Complex Deficits on Reaction Time Performance following Bilateral Intrastriatal 6-OHDA Infusion in the Rat (original) (raw)
Related papers
Behavioural Brain Research, 1999
In the present study, the effects of unilateral or bilateral dopamine denervation of either the dorsal or ventral striatum on the preparation and execution of a delayed response task in the rat were investigated. Animals were instructed to hold a lever pressed down by the presentation of a visual and/or acoustic signal, and were required to hold the lever until a trigger stimulus occurred after an unpredictable delay ranging from 2 to 4 s. The trigger stimulus required animals to release the lever and to press a second lever for food reinforcement. The time between instruction and trigger signal represented the preparation phase preceding movement. The motor performance was evaluated by using reaction and movement times in addition to correct responses in each session. Dopaminergic denervation of either the dorsal or ventral striatum ipsilaterally to the side in which the second lever to be pressed was located did not significantly change reaction and movement times, although it reduced the percentage of correct trials. A significant increase of both reaction and movement times was recorded only after bilateral denervation of the ventral striatum. The analysis of incorrect responses indicated that dopaminergic innervation of the two striatal subregions had different functions in the correct execution of the behavioral paradigm. In the group of animals with dorsal lesions the most frequent incorrect response was represented by a lack of the conditioned response to the presentation of the instruction stimulus starting the trial. If the animals reacted properly to this signal, the performance thereafter was correct in the majority of trials. Conversely, animals with ventral lesions exhibited a large repertoire of incorrect responses throughout the paradigm, including premature release or delayed press of levers, and omission of the second lever press. Histological verification of brain coronal sections by tyrosine-hydroxylase immunoreactivity showed that the lesions were confined in either the dorsal or ventral striatum, sparing the lateral region. The data support the hypothesis that dopaminergic innervation enables the two striatal regions to differently participate in the preparation and execution of complex delayed sensorimotor tasks. Indeed, the dorsal striatum seems to be involved in the correct utilization of external sensory information for the initiation of conditioned behavior, whereas, the ventral striatum appears to be mainly concerned with the temporal expectation of impending stimuli that trigger reward-reinforced movements.
European Neuropsychopharmacology, 1995
The effect of lesions of the catecholamine nerve terminals in the medial prefrontal cortex of the rat on neurotransmitter mechanisms within the basal ganglia has been investigated. Bilateral 6-hydroxydopamine lesions were stereotaxically placed in the dopamine-rich (DA) area of the frontal cortex. Animals were pretreated with desmethylimipramine to block the uptake of neurotoxin into noradrenergic (NA) terminals and to make it more selective for DA terminals. The lesion produced a selective reduction of both NA and DA from the medial prefrontal cortex, a result related to falls in tyrosine hydroxylase activity at this site. Lesioned animals showed enhanced DA turnover and utilisation in striatal and limbic regions. There was no change in subcortical tyrosine hydroxylase activity. In addition there were significant falls in other putative neurotransmitters within basal ganglia sites, including 5hydroxytryptamine and GABA. Decreased activity of the neurotransmittersynthesizing enzymes glutamate decarboxylase and choline acetyltransferase was also recorded in certain regions of the basal ganglia. The results suggest that frontal cortical catecholamine systems may serve to regulate various neurotransmitter mechanisms in the basal ganglia.
Parkinson's disease duration determines effect of dopaminergic therapy on ventral striatum function
Movement Disorders, 2012
We investigated the hypothesis that variation in endogenous dopamine (DA) across brain regions explains dissimilar effects of dopaminergic therapy on aspects of cognition in early Parkinson's disease (PD). Extensive degeneration of DA-producing cells in the substantia nigra cause dorsal striatum (DS) DA deficiency and movement abnormalities. Particularly in early PD, this contrasts with relative sparing of the dopaminergic cells of the ventral tegmental area (VTA). 1 The hypothesis predicts that DS-mediated cognitive functions are deficient at baseline and improved by DA replacement, whereas functions depending upon VTA-innervated brain regions are normal off medication and worsen with treatment. The latter pattern presumably owes to overdose of relatively DA-replete VTA-supplied brain regions with medication levels titrated to DS-mediated motor symptoms. 2,3 As PD progresses, however, VTA degeneration increases. Impairment in cognitive operations performed by VTA-innervated brain regions, such as the ventral striatum (VS), is expected. We compared the performance of early and late PD patients, on and off dopaminergic medication, relative to age-matched controls, on reward learning, previously shown to implicate the VS. As expected, in early PD, stimulus-reward learning was normal off medication, but worsened with DA replacement. At more advanced disease stages, PD patients learned stimulus-reward contingencies more poorly than controls and early PD patients off medication. Furthermore, dopaminergic medication did not worsen reward learning in late PD patients, in line with the dopamine overdose hypothesis. Unlike its effect on DS-mediated functions, however, DA-replacement therapy did not improve reward learning in late PD patients.
Parkinson's Disease, 2011
Cognitive abnormalities are a feature of Parkinson's disease (PD). Unlike motor symptoms that are clearly improved by dopaminergic therapy, the effect of dopamine replacement on cognition seems paradoxical. Some cognitive functions are improved whereas others are unaltered or even hindered. Our aim was to understand the effect of dopamine replacement therapy on various aspects of cognition. Whereas dorsal striatum receives dopamine input from the substantia nigra (SN), ventral striatum is innervated by dopamine-producing cells in the ventral tegmental area (VTA). In PD, degeneration of SN is substantially greater than cell loss in VTA and hence dopamine-deficiency is significantly greater in dorsal compared to ventral striatum. We suggest that dopamine supplementation improves functions mediated by dorsal striatum and impairs, or heightens to a pathological degree, operations ascribed to ventral striatum. We consider the extant literature in light of this principle. We also surv...
The Journal of neuroscience : the official journal of the Society for Neuroscience, 1995
Lesions of the subthalamic nucleus (STN) have been found to reduce the severe akinetic motor symptom produced in animal models of Parkinson's disease, such as in monkeys treated with 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) or in monoamine-depleted rats. However, little is known about the effect of STN exclusion on subtle motor deficits induced by moderate dopaminergic lesions in complex motor tasks. The present study was thus performed on rats trained in a reaction time (RT) task known to be extremely sensitive to variations of dopamine transmission in the striatum. Animals were trained to release a lever after the onset of a visual stimulus within a time limit to obtain a food reward. Discrete dopamine depletion produced by infusing the neurotoxin 6-hydroxydopamine (6-OHDA) bilaterally into the dorsal part of the striatum, produced motor initiation deficits which were revealed by an increase in the number of delayed responses (lever release after the time limit) and...
Synapse, 1993
Asymmetries in turning and scanning were investigated in rats with different degrees of neostriatal dopamine depletion after unilateral injections of 6-hydroxydopamine into the substantia nigra. Animals with severe lesions, i.e., residual dopamine levels of <20%, spontaneously turned ipsiversive and showed more scanning behavior with the side ipsilateral to the lesion. These asymmetries were reversed by the dopamine receptor agonist apomorphine. Animals with less severe dopamine depletion, i.e., residual dopamine levels of 20-65%, did not show a n asymmetry in spontaneous turning, but an ipsilateral asymmetry in scanning was still observed, indicating a greater sensitivity of this measure for moderate striatal dopamine depletions. Furthermore, in animals with residual dopamine levels of 45-65%, the dopamine receptor agonist apomorphine did not lead to a behavioral reversal as with severe lesions, but induced ipsilateral scanning and ipsiversive turning. These ipsiversive asymmetries are discussed in relation to asymmetries in self-regulatory mechanisms of the nigro-striatal dopamine system, such as dopamine autoreceptors controlling the release of this transmitter. Dopamine receptor-stimulated behavioral asymmetry in animals with moderate depletions of dopamine is suggested as a preclinical model to study mechanisms affected in the early state of Parkinson's disease.
Brain Research, 1996
Rats were tested in an instrumental lever pressing procedure, in which a computer program recorded detailed parameters of responding such as response initiation and duration. Initially, rats with ventrolateral striatal dopamine depletions and control rats were tested on days 3-5 after surgery. Dopamine depletions produced by local injections of 6-hydroxydopamine substantially reduced the number of lever presses emitted. Dopamine depleted animals showed significant increases in average response initiation times, average length of fast initiation times, average length of pauses and total pause time. The distribution of initiation times was altered so that DA depleted rats showed significant reductions in the relative number of very high rate responses and also showed increases in the relative number of pauses. On day 7 after surgery, dopamine-depleted rats received one of three drug treatments: injections of ascorbate vehicle, injections of 20.0 mg/kg L-DOPA, and injections of 40.0 mg\kg L-DOPA. Injections of 40.0 mg/kg L-DOPA led to some improvement in several parameters of instrumental responding. Compared to the previous baseline day, the group that received 40.0 mg\kg L-DOPA showed a significant increase in number of responses on the drug treatment day, and also showed significant decreases in average response initiation time and total pause time. The group that received 40.0 mg/kg L-DOPA also showed significant increases in number of responses (expressed as a percent of the previous day) when compared to the control group that received injections of ascorbate vehicle. These results indicate that L-DOPA can partially reverse the skilled motor deficits produced by ventrolateral striatal dopamine depletions, and suggest that this test may be useful for the assessment of antiparkinsonian drugs.