Individual features of play behavior in thick-toed geckos in weightlessness and normal gravity conditions.

The object play behavior in thick-toed geckos (Chondrodactylus turneri GRAY 1864) was studied during a 30-day orbital experiment onboard the Bion-M1 biosatellite. The play object for five geckos was a marking collar that one of the geckos in the flight group removed immediately before the launch. The play behavior started when either the gecko observed the approaching floating collar or when the gecko independently approached the stationary collar, followed by manipulation of the collar and subsequent observation of its moving away. While playing with the collar, the individuality of geckos' behavior was manifested in the frequency and number of play episodes, the nature of manipulations, and the duration of interest in play during the flight. We found that thick-toed geckos could play not only with an unknown object (marking collar) but also with familiar molting skins. In weightlessness, the play behavior of geckos with molting skin fragments was similar to the play behavior with the collar and also varied between individuals. It was established that geckos maintained a similar individual level of play activity with different objects (collar and molting skins). It was found that geckos also played with fragments of molting skin under normal gravity conditions. In contrast to weightlessness, play behavior at normal gravity was rare and limited to short durations of object manipulation.

Attachment of Turner's thick-toed geckos (Chondrodactylus turneri GRAY 1864) during weightlessness and their responses to flotation.

We investigated the behavior of 15 female Turner's thick-toed geckos (Chondrodactylus turneri GRAY 1864) during a 30-day orbital experiment on the unmanned spacecraft "BION-M" No. 1. During weightlessness, the geckos maintained their ability to attach to the surfaces using the subdigital pads on their toes. On average, the geckos spent 99.9% of the time adhering to surfaces during the flight and only 0.1% floating freely. The active geckos, when starting to float, immediately restored attachment by a number of behavioral responses. The floating quiescent geckos, when resuming their active condition, responded in the same manner. The responses during flotation are similar to the behavioral reflexes triggered by a fall under normal gravity; i.e.: 1) the ventral extension of the limbs, 2) a skydiving posture, and 3) postural righting reflexes. Ventral extension of limbs was described for the first time in weightlessness. Individual variability in the frequency of flotations was found for both active and quiescent geckos during the flight. The findings show that the ability to attach to surfaces is an important factor in the geckos' adaptation to weightlessness. The behavioral responses that originated during freefall in conditions on Earth (one-G) appear as adaptations to weightlessness and remain partially effective.

[Supporting life of Pachydactylus turneri in a projected experiment aboard robotic spacecraft: choosing feed].

An experiment was carried out to validate and select feed to be supplied to Pachydactylus turneri in a 30-day orbital flight of robotic spacecraft BION-M1. Larvae of two Tenebrionidae species, i.e., Tenebrio molitor and Zophobas were tested for survivability, tolerance of hunger and cold, ability to stick to and move along different surfaces. Tenebrio molitor was shown to be best suited. A special feeder that will sustain the beetle over 30 days was designed. The experiment provided new data about Tenebrionidae biology and suggested the feeding technology for a 2-month space experiment with Pachydactylus turneri.

[A perspective of present approaches to EEG analyses performed with intention to find seizure predictors].

In the late 90-s of the previous century the American Society of Epileptologists defined a priority for research as "possibilities to predict a seizure, early determinate and reduct". A method, which would allow the prediction of epileptical seizure's onset based on the EEG data registered with the patient with an epilepsy disease, would also allow implementing the new approach to treatment. If it became reliably possible to predict a moment of seizure, based on the EEG dynamics, one could create an automated closed loop system to prevent a seizure. In the article a number of works regarding this subject were reviewed. Also own results were discussed which were derived from analyses of brain electrical activity of rats with absence epilepsy and with the use of own developed software. Moreover specifics of absence initiation and course were discussed, as well as formation mechanism of thalamus-cortical loop, existing abilities of reduction not only absences, but also cognitive and emotional dissociations. Also described results of analyses of the EEG time series, that were derived by computation of correlation dimension with own developed software.

The role of the nucleus basalis of Meynert and reticular thalamic nucleus in pathogenesis of genetically determined absence epilepsy in rats: a lesion study.

The role of cholinergic nucleus basalis (of Meynert) and the reticular thalamic nucleus in mechanisms of the generation spontaneous spike-and-wave discharges (SWDs) was investigated in the WAG/Rij rat model of absence epilepsy. Selective lesions were affected by local unilateral intraparenchymal infusions of immunotoxin 192 IgG-saporin and cholinotoxin AF64A to the nucleus basalis and the rostral pole of reticular thalamic nucleus. Injections of 192 IgG-saporin into the nucleus basalis increased the number of spontaneous SWDs, while injections in the reticular thalamic nucleus were not effective. Thereby, a loss of cholinergic activity in the nucleus basalis stimulates the appearance of SWDs. At the same time, AF64A infused into reticular thalamic nucleus, besides the reduction of choline acetyltransferase immunoreactive neurons within contralateral nucleus basalis, produced some unspecified lesion of adjacent neuronal tissue, resulted in decrease of number and duration of SWDs as well as in spectral changes in EEG. Considering that the nucleus basalis is an important source of cortical and thalamic cholinergic afferentation, we conclude that cholinergic excitatory input from this structure is important in the control of SWDs in the WAG/Rij rat model of absence epilepsy.

[Epileptogenic activity of tripeptide corticotropin-releasing factor fragment (CRF(4-6))].

The effects of centrally administered tripeptide fragment CRF(4-6) of corticotropin-releasing factor on convulsive activity in outbred albino rats were investigated. The peptide CRF(4-6) (icv; 6, 30, 150 nmol/head) causes dose-dependent increase in total EEG power in 1-40 Hz frequency range as a reflection of tripeptide-induced various epileptiform EEG signs such as single peaks and spike trains without external convulsion. Higher doses of CRF(4-6) (icv; 150, 225, 300 nmol per animal) induce tonicoclonic seizures. Switching to convulsive activity occurs at CRF(4-6) dose of 150 nmol per animal: injection of this dose leads only to EEG paroxysmal activity under habitual conditions and induces pathological locomotor activation under stressing conditions. Thus, CRF(4-6) similarly to full-length corticotropin-releasing factor induces epileptiform activity in rats.

[The cortico-thalamic theory for generalised spike-wave discharges]. / Kortikotalamicheskaia teoriia proiskhozhdeniia generalizovannykh pik-volnovykh razriadov.

The origin of generalized absence epilepsy is still not known. In the last century, four theories have dominated the debate about the origin of the bilateral synchronous generalized spike-wave discharges associated with absence seizures: the "centrencephalic" theory [Penfield and Jasper], the "cortical" [Bancaud, Niedermeyer, Luders], the "cortico-reticular" theory [Gloor, Kostop[oulos, Avoli] and the "thalamic clock" theory [Buzsaki]. There is now some evidence that absence epilepsy, as studied in the WAG/Rij model, is a corticothalamic type of epilepsy. A new hypothesis is proposed which suggests that a cortical focus in the somatosensory cortex is driving the widespread corticothalamic networks during spontaneous absence seizures. This modern theory was given the name "hot spot' theory" [Meeren et al., 2002]. According to the present view three brain structures are critically involved and their integrity seems a minimal and sufficient condition for the occurrence of spike-wave discharges. Firstly, the reticular thalamic nucleus is involved and most likely its rostral pole. Secondly, the thalamocortical relay cells in the ventrobasal complex play a role and, thirdly and most importantly, the cerebral cortex with its epileptic zone. The zone in which the epileptic focus seems to be localised is located on the somato-sensory cortex, and more precisely in the area on which the peri-oral region including the upper lip, projects.

[Cholinergic mechanisms in the pathogenesis of genetically-caused absence epilepsy]. / Kholinergicheskie mekhanizmy v patogeneze geneticheski obuslovlennoi absansnoi épilepsii.

Frontoparietal cortex and the thalamocortical circuit comprising reticular thalamic nucleus (RTN) and relay nuclei of the ventrolateral thalamus (VLT) are critical structures in the generation of spike-wave discharges (SWD) during absence seizures. The activity of these nuclei is under the control of the ascending cholinergic projections of nucleus basalis of Meynert. The aim of our study is to make an attempt to change the pattern of SWD in WAG/Rij rats by injecting of cholinotoxine AF64A to the area of RTN. Spontaneous SWD were registered in cortex of WAG/Rij rats with genetically determined absences. The spectral content of SWD was analyzed by means of the Fast Fourier Transformation (FFT) procedure. Unilateral injections of AF64A (1 nmol) to RTN led the decrease in duration and number of SWD comparing to the basal EEG recordings 2 days after the lesion. The FFT analysis showed the disappearance of 17-18 Hz spike on the side of the lesion compared with the intact side. The immunohistochemical study for acetylcholinetransferase (ChaT)-containing neurons showed the loss of ChaT-positive cells in the nucleus basalis area on the side of the lesion. The removal of cholinergic afferentation of RTN and cortex from nucleus basalis inhibits the SWD developing most likely due to the decrease of cortical excitability. Moreover, possibly cholinergic transmission is involved in the transforation of the synchronized phenomena (SWD) to another with close mechanism of generation.

[Anxiety and behavior in WAG/Rij strain rats with genetically induced absence attacks]. / Trevozhnost' i povedenie krys linii WAG/Rij s geneticheski obuslovlennymi absansnymi pristupami.

Behavior of nonlinear rats and animals from Wistar and WAG/Rij (with inborn generalized absence epilepsy) strains was examined in the elevated plus-maze and the hole board. WAG/Rij rats demonstrated low exploratory behavior in both tests. In the elevated plus-maze, WAG/Rij rats were more balanced and more anxious than Wistar and nonlinear rats. Administration of ethosuximide completely eliminated spike-wave discharges but did not change behavioral interstrain differences. Since the spike-wave patterns develop in WAG/Rij at the age of 3 months, the behavior of young (2-moth-old) pups from different strains was compared and significant differences were revealed. Correlation between the genetically defined features (spike-wave discharges) and behavioral peculiarities in WAG/Rij rats is supposed.

[An aversive olfactory signal during the Y-maze learning of mice selected for greater or lesser brain weight]. / Aversivnyi oboniatel'nyi signal pri obuchenii v Y-obraznom labirinte myshei, slektirovannykh na bol'shoi i malyi ves mozga.

Learning abilities of mice selected by the small and large brain weights were studied in Y-maze. Thirsty mice were trained to find water in one of the maze arms. The minimal latency of this reaction reached in the process of learning was shorter in the mice selected by the heavy brain. Benzaldehyde which is commonly supposed to be an aversive olfactory stimulus being presented before drinking sharply increased the latency, nevertheless, it remained shorter in mice with heavy brain. The response to the aversive stimulus varied between the individuals, especially in mice selected by the small brain weight.