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Notes: Abstract We obtained intracellular recordings of 84 Purkinje cells in vitro from guinea pig slices and of 35 cells in vivo from ketamine-anesthetized rats in order to assess detailed properties of synaptic responses in Purkinje cells following granule cell activation. In vitro, electrical stimulation of the granule cell layer underlying recorded Purkinje cells was used in sagittal slices to predominantly activate synapses on ascending granule cell axons. In vivo, stimulation of the upper lip was used to activate Purkinje cells overlying the upper lip patch in the granule cell layer of crus IIa. In the presence of a GABAA antagonist, Purkinje cells at resting membrane potential responded to both electrical stimulation in vitro and peripheral stimulation in vivo, with a depolarization of 1–10 mV amplitude that lasted for 100–300 ms in the absence of climbing fiber input. Similar prolonged depolarizations could also be induced by brief depolarizing current pulses delivered through the recording electrode, demonstrating that either synaptic or direct depolarization may activate inward currents leading to a sustained response. In support of this hypothesis we found that prolonged depolarizations were shortened significantly when stimulation in the granule cell layer or intracellular current pulses were delivered during hyperpolarizing current steps. Stimulation in the granule cell layer or intracellular current pulses delivered during periods of spontaneous somatic spiking resulted in prolonged depolarizations in dendritic recordings, which were accompanied by an increase in somatic spiking frequency. Following upper lip stimulation in vivo, this increase in somatic spiking was interrupted by an inhibition of 10–50 ms duration. In a majority of recordings, this inhibition did not completely abolish prolonged depolarizations, however, and a delayed increase in somatic spike frequency was still observed. These results suggest that prolonged increases in Purkinje cell spike frequency following peripheral stimulation are due to an underlying prolonged dendritic depolarization induced by granule cell input. Further, a single, short burst of input via ascending granule cell axons appears to be sufficient to induce these responses.

Notes: Abstract Single cell activity was recorded from the primate putamen, caudate nucleus, and globus pallidus during a precued reaching movement task. Two monkeys were trained to touch one of several target knobs mounted in front of them after an LED was lighted on the correct target. A precue was presented prior to this target “go cue” by a randomly varied delay interval, giving the animals partial or complete advance information about the target for the movement task. The purpose of this design was to examine neuronal activity in the major structures of the basal ganglia during the preparation phase of limb movements when varying amounts of advance information were provided to the animals. The reaction times were shortest with complete precues, intermediate with partial precues, and longest with precues containing no information, demonstrating that the animals used precue information to prepare partly or completely for the reaching movement before the target go cue was given. Changes in activity were seen in the basal ganglia during the preparatory period in 30% of neurons in putamen, 31% in caudate nucleus, and 27% in globus pallidus. Preparatory changes were stronger and more closely linked to the time of movement initiation in putamen than in caudate nucleus. Although the amount of information contained in the precues had no significant effect on preparatory activity preceding the target go cue, a directional selectivity during this period was observed for a subset of neurons with preparatory changes (15% in putamen, 11% in caudate nucleus, 14% in globus pallidus) when the precue contained information about the upcoming direction of movement. A smaller subset of neurons showed selectivity for the preparation of movement amplitude. A larger number of preparatory changes showed selectivity for the direction or amplitude of movement following the target go cue than in the delay period before the cue. The intensity of preparatory changes in activity in many cases depended on the length of the delay interval preceding the target go cue. Even following the target go cue, the intensity of the preparatory changes in activity continued to be significantly influenced by the length of the preceding delay interval for 11% of changes in putamen, 8% in caudate nucleus, and 18% in globus pallidus. This finding suggests that preparatory activity in the basal ganglia takes part in a process termed motor readiness. Behaviorally, this process was seen as a shortening of reaction time regardless of precue information for trials in which the delay interval was long and the animals showed an increased readiness to move. Preparatory activity in putamen following the target go cue was most intense in trials with a short delay interval, in which motor readiness had not achieved its maximum level prior to the go cue. The results of this study indicate that the basal ganglia are involved in multiple aspects of preparatory processing for limb movement. Preparatory processing is therefore unlikely to be divided anatomically along the functional lines examined in this study. In the basal ganglia, preparatory processing reflects both preparation for target selection and control of timing the onset of movement (motor readiness). These characteristics can be integrated in a functional scheme in which the basal ganglia are predominantly responsible for the automated execution of well-trained behavior.

Notes: [Auszug] The basal ganglia are an interconnected set of subcortical regions whose established role in cognition and motor control remains poorly understood. An important nucleus within the basal ganglia, the striatum, receives cortical afferents that convey sensorimotor, limbic and cognitive ...

Notes: Abstract A dynamic model for the design of multi-section semiconductor lasers is developed based on the Transmission Line Method. The different building blocks of this model are presented and the model is evaluated for a tunable two-section laser device.

Notes: Abstract Lake Krupunder is a small, glacial, stratified lake. Before restoration it was classified as eutrophic to polytrophic. Stepwise the lake was restored to a mesotrophic status: 1. In April 1990 a deep water aeration plant was installed. Although the entire hypolimnion was sufficiently supplied with oxygen the trophic level remained high because of substochiometric natural iron concentrations. 2. In September 1991 a technical iron-phosphate precipitation was carried out, dispensing 1.8 t of iron-chloride-sulfate (‘Ferri floc’) into the hypolimnion using the aerator. Until July 1992 the chlorophyll-a concentration decreased by 90%/77% (maximum/mean value).