Study of sleep spindles in the rat: a new improvement. (33/41)

The two kinds of sleep spindles, previously described in the rat, were studied in intact animals, cerveau isole preparations and unilaterally neodecorticated rats. The anterior (frontal) spindles reach their maximum during deep slow sleep, when accompanied by theta activity, during the so-called intermediate stage which occurs just before and after paradoxical sleep. This stage is extended by low doses of barbiturate and similar patterns are induced by an intercollicular transection. The anterior spindles are suppressed by unilateral nedecortication and become abortive on contralateral hemisphere. The posterior ones, larger when recorded in the dorsal hippocampus than an the occipital cortex precede the appearance of the theta activity of intermediate stage. They are absent when the theta rhythm is present, during the long-continued intermediate stage under barbiturate ad in the cerveau isole preparation; but an unilateral neodecortication does not prevent the occurrence of posterior spindles on the white matter. Thus, during deep slow sleep, the rat shows both frontal cortex spindles, fully spread out during intermediate stage, and posterior spindles, probably originating from structures implied in the theta genesis and heralding the occurrence of this rhythmic slow activity.  (+info)

Functions of the neostriatum: cortex-dependent or autonomous? (34/41)

Studies of animals with ablations of varying amounts of the neocortex, the neostriatum, or both, are reviewed in an attempt to establish to which extent functions of the neostriatum are dependent on its cortical input. Scarce and inconclusive evidence does not allow firm conclusions. It seems well established that the neostriatum shares some functions with the neocortex. In the rat and infant monkeys these striatal functions appear to be cortex-independent, whereas in cats and adult monkeys they seem to be more cortex-dependent. It is possible, and even likely, that the neostriatum also has functions which are not shared with the cortex and which are cortex-independent. The degree to which the neostriatum is able to contribute to the integration of behavior in the absence of its cortical input is species- and age-specific.  (+info)

Interaction of pergolide with central dopaminergic receptors. (35/41)

The activity of pergolide, an N-propylergoline derivative, has been tested for stimulation of central dopaminergic receptors. Binding to dopamine receptors shows that pergolide acts as an agonist with respect to these receptors. GTP decreases the potencies of dopamine agonists and of pergolide, but not of bromocriptine, to displace [3H]spiroperidol ([3H]Spi) from striatal membrane sites. The GTP-sensitive site labeled by [3H]Spi seems to be localized on intrastriatal dopamine receptors. The potency of dopamine agonists and of pergolide to displace [3H]Spi from striatal receptor sites is reduced in membranes exposed to higher temperatures. Pergolide, but not hitherto-tested dopaminergic ergots, stimulates dopamine-sensitive adenylate cyclase in striatal homogenates. Thus, pergolide, unlike other dopaminergic ergots, acts as an agonist on GTP-sensitive components of [3H]Spi binding and stimulates dopamine receptors linked to dopamine-sensitive adenylate cyclase. The drug also induces turning behavior in rats with 6-OH-dopamine lesions and relieves tremor in monkeys with ventromedial tegmental lesions for a longer time at a lower dose than other tested dopaminergic ergots. Other studies have shown that it is effective in the treatment of patients with advanced parkinsonism.  (+info)

Hemimegalencephaly and intractable epilepsy treated with embolic hemispherectomy. (36/41)

A patient with hemimegalencephaly and intractable epilepsy underwent a preoperative embolic hemispherectomy. A seizure-free interval of 1 year followed the embolization procedure. In addition, the procedure was thought to be beneficial in limiting blood loss during a subsequent surgical hemispherectomy.  (+info)

Cerebral metabolism following neonatal or adult hemineodecortication in cats: I. Effects on glucose metabolism using [14C]2-deoxy-D-glucose autoradiography. (37/41)

In the cat, cerebral hemispherectomy sustained neonatally results in a remarkable degree of recovery and/or sparing of function as compared with the effects of a similar lesion but sustained in adulthood. We have proposed that this effect is due to a combination of reduced neuronal loss within partially denervated structures and a lesion-induced reorganization of corticofugal projections arising from the remaining intact hemisphere in the neonatally lesioned animal. The current study was designed to assess the physiological consequences of these anatomical changes utilizing [14C]2-deoxy-D-glucose autoradiography. A total of 17 adult cats were studied. Seven animals served as intact controls, five received a left cerebral hemineodecortication as neonates (NH; mean age 11.4 days), and five sustained the same lesion in adulthood (AH). Histological analysis indicated that the lesion was very similar between the two age groups and essentially represented a unilateral hemineodecortication. Local CMRglc (LCMRglc; mumol 100 g-1 min-1) values were calculated for 50 structures bilaterally and indicated that in the remaining intact contralateral (right) cerebral cortex (including all areas measured), AH cats exhibited a significantly (p < 0.05) lower level of LCMRglc (ranging from 20 to 72 mumol 100 g-1 min-1) than NH (ranging from 49 to 81 mumol 100 g-1 min-1). In comparison, the rates of NH cats within the cerebral cortex were very similar to those seen in intact animals (ranging from 48 to 119 mumol 100 g-1 min-1). Ipsilateral to the lesion in AH cats, the structures spared by the resection, including the basal ganglia and thalamus, exhibited LCMRglc rates of between 23 and 69 mumol 100 g-1 min-1, which were significantly lower (p < 0.05) than in NH cats (range 47-72 mumol 100 g-1 min-1). Considering all structures, both age-at-lesion groups exhibited a lower level of metabolism compared with similar measurements for intact control animals (LCMRglc range 45-75 mumol 100 g-1 min-1). However, this depression of glucose metabolism was more pronounced in the AH cats (p < 0.05). These results indicate that following neonatal hemineodecortication, LCMRglc is maintained at a higher level in many regions of the brain than in animals that sustain the same resection in adulthood. This higher level of glucose metabolism in NH animals suggests that the lesion-induced anatomical reorganization of structures not directly injured by the lesion plays a functional role that is probably responsible for the greater degree of recovery and/or sparing of function in these early lesioned cats.  (+info)

Spatiotemporal patterns of spindle oscillations in cortex and thalamus. (38/41)

Spindle oscillations (7-14 Hz) appear in the thalamus and cortex during early stages of sleep. They are generated by the combination of intrinsic properties and connectivity patterns of thalamic neurons and distributed to cortical territories by thalamocortical axons. The corticothalamic feedback is a major factor in producing coherent spatiotemporal maps of spindle oscillations in widespread thalamic territories. Here we have investigated the spatiotemporal patterns of spontaneously occurring and evoked spindles by means of multisite field potential and unit recordings in intact cortex and decorticated animals. We show that (1) spontaneous spindle oscillations are synchronized over large cortical areas during natural sleep and barbiturate anesthesia; (2) under barbiturate anesthesia, the cortical coherence is not disrupted by transection of intracortical synaptic linkages; (3) in intact cortex animals, spontaneously occurring barbiturate spindle sequences occur nearly simultaneously over widespread thalamic territories; (4) in the absence of cortex, the spontaneous spindle oscillations throughout the thalamus are less organized, but the local coherence (within 2-4 mm) is still maintained; and (5) spindling propagation is observed in intact cortex animals only when elicited by low intensity cortical stimulation, applied shortly before the initiation of a spontaneous spindle sequence; propagation velocities are between 1 and 3 mm/sec, measured in the anteroposterior axis of the thalamus; increasing the intensity of cortical stimulation triggers spindle oscillations, which start simultaneously in all leads. We propose that, in vivo, the coherence of spontaneous spindle oscillations in corticothalamic networks is attributable to the combined action of continuous background corticothalamic input initiating spindle sequences in several thalamic sites at the same time and divergent corticothalamic and intrathalamic connectivity.  (+info)

Short-term plasticity during intrathalamic augmenting responses in decorticated cats. (39/41)

The intrathalamic mechanisms of frequency-dependent augmenting responses were investigated in decorticated cats by means of intracellular recordings from thalamocortical (TC) neurons in ventrolateral (VL) nucleus, including simultaneous impalements from two TC neurons. Pulse trains (10 Hz) applied to VL nucleus elicited two types of augmenting responses: (1) in 68% of cells, the incremental responses occurred on a progressive depolarization associated with the decrease in IPSPs produced by preceding stimuli in the train; (2) in the remaining cells, progressively growing low-threshold (LT) responses resulted from the enhancement of Cl--dependent IPSPs, giving rise to postinhibitory rebound bursts, followed by a self-sustained sequence of spindle waves. Although in some TC cells the augmenting responses developed from LT responses once the latter reached a given level of depolarization, other neurons displayed augmenting responses immediately after the early antidromic spike that depolarized the neuron to the required level, without an intermediate step of LT rebound. Repeated pulse trains led to a progressive and persistent increase in slow depolarizing responses of TC cells, as well as to a persistent and prolonged decrease in the amplitudes of the IPSPs. On the basis of parallel experiments, we propose that the two types of augmentation in TC cells are a result of contrasting responses of thalamic reticular neurons evoked by repetitive thalamic stimuli: decremental responses, which may account for disinhibition leading to depolarizing responses in TC cells, and incremental responses, explaining the progressive hyperpolarization of TC cells. These data demonstrate that frequency-dependent changes in neuronal excitability are present in the thalamus of a decorticated hemisphere and suggest that short-term plasticity processes in the gateway to the cerebral cortex may decisively influence cortical excitability during repetitive responses.  (+info)

Cellular mechanisms underlying intrathalamic augmenting responses of reticular and relay neurons. (40/41)

Augmenting (or incremental) responses are progressively growing potentials elicited by 5- to 15-Hz stimulation within the thalamus, cerebral cortex, or by setting into action reciprocal thalamocortical neuronal loops. These responses are associated with short-term plasticity processes in thalamic and cortical neurons. In the present study, in vivo intracellular recordings of thalamic reticular (RE) and thalamocortical (TC), as well as dual intracellular recordings, were used to explore the mechanisms of two types of intrathalamic augmenting responses elicited by thalamic stimuli at 10 Hz in decorticated cats. As recently described, after decortication, TC cells display incremental burst responses to thalamic stimuli that occur through either progressive depolarization (high threshold, HT) or progressive hyperpolarization leading to deinactivation of low-threshold (LT) spike bursts. Here, low-intensity stimuli (10 Hz) to dorsal thalamic nuclei elicited decremental responses in GABAergic RE cells, consisting of a progressive diminution in the number of action potentials in successive spike bursts, whereas higher stimulation (>50% of maximal strength) induced augmentation characterized by an increased number of spikes in repetitive responses. These opposing discharge patterns occurred in the absence of changes in the membrane potential of RE cells. In TC cells, augmentation depended on the thalamic site where testing volleys were applied. With stimuli applied closer to the site of impalement, augmenting resulted from a transformation from LT spike bursts into HT responses. Augmenting responses were followed by self-sustained oscillatory activity, within the frequency of spindles (7-14 Hz) or clock-like delta oscillation (1-4 Hz). As LT augmentation in TC cells results from their progressive hyperpolarization, we tested the effects exerted by the activating depolarizing system arising in the mesopontine cholinergic nuclei and found that such conditioning pulse-trains prevented the hyperpolarizing-rebound sequences as well as the LT augmenting in TC cells. We propose that the depolarization-dependent (HT) augmenting responses in TC cells result from decremental responses in RE neurons that are due to intra-RE inhibitory processes leading to disinhibition in target TC neurons, whereas LT-type augmenting in TC cells is produced mainly by incremental responses in GABAergic RE neurons.  (+info)