Discontinuation of methylphenidate after long-term exposure in nonhuman primates.

Attention-deficit hyperactivity disorder (ADHD) is a common human neurobehavioral disorder that usually begins in early childhood. Methylphenidate (MPH) has been used extensively as a first-line medicine for the treatment of ADHD. Since ADHD is often diagnosed in early childhood and can persist for the entire lifespan, individuals may take MPH for many years. Given that in the course of one's lifetime a person may stop taking MPH for periods of time, or may implement lifestyle changes that may reduce the need for MPH entirely, it is important to understand how cessation of MPH affects the adult brain following long-term use of MPH. The blockage of the dopamine transporter (DAT) and the norepinephrine transporter (NET) by MPH may help with ADHD symptoms by boosting monoamine levels in the synapse. In the present study, microPET/CT was used to investigate possible neurochemical alterations in the cerebral dopamine system after cessation of long-term MPH administration in nonhuman primates. MicroPET/CT images were collected from adult male rhesus monkeys 6 months after they stopped receiving vehicle or MPH following 12 years of chronic treatment. The neurochemical status of brain dopaminergic systems was evaluated using the vesicular monoamine transporter 2 (VMAT2) ligand [18F]-AV-133 and a tracer for imaging dopamine subtype 2 (D2) and serotonin subfamily 2 (5HT2) receptors, [18F]-FESP. Each tracer was injected intravenously and ten minutes later microPET/CT images were obtained over 120 min. The binding potential (BP) of each tracer in the striatum was obtained using the Logan reference tissue model with the cerebellar cortex time activity curve (TAC) as an input function. Brain metabolism was also evaluated using microPET/CT images of [18F]-FDG. [18F]-FDG was injected intravenously, and ten minutes later, microPET/CT images were obtained over 120 min. Radiolabeled tracer accumulation in regions of interest (ROIs) in the prefrontal cortex, temporal cortex, striatum, and cerebellum were converted into standard uptake values (SUVs). Compared to the vehicle control group, the BPs of [18F] AV-133 and [18F]-FESP in the striatum were not significantly altered in MPH treated groups. Additionally, no significant differences were detected in the SUVs of [18F]-FDG in the MPH treated group compared with control. This study demonstrates that 6 months after cessation of long-term, chronic MPH treatment, there are no significant neurochemical or neural metabolic changes in the central nervous system (CNS) of non-human primates (NHPs) and suggests that microPET imaging is helpful in assessing the status of biomarkers of neurochemical processes linked to chronic CNS drug exposure. (Supported by NCTR).

MicroPET imaging of ketamine-induced neuronal apoptosis with radiolabeled DFNSH.

Recent reports indicate that 6-12 h of ketamine anesthesia can trigger neuronal apoptosis in postnatal day (PND) 7 rats. In vitro, ex vivo, and confocal fluorescent imaging studies suggest that dansyl compounds can accumulate within the cytoplasm of the apoptotic cell. High-resolution positron emission tomography (microPET) imaging has been proposed as a minimally invasive method for detecting apoptosis in the rat brain. Compared with [(18)F]-labeled annexin V, which binds to externalized phosphatidylserine (PS) on the outer membrane of apoptotic cells, intracellular uptake of the dansylhydrazone of p-fluorobenzaldehyde (DFNSH) may lead to improved target-to-background contrast ratios. In this study, the effect of ketamine on the uptake and retention of [(18)F]-DFNSH in the rat brain was investigated using microPET imaging. On PND 7, rat pups in the experimental group were exposed, at 2-h intervals, to six subcutaneous injections of ketamine (20 mg/kg) and control rat pups received six injections of saline. On PND 35, [(18)F]-DFNSH (37 MBq) was injected into the tail vein of rats and microPET images were obtained over 2 h following the injection. Radiolabeled tracer accumulation in the region of interest (ROI) in the frontal cortex was converted into standard uptake values (SUVs). The radiotracer was quickly distributed into the brains of both ketamine- and saline-treated rats. Compared with the control group, the uptake of [(18)F]-DFNSH was significantly increased in the ROI, frontal cortex area of ketamine-treated rats. In addition, the wash-out duration of the tracer was prolonged in the ketamine-treated animals. This study demonstrates that microPET imaging is capable of distinguishing differences in retention of [(18)F]-DFNSH in ROI and suggests that this compound may serve as a minimally invasive biomarker of neuronal apoptosis in rodents.

MicroPET/CT assessment of neurochemical effects in the brain after long-term methylphenidate treatment in nonhuman primates.

Methylphenidate (MPH) is a psychostimulant approved by the FDA to treatment Attention-Deficit Hyperactivity Disorder (ADHD). MPH is believed to exert its pharmacological effects via preferential blockade of the dopamine transporter (DAT) and the norepinephrine transporter (NET), resulting in increased monoamine levels in the synapse. We used a quantitative non-invasive PET imaging technique to study the effects of long-term methylphenidate use on the central nervous system (CNS). We conducted microPET/CT scans on young adult male rhesus monkeys to monitor changes in the dopaminergic system. We used [18F] AV-133, a ligand for the vesicular monoamine transporter 2 (VMAT2), and [18F]FESP a ligand for the D2 and 5HT2 receptors. In this study we evaluated the effects if chronic MPH treatment in the nonhuman primates (NHP). Two-year-old, male rhesus monkeys were orally administered MPH diluted in the electrolyte replenisher, Prang, twice a day, five days per week (M-F) over an 8-year period. The dose of MPH was gradually escalated from 0.15 mg/kg initially to 2.5 mg/kg/dose for the low dose group, and 1.5 mg/kg to 12.5 mg/kg/dose for the high dose group (Rodriguez et al., 2010). Scans were performed on Mondays, about 60 h after their last treatment, to avoid the acute effects of MPH. Tracers were injected intravenously ten minutes before microPET/CT scanning. Sessions lasted about 120 min. The Logan reference tissue model was used to determine the Binding Potential (BP) of each tracer in the striatum with the cerebellar cortex time activity curve as an input function. Both MP treatment groups had a lower [18F] AV-133 BP, although this failed to reach statistical significance. MPH treatment did not have a significant effect on The BP of [18F] FESP in the striatum. Long-term administration of MPH did not significant change any of the marker of monoamine function used here. These data suggest that, despite lingering concerns, long-term use of methylphenidate does not negatively impact monoamine function. This study also demonstrates that microPET imaging can distinguish differences in binding potentials of a variety of radiotracers in the CNS of NHPs. This approach may provide minimally-invasive biomarkers of neurochemical processes associated with chronic exposure to CNS medications. (Supported by NCTR).

The effects of L-carnitine on the combination of, inhalation anesthetic-induced developmental, neuronal apoptosis in the rat frontal cortex.

The anesthetic gas nitrous oxide (N2O) and the volatile anesthetic isoflurane (ISO) are commonly used in surgical procedures for human infants and in veterinary and laboratory animal practice to produce loss of consciousness and analgesia. Recent reports indicate that exposure of the developing brain to general anesthetics that block N-methyl-D-aspartate (NMDA) glutamate receptors or potentiate GABA(A) receptors can trigger widespread apoptotic neurodegeneration. In the present study, the question arises whether a relatively low dose of ISO alone or its combination with N2O entails significant risk of inducing enhanced apoptosis. In addition, the role of L-carnitine to attenuate these effects was also examined. Postnatal day 7 (PND-7) rat pups were exposed to N2O (75%) or a low dose of ISO (0.55%) alone, or N2O plus ISO for 2, 4, 6 or 8 h with or without L-carnitine. The neurotoxic effects were evaluated 6 h after completion of anesthetic administration. No significant neurotoxic effects were observed for the animals exposed to N2O or ISO alone. However, enhanced apoptotic cell death was apparent when N2O was combined with ISO at exposure durations of 6 h or more. Co-administration of L-carnitine (300 or 500 mg/kg, i.p.) effectively protected neurons from the anesthetic-induced damage. These data indicate that 6 h or more of inhaled anesthetic exposure consisting of a combination of N2O and ISO results in enhanced neuronal apoptosis, and L-carnitine effectively blocks the neuronal apoptosis caused by inhalation anesthetics in the developing rat brain.

L-carnitine protects neurons from 1-methyl-4-phenylpyridinium-induced neuronal apoptosis in rat forebrain culture.

1-Methyl-4-phenylpyridinium ion (MPP+), an inhibitor of mitochondrial complex I, has been widely used as a neurotoxin because it elicits a severe Parkinson's disease-like syndrome with an elevation of intracellular reactive oxygen species (ROS) and apoptosis. L-carnitine plays an integral role in attenuating the brain injury associated with mitochondrial neurodegenerative disorders. The present study investigates the effects of L-carnitine against the toxicity of MPP+ in rat forebrain primary cultures. Cells in culture were treated for 24 h with 100, 250, 500 and 1000 microM MPP+ alone or co-incubated with L-carnitine. MPP+ produced a dose-related increase in DNA fragmentation as measured by cell death ELISA (enzyme-linked immunosorbent assay), an increase in the number of TUNEL (terminal dUTP nick-end labeling)-positive cells and a reduction in the mitochondrial metabolism of 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT). No significant effect was observed with the release of lactate dehydrogenase (LDH), indicating that cell death presumably occurred via apoptotic mechanisms. Co-incubation of MPP+ with L-carnitine significantly reduced MPP+-induced apoptosis. Western blot analyses showed that neurotoxic concentrations of MPP+ decreased the ratio of BCL-X(L) to Bax and decreased the protein levels of polysialic acid neural cell adhesion molecules (PSA-NCAM), a neuron specific marker. L-carnitine blocked these effects of MPP+ suggesting its potential therapeutic utility in degenerative disorders such as Parkinson's disease, Alzheimer's disease, ornithine transcarbamylase deficiency and other mitochondrial diseases.

Behavioral effects associated with chronic ketamine or remacemide exposure in rats.

The effects of chronic exposure to ketamine or remacemide on the acquisition and performance of food-reinforced operant behaviors was assessed in female Sprague-Dawley rats. Ketamine is an anesthetic N-methyl-D-aspartate (NMDA) receptor antagonist, whereas remacemide is an active central nervous system compound with both NMDA receptor antagonist and sodium channel blocking properties. Learning, audio/visual discrimination and motivation were modeled using incremental repeated acquisition (IRA), audio/visual discrimination (AVD) and progressive ratio (PR) tasks, respectively. Ketamine (10 or 100 mg/kg/day), remacemide (100 or 150 mg/kg/day) or water was administered daily (7 days/week) via orogastric gavage beginning on postnatal day (PND) 23 and continuing until PND 257. Monday through Friday behavioral assessments began on PND 27 and continued until PND 383. Chronic treatment with the high dose of ketamine decreased response rate in all tasks suggesting decreased motivation or motoric capabilities. Chronic treatment with ketamine or remacemide had no effect on the acquisition of IRA task performance at any dose tested. While chronic treatment with either high-dose ketamine or low-dose remacemide only delayed the acquisition of AVD task performance for a brief period midway through treatment, chronic treatment with high-dose remacemide delayed the acquisition of AVD task performance until late in treatment. The findings for ketamine are quite different from those of MK-801 (the prototypic NMDA receptor antagonist) in a previous rat study in which MK-801 severely disrupted the acquisition of both IRA and AVD task performances. These observations suggest important differences in the mechanism of action between ketamine and MK-801. For example, ketamine has a much lower binding affinity than MK-801 for the NMDA receptor, the dopamine transporter and the dopamine D2 receptor. In addition, the findings for remacemide observed in rats are in marked contrast with those seen in monkeys where chronic remacemide had profound disruptive effects on the acquisition of both IRA and AVD task performances and suggest important species differences.

Effect of chronic MK-801 and/or phenytoin on the acquisition of complex behaviors in rats.

The purpose of the present experiment was to assess the effects of chronic MK-801 (an N-methyl-D-aspartate receptor antagonist) and/or phenytoin (a sodium channel blocker) treatment on behavioral acquisition and performance in rats. Learning, audio/visual discrimination and motivation were modeled using incremental repeated acquisition (IRA), audio/visual discrimination (AVD) and progressive ratio (PR) tasks, respectively. MK-801 and/or phenytoin were administered daily, 7 days/week by orogastric gavage beginning just after weaning on postnatal day (PND) 23 and continuing until PND 306. Monday through Friday behavioral assessments began on PND 27 and continued until PND 430. Throughout treatment, subjects in the high dose MK-801 (1.0 mg/kg/day) and the high dose drug combination (1.0 mg/kg/day MK-801+150 mg/kg/day phenytoin) groups exhibited decreased body weight gains compared to control subjects. For these two affected groups, response rates were also decreased in all tasks. Task acquisition, as evidenced by an increase in response accuracy, was decreased for both these groups in the AVD task, but only for the high dose MK-801 group in the IRA task. The data suggest that chronic MK-801 treatment adversely affects the acquisition of IRA and AVD task performance and that the inclusion of phenytoin in the MK-801 dosing regimen blocks some of the adverse effects of chronic MK-801 treatment on IRA task acquisition. These findings are in marked contrast with those observed in nonhuman primates and suggest important species differences associated with chronic exposure to compounds that block NMDA receptors and/or sodium channels.

Response sequence difficulty in an incremental repeated acquisition (learning) procedure.

Incremental repeated acquisition (IRA) procedures require subjects to learn a different sequence of behavioral responses during each experimental session with required response sequences increasing incrementally in length as subjects demonstrate mastery of shorter response chains. The purpose of this study was to investigate whether some response sequences are more or less difficult to acquire than others. If true, then sequence difficulty must be considered as a potential confound when attempting to assess the effects of drugs and other experimental manipulations on learning. Accuracy for each response sequence was assessed using control data from two large rodent studies, and each sequence was classified as easy, moderate or hard. Sequences that required responses on adjacent levers were easier (characterized by higher accuracies) to acquire than those that required responses on non-adjacent levers. In addition, sequences that required responses on only two of three response levers were easier to acquire than those that required responses on all three levers. These results provide strong evidence for differing levels of response sequence difficulty in IRA procedures with sequence difficulty seeming to be dependent on whether or not responses are required on adjacent levers.

Minimally invasive biomarkers of general anesthetic-induced developmental neurotoxicity.

The association of general anesthesia with developmental neurotoxicity, while nearly impossible to study in pediatric populations, is clearly demonstrable in a variety of animal models from rodents to nonhuman primates. Nearly all general anesthetics tested have been shown to cause abnormal brain cell death in animals when administered during periods of rapid brain growth. The ability to repeatedly assess in the same subjects adverse effects induced by general anesthetics provides significant power to address the time course of important events associated with exposures. Minimally-invasive procedures provide the opportunity to bridge the preclinical/clinical gap by providing the means to more easily translate findings from the animal laboratory to the human clinic. Positron Emission Tomography or PET is a tool with great promise for realizing this goal. PET for small animals (microPET) is providing valuable data on the life cycle of general anesthetic induced neurotoxicity. PET radioligands (annexin V and DFNSH) targeting apoptotic processes have demonstrated that a single bout of general anesthesia effected during a vulnerable period of CNS development can result in prolonged apoptotic signals lasting for several weeks in the rat. A marker of cellular proliferation (FLT) has demonstrated in rodents that general anesthesia-induced inhibition of neural progenitor cell proliferation is evident when assessed a full 2weeks after exposure. Activated glia express Translocator Protein (TSPO) which can be used as a marker of presumed neuroinflammatory processes and a PET ligand for the TSPO (FEPPA) has been used to track this process in both rat and nonhuman primate models. It has been shown that single bouts of general anesthesia can result in elevated TSPO expression lasting for over a week. These examples demonstrate the utility of specific PET tracers to inform, in a minimally-invasive fashion, processes associated with general anesthesia-induced developmental neurotoxicity. The fact that PET procedures are also used clinically suggests an opportunity to confirm in humans what has been repeatedly observed in animals.

MicroPET/CT assessment of FDG uptake in brain after long-term methylphenidate treatment in nonhuman primates.

Methylphenidate (MPH) is a psychostimulant commonly used for the treatment of Attention-Deficit Hyperactivity Disorder (ADHD). Since the long-term effects of this drug on the central nervous system (CNS) are not well understood, we conducted microPET/CT scans on young adult male rhesus monkeys (n=4/group) to gather information on brain metabolism using the uptake of [(18)F]Fluoro-2-deoxy-2-d-glucose (FDG) as a marker. Approximately two-year old, male rhesus monkeys were treated orally with MPH twice per day, five days per week (M-F) over a 6-year period. Subjects received MPH at either 2.5 or 12.5mg/kg/dose or vehicle (Prang). To minimize the acute effects of MPH on FDG uptake, microPET/CT scans were scheduled on Mondays before their first daily dosing of the week (approximately 68h since their last treatment). FDG (370±8.88MBq) was injected intravenously and 30min later microPET/CT images were obtained over 60min. Radiolabeled tracer accumulation in regions of interest (ROIs) in the prefrontal cortex, temporal cortex, striatum and cerebellum were converted into Standard Uptake Values (SUVs). Compared to the control group, the uptake of FDG in the cerebellum was significantly decreased in both the low and high dose groups. These preliminary data demonstrate that microPET imaging is capable of distinguishing differences in retention of FDG in the brains of NHPs treated chronically with MPH and suggests that this approach may provide a minimally invasive biomarker for exploring the effects of chronic MPH treatment on aspects of brain function.

Effects of MDMA on complex brain function in laboratory animals.

This review surveys experiments that have examined the effects of acute and chronic MDMA exposure on schedule-controlled operant behaviors thought to engender responses that reflect the expression of complex brain functions. Such functions include time estimation, short-term memory, learning, motivation, and color and position discrimination. Recent experiments conducted in the Behavioral Toxicology Laboratory at the National Center for Toxicological Research concerning MDMA's acute and long-term effects on rhesus monkey performance in an operant test battery are compared to previous studies involving the effects of MDMA on operant behaviors. Results of these experiments suggest that when given acutely, MDMA disrupts complex brain functions associated with learning and time estimation more than those associated with short-term memory and visual discrimination, and that behavioral tasks requiring relatively high rates of responding are particularly sensitive to the disruptive effects of MDMA. Repeated exposure to doses of MDMA sufficient to produce long-lasting changes in brain neurotransmitter systems results in residual effects (e.g. tolerance, sensitivity) on behavioral task performance when subjects are subsequently challenged with acute MDMA, whereas baseline (non-challenged) performance of these tasks after such exposure generally remains unchanged. Although the experiments described herein were conducted on a relatively small number of non-human subjects, they raise the possibility that long-term effects on cognitive processes may also occur in humans exposed to repeated or acute high doses of MDMA.

Repeated acquisition of response sequences: the analysis of behavior in transition.

Repeated acquisition (RA) procedures are behavioral preparations in which subjects are required to learn new response sequences within each experimental session. Such procedures avoid problems inherent in nonRA learning procedures. For example, as the subject masters nonRA tasks, one begins to measure performance of a learned response rather than learning itself. Advantages to using RA procedures include (a) the strength of the within-subjects design, including the ability to establish dose effect curves within individual subjects; (b) the ability to assess learning phenomena over extended periods of time; (c) the ability to use chronic dosing regimens; and (d) the ability to assess treatments with permanent or long-lasting effects. In addition, analysis of the response patterns committed during acquisition allows for a description of how behavioral strategies may change in response to experimental manipulation. Difficulties include the relatively long training period often preceding attainment of a stable baseline of acquisition. This review examines the history of RA paradigms, with an emphasis on procedural comparisons.

Behavioral effects of methylazoxymethanol-induced micrencephaly.

This study was prompted by reports of functionally normal humans with micrencephaly or cortical hypoplasia. Methylazoxymethanol acetate (MAM) treatment, which induces micrencephaly in rats, was administered by injection (20 mg/kg) on gestational day 14. Prior to weaning and into adulthood, offspring were assessed on many behavioral tests. There were 3 findings. First, MAM rats (forebrain weight less than 2/3 of controls) were not profoundly hyperactive. Increased activity was seen only on prolonged tests or after amphetamine administration. Second, MAM rats were hypoactive in some conditions. These rats were light shy and less likely to explore lighted areas. MAM rats appeared hyperreactive to environmental stimuli, but not hyperactive. Finally, no MAM effect on behavior was as large as that on brain weight. Thus, as with clinical findings, rat micrencephalics are more remarkable for functional sparing than for behavioral abnormalities.

The effects of cocaine on nonhuman primate brain function are age dependent.

The effects of acute intravenous (i.v.) cocaine (COC) on several complex brain functions were studied in rhesus monkeys at 1.5, 3 and 10-11 years of age. Subjects performed several operant tasks (for food) that were used to model learning, short-term memory, color and position discrimination, and motivation, and disruption of performance of these tasks was used to quantitate drug effect. Drug effects were age dependent: The youngest subjects were 3 to 10 times less sensitive than the oldest. Presuming the observed behavioral effects of cocaine were caused primarily via its interaction with dopamine (DA) systems, changes in sensitivity to its effects with age are likely a reflection of the functional status of the DA system. These data, along with preliminary data on levels of DA transporters, suggest that the age-related differences in sensitivity to cocaine lie in, 'downstream' from, the dopamine receptor.

Acute effects of dexfenfluramine (d-FEN) and methylenedioxymethamphetamine (MDMA) before and after short-course, high-dose treatment.

The acute behavioral effects of methylenedioxymethamphetamine (MDMA) and dexfenfluramine (d-FEN) were assessed in six rhesus monkeys using performance in the National Center for Toxicological Research (NCTR) Operant Test Battery (OTB); three additional animals served as controls for neurochemical endpoints. The OTB consists of five food-reinforced tasks designed to model aspects of learning, short-term memory and attention, time estimation, motivation, and color and position discrimination. Shortly after the acute effects of each drug were determined, three of the monkeys received a short-course, high-dose exposure (2x /day x 4 days, intramuscular (i.m.) injections) of MDMA (10 mg/kg), while three monkeys were exposed to an identical regimen of d-FEN (5 mg/kg). Approximately one month later, the acute effects of each drug were again determined. In monkeys exposed to high-dose d-FEN, the sensitivities of the OTB tasks to acute disruption by either MDMA or d-FEN were essentially unchanged. Conversely, monkeys treated with high-dose MDMA were less sensitive to the acute behavioral effects of both drugs, although such an effect was seen more frequently for d-FEN and was OTB task specific. Thus a residual behavioral tolerance to the acute behavioral effects of MDMA and d-FEN was noted after high-dose MDMA exposure, but not after high-dose d-FEN exposure. These findings are surprising, as similar neurochemical effects (i.e., significant decreases of ca. 50% in serotonin in frontal cortex and hippocampus) were observed in all monkeys approximately six months after short-course, high-dose MDMA or d-FEN treatment.

Repeated acquisition and the assessment of centrally acting compounds.

Repeated acquisition (RA) procedures are behavioral preparations in which subjects learn new sequences of responses during each experimental session. They have been used with great success to assess the effects of drugs and other compounds on learning processes. As learning can be measured over many sessions in individual subjects, RA procedures can prove invaluable when conducting studies of the effects of chronic drug administration, aging and the long-term effects of exposure to toxic compounds. Analyzing the patterns of responding during acquisition can provide insights into the behavioral mechanisms underlying the effects of drugs and other centrally acting compounds on learning. Systematic comparisons are needed on the influence of many procedural variables on RA and the extent to which they may modulate the effects of chemicals.

Cognitive tests: interpretation for neurotoxicity? (Workshop summary).

The appropriate use and interpretation of cognitive tests presents important challenges to the toxicologist and to the risk assessor. For example, intelligence cannot be measured directly; rather intelligence is quantified indirectly by scoring responses (i.e., behaviors) to specific situations (problems). This workshop, "Cognitive Tests: Interpretation for Neurotoxicity?" provided an overview on the types of cognitive tests available and described approaches by which the validity of such tests can be assessed. Unlike many tools available to the toxicologist, cognitive tests have a particular advantage. Being noninvasive and species-neutral, the same test can be performed in different mammalian species. This enhances one's ability to assess the validity of test results. Criteria for test validity include comparable responses across species as well as similar disruption by the same neurotoxicant across species. Test batteries, such as the Operant Test Battery, have indicated remarkable similarity between monkeys and children with respect to performance of certain tasks involving, for example, short-term memory. Still, there is a need for caution in interpretation of such tests. In particular, cognitive tests, especially when performed in humans, are subject to confounding by a range of factors, including age, gender, and, in particular, education. Moreover, the ability of such tests to reflect intelligence must be considered. Certain aspects of intelligence, such as the ability to plan or carry out specific tasks, are not well reflected by many of the standard tests of cognition. Nonetheless, although still under development, cognitive tests do hold promise for reliably predicting neurotoxicity in humans.

Similar effects of amphetamine and methylphenidate on the performance of complex operant tasks in rats.

Methylphenidate and D-amphetamine are central nervous system stimulants that have been suggested to share certain behavioral and neurochemical effects. The current study was undertaken to determine whether methylphenidate and D-amphetamine have similar effects on the performance of a battery of complex operant tasks in rats. Thus, the effects of amphetamine (0.1-6.0 mg/kg, i.p.) and methylphenidate (1.12-18.0 mg/kg, i.p) on the performance of rats in three complex food-reinforced operant tasks were examined. The tasks (and the brain functions they are intended to model) included: (1) conditioned position responding (auditory/visual/position discrimination); (2) incremental repeated acquisition (learning); and (3) temporal response differentiation (time estimation). In addition, each of these tasks was paired with a progressive ratio task to assess drug effects on the rats' motivation to lever press for the food reinforcers used. Consistent with their effects in other behavioral paradigms, methylphenidate and D-amphetamine produced very similar patterns of disruption of the four tasks. Drug-induced changes in the endpoints of the progressive ratio task generally paralleled changes in the other three tasks, suggesting a major role for appetitive motivation in the effects of these agents. Several effects of these agents seen in the current study are consistent with their effects in children with attention-deficit-hyperactivity disorder. These data further validate the use of this battery of operant tasks for the characterization of pharmacological agents, and suggest that findings using these tasks may be predictive of what is seen in humans.

No alterations in the performance of two interval timing operant tasks after alpha-difluoromethylornithine (DFMO)-induced cerebellar stunting.

The cerebellum is critically involved in temporal processes in the millisecond range and may be involved in longer time estimations (i.e. in the seconds range). Estimates in the millisecond range are impaired after developmentally induced cerebellar alterations, however, little is known about the effects of similar alterations on longer timing performance. Appropriately timed DFMO treatment reliably causes cerebellar stunting in rats, however, its effects on temporal estimation performance are unknown. Here, male and female Sprague-Dawley rats were treated with subcutaneous injections of 500 mg/kg DFMO on postnatal days 5-12, causing a 10% cerebellar weight reduction at adulthood. As adults, subjects were tested under one of two paradigms - a differential reinforcement of low response rate (DRL) task requiring that subjects withhold a lever press response for 10-14 s or a temporal response differentiation (TRD) task requiring that subjects maintain a lever press response for 10-14 s. Training and steady-state performance of the DRL and TRD tasks were not significantly altered by DFMO treatment. Performance after acute challenges with two dopaminergic agonists (2.00-7.50 mg/kg methylphenidate and 0.10-1.00 mg/kg d-amphetamine) was measured after which all subjects underwent behavioral extinction. Generally, performance after methylphenidate and d-amphetamine was similar in control and DFMO-treated rats and DFMO treatment had no differential effects on performance during extinction. These results support findings from an earlier study [Ferguson SA, Paule MG, Holson RR. Neonatal dexamethasoneon day 7 in rats causes behavioral alterations reflective of hippocampal, but not cerebellar, deficits. Neurotoxicol Teratol, 2001; 23:57-69] indicating that developmental cerebellar stunting has few effects on time estimation within the range of seconds.

Morphometric studies of the rat hippocampus following chronic delta-9-tetrahydrocannabinol (THC).

Persistent behavioral effects resembling those of hippocampal brain lesions have been reported following chronic administration of marijuana or its major psychoactive constituent, delta-9-tetrahydrocannabinol (THC) to rats. We used morphometric techniques to investigate the effects of chronic THC on the anatomical integrity of the hippocampus. Rats dosed orally for 90 days with 10 to 60 mg/kg THC or vehicle were evaluated by light and electron microscopy up to 7 months after their last dose of drug. Electron micrographs revealed a striking ultrastructural appearance and statistically significant decreases in mean volume of neurons and their nuclei sampled from the hippocampal CA3 region of rats treated with the highest doses of THC. A 44% reduction in the number of synapses per unit volume was demonstrated in these same rats. Golgi impregnation studies of additional groups of rats treated with 10 or 20 mg/kg/day THC and sacrificed 2 months after their last treatment with THC revealed a reduction in the dendritic length of CA3 pyramidal neurons, despite normal appearing ultrastructure and no changes in synaptic density. The hippocampal changes reported here may constitute a morphological basis for behavioral effects after chronic exposure to marijuana.