Statistical characteristics of spontaneous and evoked unit activity in the cat superior colliculus

Spontaneous and evoked unit activity of the superior colliculus was studied in cats immobilized with gallamine or with the spinal cord divided (encephalé isolé). Statistical parameters of unit activity were calculated in light and darkness and in the presence of a moving photic stimulus. Spontaneously active neurons were divided into four main groups: 1) with a mean interspike interval of about 300 msec, coefficient of variation 1.9, and with two modes in the autocorrelation histogram; 2) with similar statistical parameters but distinguished by correlation with saccadic eye movements; 3) histogram of interspike intervals exponential in type, autocorrelation histogram flat, mean interval and standard deviation about 100 msec; 4) with symmetrical distribution of interspike intervals, mean interval about 50 msec, coefficient of variation 0.4–0.5. Spontaneous activity in light and darkness differed only in the neurons of the second group. Comparison of the statistical parameters of the spontaneous and evoked activity shows that encoding of the stimulus could be carried out by neurons of groups 3 and 4. In some cases the mode of the histogram of interspike intervals and the standard deviation changed significantly and activity appeared regularly in the autocorrelation histogram.     

Inhibition of complex I by neuroleptics in normal human brain cortex parallels the extrapyramidal toxicity of neuroleptics

There is increasing evidence that a defect of the mitochondrial respiratory chain is implicated in the development of Parkinson disease. Decreased complex I activity of the mitochondrial respiratory chain has been reported in platelets, muscle, and brain of patients with Parkinson disease. Extrapyramidal symptoms (e.g. parkinsonism and dystonic reactions) are major limiting side effects of neuroleptics. Experimental evidence suggests that neuroleptics inhibit complex I in rat brain. There has not been a study of the effects of neuroleptics in human tissue, however. We therefore analyzed the activities of complexes I + III, complexes II + III, succinate dehydrogenase, complex IV (cytochrome c oxidase), and of citrate synthase in normal human brain cortex after the addition of haloperidol and chlorpromazine and the atypical neuroleptics risperidone, zotepine, and clozapine. Activity of complex I was progressively inhibited by all neuroleptics. Half maximal inhibition (IC₅₀) was 0.1 mM fo r haloperidol, 0.4 mM for chlorpromazine, and 0.5 mM for risperidone and zotepine. Clozapine had no effect on enzyme activity at concentrations up to 0.5 mM, followed by a slow decline with a maximum inhibition of 70% at 10 mM. IC50 was at about 2.5 mM. Thus, the concentration of clozapine needed to cause 50% inhibition of the activity of complexes I and III was about 5 times that of zotepine and risperidone, about 6 times that of chlorpromazine, and 25 times that of haloperidol. The inhibition thus paralleled the incidence of extrapyramidal effects caused by the different neuroleptics as they are known from numerous clinical studies. Our data support the hypothesis that neuroleptic-induced extrapyramidal side effects may be due to inhibition of the mitochondrial respiratory chain. (Mol Cell Biochem 174: 255–259, 1997)     

Comparison of spontaneous activity of mesencephalic reticular neurones in the waking state and during pentobarbital anaesthesia.

In rats immobilized by d-Tubocurarine the spontaneous activity of 100 mesencephalic reticular neurones was recorded extracellularly and statistically evaluated before and after repeated intravenous administration of 15 mg/kg doses of Pentobarbital. Number of spontaneously active neurones decreases quasi-linearly with repeated 15 mg/kg Pentobarbital doses. After a 75 mg/kg cumulative dose practically all neurones ceased firing spontaneously, whereas cortical EEG activity fully disappeared after the 90 mg/kg Pentobarbital dose. The firing rate was characterized by the mean interval with its standard deviation. Mean value for the total sample of spontaneously active neurones was 146.7 +/- 192.3 msec without Pentobarbital and increased to 302.7 +/- 367.5 msec after 15 mg/kg and to 400.6 +/- 452.5 msec after 30 mg/kg cumulative dose of Pentobarbital. The 15 mg/kg dose increased the frequency of firing in 5% of neurones only. The most often encountered type of interval histogram in the mesencephalic reticular formation was the exponential type (59% in unanaesthetized state), which was also most sensitive to Pentobarbital. Synchronized activity in bursts, characterized by periodical peaks and dips frequently occurred in neurones with the exponential-like interspike interval density after Pentobarbital administration. On the contrary, neurones with gamma-like and especially with symmetrical-like types of density were less influenced by Pentobarbital. In many neurones a periodical increase in the firing rate (with intervals of tens of seconds) related to the occurrence of spindles was present in the cortical EEG activity.     

A spin label study of the membrane effect of various psychoactive drugs in human erythrocytes

The effect of psychoactive agents with different clinical actions: three sedative neuroleptics (trifluoperazine, alimemazine tartrate, chlorpromazine), an anticholinergic agent (trihexyphenidyl hydrochloride), two tricyclic antidepressants (imipramine, desipramine) and lithium carbonate on the rotational correlation frequency (V⁺) of the spin label 16NS has been comparatively investigated in whole human erythrocytes. V⁺ was about 40% increased by the three neuroleptics, the anticholinergic agent and the antidepressant molecules at 0.2mM. By contrast, lithium did not induce any significant change in V⁺ at the same concentrations. It can be suggested that the increase in “membrane fluidity”, observed with a wide variety of drugs, is a non specific effect, unrelated to the psychotropic action, that can be ascribed to the amphiphilic properties of the tested drugs.     

Effect of psychotropic substances on orienting-exploratory behavior after startling caused by acoustic stimulation

Frightening sound stimulation induced alarm and alertness which resulted in weakening of attention to novel environment and increasing of orienting response to the source of the frightening sound. Defense motivation occurring under these conditions failed to alter with the increase of sound loudness. Tranquilizers (diazepam, chlordiazepoxide, benatyzine), antidepressants (amytriptiline, imipramine) and some neuroleptics (trifluoperazine, haloperidol) in a low doze prevented these disturbances. High doses of pentobarbital, chlorpromazine, as well as trifluoperazine and haloperidol did not prevent the mentioned consequences of emotional excitation.     

Effect of neuroleptics on acetylcholine metabolism in the basal ganglia of the brain

Neuroleptics (haloperidol) closapine, pimozid, chlorpromazine) diminished the level of free (functionally active) form of acetylcholine (ACh), and, to some extent, the bound form of ACh; they changed the content of the labile-bound (vesicular) form of ACh and weakly influenced the choline-acetyltranspherase activity in the basal ganglia of the rat brain 5 to 30 min after the injection. In contrast to the inhibitory action on the acetyl-cholinesterase (AChE) activity in vitro, most of the neuroleptics, except closapine, increased the AChE activity in vivo. These results indicate that the neuroleptics activate ACh-metabolism and probably stimulate the cholinergic structure in the basal ganglia of the brain; the AChE activity may serve as a criterion of such stimulating action of neuroleptics.     

Classification of cortical neurons according to the character of their background impulse activity]

The method of basic components and cluster analysis was used to classify 75 units in the visual cortex of alert rabbits, proceeding from the empiric form of distribution of interspike intervals (DII), the mean frequency of impulsation and the relative number of intervals up to 500 msec. They were classified into nine groups containing from two to twelve units. Besides the cues, used as a basis for classification, the groups of units also differed in the structure of burst activity, the correlation of adjacent intervals and the ratio between the short (up to 20 to 60 msec) and long intervals. The latter served to make suggestions on the genetic affinity of bimodal DII to those with a bend on the waning after the maximum, and on the nature of formation of high frequency bursts and intervals exceeding 20 to 60 msec.     

Reflection of the plastic properties of the simplest neuronal associations in statistical characteristics of the spike activity of their elements. Polysynaptically linked neurons

Changes of crosscorrelation histograms of trains of action potentials and mean interspike intervals of polysynaptically connected neurones were studied by means of mathematical modelling of synaptic neuronal interaction at changes of efficiency of interneuronal monosynaptic connections, at changes of neuronal excitability, and at changes of total action on them of independent disorderly afferent synaptic inflows. Increase of amplitude of the main maximum (minimum) of the normalized crosscorrelation histogram of trains of action potentials accompanied by reduction of mean interspike intervals of both neurones, was shown to be a unsignificant indication of an increase of efficiency of polysynaptic excitatory (inhibitory) connections between the neurones (due to modification of synapses or to a change of the functional state of interneurones).     

Effect of triftazin on the transmission of excitation in the brain of the rabbit under the prolonged administration of the preparation]

Experiments were conducted on awake rabbits to which trifluoperazine was given daily for 2 weeks in a dose of 1 mg/kg a day; a study was made of the reaction of the cortical neurones in response to the electrostimulation of its adjacent areas. In measuring the dispersions of the poststimular histograms it was found that under the effect of trifluoperazine there occurred a reduction of the value and the duration of the responses of the cortical neurons after the infliction of stimulation. The effect obtained after the administration of trifluoperazine was regarded from the point of view of aggravation of the signal conduction in the neuronal reticula.     

Neuroleptics antagonize a calcium-activated potassium channel in airway smooth muscle

We examined the effect of neuroleptics on Ca-activated K channels from dog airway smooth muscle cells. Because these agents inhibit a variety of other Ca-mediated processes, it seemed possible that they might also inhibit Ca-activated K channels. In excised, inside-out patches, several neuroleptics potently and reversibly inhibited the K channel from the internal but not the external surface of the patch. Measurements of the effect on open probability and open- and closed-state durations support a simple kinetic model in which neuroleptics bind to and block the open channel. Inhibition by neuroleptics was moderately voltage dependent, with blockers less potent at hyperpolarizing voltages. The relationship between voltage and the dissociation constant for the blocker suggests that the binding site is one-third of the way across the channel's electrical field. Equilibrium dissociation constants for the drug-channel complex were: haloperidol, 1.0 +/- 0.1 microM; trifluoperazine, 1.4 +/- 0.1 microM; thioridazine, 2.4 +/- 0.1 microM; and chlorpromazine, 2.0 microM. This rank-order potency is different from their potency as calmodulin inhibitors, which suggests that neuroleptics bind to the channel rather than a calmodulin-channel complex.     

The dynamics of the interimpulse intervals in the activity of sensorimotor cortex neurons during the acquisition of the food-procuring reflex in the rabbit]

State of hunger is characterized by the presence of definite distribution of interimpulse intervals in the activity of sensorimotor cortical neurones (SMC) of rabbit. Mostly bi- and three-modal distribution of interimpulse intervals in the background activity in hungry animals changes in the process of elaboration of food-procuring habit. As the habit consolidates, the SMC neurones acquire the ability to forestalling actions. Peculiarities are revealed of organization of the SMC neurones impulse stream in response to the action of conditioned signal in the case of abolition or substitution of the reinforcement. Repeated substitutions of reinforcement cause the formation of activity of concordance in the moment of substitute "recognition" despite the absence of alimentary reinforcement.     

Depolarisation-Dependent Protein Phosphorylation in Rat Cortical Synaptosomes Is Inhibited by Fluphenazine at a Step After Calcium Entry

Abstract: The sequence of molecular events linking depolarisation-dependent calcium influx to calcium-stimulated protein phosphorylation is unknown. In this study the effect of the neuroleptic drug fluphenazine on depolarisation-dependent protein phosphorylation was investigated using an intact postmitochondrial pellet isolated from rat cerebral cortex. Fluphenazine, in a dose-dependent manner, completely inhibited the increases in protein phosphorylation observed previously. The concentration of fluphenazine required for 50% inhibition varied for different phosphoproteins but for synapsin I was 123 μ M. Other neuroleptics produced effects similar to fluphenazine with their order of potency being thioridazine > haloperidol > trifluoperazine > fluphenazine > chlorpromazine. Fluphenazine also increased the phosphorylation of proteins in nondepolarised controls at concentrations of 20 and 60 μ M. The inhibition of depolarisation-dependent phosphorylation was apparently not due to a loss of synaptosomal integrity or viability, a decrease in calcium uptake, a change in substrate availability, or to a change in protein phosphatase activity. The data are most consistent with an inhibition of protein kinase activity by blockade of calmodulin or phospholipid activation.     

Haloperidol-induced suppression of carotid chemoreception in vitro

Effects of antagonism of endogenous dopamine with haloperidol on single-unit frequency, interspike interval distribution, and interval serial dependency of the cat sinus nerve were tested using an in vitro carotid body-sinus nerve superfusion technique. A dose dependency of inhibition by haloperidol (0.05-2.0 microgram/ml) was observed. Superfusion with 1-2 microgram/ml haloperidol significantly reduced frequency within 5 min (P less than 0.05) and caused a complete cessation of firing within 25 min in 5 of 10 chemoreceptor units. Frequency recovered to control during drug washout. Acetylcholine (10-micrograms/ml superfusion or 500-micrograms bolus) increased sinus nerve activity under control conditions but not during superfusion with haloperidol. No effect of haloperidol on impulse serial dependency was detected. However, interval distribution was significantly altered by haloperidol in five of six chemoreceptor units. Our results suggest an excitatory role for dopamine in carotid chemoreception.     

The effect of clozapine on prolactin secretion at the level of the lactotroph

Clozapine is an antipsychotic drug which is unusual in that it has no dopamine receptor-blocking activity. Previous studies gave conflicting results whether administration of clozapine induces hyperprolactinemia. In the present study it was shown that a wide concentration range of clozapine does not interfere with dopamine-mediated inhibition of prolactin (PRL) secretion by normal cultured rat pituitary cells. This in contrast to other neuroleptics, like haloperidol and trifluoperazine. Clozapine does also not antagonize norepinephrine-mediated inhibition of PRL secretion. Clozapine exerts at micromolar concentrations a direct inhibitory action on PRL release by cultured normal rat pituitary cells. In cultured rat pituitary tumor cells, these high concentrations of clozapine directly inhibit PRL release as well as the DNA content of the cells, suggesting a direct antimitotic action. In this model clozapine was about 5-10 times less potent than trifluperazine. Clozapine and trifluoperazine exert an additive inhibitory action both on PRL release and on the DNA content of the pituitary tumor cells. It is concluded that clozapine does not interfere at the pituitary level with dopamine-mediated inhibition of PRL release. At micromolar concentrations clozapine may act on lactotrophs as a calmodulin-inhibitor. These observations suggest that the transient PRL-releasing effects which have been observed in both animal and human studies after clozapine administration are mediated via supra-pituitary actions of the drug.     

Participation of frontal lobe neurons in the organization of successive inhibition and disinhibition of conditioned reflexes in the dog

Neuronal activity in g. proreus was studied during classical secretory conditioning and its differentiation in dogs. Three types of changes in neuronal reaction pattern were identified during differential conditioned stimulus compared to the pattern observed during positive conditioned stimulus. It has been shown that signal significance of the conditioned stimulus may be coded by specific distribution of interspike intervals in response to different conditioned stimuli. In situation of successive inhibition or disinhibition of the differentiation some neurones displayed simultaneous appearance of interspike intervals specific for responses to current and previously presented conditioned stimuli.     

Modulation of dopamine-induced hypermotility following injection of various opioids into the nucleus accumbens

The aim of the present work was to obtain some data on the eventual role of nucleus accumbens in the antidopamine action of some opioids. Classical neuroleptics are known to inhibit the dopamine-elicited hypermotility when injecting them into the nucleus accumbens of rats pretreated with MAO inhibitors. In the present study the effects of some opioids have been examined in this model. The opioids examined were morphine, a mu-selective classical opiate, D-Ala2, Nle5-enkephalin sulphonic acid (ES), a delta selective opioid peptide and D-Met2, Pro5-enkephalinamide (EA), a non-selective opioid peptide. Haloperidol and chlorpromazine have been used for comparison. EA and morphine, especially the former, potently antagonized the dopamine-induced hyperactivity, similarly to haloperidol and chlorpromazine. ES exerted biphasic effect, the initial inhibition was followed by potentiation of the dopamine-elicited excitation. Thus the order of potency was: EA greater than haloperidol approximately equal to morphine greater than chlorpromazine greater than EA. The data indicate that the antidopamine action of opioids might be mediated, at least in part, by mu-receptors in the nucleus accumbens.     

Differential effects after repeated treatment with haloperidol, clozapine, thioridazine and tefludazine on SNC and VTA dopamine neurones in rats

The effects of repeated treatment (21 days) with different antipsychotic compounds (haloperidol, clozapine, thioridazine and tefludazine) on dopamine (DA) neurones in substantia nigra pars compacta (SNC) and ventral tegmental area (VTA) were studied in rats using single unit recording techniques. A dose-dependent decrease in the number of spontaneously active DA neurones in SNC and in VTA was observed with haloperidol. Clozapine showed no significant effect on the activity in SNC while a dose-dependent decrease in the number of active DA neurones in VTA was observed. Thioridazine showed no or weak effect in SNC while repeated treatment induced a marked inhibitory effect on the DA neurones in VTA. Tefludazine, a potential antipsychotic compound, induced a dose-dependent decrease in both SNC and VTA DA activity. However, the effect on the DA neurones in VTA was more pronounced at all doses. Since the classical neuroleptic haloperidol is equally effective in both regions, while the atypical neuroleptics clozapine and thioridazine have selective or predominant effect in the VTA area it has previously been thought that the inhibition of spontaneously active DA neurones in VTA should indicate an antipsychotic effect of a compound while the inhibition of DA neurones in SNC should account for the development of neurological side effects. The data suggests that the potential antipsychotic compound tefludazine should not induce neurological side effects at lower doses but still has an antipsychotic activity while repeated treatment with higher doses of tefludazine might cause extrapyramidal side effects.     

Effect of some psychotropic drugs on luminol-dependent chemiluminescence induced by O2-, *OH,HOCl

We studied antioxidant activity of six neuroleptics (chlorpromazine, levomepromazine, promethazine, trifluoperazine and thioridazine) and two antidepressants (imipramine and amitriptyline) in the range of concentration of 10(-7)-10(-4) M. We applied luminol-dependent chemiluminescence to test the ability of these drugs to scavenge the biologically relevant oxygen-derived species: hydroxyl radical, superoxide radical, hypochlorous acid in vitro. We found that the phenothiazines were powerful scavengers of hydroxyl and superoxide radicals. Chlorprothixene, amitriptyline and imipramine had no scavenge activity to the superoxide radical. All drugs showed a moderate scavenger effect on hypochloric anion.     

ON THE RELEVANCE OF PREFERENTIAL INCREASES OF MESOLIMBIC VERSUS STRIATAL DOPAMINE TURNOVER FOR THE PREDICTION OF ANTIPSYCHOTIC ACTIVITY OF PSYCHOTROPIC DRUGS

Abstract— Drugs possessing (chlorpromazine, haloperidol, clozapine, thioridazine and sulpiride) or lacking (benzoctamine and perlapine) antipsychotic activity were compared with respect to their ability to enhance x-methyl-p-tyrosine-induced dopamine disappearance from the mesolimbic area and corpus striutum of rat brain. In addition, their effects on the endogenous concentrations of homovanillic (HVA) and 3.4-dihydroxyphenylacetic (DOPAC) acids in these two brain areas were determined. Some of the drugs enhanced dopamine disappearance in the mesolimbic area more than in the striatum. The most active in this respect were sulpiride. perlapine and chlorpromazine. By contrast, haloperidol was slightly more active in the striatum than in the mesolimbic area. None of the drugs was more efficient in elevating HVA levels in the mesolimbic area than in the striatum. However, there were large differences in the relative extent of the HVA increases in the two regions. Benzoctamine, perlapine and chlorpromazine increased HVA concentrations in the mesolimbic area nearly as much as in the striatum. Thioridazine and haloperidol, however, elevated striatal HVA much more effectively. Haloperidol and clozapine increased the DOPAC concentration in both areas to about the same extent. The other drugs were more active in the striatum. The largest difference between both regions was shown by chlorpromazine. Perlapine and benzoctamine, both lacking antipsychotic activity, produced much larger increases of HVA than of DOPAC. This is in contrast to the results obtained with true neuroleptics and may reflect an involvement of release phenomena in the action of these two drugs on dopamine metabolism. These results suggest that a preferential increase of dopamine turnover in the mesolimbic area is not necessarily linked to a better ratio of antipsychotic activity vs. extrapyramidal side effects. Moreover, an antiacetylcholine component of dopamine receptor blocking drugs does not seem to be a prerequisite for preferential activity on dopamine turnover in the mesolimbic system.     

Psychopharmacological analysis of hypothalamically-induced emotions

The effect of minor tranquilizers and neuroleptics was compared on self-stimulation and escape behaviourelicited by electrical stimulation of the hypothalamic nuclei in rabbits. It was shown that while tranquilizers (diazepam, oxazepam and meprobamate) increased the rate of self-stimulation elicited from the lateral hypothalamus, neuroleptics considerably suppressed such behaviour. Tranquilizers caused a remarkable reversal of the escape behaviour into a high-rate self-stimulation, both responses being induced from the same electrodes within the medial hypothalamus. Neuroleptics (chlorpromazine, reserpine and haloperidol) had not such an influence, though they somewhat increased the general activity of the animals. The reversing effect of the tranquilizers was compared with similar findings obtained after electrolytic ablation of the ventral hippocampus. It is suggested that the hippocampus has an inhibitory influence on the hypothalamic motivational system thus providing substantially for the animals' survival in a hostile environment.