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Fractured brain function in unconscious humans II: functional brain imaging using MEG [Meeting Abstract]

Ribary U; Schiff N; Kronberg E; Plum F; Llinas R
ORIGINAL:0004425
ISSN: 1053-8119
CID: 33826

Frequency dependent spatiotemporal responses in somatosensory thalamocortical slices studied with voltage-sensitive dyes [Meeting Abstract]

Pedroarena, Christine; Contreras, Diego; Llinas, Rodolfo
BIOSIS:PREV199900032450
ISSN: 0190-5295
CID: 92327

Temporal conjunction in thalamocortical transactions

Llinas RR; Ribary U
PMID: 9709819
ISSN: 0091-3952
CID: 9879

Kinetic and stochastic properties of a persistent sodium current in mature guinea pig cerebellar Purkinje cells

Kay AR; Sugimori M; Llinas R
Whole cell voltage-clamp techniques were employed to characterize the sodium (Na) conductances in acutely dissociated, mature guinea-pig cerebellar Purkinje cells. Three phenomenological components were noted: two inactivating and a persistent component (I(P)(Na). All exhibited similar sensitivities to tetrodotoxin (TTX; IC50 approximately 3 nM). The inactivating Na current demonstrates two components with different rates of inactivation. The persistent component activates at a more negative membrane potential than the inactivating components and shows little inactivation during a 5-s pulse. The amplitude of the persistent Na conductance had a higher Q10 than the inactivating Na conductance (2.7 vs. 1.3). (I(P)(Na) rapidly activates (approximately 1 ms) and deactivates (< 0.2 ms) and like the fast component appears to be exclusively Na permeable. (I(P)(Na) is not a 'window' current because its range of activation exceeds the small overlap between the steady-state activation and inactivation characteristics of the inactivating current. Anomalous tail currents were observed during voltage pulses above -40 mV after a prepulse above -30 mV. The tails rose to a maximum inward current with a time constant of 1.5 ms and decayed to a persistent inward current with a time constant of 20 ms. The tails probably arose as a result of recovery from inactivation through the open state. The noise characteristics of (I(P)(Na) were anomalous in that the measured variance was lower at threshold voltages than would be predicted by a binomial model. The form of the variance could be partially accounted for by postulating that the maximum probability of activation of the persistent current was less than unity. The noise characteristics of (I(P)(Na) are such as to minimize noise near spike activation threshold and sharpen the threshold
PMID: 9744930
ISSN: 0022-3077
CID: 9878

Nerve growth factor acutely reduces chemical transmission by means of postsynaptic TrkA-like receptors in squid giant synapse

Moreno H; Nadal M; Leznik E; Sugimori M; Lax I; Schlessinger J; Llinas R
Tyrosine phosphorylation has been shown to be an important modulator of synaptic transmission in both vertebrates and invertebrates. Such findings hint toward the existence of extracellular ligands capable of activating this widely represented signaling mechanism at or close to the synapse. Examples of such ligands are the peptide growth factors which, on binding, activate receptor tyrosine kinases. To gain insight into the physiological consequences of receptor tyrosine kinase activation in squid giant synapse, a series of growth factors was tested in this preparation. Electrophysiological, pharmacological, and biochemical analysis demonstrated that nerve growth factor (NGF) triggers an acute and specific reduction of the postsynaptic potential amplitude, without affecting the presynaptic spike generation or presynaptic calcium current. The NGF target is localized at a postsynaptic site and involves a new TrkA-like receptor. The squid receptor crossreacts with antibodies generated against mammalian TrkA, is tyrosine phosphorylated in response to NGF stimulation, and is blocked by specific pharmacological inhibitors. The modulation described emphasizes the important role of growth factors on invertebrate synaptic transmission
PMCID:24564
PMID: 9844004
ISSN: 0027-8424
CID: 9877

Fractured brain function correlates with isolated behavioral patterns in the vegetative state [Meeting Abstract]

Ribary, U; Schiff, N; Kronberg, E; Llinas, R; Plum, F
ISI:000073196500186
ISSN: 0898-929x
CID: 53505

Dyschronic language-based learning disability

Chapter by: Llinas R; Ribary U; Tallal P
in: Basic mechanisms in cognition and language : with special reference to phonological problems in dyslexia by Von Euler C; Lundberg I; Llinas R [Eds]
Amsterdam : Elseiver, 1998
pp. 101-108
ISBN: 0080427472
CID: 2976

The first-order giant neurons of the giant fiber system in the squid: electrophysiological and ultrastructural observations

Pozzo-Miller LD; Moreira JE; Llinas RR
The giant fiber system controlling mantle contraction used for jet propulsion in squid consists of two sets of three giant neurons organized in tandem. The somata of the 1st- and 2nd-order giant cells are located in the brain, while the perikarya of the 3rd-order giant cells are encountered in the stellate ganglia of the mantle. The somata and dendrites of one fused pair of 1st-order giant cells are thought to receive synaptic input from the eye, statocyst, skin proprioceptors, and supraesophageal lobes. To define the cellular properties for integration of such an extensive synaptic load, especially given its diversity, intracellular recordings and electron microscopic observations were performed on 1st-order giant cells in an isolated head preparation. Spontaneous bursts of action potentials and spikes evoked by extracellular stimulation of the brachial lobe were sensitive to the Na+ channel blocker TTX. Action potentials were also abolished by recording with microelectrodes containing the membrane impermeant, use dependent Na+ channel blocker QX-314. The small action potential amplitude and the abundant synaptic input imply that the spike initiation zone is remotely located from the recording site. The high spontaneous activity in the isolated head preparation, as well as the presence of synaptic junctions resembling inhibitory synapses, suggest; that afferent synapses on 1st-order giant neurons might represent the inhibitory control of the giant fiber system. The characterization of the electroresponsive properties of the 1st-order giant neurons will provide a description of the single cell integrative properties that trigger the rapid jet propulsion necessary for escape behavior in squid
PMID: 10192523
ISSN: 0300-4864
CID: 7427

Presynaptic injection of syntaxin-specific antibodies blocks transmission in the squid giant synapse

Sugimori M; Tong CK; Fukuda M; Moreira JE; Kojima T; Mikoshiba K; Llinas R
A polyclonal antibody, raised against the squid (Loligo pealei) syntaxin I, inhibited Ca2+-dependent interaction of syntaxin with synaptotagmin C2A domain in vitro. Presynaptic injection of the anti-Loligo syntaxin IgG into the squid giant synapse blocked synaptic transmission without affecting the presynaptic action potential or the voltage-gated calcium current responsible for transmitter release. Repetitive presynaptic stimulation produced a gradual decrease in the amplitude of the postsynaptic potential as the synaptic block progressed, indicating that the antibody interferes with vesicular fusion. Confocal microscopy of the fluorescein-labelled anti-Loligo syntaxin IgG showed binding at the synaptic active zone, while ultrastructurally, an increase in synaptic vesicular numbers in synapses blocked when this antibody was observed. These results implicate syntaxin in the vesicular fusion step of transmitter release in concert with synaptotagmin
PMID: 9692742
ISSN: 0306-4522
CID: 7814

The neuronal basis for consciousness

Llinas R; Ribary U; Contreras D; Pedroarena C
Attempting to understand how the brain, as a whole, might be organized seems, for the first time, to be a serious topic of inquiry. One aspect of its neuronal organization that seems particularly central to global function is the rich thalamocortical interconnectivity, and most particularly the reciprocal nature of the thalamocortical neuronal loop function. Moreover, the interaction between the specific and non-specific thalamic loops suggests that rather than a gate into the brain, the thalamus represents a hub from which any site in the cortex can communicate with any other such site or sites. The goal of this paper is to explore the basic assumption that large-scale, temporal coincidence of specific and non-specific thalamic activity generates the functional states that characterize human cognition
PMCID:1692417
PMID: 9854256
ISSN: 0962-8436
CID: 9876