Discriminative stimulus properties of toluene in the mouse

Abuse-like toluene exposure during early adolescence alters subsequent ethanol and cocaine behavioral effects and brain monoamines in male mice

Currently, there is a gap in understanding the neurobiological impact early adolescent toluene exposure has on subsequent actions of other drugs. Adolescent (PND 28-32) male Swiss-Webster mice (N = 210) were exposed to 0, 2000, or 4000 ppm of toluene vapor for 30 min/day for 5 days. Immediately following the last toluene exposure (PND 32; n = 15) or after a short delay (PND 35; n = 15), a subset of subjects' brains was collected for monoamine analysis. Remaining mice were assigned to one of two abstinence periods: a short 4-day (PND 36) or long 12-day (PND 44) delay after toluene exposure. Mice were then subjected to a cumulative dose response assessment of either cocaine (0, 2.5, 5, 10, 20 mg/kg; n = 60), ethanol (0, 0.5, 1, 2, 4 g/kg; n = 60), or saline (5 control injections; n = 60). Toluene concentration-dependently increased locomotor activity during exposure. When later challenged, mice exposed previously to toluene were significantly less active after cocaine (10 and 20 mg/kg) compared to air-exposed controls. Animals were also less active at the highest dose of alcohol (4 g/kg) following prior exposure to 4000 ppm when compared to air-exposed controls. Analysis of monoamines and their metabolites using High Pressure Liquid Chromatography (HPLC) within the medial prefrontal cortex (mPFC), nucleus accumbens (NAc), dorsal striatum (dSTR), and ventral tegmental area (VTA) revealed subtle effects on monoamine or metabolite levels following cumulative dosing that varied by drug (cocaine and ethanol) and abstinence duration. Our results suggest that early adolescent toluene exposure produces behavioral desensitization to subsequent cocaine-induced locomotor activity with subtle enhancement of ethanol's depressive effects and less clear impacts on levels of monoamines.

The Effects of the Inhalant Toluene on Cognitive Function and Behavioral Flexibility: A Review of Recent Findings

Substance use disorder (SUD) is characterized, in part, by lack of control over drug seeking and taking. The prefrontal cortex (PFC) is highly involved in control of behavior and deficits in PFC structure and function have been demonstrated in clinical and preclinical studies of SUD. Of the various classes of drugs associated with the development of SUD, inhalants are among the least studied despite their widespread use among adolescents and children. In this work, we review what is currently known regarding the sites and mechanisms of action of inhalants with a focus on the volatile solvent toluene that is contained in a wide variety of legal and easily obtained products. We then describe how inhalants including toluene affect various behaviors with an emphasis on those associated with PFC function and how chronic use of inhalants alters brain structure and neuronal signaling. Findings from these studies highlight advances made in recent years that have expanded our understanding of the effects of inhalants on brain structure and reinforce the need for continued work in this field.

Discriminative Stimulus Effects of Abused Inhalants

Inhalants are a loosely organized category of abused compounds defined entirely by their common route of administration. Inhalants include volatile solvents, fuels, volatile anesthetics, gasses, and liquefied refrigerants, among others. They are ubiquitous in modern society as ingredients in a wide variety of household, commercial, and medical products. Persons of all ages abuse inhalants but the highest prevalence of abuse is in younger adolescents. Although inhalants have been shown to act upon a host of neurotransmitter receptors, the stimulus effects of the few inhalants which have been trained or tested in drug discrimination procedures suggest that their discriminative stimulus properties are mediated by a few key neurotransmitter receptor systems. Abused volatile solvent inhalants have stimulus effects that are similar to a select group of GABAA positive modulators comprised of benzodiazepines and barbiturates. In contrast the stimulus effects of nitrous oxide gas appear to be at least partially mediated by uncompetitive antagonism of NMDA receptors. Finally, volatile anesthetic inhalants have stimulus effects in common with both GABAA positive modulators as well as competitive NMDA antagonists. In addition to a review of the pharmacology underlying the stimulus effects of inhalants, the chapter also discusses the scientific value of utilizing drug discrimination as a means of functionally grouping inhalants according to their abuse-related pharmacological properties.

Benzodiazepine-like discriminative stimulus effects of toluene vapor

In vitro studies show that the abused inhalant toluene affects a number of ligand-gated ion channels.The two most consistently implicated of these are γ-aminobutyric acid type A(GABAA) receptors which are positively modulated by toluene and N-methyl-D-aspartate(NMDA) receptors which are negatively modulated by toluene. Behavioral studies also suggest an interaction of toluene with GABAA and/or NMDA receptors but it is unclear if these receptors underlie the abuse-related intoxicating effects of toluene. Seventeen B6SJLF1/J mice were trained using a two-choice operant drug discrimination procedure to discriminate 10 min of exposure to 2000 ppm toluene vapor from 10 min of exposure to air. The discrimination was acquired in a mean of 65 training sessions. The stimulus effects of 2000 ppm toluene vapor were exposure concentration-dependent but rapidly diminished following the cessation of vapor exposure. The stimulus effects of toluene generalized to the chlorinated hydrocarbon vapor perchloroethylene but not 1,1,2-trichloroethane nor the volatile anesthetic isoflurane. The competitive NMDA antagonist CGS-19755, the uncompetitive antagonist dizocilpine and the glycine-site antagonist L701,324 all failed to substitute for toluene. The classical nonselective benzodiazepines midazolam and chlordiazepoxide produced toluene-like stimulus effects but the alpha 1 subunit preferring positive GABAA modulator zaleplon failed to substitute for toluene. The barbiturates pentobarbital and methohexital and the GABAA positive modulator neurosteroid allopregnanolone did not substitute for toluene. These data suggest that the stimulus effects of toluene may be at least partially mediated by benzodiazepine-like positive allosteric modulation of GABAA receptors containing alpha 2, 3 or 5 subunits.

Discriminative stimulus effects of inhaled 1,1,1-trichloroethane in mice: comparison to other hydrocarbon vapors and volatile anesthetics

RATIONALE

Because the toxicity of many inhalants precludes evaluation in humans, drug discrimination, an animal model of subjective effects, can be used to gain insights on their poorly understood abuse-related effects.

OBJECTIVES

The purpose of the present study was to train a prototypic inhalant that has known abuse liability, 1,1,1-trichloroethane (TCE), as a discriminative stimulus in mice, and compare it to other classes of inhalants.

MATERIALS AND METHODS

Eight B6SJLF1/J mice were trained to discriminate 10 min of exposure to 12,000 ppm inhaled TCE vapor from air and seven mice were trained to discriminate 4,000 ppm TCE from air. Tests were then conducted to characterize the discriminative stimulus of TCE and to compare it to representative aromatic and chlorinated hydrocarbon vapors, volatile halogenated anesthetics as well as an odorant compound.

RESULTS

Only the 12,000 ppm TCE versus the air discrimination group exhibited sufficient discrimination accuracy for substitution testing. TCE vapor concentration- and exposure time-dependently substituted for the 12,000 ppm TCE vapor training stimulus. Full substitution was produced by trichloroethylene, toluene, enflurane, and sevoflurane. Varying degrees of partial substitution were produced by the other volatile test compounds. The odorant, 2-butanol, did not produce any substitution for TCE.

CONCLUSIONS

The discriminative stimulus effects of TCE are shared fully or partially by chlorinated and aromatic hydrocarbons as well as by halogenated volatile anesthetics. However, these compounds can be differentiated from TCE both quantitatively and qualitatively. It appears that the degree of similarity is not solely a function of chemical classification but may also be dependent upon the neurochemical effects of the individual compounds.

Characterization of an inhaled toluene drug discrimination in mice: effect of exposure conditions and route of administration

The drug discrimination procedure in animals has been extensively utilized to model the abuse related, subjective effects of drugs in humans, but it has seldom been used to examine abused volatile inhalants like toluene. The present study sought to characterize the temporal aspects of toluene's discriminative stimulus as well assess toluene blood concentrations under identical exposure conditions. B6SJLF1/J mice were trained to discriminate 10 min of exposure to 6000 ppm inhaled toluene vapor from air. Toluene vapor concentration dependently substituted for the training exposure condition with longer exposures to equivalent concentrations producing greater substitution than shorter exposures. Toluene's discriminative stimulus effects dissipated completely by 60 min after the cessation of exposure. Injected liquid toluene dose-dependently substituted for toluene vapor as well as augmenting the discriminative stimulus effects of inhaled toluene. Toluene blood concentrations measured under several exposure conditions which produced full substitution were all nearly identical suggesting that the concentration of toluene in the animal tissues at the time of testing determined discriminative performance. These results indicate that the discriminative stimulus effects of inhaled toluene vapor are likely mediated by CNS effects rather than by its pronounced peripheral stimulus effects.

Inhaled toluene vapor as a discriminative stimulus

Few studies exist exploring the discriminative stimulus effects of inhalants and none that have trained an interoceptive discrimination using the inhaled route. This study was designed to assess if it was possible to train an inhaled toluene discrimination. The second objective was to determine whether the discrimination was based on interoceptive or exteroceptive stimulus effects. Eight B6SJLF1/J mice were trained to discriminate 10 min of exposure to 6000 ppm inhaled toluene vapor from air, using a standard food-reinforced operant procedure. Toluene vapor produced robust, concentration-dependent, discriminative stimulus effects, with concentrations of 4000 ppm and higher producing full substitution. Substitution of inhaled toluene vapor for the training condition was exposure-time dependent. A minimum of 7 min of exposure to 6000 ppm was required to produce complete substitution. Injected intraperitoneal toluene produced dose-dependent full substitution for inhaled toluene vapor. Both inhaled and intraperitoneal ethylbenzene produced similar levels of partial substitution for 6000 ppm toluene vapor. Inhaled isoflurane vapor produced no substitution for toluene vapor. These results show that a toluene vapor discrimination can be successfully trained in mice and the discrimination is selective for toluene compared to ethylbenzene and isoflurane. The results also suggest that the discrimination was likely to have been based primarily on interoceptive rather than exteroceptive stimulus effects.

Comparative study of the effects of toluene, benzene, 1,1,1-trichloroethane, diethyl ether, and flurothyl on anxiety and nociception in mice

The main purpose of this study was to compare the effects of solvents from different chemical classes on anxiety and nociception. Independent groups of mice were exposed to air (control group), toluene (1000-4000 ppm), benzene (1000-4000 ppm), 1,1,1-trichloroethane (TCE, 2000-12000 ppm), diethyl ether (10,000-30,000) or flurothyl (200-600 ppm). After a 30-min exposure, animals were tested either in the anxiety paradigm conditioned defensive burying (CDB) test or in the hot plate test. All solvents but flurothyl produced anxiolytic-like actions being the order of potency toluene > benzene > TCE > diethyl ether. When tested in the hot plate paradigm, toluene and TCE increased nociception, benzene and diethyl ether had no effects, and flurothyl decreased nociception Additional groups of mice were conditioned to recognize the aversive stimulus (electrified prod) prior to toluene exposure and then tested in the CDB test. In unconditioned animals, toluene increased the number of shocks that mice received; however, when mice had previous experience in the CDB test, toluene lacked this effect. Taken together, these results show that inhalants have different effects with different potencies both in the CDB and in the hot plate tests. Additionally, data suggest that acute administration of toluene could impair learning.

Inhibition of neuronal nicotinic acetylcholine receptors by the abused solvent, toluene

1 Toluene is a representative example of a class of industrial solvents that are voluntarily inhaled as drugs of abuse. Previous data from this lab and others has shown that toluene modulates the function of N-methyl-D-aspartate (NMDA), gamma-aminobutyric acid (GABA) and glycine receptors at concentrations that do not affect non-NMDA receptors. 2 We utilized two-electrode voltage-clamp and whole cell patch-clamp techniques to assess the effects of toluene on neuronal nicotinic acetylcholine receptors expressed in oocytes and cultured hippocampal neurons. Toluene (50 micro M to 10 mM) produced a reversible, concentration-dependent inhibition of acetylcholine-induced current in Xenopus oocytes expressing various nicotinic receptor subtypes. The alpha4beta2 and alpha3beta2 subunit combinations were significantly more sensitive to toluene inhibition than the alpha4beta4, alpha3beta4 and alpha7 receptors. 3 Receptors composed of alpha4 and beta2(V253F) subunits showed alpha4beta4-like toluene sensitivity while those containing alpha4 and beta4(F255V) subunits showed alpha4beta2-like sensitivity. 4 In hippocampal neurons, toluene (50 micro M to 10 mM) dose-dependently inhibited ACh-mediated responses with an IC(50) of 1.1 mM. 5 Taken together, these results suggest that nicotinic receptors, like NMDA receptors, show a subunit-dependent sensitivity to toluene and may represent an important site of action for some of the neurobehavioural effects of toluene.

Evaluation of rewarding effect of toluene by the conditioned place preference procedure in mice

Toluene and many toluene-containing products are abused via inhalation. Previous investigations have used the place preference paradigm to evaluate the rewarding effects of commonly abused drugs such as morphine, cocaine, and amphetamine. A conditioning paradigm of toluene inhalation was developed in order to estimate the rewarding effect in mice. Conditioning sessions (five for toluene, five for air) were conducted twice daily for 5 days using a newly developed airtight inhalation shuttlebox (15x30x15 cm: wxlxh), which was divided into two compartments of equal size. One compartment was white with a textured floor, and the other was black with a smooth floor. All conditioning sessions were 20 min in duration, with a minimum of 7 h between sessions. Test sessions were carried out 1 day after the final training session with mice in a drug-free state. The time spent in each compartment during a 20-min session was measured using a digital video camera. Exposure to toluene vapors (700-3200 ppm) produced a significant conditioned place preference in mice. These results suggest that the conditioned place preference procedure using the newly developed airtight inhalation shuttlebox constitutes an important tool for studying the rewarding effect of abused solvents.

Toluene inhalation produces regionally specific changes in extracellular dopamine

The aim of the present study was to investigate the effect of toluene inhalation on dopaminergic transmission in two distinct brain areas presumably involved in mediating the reward processes important for toluene abuse. Extracellular dopamine (DA) levels were measured in prefrontal cortex (PFC) and nucleus accumbens (NACC) of freely moving rats using in vivo microdialysis. Inhalation of a behaviorally relevant concentration of toluene (3000 ppm) produced a significant increase in the PFC but not in the NACC. However, the odorant isoamyl acetate, increased PFC DA levels by only 37%, significantly less than the 96% increase observed following toluene exposure. When toluene inhalation was combined with cocaine administration (20 mg/kg i.p.), the response to the combined challenge was not different from the response to toluene alone in the PFC. However, the combination of these two drugs produced a supradditive response of 802% in the NACC, compared with the 450% increase observed following cocaine alone. Recent reports indicate that toluene influences the function of several ionotropic receptors in a subunit specific manner. As further evidence of specific effects, our results indicate regionally specific changes in dopaminergic transmission following toluene exposure.

Evaluation of 1,1,1-trichloroethane and flurothyl locomotor effects following diazepam treatment in mice

The abused volatile solvent 1,1,1-trichloroethane (TCE) shares many acute behavioral effects with central nervous system (CNS) depressants; however, demonstration of tolerance to these effects has been difficult. The purpose of the present study was to investigate the development of TCE-induced changes in locomotor activity in mice following repeated injections with diazepam. In the initial concentration-effect curve determinations, diazepam decreased locomotor activity at all doses tested and TCE produced a biphasic effect, increasing locomotor activity at lower concentrations with return to control levels at a high (16,000 ppm) concentration. Flurothyl, a vapor with convulsive properties, had no pronounced effects on locomotor activity at subconvulsant concentrations. Following four daily injections with vehicle or with 10 mg/kg/day diazepam, mice were administered the same concentration of drug/inhalant that they received initially and were retested for locomotor activity effects. Concentration-effect curves for diazepam and flurothyl were not altered by this modest regimen of repeated dosing with diazepam. In contrast, sensitization to the locomotor-stimulating effects of TCE was observed in diazepam-treated mice, but not in vehicle-treated mice. These results suggest that the development of sensitization to TCE involves common mechanisms with those that are affected by repeated dosing with the CNS depressant diazepam.

Effects of chronic inhalation of volatile solvents, malnutrition and their interaction on seizures induced by pentylenetetrazole in rats

Chronic inhalation of volatile solvents induce severe brain damage. In humans, intense exposure to volatile solvents for recreational purposes is frequently associated with chronic malnutrition. We studied in rats the effects of chronic inhalation of volatile solvents and malnutrition, alone and combined, on the seizures induced by pentylenetetrazole. Animals were subjected to 14 months of either normal rodent diet or malnutrition induced by a diet based on corn derivatives; some animals were subjected for the last 4 months to daily inhalation of volatile solvents (paint thinner). Afterwards, a trial of pentylenetetrazole-induced seizures was conducted in all animals. When compared with controls, malnutrition, chronic inhalation of volatile solvents and their combination greatly reduced the threshold for both, the forebrain and the brain stem components of seizures. However, an expected lowering of the threshold when malnutrition and solvent inhalation were combined was not observed when compared with each condition alone. It is possible that malnutrition plus solvents exposure induce severe brain damage that interferes with the brain structures involved in the propagation of epileptic seizures.

Neural basis of inhalant abuse

It should be apparent from this review that far less is known about the neural basis for inhalant abuse than for other forms of drug abuse. This reflects a lack of research interest in this area (Balster, 1997). Indeed, conclusions are difficult to draw. In the case of the volatile alkyl nitrites, the most reasonable hypothesis at this time is that the cellular basis for their abuse resides in their actions on smooth muscles to produce vasodilation and relaxation, however, direct effects on the brain cannot be ruled out. Although there is some evidence that analgesic effects of nitrous oxide may involve opiate systems, even this conclusion is controversial. There is no evidence that opiate systems play a role in nitrous oxide intoxication or reinforcement. The mechanisms for these effects are unknown. They may reflect the same actions on lipid membranes or on hydrophobic sites on unspecified proteins that have been proposed as mechanisms for nitrous oxide anesthesia. In the case of the volatile solvents, fuels and anesthetics we are faced with a wide variety of specific chemicals which may produce different profiles of pharmacological effects. There is evidence that the prototypic abused solvents toluene and trichloroethane produce acute effects similar to subanesthetic concentrations of general anesthetics, as well as to the effects of classical CNS depressant drugs, such as alcohol and the barbiturates. For the anesthetics, evidence suggests that enhancement of GABAergic inhibition may be an important cellular target for their acute effects, just as it is for alcohol and other depressant drugs. For toluene, as with alcohol, recent evidence suggests a possible role for inhibition of glutamatergic neurotransmission involving NMDA receptors. Toluene has also been shown to have some dopaminergic effects which may be important to its abuse. As for the large number of other abused vapors, practically no information can be found on their cellular actions, and certainly not on actions that may be relevant to their abuse. This entire area would seem an important direction for future research.

The effects of abused inhalants on mouse behavior in an elevated plus-maze

Previous research has shown that abused inhalants (i.e., the volatile solvents) share some of the pharmacological properties of drugs used in the treatment of anxiety. In an attempt to further examine commonalities in the effects of inhalants and central nervous system depressant drugs, the behavioral effects of inhaled 1,1,1-trichloroethane, toluene, methoxyflurane and the convulsant vapor flurothyl were examined and compared to those of diazepam in the elevated plus-maze, a test used to predict antianxiety effects. After inhalant exposure or diazepam injection, mice were placed in the center of an elevated plus-maze and the number of entries and time spent in each type of arm (open versus closed) were measured during 5-min tests. Exposure to increasing concentrations of toluene produced concentration-related increases in the total number of open arm entries and the total time spent on the open arms, a pattern of behavioral effects similar to that produced by diazepam. A similar pattern was observed for increasing concentrations of 1,1,1-trichloroethane and methoxyflurane but changes in open arm activity were only observed at concentrations that increased locomotor activity. Conversely, only decreases in open arm time and number of entries were observed for flurothyl. The increasing evidence for commonalities in the behavioral effects of volatile solvents and depressant drugs may provide a foundation for understanding the neurobehavioral basis of inhalant abuse.

Dog liver microsomal P450 enzyme-mediated toluene biotransformation

1. We studied toluene metabolism in dog liver microsomes and the major metabolite was benzyl alcohol with o- and p-cresol as minor metabolites. 2. The enzyme kinetics of toluene biotransformation were examined by means of Lineweaver-Burk analyses. The Michaelis-Menten values differed among the three pathways, the order being; Km, o-cresol > p-cresol > benzyl alcohol; Vmax, benzyl alcohol > o-cresol > p-cresol; and Cl(int), benzyl alcohol > p-cresol > o-cresol. 3. The formation of benzyl alcohol, o- and p-cresol from toluene was substantially inhibited by the P4502E inhibitors such as DDC (diethyldithiocarbamate) and 4-methylpyrazole in all pathways, with IC50's in the range of 0.02-0.59 mM. The P4502B inhibitors, metyrapone and secobarbital also inhibited benzyl alcohol and p-cresol formation, whereas o-cresol was not inhibited by these latter compounds. 4. Anti-rat P4502E1 antibodies inhibited benzyl alcohol, o- and p-cresol formation from 26 to 30% 0.2 ml serum/mg microsomal protein. Furthermore, anti-rat P4502B1/2 antibody inhibited benzyl alcohol and p-cresol formation (47 and 44% respectively), but not that of o-cresol. Anti-rat P4502C11/6 antibody also inhibited benzyl alcohol and p-cresol formation 31 and 24% respectively in a similar manner to that by the anti-rat P4502B1/2 antibody. 5. These results suggested that the P4502B, 2C and 2E isozymes in dog liver contribute to the formation of benzyl alcohol and p-cresol from toluene, and 2E isozyme preferentially contributes to the formation of o-cresol.

Experimental estimation of addictive potential of a mixture of organic solvents

In the present study we investigated in rats the reinforcing properties of glue vapours which are a mixture of four organic solvents (toluene 25%, benzine fraction 37%, ethyl acetate 31% and methylene chloride 7%). This mixture is used as a glue thinner and is a very popular among glue-sniffing children. Immediately after inhalation at a concentration of 7200 ppm, the glue vapours increased locomotor activity in the open field and response rate of self-stimulation in the lateral hypothalamus. Contrary to classical drug abuse, glue vapours enhanced the threshold current of self-stimulation. While the response rate of self-stimulation decreased to the control level 30 min after inhalation, the threshold current was still enhanced. Increasing the concentration of the vapours produced a decrease in response rate of self-stimulation and locomotor activity. When glue vapours were inhaled at a concentration of 14,400 ppm and higher, the response rate of self-stimulation was completely suppressed. The discriminative stimulus effects of the glue vapours appeared to be similar to those of general anaesthetics such as ether and pentobarbital. At vapour concentrations of 7200 and 14,400 ppm, conditioned place preference was established. The ability of solvents to reinforce conditioning in the place preference paradigm and to activate the brain reward system in intracranial self-stimulation experiments may be useful for predicting the addictive potential of inhalants.

CNS depressant effects of volatile organic solvents

Volatile chemicals used widely as solvents can produce acute effects on the nervous system and behavior after inhalation exposure, and many are subject to abuse. This review considers the nature of the acute effects of volatile organic solvents by comparing their actions to those of classical CNS depressant drugs such as the barbiturates, benzodiazepines and ethanol. Like CNS depressant drugs, selected inhalants have been shown to have biphasic effects on motor activity, disrupt psychomotor performance, have anticonvulsant effects, produce biphasic drug-like effects on rates of schedule-controlled operant behavior, increase rates of punished responding, enhance the effects of depressant drugs, serve as reinforcers in self-administration studies and share discriminative stimulus effects with barbiturates and ethanol. Toluene and 1,1,1-trichloroethane, as well as subanesthetic concentrations of halothane, have been the most extensively studied; however, it is unclear whether important differences may exist among solvents in their ability to produce a depressant profile of acute effects. The possibility that selected solvents can have acute effects similar to those of depressant drugs may shed light on the nature of their acute behavioral toxicology and on their abuse.

Kinetic studies on toluene metabolism in ethanol- and phenobarbital-induced rat liver microsomes in vitro

In vitro metabolism of toluene was investigated at substrate concentrations of 0.03-6.25 mM in liver microsomes from control and ethanol- and phenobarbital (PB)-treated rats. Three metabolites, benzylalcohol (BA), o- and p-cresol, were measured by high-performance liquid chromatograph. BA was the main metabolite of toluene, whereas o- and p-cresol contributed only 1.1-1.5% and 1.7-2.8% of total metabolites, respectively, in microsomes from control rats. Ethanol treatment showed little effect on the percentages of three metabolites, but PB increased the percentages of o- and p-cresol to as high as 5.5% and 8.0%, respectively, following the increase in toluene concentration. There were two different isozymes with different Km involved in the side-chain hydroxylation of toluene in microsomes from control and ethanol-treated rats. One had a low Km value (0.13-0.17 mM) and could be greatly induced with ethanol treatment. The other was a high Km isozyme (0.60-0.87 mM). PB-induced isozyme showed a similar Km value to that of the high Km isozyme existing in microsomes from control and ethanol-treated rats. Two isozymes were involved in the formation of p-cresol in microsomes of control rats: the low-Km type had a similar value (0.15 mM) to the low isozyme of BA formation, but the high Km isozyme had a larger value (2.04 mM) than the high isozyme of BA. Only one enzyme responsible for o-cresol formation was detected in microsomes of control rats, and had a similar Km (2.11 mM) to that of the high Km isozyme of p-cresol.(ABSTRACT TRUNCATED AT 250 WORDS)

Discriminative stimulus properties of toluene in the rat

Rats were trained to discriminate toluene (100 mg/kg, IP) from vehicle in a two-lever operant task. Acquisition of the discrimination required a range of 85-219 training days. Injections of either methohexital (0.5-10 mg/kg) or oxazepam (0.5-20 mg/kg) produced toluene-lever responding in a dose-dependent fashion in most animals. The discriminative stimulus properties of toluene were not found to generalize to chlorpromazine (0.3-10 mg/kg). These results are consistent with those obtained in the mouse and provide further evidence that toluene has stimulus properties similar to those of CNS depressant drugs. These results further suggest that toluene may have drug abuse potential of the CNS depressant type.

Effect of toluene on rat synaptosomal phospholipid methylation and membrane fluidity

This study investigated the effects of toluene (1 g/kg, 1 hr, i.p.) on rat synaptosomal phospholipid methylation (PLM), phospholipid composition, and membrane fluidity. Toluene significantly decreased basal PLM (35%) in studies using [3H]methionine [( 3H]Met) as the methyl donor; this was reflected by similar decreases in phosphatidylmonomethylethanolamine (PME) (30%). No effects were observed in either PLM reactions that used [3H]adenosylmethionine [( 3H]AdoMet) as methyl donor, or AdoMet synthetase, suggesting that toluene preferentially affects PLM reactions that derive methyl groups from [3H]Met. Also, toluene decreased synaptosomal phosphatidylethanolamine (PE) (24%), the initial substrate for PLM, and the addition of PE back to PE-depleted synaptosomes restored methyltransferase activity. Agonist-stimulated PLM using norepinephrine (NE) demonstrated that agonist-receptor coupling returned PLM to control values in synaptosomes from toluene-treated rats. NE-stimulated PLM was also blocked by propranolol (PRO), suggesting a role for toluene in receptor-mediated events. Membrane fluidity studies demonstrated that in vivo administration of toluene increased the outer synaptosomal membrane fluidity, whereas in vitro administration of toluene had no effect. Our observations support a positive relationship between increased PLM activity and increased outer, not core, membrane fluidity. These data demonstrate that specific toluene-phospholipid interactions occur in synaptosomes, resulting in altered membrane composition, function and fluidity.

Evidence of tolerance following repeated exposure to toluene in the rat

Toluene shares pharmacological properties with other abused central nervous system depressants such as ethanol and the barbiturates. Although tolerance has been clearly demonstrated for these classic CNS depressants, evidence of tolerance following repeated toluene exposure is equivocal. The present work examined if tolerance would develop to the effects of repeated toluene exposure on learned behavior and examined the possibility that external discriminative stimuli could influence these effects. Two variants of a fixed-consecutive-number schedule of reinforcement were used as components in a multiple schedule. The components differed in whether or not behavior within them was under the control of external discriminative stimuli. Rats were exposed daily for two hours to toluene (1780 to 4500 ppm). Different patterns of effects emerged from repeated exposure; some rats displayed tolerance while the performance of others deteriorated. Behavior controlled by external discriminative stimuli was more resistant to disruption and showed tolerance more readily than did behavior not under such control.