparison, chronic clozapine treatment affected neither DA nor 5-HT metabolism. These results show that the biochemical effects of chronic haloperidol treatment on the major ascending DA neurons cannot be modulated by concomitant 5-HT₂ receptor blockade.     

Maternal exposure to diphenhydramine during the fetal period in rats: effects on physical and neurobehavioral development and on neurochemical parameters

Previous research from our laboratory suggested that the administration of antihistaminics (H(1) receptor antagonists) to pregnant Wistar rats throughout pregnancy altered brain sexual differentiation and dopaminergic physiology of the offspring. In the present study, we assessed the effects of 20 mg/kg diphenhydramine (DPH) administration to pregnant rats during the fetal period of pregnancy [Gestation Days (GDs) 16-21], a critical period for brain sexual differentiation and central nervous system (CNS) maturation. Maternal body weight and water and food consumption were measured during pregnancy and offspring physical and behavioral development were evaluated during lactation. Offspring open-field behavior was assessed at 21 and 100 days of age. After the final open-field test, male and female sexual behavior, stereotypy following an apomorphine challenge, striatal content of dopamine (DA), the dopamine metabolites 3,4-dihydroxyphenylacetic acid (DOPAC) and homovanilic acid (HVA), serotonin (5-HT) and the serotonin metabolite 5-hydroxyindolacetic acid (5-HIAA) were assessed. There were no significant treatment-related changes in maternal reproductive parameters, but DPH treatment decreased maternal body weight gain during the treatment period. Offspring physical parameters were not altered in the treated group, and no significant treatment-related changes were found in female open-field measures, sexual behavior or in striatal neurochemical measurements. However, delayed testis descent and altered patterns of sexual behavior occurred in male offspring accompanied by increased striatal DA, decreased striatal DOPAC as well as reduced DOPAC/DA, HVA/DA and 5-HIAA/5-HT ratios. Taken together, these data suggest that exposure to DPH during the fetal period of rat development altered postnatal CNS maturation and sexual development of male offspring via changes in striatal bioamine systems.     

Sibutramine, a serotonin uptake inhibitor, increases dopamine concentrations in rat striatal and hypothalamic extracellular fluid

We measured, using microdialysis, the effects of sibutramine, given intraperitoneally, on brain dopamine and serotonin flux into striatal and hypothalamic dialysates of freely moving rats, and on the uptake of [(3)H]-DA into striatal synaptosomes. For microdialysis experiments, samples collected every 30 min were assayed by high-pressure liquid chromatography, in a single run. Administration of a low dose of sibutramine (2.0 mg/kg, i.p) had no effect on dopamine or serotonin concentrations in striatal dialysates but higher doses increased both: 5 mg/kg increased these concentrations to 196+/-24% (p<0.01) and 221+/-28% (p<0.01) of baseline, respectively; 10 mg/kg increased dopamine to 260+/-66% (p<0.01) and serotonin to 160+/-20% (p<0.05) of baseline. In hypothalamus, the 5 mg/kg sibutramine dose increased the dopamine concentration to 186+/-40% (p<0.05) and that of serotonin to 312+/-86% (p<0.01) of baseline, while the 10 mg/kg (i.p.) dose increased dopamine to 392+/-115% (p<0.01), and serotonin to 329+/-104% (p<0.01) of baseline. In vitro, sibutramine blocked [(3)H]-dopamine uptake into striatal synaptosomes, with an IC(50) value of 3.8 microM. These findings indicate that sibutramine has at least as great an effect on brain extracellular dopamine levels as on brain serotonin, and suggest that the drug's antiobesity action may result from the changes it produces in brain dopamine as well as serotonin metabolism.     

The acute effect in rats of 3,4-methylenedioxyethamphetamine (MDEA, "eve") on body temperature and long term degeneration of 5-HT neurones in brain: a comparison with MDMA ("ecstasy").

Administration of a single dose of the recreationally used drug 3,4-methylenedioxyethamphetamine (MDEA or "eve") to Dark Agouti rats resulted in an acute dose-dependent hyperthermic response. The peak effect and duration of hyperthermia of a dose of MDEA of 35 mg/kg intraperitoneally was similar to a dose of 3,4-methylenedioxymethamphetamine (MDMA or "ecstasy") of 15 mg/kg intraperitoneally. Seven days later this dose of MDMA produced a marked (approximately 50%) loss of 5-HT and its metabolite 5-HIAA in cortex, hippocampus and striatum and a similar loss of [3H]-paroxetine binding in cortex: these losses reflecting the MDMA-induced neurotoxic degeneration of 5-HT nerve endings. In contrast, administration of MDEA (15, 25 or 35 mg/kg), even at the highest dose, produced only a 20% loss in cortex and hippocampus and no decrease in striatum. The neurotoxic effect of MDEA was only weakly dose-dependent. Neither MDEA (35 mg/kg) nor MDMA (15 mg/kg) altered striatal dopamine content 7 days later. MDEA appeared to have about half the potency of MDMA in inducing acute hyperthermia and 25% of the potency in inducing degeneration of cerebral 5-HT neurones. However since higher doses of MDEA (compared to MDMA) are probably necessary to induce mood changing effects, these data do not support any contention that this compound is a "safer" recreational drug than MDMA in terms of either acute toxicity or long term neurodegeneration.     

A single high dose treatment of kala-azar with Ambisome (amphotericin B lipid complex): a pilot study

Thirty four patients with parasitologically confirmed visceral leishmaniasis were divided randomly into two groups of 17. Group A received Ambisome (amphotericin B lipid complex) at a dose of 15mg/kg body weight infused over 2h as a single dose; patients in group B received amphotericin B deoxycholate at a dose of 1mg/kg body infused for 2h for 20days. All 34 patients had a clinical, parasitological and ultimate cure. Ambisome was much better tolerated than amphotericin B, and adverse events were fewer in the Ambisome group. It was concluded that, if the cost of Ambisome were reduced, it would be a suitable first line drug. A longer study comparing three regimes of Ambisome: 15mg/kg body weight, 11mg/kg body weight and 7.5mg/kg body weight, should be undertaken.     

Effect of p-chloroamphetamine on morphine withdrawal syndrome

Adult male rats were injected four times a day with increasing doses of morphine sulfate until a dose of 405 mg/kg/day was tolerated. After 5 days of maintenance at that dose, withdrawal signs were observed at 24, 48, and 72 hr of withdrawal. Given 4 or 18 hr after last morphine injection, a single administration (3–12 mg/kg) of p-chloroamphetamine (PCA) blocked withdrawal “wet shakes” and ptosis during the following withdrawal period. Dose-dependent reduction in withdrawal hypothermia was observed only at 24 hr of withdrawal. Writhing was blocked only at higher doses. Morphine-withdrawal aggression measured at 72 hr of withdrawal and loss in body weight were not blocked by any delayed action of PCA. However, withdrawal aggression was blocked by PCA when given 1 hr before measurement at a dose of 3 mg/kg. Mice that were made morphine dependent by repeated injections of morphine given in large doses, exhibited withdrawal jumping either after cessation of morphine injections, or on injection of naloxone. PCA (3–12 mg/kg) given 2 hr before naloxone blocked this jumping in a dose-dependent manner. It also blocked withdrawal jumping in morphine-deprived mice when injected 2 hr, but not 14 or 17 hr before measurement. Jumping induced by α-naphthyloxyacetic acid (α-NOAA) was not blocked. The effect of PCA on different signs of morphine withdrawal is time dependent and may be related to its similarly time-dependent effect on brain serotonin and dopamine.     

THE EFFECT OF δ9-TETRAHYDROCANNABINOL (δ9-THC) ON THE TURNOVER RATE OF BRAIN SEROTONIN OF THE RAT

1. One isotopic and three non-isotopic methods were used to determine the effect of an acute intravenous dose of Δ⁹-tetrahydrocannabinol (Δ⁹-THC, 2 mg/kg) on the rat brain turnover rate of serotonin. 2. In control animals the turnover rate of serotonin was about 2 nmol/g per h. This rate was not altered by Δ⁹-THC when it was calculated from the rise of 5-hydroxyindoleacetic acid following probenecid or from the rise of serotonin following pargyline. 3. Δ⁹-THC did not alter the serotonin turnover rate when it was calculated from the conversion of ³H-tryptophan to ³H-serotonin. 4. The serotonin turnover rate was significantly increased by Δ⁹-THC when the rate was calculated from the decline of 5-hydroxyindoleacetic acid following pargyline. 5. These results suggest that Δ⁹-THC does not alter the turnover of rat brain serotonin. The previously reported Δ⁹-THC-induced changes in body temperature and increased brain levels of 5-hydroxyindoleacetic acid may be mediated by some other mechanism such as interference by Δ⁹-THC of the vesicular binding of serotonin.     

Domoic acid: Neurobehavioral and neurohistological effects of low-dose exposure in adult rats

Adult rats treated IP with domoic acid at 0, 0.22, 0.65, or 1.32 mg/kg were tested for passive avoidance (PA), auditory startle (AS), or conditioned avoidance (CAR) behaviors. Clinical signs were observed only at the 1.32 mg/kg dose level. Within 24 h of dosing, rats surviving a dose of 1.32 mg/kg exhibited transient decreased body weight and exaggerated AS responding. Startle latency and habituation, PA, and CAR were not affected. Examination of brains from six rats per group revealed a subset (2/6) of animals receiving 1.32 mg/kg domoic acid with degenerating neurons in the hippocampal CA1/CA3 subregions and gliosis. The decreased body weight and increased startle suggest a hyperreactivity syndrome possibly related to neuronal degeneration in the hippocampus. In a separate experiment, domoic acid at an IP dose of 0.93 mg/kg was found to produce hypomotility in addition to a decrease in body weight. Both effects were reduced by pretreatment with scopolamine (2 mg/kg), but not with caffeine (30 mg/kg), indicating a possible cholinergic involvement in domoate's toxicity.