The ability of four central cholinomimetics to reverse a scopolamine-induced spatial memory impairment or to improve visual recognition memory in primates was examined. Physostigmine (0.04-0.08 mg/kg IM) fully reversed the effects of scopolamine (0.03 mg/kg). Coadministration of pilocarpine (3.0-5.0 mg/kg) caused partial reversal of the scopolamine impairment after intermediate or long retention intervals (10 or 20 s). Treatment with arecoline (0.1-1.8 mg/kg) or nicotine (1.0-2.0 mg/kg) generally did not reverse the effects of scopolamine. A task in which memory could be taxed by increasing the number of visual stimuli presented appeared more sensitive to the effects of cholinomimetics on cognition than the scopolamine reversal model. In this paradigm treatment with physostigmine (0.001, 0.01 or 0.03 mg/kg) increased choice accuracy from about 55 to 70% correct. Arecoline improved performance at one dose only (0.1 mg/kg) which also induced marked adverse side-effects (salivation and tremor). Pilocarpine improved performance in the dose range 0.125-0.35 mg/kg, but not at higher doses which also induced marked salivation. Treatment with nicotine (0.001-2.0 mg/kg tended to improve performance but this did not reach statistical significance. The relevance of these findings for studies in man and for animal models of dementia is discussed.
Intermittent treatment with L-dopa over a 2-year period induced abnormal involuntary movements in MPTP-treated squirrel monkeys. Dyskinesias included a choreic and dystonic component. Dose-response curves for chorea and dystonia revealed that the same dose of L-dopa (30 mg/kg) induced the highest score for both dyskinesias: however, the severity was much greater for chorea. Choreic movements were always most prevalent at the time of peak effect, whereas dystonia was apparent at the time of peak effect and at "end-of-dose", and was occasionally observed spontaneously. Our findings indicate that squirrel monkeys treated with MPTP develop L-dopa-induced dyskinesias which closely resemble those observed in Parkinson's disease. This species provides a valuable animal model to develop improved therapeutic agents.
Administration of the indirect agonist L-dopa, the nonselective direct agonist apomorphine, or the selective D2 agonist (+)-PHNO, reversed parkinsonism and induced locomotor activation in MPTP-treated squirrel monkeys. In contrast, administration of the selective partial D1 agonist SKF38393 did not induce locomotor activity, but rather decreased activity. Choreiform movements were observed only following treatment with L-dopa. Coadministration of the D1 antagonist SCH23390 prevented L-dopa-induced chorea at the time of peak effect. However, a rebound exaggeration of chorea was observed following SCH 23390 at the time when chorea induced by L-dopa alone would normally be subsiding. Unlike chorea, dystonia could be induced by treatment with either L-dopa or (+)-PHNO. Administration of apomorphine failed to significantly induce dystonia, although a small increase was observed with the highest dose. Treatment with SKF38393 actually decreased dystonia. Our findings clearly indicate that D2 receptor stimulation appears essential for antiparkinsonian activity, and also implicate D2 receptors in the genesis of dystonia, but not chorea. D1 receptor stimulation appears to be involved in the genesis of chorea and possibly also dystonia.
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