Differential effects of two NMDA receptor antagonists on cognitive--behavioral performance in young nonhuman primates II

Neurocognitive performance and repeated-dose intravenous ketamine in major depressive disorder

OBJECTIVE

Ketamine has demonstrated a rapid antidepressant and antisuicidal effect in patients with major depressive disorder (MDD), but the neurocognitive effects of ketamine are relatively unknown. This study aims to examine the neurocognitive effects of six ketamine infusions and the association of baseline neurocognitive function and the change in severity of depressive symptoms after the last infusions.

METHODS

Sixty-four patients with MDD completed six intravenous infusions of ketamine (0.5 mg/kg over 40 min) administered over a 12-day period (Monday-Wednesday-Friday), and were followed by a 2-week observational period. Four domains of neurocognitive function (including speed of processing, working memory, visual learning and verbal learning) were assessed using the MATRICS Consensus Cognitive Battery (MCCB) at 0, 13 and 26 days.

RESULTS

In linear mixed model, significant improvements were found in terms of speed of processing (F = 20.7, p < 0.001) and verbal learning (F = 11.1, p < 0.001). The Sobel test showed the improvement of speed of processing (Sobel test = 2.8, p < 0.001) and verbal learning (Sobel test = 3.6, p < 0.001) were significantly mediated by change in depressive symptoms. Other two neurocognitive domains showed no significant changes over time. Correlation analysis showed no significant association of change in depressive symptoms with neurocognitive function at baseline.

CONCLUSION

Our findings suggest that six ketamine infusions were associated with the improvement of speed of processing and verbal learning, which were partly accounted for by improvement in the severity of depression symptoms over time.

Peripheral fibroblast metabolic pathway alterations in juvenile rhesus monkeys undergoing long-term fluoxetine administration

We report on biochemical pathways perturbed upon chronic fluoxetine administration to juvenile macaques using global metabolomics analyses of fibroblasts derived from skin biopsies. After exposure to tissue culture conditions confounding environmental factors are eliminated and identification of metabolites whose levels are affected by the drug become apparent with a better signal-to-noise ratio compared to data obtained from plasma and cerebrospinal fluid (CSF). Levels of more than 200 metabolites were analyzed to interrogate affected molecular pathways and identify biomarkers of drug response. In addition, we have correlated the metabolomics results with monoamine oxidase (MAOA) genotype and impulsivity behavioral data. Affected pathways include Purine and Pyrimidine metabolisms that have been previously implicated to contribute to neuropsychiatric disorders.

Neurocognitive performance and serial intravenous subanesthetic ketamine in treatment-resistant depression

The N-methyl-D-aspartate glutamate receptor antagonist ketamine has demonstrated rapid antidepressant effects in treatment-resistant depression (TRD). However, evaluation of ketamine's neurocognitive aspects in TRD has started to be explored. This study aims to (1) examine baseline neurocognitive performance and change in severity of depressive symptoms through six ketamine infusions, (2) examine the neurocognitive effects after completion of serial infusions and whether changes were associated to relapse to depression. Six IV infusions of 0.5 mg/Kg ketamine over 40 min were conducted on a Monday-Wednesday-Friday schedule during a 12-d period on 15 patients with TRD followed by a 4-wk observational period. Neurocognitive functioning was assessed using the CogState battery at baseline and at each follow-up visit. Tasks were designed to test attention, memory (working, visual, and verbal), speed of processing, and set shifting. The likelihood of response through six infusions was greater among depressed subjects with lower attention at baseline (F(1,13)=5.59, p=0.034). Significant improvement was found in scores of visual memory (F(4,33.82)=5.12, p=0.002), simple working memory (F(4, 24.85)=3.29, p=0.027) and complex working memory (F(4, 32.76)=4.18, p=0.008) after the last ketamine infusion. However, neurocognitive changes were accounted for by improvement in the severity of depressive symptom. The acute neurocognitive effect after completion of repeated infusions was not associated with the likelihood of subsequent relapse during follow-up. Our findings suggest a potential baseline neurocognitive predictor of ketamine response and the apparently lack of short-term neurocognitive impairment after completion of six ketamine infusions in TRD.

Neuropathological sequelae of developmental exposure to antiepileptic and anesthetic drugs

Glutamate (Glu) and γ-aminobutyric acid (GABA) are major neurotransmitters in the mammalian brain which regulate brain development at molecular, cellular, and systems level. Sedative, anesthetic, and antiepileptic drugs (AEDs) interact with glutamate and GABA receptors to produce their desired effects. The question is posed whether such interference with glutamatergic and GABAergic neurotransmission may exert undesired, and perhaps even detrimental effects on human brain development. Preclinical research in rodents and non-human primates has provided extensive evidence that sedative, anesthetic, and AEDs can trigger suicide of neurons and oligodendroglia, suppress neurogenesis, and inhibit normal synapse development and sculpting. Behavioral correlates in rodents and non-human primates consist of long-lasting cognitive impairment. Retrospective clinical studies in humans exposed to anesthetics or AEDs in utero, during infancy or early childhood have delivered conflicting but concerning results in terms of a correlation between drug exposure and impaired neurodevelopmental outcomes. Prospective studies are currently ongoing. This review provides a short overview of the current state of knowledge on this topic.

Behavioral toxicology of cognition: extrapolation from experimental animal models to humans: behavioral toxicology symposium overview

A variety of behavioral instruments are available for assessing important aspects of cognition in both animals and humans and, in many cases, the same instruments can be used in both. While nonhuman primates are phylogenetically closest to humans, rodents, pigeons and other animals also offer behaviors worthy of note. Delay Discounting procedures are as useful as any in studies of impulsivity and may have utility in shedding light on processes associated with drug abuse. Specific memory tests such as Visual Paired Comparisons tasks (similar to the Fagan test of infant intelligence) can be modified to allow for assessment of different aspects of memory such as spatial memory. Use of these and other specific memory tasks can be used to directly monitor aspects of cognitive development in infant animals, particularly in nonhuman primates such as monkeys, and children and to draw inferences with respect to possible neuroanatomical substrates sub-serving their functions. Tasks for assessing working memory such as Variable Delayed Response (VDR), modified VDR and Spatial Working Memory tasks are now known to be affected in Parkinson's disease (PD). These and other cognitive function tasks are being used in a monkey model of PD to assess the ability of anti-Parkinson's disease therapies to ameliorate these cognitive deficits without diminishing their therapeutic effects on motor dysfunction. Similarly, in a rat model of the cognitive deficits associated with perinatal exposure to polychlorinated biphenyls (PCBs), clear parallels with children can be seen in at least two areas of executive function: cognitive flexibility and response inhibition. In the rat model, discrimination reversal tasks were utilized to assess cognitive flexibility, a function often assessed in humans using the Wisconsin Card Sorting Task. Response inhibition was assessed using performance in a Differential Reinforcement of Low Response Rates (DRL) task. As the data continue to accumulate, it becomes more clear that our attempts to adapt animal-appropriate tasks for the study of important aspects of human cognition have proven to be very fruitful.

Ketamine anesthesia during the first week of life can cause long-lasting cognitive deficits in rhesus monkeys

Previously our laboratory has shown that ketamine exposure (24h of clinically relevant anesthesia) causes significant increases in neuronal cell death in perinatal rhesus monkeys. Sensitivity to this ketamine-induced neurotoxicity was observed on gestational days 120-123 (in utero exposure via maternal anesthesia) and on postnatal days (PNDs) 5-6, but not on PNDs 35-37. In the present study, six monkeys were exposed on PND 5 or 6 to intravenous ketamine anesthesia to maintain a light surgical plane for 24h and six control animals were unexposed. At 7 months of age all animals were weaned and began training to perform a series of cognitive function tasks as part of the National Center for Toxicological Research (NCTR) Operant Test Battery (OTB). The OTB tasks used here included those for assessing aspects of learning, motivation, color discrimination, and short-term memory. Subjects responded for banana-flavored food pellets by pressing response levers and press-plates during daily (M-F) test sessions (50 min) and were assigned training scores based upon their individual performance. As reported earlier (Paule et al., 2009) beginning around 10 months of age, control animals significantly outperformed (had higher training scores than) ketamine-exposed animals for approximately the next 10 months. For animals now over 3 and one-half years of age, the cognitive impairments continue to manifest in the ketamine-exposed group as poorer performance in the OTB learning and color and position discrimination tasks, as deficits in accuracy of task performance, but also in response speed. There are also apparent differences in the motivation of these animals which may be impacting OTB performance. These observations demonstrate that a single 24-h episode of ketamine anesthesia, occurring during a sensitive period of brain development, results in very long-lasting deficits in brain function in primates and provide proof-of-concept that general anesthesia during critical periods of brain development can result in subsequent functional deficits. Supported by NICHD, CDER/FDA and NCTR/FDA.

Toxicity assessment of pramipexole in juvenile rhesus monkeys

Pramipexole (PPX) is a dopamine agonist approved for the treatment of the signs and symptoms of idiopathic Parkinson's disease as well as restless leg syndrome. The objective of this study was to investigate the toxicity of PPX when administered orally to juvenile rhesus monkeys once daily for 30 weeks, and to assess the reversibility of toxicity during a 12-week recovery. Rhesus monkeys (N=4 males and 4 females/group; 22-24 months of age) were orally treated daily for 30 weeks with 0.0, 0.1, 0.5 or 2.0 mg/kg PPX, and subjects were assessed daily using the NCTR Operant Test Battery (OTB). Clinical chemistry, hematology, ophthalmology and other standard postmortem toxicological evaluations, including histopathology and neuropathology as well as toxicokinetics were performed. The systemic exposure to PPX was higher than that at therapeutic doses in man and AUC(0-24 h)-data increased proportionally to dose. Blood pressure significantly decreased over time in all groups including control. Near the end of treatment, there were statistically significant decreases in heart rate for the 0.5 and 2.0 mg/kg/day groups compared to control. After 4 weeks of dosing, serum prolactin was significantly decreased in all treatment groups compared to control. This decrease remained at the end of treatment in the 0.5 and 2.0 mg/kg/day groups. In summary, administration of PPX at doses of up to 2.0 mg/kg/day for 30 weeks to juvenile rhesus monkeys produced adverse findings which were attributable to its pharmacological properties, including hypoprolactinemia.

The effects of chronic methylphenidate administration on operant test battery performance in juvenile rhesus monkeys

Methylphenidate (MPH) is an amphetamine derivative widely prescribed for the treatment of attention deficit-hyperactivity disorder. Recent concern over its genotoxic potential in children [11] spurred a study on the effects of chronic MPH treatment in a nonhuman primate population and the studies reported here were conducted in conjunction with that study in the same animals. Here, the focus was on the ability of juvenile rhesus monkeys to learn how to perform a battery of operant behavioral tasks while being treated chronically with MPH. Performance of the National Center for Toxicological Research (NCTR) Operant Test Battery (OTB) was used to quantify the learning of tasks thought to model specific aspects of cognitive function including learning, motivation, color and position discrimination, and short-term memory. The OTB tasks designed to assess these specific behaviors included Incremental Repeated Acquisition (IRA), Progressive Ratio (PR), Conditioned Position Responding (CPR), and Delayed Matching-to-Sample (DMTS), respectively. Juvenile males (n=10/group) pressed levers and press-plates for banana-flavored food pellets. Subjects were treated orally, twice a day, five days per week (M-F) for 66 weeks with escalating doses (0.15 mg/kg initially, increased to 2.5 mg/kg for the low dose group and to 12.5 mg/kg for the high dose group) and tested in OTB tasks 30 to 60 min after the morning dose. The findings indicate that MPH at doses up to 2.5 mg/kg twice per day were well tolerated (performance was no different than controls) but at doses of 12.5 mg/kg twice per day there was a significant decrement in OTB performance, characterized by decreases in both percent task completed and response rates for all tasks. These effects of MPH seem primarily due to decreases in motivation to perform for food, which is not surprising given the well known appetite suppressing effects of amphetamine-like stimulants. Thus, the current data do not strongly suggest cognitive impairments following chronic MPH administration.

Approaches for assessing risks to sensitive populations: lessons learned from evaluating risks in the pediatric population

Assessing the risk profiles of potentially sensitive populations requires a "tool chest" of methodological approaches to adequately characterize and evaluate these populations. At present, there is an extensive body of literature on methodologies that apply to the evaluation of the pediatric population. The Health and Environmental Sciences Institute Subcommittee on Risk Assessment of Sensitive Populations evaluated key references in the area of pediatric risk to identify a spectrum of methodological approaches. These approaches are considered in this article for their potential to be extrapolated for the identification and assessment of other sensitive populations. Recommendations as to future research needs and/or alternate methodological considerations are also made.

The cognitive and psychomotor effects of remacemide and carbamazepine in newly diagnosed epilepsy

An international trial comparing remacemide hydrochloride with carbamazepine was undertaken in individuals with newly diagnosed epilepsy using a novel double-blind, parallel-group, double triangular sequential design. Patients with two or more partial or generalized tonic-clonic seizures in the previous year were randomized to remacemide or carbamazepine and titrated to a target dose of 600 mg/day. Subsequent dosage adjustments were allowed while maintaining the blind. Repeated assessments of neuropsychological function and mood were carried out using computerized and conventional measures. The trial was completed 20 months after initiation, following the second interim analysis. Efficacy as measured by seizure recurrence showed remacemide to be inferior to carbamazepine. Baseline cognitive and neuropsychological measures showed impairment across the whole patient population. Cognitive/neuropsychological performance at 8, 24, and 48 weeks was compared with that at baseline. Significant deterioration was seen on measures of information processing speed and attention after treatment with carbamazepine. The study data provide evidence for the utility and sensitivity of a number of cognitive assessments, which may be employed in future trials of antiepileptic drugs.

Learning large-scale spatial relationships in a maze and effects of MK-801 on retrieval in the rhesus monkey

Monkeys have strong abilities to remember the visual properties of potential food sources for survival in the nature. The present study demonstrated the first observations of rhesus monkeys learning to solve complex spatial mazes in which routes were guided by visual cues. Three monkeys were trained in a maze (6 m x 6 m) included of four different mazes. We recorded the cue and cup errors, latencies, and pathway for each trial. The data showed that monkeys learned the target place after three days in the first maze and spent a shorter time in learning the following mazes. The maze was an efficient method to measure the ability and proceeding of spatial memory in monkeys. Moreover, working memory can also be tested by using the maze. MK-801 at 0.02 mg/kg but not at 0.005 mg/kg impaired monkeys' retrieval of spatial memory after they learned all four mazes. The present maze may provide an efficient method to help bridging the gap in cognition between nonhuman primates and humans, and in particular to gain insight into human cognitive function and dysfunction.

Glutamate antagonists are neurotoxins for the developing brain

Neurotransmitters and neuromodulators are essential for normal nervous system development. Disturbances in the expression timetable or intensity of neurotransmitter signalling during critical periods of brain development can lead to permanent damage. Neuroactive drugs and environmental toxins interfere with neurotransmitter signalling and may thereby provide one mechanism underlying neurological abnormalities. Glutamate is the main excitatory neurotransmitter in the mammalian central nervous system and mediates neurotransmission across most excitatory synapses. In this article we review the timely expression of the excitatory neurotransmitter glutamate and its receptors during brain development, briefly review glutamate receptor antagonists and present clinical and experimental evidence describing their adverse effects in the developing brain.

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.

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.

Tuning the engine of cognition: A focus on NMDA/D1 receptor interactions in prefrontal cortex

The prefrontal cortex of the primate frontal lobes provides the capacity for judgment which can constantly adapt behavior in order to optimize its outcome. Adjudicating between long-term memory programs and prepotent responses, this capacity reviews all incoming information and provides an interpretation dependent on the events that have just occurred, the events that are predicted to happen, and the alternative response strategies that are available in the given situation. It has been theorized that this function requires two essential integrated components, a central executive which guides selective attention based on mechanisms of associative memory, as well as the second component, working memory buffers, in which information is held online, abstracted, and translated on a mental sketchpad of work in progress. In this review, we critically outline the evidence that the integration of these processes and, in particular, the induction and maintenance of persistent activity in prefrontal cortex and related networks, is dependent upon the interaction of dopamine D1 and glutamate NMDA receptor signaling at critical nodes within local circuits and distributed networks. We argue that this interaction is not only essential for representational memory, but also core to mechanisms of neuroadaptation and learning. Understanding its functional significance promises to reveal major new insights into prefrontal dysfunction in schizophrenia and, hence, to target a new generation of drugs designed to ameliorate the debilitating working memory deficits in this disorder.

Snakes as agents of evolutionary change in primate brains

Current hypotheses that use visually guided reaching and grasping to explain orbital convergence, visual specialization, and brain expansion in primates are open to question now that neurological evidence reveals no correlation between orbital convergence and the visual pathway in the brain that is associated with reaching and grasping. An alternative hypothesis proposed here posits that snakes were ultimately responsible for these defining primate characteristics. Snakes have a long, shared evolutionary existence with crown-group placental mammals and were likely to have been their first predators. Mammals are conservative in the structures of the brain that are involved in vigilance, fear, and learning and memory associated with fearful stimuli, e.g., predators. Some of these areas have expanded in primates and are more strongly connected to visual systems. However, primates vary in the extent of brain expansion. This variation is coincident with variation in evolutionary co-existence with the more recently evolved venomous snakes. Malagasy prosimians have never co-existed with venomous snakes, New World monkeys (platyrrhines) have had interrupted co-existence with venomous snakes, and Old World monkeys and apes (catarrhines) have had continuous co-existence with venomous snakes. The koniocellular visual pathway, arising from the retina and connecting to the lateral geniculate nucleus, the superior colliculus, and the pulvinar, has expanded along with the parvocellular pathway, a visual pathway that is involved with color and object recognition. I suggest that expansion of these pathways co-occurred, with the koniocellular pathway being crucially involved (among other tasks) in pre-attentional visual detection of fearful stimuli, including snakes, and the parvocellular pathway being involved (among other tasks) in protecting the brain from increasingly greater metabolic demands to evolve the neural capacity to detect such stimuli quickly. A diet that included fruits or nectar (though not to the exclusion of arthropods), which provided sugars as a neuroprotectant, may have been a required preadaptation for the expansion of such metabolically active brains. Taxonomic differences in evolutionary exposure to venomous snakes are associated with similar taxonomic differences in rates of evolution in cytochrome oxidase genes and in the metabolic activity of cytochrome oxidase proteins in at least some visual areas in the brains of primates. Raptors that specialize in eating snakes have larger eyes and greater binocularity than more generalized raptors, and provide non-mammalian models for snakes as a selective pressure on primate visual systems. These models, along with evidence from paleobiogeography, neuroscience, ecology, behavior, and immunology, suggest that the evolutionary arms race begun by constrictors early in mammalian evolution continued with venomous snakes. Whereas other mammals responded by evolving physiological resistance to snake venoms, anthropoids responded by enhancing their ability to detect snakes visually before the strike.

Maintenance in working memory or response selection? Functions of NMDA receptors in the pigeon "prefrontal cortex"

The prefrontal cortex is involved in various aspects of working memory like stimulus maintenance and response selection functions. Neurobehavioral studies and neurocomputational models assume a role for NMDA receptors in prefrontal cortex for maintenance processes, while our previous studies on NMDA receptors in the avian prefrontal cortex-analogue, the nidopallium caudolaterale (NCL), showed them to be involved in response selection functions. Various tasks used in PFC-related research address in fact both functions, so they cannot disambiguate their separate contributions to performance. In order to investigate the role of NMDA receptors in avian NCL for stimulus maintenance and response selection, we trained pigeons in a delayed matching-to sample (DMTS) task, requiring both functions, and a simultaneous matching to sample (SMTS) task, requiring only response selection. After reaching criterion, pigeons had to perform the tasks alternately under local NMDA receptor blockade in NCL (DL-AP5) and after infusion of vehicle (saline solution). Blockade of NCL-based NMDA receptors led to significant increases in error rates in both DMTS and SMTS--compared with the same subjects' performance during training and in the control condition. However, there was no additional increase in errors due to the additional maintenance component, so the impairment appears to be due to deficits in adequate selection of responses, the function necessary for both tasks. We conclude that NMDA receptors in the pigeon NCL participate in response selection rather than stimulus maintenance in tasks requiring the processing of context information.

Effects of dizocilpine (MK-801) on circling behavior, swimming activity, and place preference in zebrafish (Danio rerio)

Glutamate transmission plays an important role in many behavioral systems, including motor activity, learning, and memory. The noncompetitive NMDA receptor antagonist (+)MK-801 has been shown to increase motor activity and impair learning and memory in a variety of tasks in rats, mice, and other species. In an attempt to characterize the effects of MK-801 on motor activity and cognitive performance in an emerging neurobehavioral model, the zebrafish (Danio rerio), we examined the effects of MK-801 on circling behavior, swimming activity, and latency to enter, as well as preference for, an enriched chamber (EC). In Experiment 1, the effects of a 37-min acute exposure to (+)MK-801 (0, 2.0, and 20.0 microM) on circling behavior were measured in a round observation chamber. (+)MK-801 was observed to increase circling behavior in a dose-dependent manner. In the second experiment, fish were treated with 0, 2, 20, or 200 microM (+)MK-801 for 1 h, and swimming activity was measured in a rectangular observation chamber for 60 min following dosing. The lowest dose of (+)MK-801 decreased swimming activity. In the third experiment, fish were treated with either 0 or 20 microM (+)MK-801 for 1 h each day over four consecutive days. The fish were tested in a modified T-maze to assess both latency to enter, and preference for, an EC 24, 27, and 48 h after the last treatment. The results showed that untreated fish exhibited a preference for the EC at the 27- and 48-h trials, but (+)MK-801-treated fish did not exhibit a preference for the EC at any trial. No significant reduction in latency to enter the chamber was found for either treated or control fish. Together, the results of these experiments suggest that NMDA receptor antagonism (1) increases circling behavior, (2) alters swimming activity, and (3) impairs place preference. These findings lend further support for the usefulness of the zebrafish for assessing the acute and chronic exposure effects of water-soluble compounds on motor and cognitive functions.

Neuroimaging: New Approaches for Neurotoxicology

Over the last 20 years, the impact of imaging on the clinical sciences is unquestionable. It has revolutionized the diagnosis and treatment of disease. Interestingly, the use of imaging in preclinical neurotoxicology has been relatively negligible. This has been in part due to the lack of knowledge or understanding of the capabilities of these powerful technologies. However, some of the more immediately applicable imaging approaches could impact the present approach to neurotoxicology. In addition, the recent advent of the development of imagers specifically for application to small animals will provide the opportunity of obtaining information for neurotoxicological risk assessment in a more timely and relevant manner. The ability to visualize changes in structure and function due to neurotoxic insult in a noninvasive manner is a promising direction. Changes in anatomy of soft and hard tissue, metabolism, function and gene expression can now be done in both a preclinical and a clinical setting using such technologies as magnetic resonance imaging (MRI), magnetic resonance imaging microscopy (MRM), and positron emission tomography (PET). This type of information is not readily accessible using conventional preclinical neurotoxicological procedures and usually requires total destruction of the intrinsic structure of the sample of interest. Imaging provides an opportunity to produce much of these data in a nondestructive manner and presents the data in a three-dimensional format. This permits longitudinal studies of the same subject subsequently reducing the number of animals required for studies while providing more information. In addition, as these technologies have been primarily developed for clinical purposes, they provide an outstanding opportunity for cross-species and animal-to-human extrapolation and testing.

Chronic exposure to NMDA receptor and sodium channel blockers during development in monkeys and rats: long-term effects on cognitive function

The effects of chronic administration of MK-801 (NMDA-receptor antagonist) and remacemide (sodium channel blocker) on monkey learning of several brain function tasks was assessed in juveniles (nine months old). Low (LO) and high (HI) doses of both drugs were given orally each day for 18 months. There were no adverse effects of any treatment on tests of short-term memory or motivation. HI doses of both MK-801 and remacemide delayed acquisition of a visual discrimination task (the remacemide effect was much greater). HI doses of remacemide alone severely disrupted learning task acquisition and this effect lasted for several months after dosing. Thus, in monkeys, chronic blockade of NMDA receptors is relatively well tolerated, whereas blockade of sodium channels (perhaps in conjunction with NMDA receptor blockade) has long-term-perhaps permanent-consequences. To further explore the roles of NMDA receptors and sodium channels in these effects, MK-801, phenytoin (sodium channel blocker), or both were administered to rats and the acquisition of tasks similar to those used in the monkey study were assessed. Dosing began at weaning and continued for nine months. Throughout the study, HI MK-801 subjects exhibited impaired performance in all tasks. Some effects of MK-801 were blocked completely by phenytoin. In the rat, blockade of sodium channels was well tolerated but blockade of NMDA receptors had significant and long-term (permanent?) adverse consequences. These data contrast markedly with those obtained for the monkey and suggest, at least for some drug classes, that the rat might not be a good predictor of effects in primates.

Assessing the potential toxicity of MK-801 and remacemide: chronic exposure in juvenile rhesus monkeys

The present experiment examined the effects of chronic exposure to either 0.1 or 1.0 mg/kg MK-801 [a selective N-methyl-D-aspartate (NMDA) receptor antagonist] or 20.0 or 50.0 mg/kg remacemide (an NMDA receptor antagonist which also blocks fast sodium channels) in juvenile rhesus monkeys. Endpoints were monitored to provide a general index of subjects' health and included measures of clinical chemistry, hematology, ophthalmology, spontaneous home-cage behavior, and peak drug plasma levels. In general, both drugs were well tolerated and produced no treatment-related effects during 2 years of dosing and assessment. Periodic plasma drug level determinations provided limited evidence that both compounds may induce their own metabolism. The present results contrast sharply with previously reported effects of long-lasting impairments in the acquisition of incremental learning and in the development of color and position discrimination in these same subjects. These observations highlight the importance of collecting a broad range of toxicology data, including tests of cognitive function, to make comprehensive assessments of new drug safety. In the present case, the less obvious effects of these drugs on cognition defined the toxicologic response.

Differential effects of two NMDA receptor antagonists on cognitive-behavioral development in nonhuman primates I

The present experiment examined effects of chronic exposure to remacemide (an N-methyl-D-aspartate [NMDA] antagonist which also blocks fast sodium channels) or MK-801 (which blocks NMDA receptors, exclusively) on learning and motivation in young rhesus monkeys. Remacemide (20 or 50 mg/kg/day) or MK-801 (0.1 or 1.0 mg/kg/day) was administered every day to separate groups of animals via orogastric gavage for up to 2 years. Immediately prior to dosing, 5 days per week (M--F), throughout the 2-year dosing period, an incremental repeated acquisition (IRA) task was used to assess learning and a progressive ratio (PR) task was used to assess motivation. The results indicate an effect of 50 mg/kg/day remacemide to impair learning (IRA) which persisted even after drug treatment was discontinued. MK-801 had no effect on learning but transiently increased motivation. Because the effects of remacemide occurred independently of changes in motivation or response rates, they are likely due to specific cognitive impairments and are not due to an inability of subjects to fulfill the motoric requirements of the task. The fact that MK-801 did not alter learning suggests that NMDA antagonism alone may be insufficient to produce learning deficits in young monkeys and that such deficits may rely on the ancillary blockade of fast sodium channels.