Baseline behavior, but not sensitivity to stimulant drugs, differs among spontaneously hypertensive, Wistar-Kyoto, and Sprague-Dawley rat strains.

Deficits in temporal processing are implicated in Attention Deficit Hyperactivity Disorder (ADHD) for which the most common rodent model is the Spontaneously Hypertensive Rat (SHR). To assess strain differences in temporal processing, males and females of the SHR, Wistar-Kyoto (WKY), and Sprague-Dawley (SD) strains were compared on two timing tasks: one requiring maintenance of a lever press for 10-14 s (TRD, temporal response differentiation) and the other requiring withholding of a lever press for 10-14 s (DRL, differential reinforcement of low rates). Performance of the progressive ratio (PR) task more directly assessed food-motivated behavior. Strains did not differ in task acquisition; however, steady state TRD and DRL performance of the SHR and WKY strains was less accurate which was related to increased burst (non-timing related) responses in those strains relative to the SD. PR performance demonstrated that the SHR and WKY strains exhibited higher response rates and breakpoints than the SD. Subsequently, methylphenidate (1, 3.25, 4.50, 7.50, and 12.0 mg/kg) and d-amphetamine (0.1, 0.25, 0.65, 1.0, and 2.0 mg/kg) were administered intraperitoneally pre-testing. Both drugs disrupted TRD and DRL performances by increasing burst response frequency; however, the strains were not differentially sensitive to either drug. Strain differences were generally maintained throughout the drug and extinction portions of the study. These results indicate increased similarity between the SHR and WKY strains relative to the SD in performance of timing and motivation tasks. Further, the current results do not support continued use of the SHR as a model for ADHD.

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.

Alteration in Electroencephalogram and Monoamine Concentrations in Rat Brain following Ibogaine Treatment.

Ibogaine (IBO) is a psychoactive indole alkaloid that has antiaddictive properties. However, treatment with IBO may lead to neurotoxicity, since IBO and its metabolites interact persistently with many neurotransmitter systems. Here, we recorded cortical electroencephalogram (EEG) signals from rats anesthetized with isoflurane. The heart rate (HR) was monitored via electrocardiogram (EKG) electrodes. After the baseline EEG was recorded, rats received one intraperitoneal (i.p.) dose of 50 mg/kg IBO. EEG signals were recorded for 2 hr. Rats were then sacrificed and brains dissected into frontal cortex (FC), caudate nucleus (CN), hippocampus (HIP), and brain stem (BS). The level of dopamine (DA), serotonin (5-HT), and their metabolites were determined by high-performance liquid chromatography with electrochemical detection (HPLC-ECD). Compared with baseline, a decrease in HR immediately after IBO injection and a decrease in δ, θ, α, and ß power spectra frequency bands (1-4, 4-8, 8-13, 13-32Hz) during the first 30 min after IBO administration was observed. EEG recovered within the next 15 min. In CN, the level of DA decreased and DA turnover rate increased significantly. The levels of 5-HT increased in FC. The pattern of EKG and EEG response to IBO may be due to multiple receptor interactions of IBO.