1,720,986 research outputs found
Is there a link between increased ASD prevalence and immediate umbilical cord clamping?
No full texthttp://pediatricsaappublicationsorg/cgi/eletters/peds2009-1522v1#4920
Intrinsic oscillations in CA3 hippocampal pyramids: physiological relevance to theta rhythm generation.
No full text
Giant GABAergic potentials in the developing hippocampus: a model of neuronal synchronization.
No full textExperience-dependent plasticity in S1 caused by noncoincident inputs
No full textPrior work has shown that coincident inputs became corepresented in somatic sensory cortex. In this study, the hypothesis that the corepresentation of digits required synchronous inputs was tested, and the daily development of two-digit receptive fields was observed with cortical implants. Two adult primates detected temporal differences in tap pairs delivered to two adjacent digits. With stimulus onset asynchronies of >= 100 ms, representations changed to include two-digit receptive fields across the first 4 wk of training. In addition, receptive fields at sites responsive to the taps enlarged more than twofold, and receptive fields at sites not responsive to the taps had no significant areal change. Further training did not increase the expression of two-digit receptive fields. Cortical responses to the taps were not dependent on the interval length. Stimuli preceding a hit, miss, false positives, and true negatives differed in the ongoing cortical rate from 50 to 100 ms after the stimulus but did not differ in the initial, principal, response to the taps. Response latencies to the emergent responses averaged 4.3 ms longer than old responses, which occurs if plasticity is cortical in origin. New response correlations developed in parallel with the new receptive fields. These data show corepresentation can be caused by presentation of stimuli across a longer time window than predicted by spike-timing-dependent plasticity and suggest that increased cortical excitability accompanies new task learning
Effects of sensorimotor restriction and anoxia on gait and motor cortex organization: implications for a rodent model of cerebral palsy
No full textChronic or acute perinatal asphyxia (PA) has been correlated with the subsequent development of cerebral palsy (CP), a developmental neurological disorder characterized by spasticity and motor abnormalities often associated with cognitive deficits. Despite the prevalence of CP, an animal model that mimics the lifetime hypertonic motor deficits is still not available. In the present study, the consequences of PA on motor behavior, gait and organization of the primary motor cortex were examined in rats, and compared with the behavioral and neurological consequences of early postnatal movement-restriction with or without oxygen deprivation. Rats subjected to PA had mild increases in muscular tone accompanied by subtle differences in walking patterns, paralleled by significantly altered but relatively modest disorganization of their primary motor cortices. Movement-restricted rats, suffering PA or not, had reduced body growth rate, markedly increased muscular tone at rest and with active flexion and extension around movement-restricted joints that resulted in abnormal walking patterns and in a profoundly distorted representation of the hind limbs in the primary motor cortex. Within the sensorimotor-restricted groups, non-anoxic rats presented the most abnormal pattern and the greatest cortical representational degradation. This outcome further supports the argument that PA per se may represent a substrate for subtle altered motor behaviors, and that PA alone is sufficient to alter the organization of the primary motor cortex. At the same time, they also show that early experience-dependent movements play a crucial role in shaping normal behavioral motor abilities, and can make a powerful contribution to the genesis of aberrant movement abilities
Thalamic and cortical contributions to neural plasticity after limb amputation.
No full text Little is known about the substrates for the large-scale shifts in the cortical representation produced by limb amputation. Subcortical changes likely contribute to the cortical remodeling, yet there is little data regarding the extent and pattern of reorganization in thalamus after such a massive deafferentation. Moreover, the relationship between changes in thalamus and in cortex after injuries of this nature is virtually unexplored. Multiunit microelectrode maps were made in the somatosensory thalamus and cortex of two monkeys that had long-standing, accidental forelimb amputations. In the deprived portion of the ventroposterior nucleus of the thalamus (VP), where stimulation to the hand would normally activate neurons, new receptive fields had emerged. At some recording sites within the deprived zone of VP, neurons responded to stimulation of the remaining stump of the arm and at other sites neurons responded to stimulation of both the stump and the face. This same overall pattern of reorganization was present in the deprived hand representation of cortical area 3b. Thus thalamic changes produced by limb amputation appear to be an important substrate of cortical reorganization. However, a decrease in the frequency of abnormal stump/face fields in area 3b compared with VP and a reduction in the size of the fields suggests that cortical mechanisms of plasticity may refine the information relayed from thalamus. </jats:p
Whole Cell and Single Channel Properties of a New GABA Receptor Transiently Expressed in the Hippocampus.
No full text 1. The patch-clamp technique was used to characterize, in acutely dissociated CA3 rat hippocampal neurons, the whole cell and single channel properties of a novel response to gamma-aminobutyric acid (GABA) present only during a restricted period of postnatal development. 2. At postnatal days 0-10 (P0-P10), both GABA (100 microM) and isoguvacine (50 microM) evoked at a holding potential of -50 mV, in symmetrical chloride solution, whole cell inward currents. Bicuculline blocked the response to isoguvacine but only reduced the response to GABA (from 512 +/- 137 pA to 60 +/- 13 pA, mean +/- SE). After P12, bicuculline abolished the response to GABA. 3. The bicuculline-insensitive GABA currents were Cl- mediated and antagonized by picrotoxin. The desensitization rate was slower than the conventional bicuculline-sensitive response. The peak to plateau ratio induced by 0.1 or 1 mM of GABA shifted from 4.6 +/- 0.4 and 17.7 +/- 2.6 to 1.5 +/- 0.1 and 3.1 +/- 0.5 in the absence or in the presence of bicuculline, respectively. The recovery from desensitization was significantly faster for the bicuculline-insensitive responses. 4. In excised outside-out patches, GABA (20 microM) activated, in the presence of bicuculline (100 microM), single channel currents having conductances of 14, 22, and 31 pS. These values were similar to those obtained in the same preparation, in the absence of bicuculline. 5. These findings suggest that this new receptor type, which mediates bicuculline-insensitive responses with slow kinetics, may potentiate the depolarizing action of GABA during a critical period of postnatal development and therefore play a crucial role in synaptogenesis. </jats:p
GABAC receptors: a novel receptor family with unusual pharmacology
No full text GABAC-receptor channels constitute a novel class of structurally defined receptors that are composed by the recently discovered r-subunits. They conduct chloride ions, are insensitive to both bicuculline and baclofen, and are blocked by picrotoxin. They are present in the hippocampus during development and in the retina where they play a crucial role in regulating visual processing. </jats:p
- …
