Experimental reproduction of catecholamine-depleted states and parkinsonism ? Theoretical and practical aspects

Electrophysiological investigation of thalamic neuronal mechanisms of motor disorders in parkinsonism: an influence of D2ergic transmission blockade on excitation and inhibition of relay neurons in motor thalamic nuclei of cat

In acute experiments on cats anaesthetized with ketamine (25 mg/kg, i.m.) and immobilized with myorelaxine (2 mg/kg, i.v.) the activity of two groups of motor thalamic (nucleus ventralis anterior thalami-nucleus ventralis lateralis thalami) relay neurons was studied. The neurons (n = 7) receiving afferents from deep cerebellar nuclei and projecting to the motor area 4 gamma were included in the first group, and those (n = 12) receiving afferents from nucleus entopeduncularis and projecting to the supplementary motor area 6 were included in the second one. All changes in the background activity and reactions to cerebellothalamic or nucleus entopeduncularis stimulation developing under the influence of D2 receptor antagonist haloperidol (1.5-1.7 mg/kg, i.v.) have been studied in the same cell. Under haloperidol influence both groups of neurons showed a reliable decrease of background activity and generation of high frequency discharges accompanied by a shift in the mode of interspike interval histograms. A regular decrease of probability and increase of response latencies after stimulation of afferent input were observed in neurons receiving afferents from the cerebellum. In nucleus ventralis anterior thalami-nucleus ventralis lateralis thalami neurons with an inhibitory input from nucleus entopeduncularis, a shortening of inhibition from 17.5 +/- 3.6 to 9.1 +/- 1.8 ms (P < 0.05) under the haloperidol influence was evident. If the inhibition evoked by nucleus entopeduncularis stimulation consisted of two phases separated by a period of excitation (n = 4), the duration of the second phase of inhibition after haloperidol injection regularly increased and the excitation separating the phase of inhibition after haloperidol injection regularly increased and the excitation separating the phases of inhibition became more prominent. Observation on the spontaneous activity and reactions of the same neuron for 2 h or more showed a gradual moderation of the changes evoked by haloperidol. On the basis of data obtained it is concluded that the blockade of D2 receptors is followed by the increase of inhibitory processes in the relay neurons of motor thalamic nuclei. The suggestion is discussed that during the blockade of D2 receptors afferent impulsation to the motor cortex is being restricted and its influence on segmental apparatus of the spinal cord decreases. These conditions are beneficial for the development of spasticity (rigidity). At the same time, hyperpolarization of the relay neurons promotes the development of oscillatory processes at least in part of them and creates conditions for forming of tremor generators.

Participation of nucleus entopeduncularis in motor instrumental reflex and entopeduncular influences on motor thalamic nuclei in normal and MPTP-treated cats

Activity of entopeduncular neurons was studied in chronic experiments on cats during performance of instrumental movement: pedal pressing and holding. One-hundred and twenty-four neurons were extracellularly investigated in intact animals and 81 neurons in cats treated with N-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) (5 mg/kg daily, intramuscularly for five days). The mean discharge frequency of nucleus entopeduncularis neurons recorded 48-72 h after the last MPTP injection increased from 12.9 +/- 1.5 to 22.1 +/- 1.4 impulses/s, but dropped to preinjection values within the next ten days. In intact animals and in MPTP-treated cats 23 and 17%, respectively, of neurons changed their activity before or during the movement performance. Along with nucleus entopeduncularis neurons that changed their activity simultaneously with instrumental movement performance, 16% of nucleus entopeduncularis nerve cells in intact cats and 12% in MPTP-treated cats responded 50-800 ms before the myogramme of working forepaw biceps was started. Excitatory responses associated with movement performance in MPTP-exposed cats were more pronounced, indicating enhancement of nucleus entopeduncularis neuronal activity in animals with injured nigrostriatal system. Since nucleus entopeduncularis neurons are inhibitory cells, the increase in their activity had to be accompanied by reinforcement of inhibitory influence on neurons in motor thalamic nuclei. In order to test this hypothesis, two groups of acute experiments were performed on ketamine-anaesthetized and myorelaxine-immobilized cats. Neuronal responses in ventral anterior and ventral lateral thalamic nuclei to nucleus entopeduncularis stimulation were investigated in normal and MPTP-treated animals in doses that were identical to those administered in chronic experiments. In intact cats, 28% of neurons responded to nucleus entopeduncularis stimulation with the latency shorter than 7 ms. In half of the inhibited neurons after the first phase of inhibition lasting 18 +/- 2 ms, the second inhibitory phase was recorded. The duration of the latter was 24 +/- 4 ms. Although in MPTP-treated cats the number of neurons inhibited by nucleus entopeduncularis stimulation was practically the same as in normal ones (24.5%), the first phase tended to be shorter, and a statistically significant increase of the second inhibitory phase duration (up to 50 +/- 11 ms) was found. It was suggested that changes in the inhibitory processes in motor thalamic neurons receiving afferents from nucleus entopeduncularis could be explained by GABAB-mediated hyperpolarization of the neuronal membrane, evoked by increasing pallidothalamic inhibitory influences.