Seasonal changes in the behavioral effects of neuroleptics on white rats

Summarized results of the experiments (conducted in 1981-1984) demonstrate seasonal rhythms of some behavioural effects (catalepsy and depression of locomotor activity) of haloperidol (0.5 mg/kg) and levomepromazine (5 mg/kg) in white rats. In intact rats neuroleptics were more effective in depressing high than low motor activity. Catalepsy induced by single administration of neuroleptics was more pronounced in spring and autumn months. A certain negative correlation exists between seasonal variations of neuroleptic catalepsy and the speed of monoamine (dopamine and serotonin) metabolism in the brain of intact rats.     

Phencyclidine-induced stereotyped behavior in rats: dose response effects and antagonism by neuroleptics.

Phencyclidine hydrochloride produced a very characteristic and reproducible stereotyped behavioral syndrome in rats. Both the intensity and the duration of the phencyclidine-induced stereotyped behavior are elicited in a dose-dependent manner in the 2–16 mg/kg dose range. The predominant behavior elicited by low doses was repetitive lateral head swaying, while with higher doses circling and backward walking were observed in addition to the head swaying. This behavior was antagonized by the neuroleptic agents chlorpromazine, haloperidol, and pimozide, but not by α- or β-adrenergic blockers. These results indicate that the phencyclidine-induced stereotyped behavior may be mediated by central dopaminergic mechanisms.     

Pharmacologic features and effects of neuroleptics.

Neuroleptic drugs reduce the severity and prevent the recurrence of symptoms of schizophrenia. Recent studies indicate that these drugs probably produce their antipsychotic effects by blocking dopamine receptors in the brain, although they also block acetylcholine and norepinephrine receptors. The potency of commercially available neuroleptics in blocking dopamine receptors varies widely, being related to the compound''s lipid solubility. Neuroleptics predispose the patient to short-term and long-term medical hazards that must be weighed against the benefits of reduced symptom intensity, shortened psychotic episodes and lessened likelihood of recurrence of acute schizophrenic epidoses. The side effects associated with short-term therapy are either extremely rare or are treatable by dose change, medication change or the use of additional drugs. In long-term therapy the risks are more problematic in that they are sometimes irreversible. These include tardive dyskinesia, skin discoloration and corneal deposits. The clinician must consider the pattern aand severity of each patient''s present and past psychotic episodes before deciding whether maintenance therapy with neuroleptics is justified. If it is, doses should be re-evaluated frequently and kept as low as possible. Concomitant administration of anticholinergic agents should be avoided if possible. Most important, the long-term administration of neuroleptics should be prescribed only for patients with schizophrenia and not for those with conditions that respond to other treatments.     

Electrophysiological study of effects of chronic injection of caffeine on defensive reflex conditioning in grape snail

It was found that chronic injection of caffeine to grape snail increases a velocity of elaboration of conditioned defensive reflex. It was shown that after daily injection of caffeine immediately after procedure of learning the conditioned defensive reflex elaborated faster than daily injection before procedure of learning. It has been shown, that chronic injection of caffeine both in naive as well as learned snails led to depolarizing shift of membrane potential and to decrease of threshold potential of command neurons of the defensive behaviour of grape snails. It was also found that addition of caffeine in bath solution led to decrease of threshold of generation of action potential of command neurons both in intact and learned snails. The resting membrane potential of command neurons was not changed.     

The dynamics of forming an active defensive reflex in cats]

Active defensive reflexes were elaborated in cats with pain stimulations of the forepaw by means of an electrical pricking device with a target attached to it. The elaboration was carried out during action of a flickering light used for the convenience of the EEG analysis. Repeated pain stimulation led to elaboration of an aggressive attacking reaction, chiefly manifested in the paw striking the target. At the beginning of the elaboration, passive-defensive reactions were manifest, which did not completely disappear even after formation of a stable attacking reflex. Two types of active defensive reflexes were elaborated: A-type reflex which helped the animal to get rid of the pain stimulation at the very beginning; B-type reflex which prevented the pain stimulation. The difference beteween these two types is discussed.     

Influence of acoustic signal with ultrasonic components on the development of defensive conditioned reflex in Wistar rats

Short-term (90 s) effects of the complex acoustic signal (CAS) with ultrasonic components on the development of defensive conditioned reflex of two-way active avoidance in a shuttle-box were studied in female Wistar rats. The learning ability of rats was measured on a scale designed in our laboratory. It was shown that CAS stimulation triggered an audiogenic seizure of different strength in 59% of animals. The CAS was extremely stressful for Wistar rats: it prevented the active avoidance learning in early terms after its application (the first training session in 4 or 6 days). This effect did not depend on the presence or intensity of audiogenic seizures during CAS. In the second training session in 9 days (the first session was in 4 days), learning was impaired as compared to control without CAS. However, during repeated training procedure 1.5 months after the CAS (the first session in 6 days), rats rapidly reached the criterion of learning (10 consecutive avoidance reactions). On the other hand, if the CAS was presented with different time lags (immediately, in 3 or in 45 days) after the first training session, the ability of animals to learn during the second session was not impaired both in early and late terms after exposure to the stressor. The results suggest that exposure to CAS prevents development of short-term memory but does not affect consolidation process and long-term memory.     

Electrophysiological study of 5,6-dihydroxytryptamine effect on defensive reflex conditioning in the snail

The role of serotonin in expression of membrane properties of identified neurons was studied during defensive reflex conditioning using the neurotoxic analogue of serotonin 5,6-dihydroxytryptamine (5,6-DHT). The defensive reflex conditioning in snails was destroyed on the second day after second injection of 5,6-DHT. Through the 1st weeks after second injection of 5,6-DHT the snails were learned but worse than snails after injection of saline solution. This result shows the recovery of snail's learning ability within 2 weeks after the second injection of 5,6-DHT. It was found that injection of 5,6-DHT prevented the decrease of membrane and threshold potentials of command neurons during defensive reflex conditioning as compared with the snails injected with 5,6-DHT without learning.     

The action of korazol on the defensive behavior of rats]

The paper shows the dependence of behavioral changes provoked by corazol on individual characteristics of the animals. The rats with high activity in the ATS demonstrated the highest response to the drugs.     

The neurochemical basis of recurrent inhibition in the reflex arch of the defensive reaction]

Mechanisms of habituation in the network of identified neurones were investigated in isolated preparation of central nervous system in the snail Helix. It has been found that intracellularly induced spike discharge in premotor command neurones decreases synaptic responses to repeated nerve stimulation in all recorded command neurones. Application of the neuropeptide FMRFamide elicits similar changes in the network. Taking into account that the investigated command neurones contain FMRFamide, as was shown immunochemically, it is possible to assume the existence of recurrent inhibition in the network underlying avoidance reactions. This recurrent inhibition causes habituation of the network output in the cases when the repeated stimuli do not evoke sensitization via activation of serotonergic cells.     

The defensive role of latex in plants: detrimental effects on insects

The defensive role of the latex of Calotropis procera has recently been reported. In this study, latex proteins involved in detrimental effects on insects were evaluated on another important crop pest. The latex was fractionated to obtain its major protein fraction, which was then used to evaluate its insecticidal properties against Callosobruchus maculatus (Coleoptera: Bruchidae) in artificial bioassays. Laticifer proteins (LP) were investigated to characterize their action in such an activity. LP was highly insecticidal at doses as low as 0.1% (W/W). This effect was slightly augmented in F₁ generation reared in artificial seeds containing LP at similar proportions of F₀, but was fully reversed when F₁ developed in LP-free seeds. The insecticidal proteins were not retained in a chitin column, and did not lose their insecticidal activity, even after heat treatment or pronase digestion. However, these samples inhibited papain (EC 3.4.22.2) activity and gut proteases of C. maculatus larvae, and a reverse zymogram showed the presence of protein bands resistant to papain digestion. These activities were not observed in unheated LP as they were probably masked by abundant endogenous cysteine protease (EC 3.4.22.16) activity present in unheated LP. LP was resistant to proteolysis when assayed with C. maculatus gut extract. However, gut proteins of C. maculatus were digested when incubated with LP. These observations and the deleterious effects of LP upon C. maculatus, reinforce the hypothesis that laticifer fluids are involved in plant defense against insects and indicate C. procera latex to be a source of promising insecticidal proteins. The inhibitor of proteolysis present in the latex seems to be resistant to heat and proteolysis and is certainly involved in the detrimental effects observed.     

The vestibulo-ocular reflex of hypergravity rats

The vertebrate vestibular system detects linear (otolith organs) and angular (semicircular canals) acceleration. The function of the otolith system is twofold, 1: perception of linear acceleration of the head, and 2: assessment of the spatial orientation of the head relative to the vector of gravity. Because of the latter function, a change of gravity will affect the vestibular input which, in turn, may have a wide range of serious physiological effects, for instance on ocular reflexes. The function of the vestibulo-ocular reflex (VOR) is to stabilize the visual image on the retina. Measurement of this VOR provides a method to investigate the (processing within the) vestibular system. Discrimination between gravity and linear acceleration, caused by movement of the head, is not possible. Therefore, information from the otolith system must be constantly compared with additional information from other sensory systems in order to solve the inherent ambiguity between tilt and translation. In this processing, cues from the semicircular canals also play a role. During parabolic flight, experiments can be performed at altered gravity levels for brief periods of time. On earth, the only effective possibility to manipulate gravity for longer periods of time is a centrifuge. Together with experiments in weightlessness during orbital flight, these methods form useful tools to investigate the influence of gravity on physiology. In our laboratory, rats have been kept inside a centrifuge at 2.5 g during their entire life-span (i.e. including gestation).     

Sensitization and habituation of command neurons during a defensive reflex in grape snails

All investigated neurones were classified into functional groups depending on their participation in unconditioned avoidance reflex of pneumostome closure. Habituation was produced by tactile stimuli applied with a frequency of 0.1 c/s. Spike responses of neurons participating in processing sensory information habituated gradually, while reactions of command neurones of avoidance behaviour became sensitized to the second or third stimulus of the series. Behavioral reaction was sensitized in parallel with command neurones in spite of habituation in other types of nerve cells. A conclusion is drawn that behavioral habituation is due to waning of responses in all the participating neurones, but the independnet process of sensitization is due to sensitization of command neurones. Probable mechanisms of neuronal sensitization are discussed.