Latency between stimulus and onset of gammaoscillation was increased with cooling.
2
Cooling dramatically attenuated gammaoscillation and abolished epileptiform bursts in a reversible manner.
3
Cooling also suppresses transition from gammaoscillation to ictal bursting at higher stimulus intensities.
4
Tetanic stimulation at high intensity elicited not only gammaoscillation, but also epileptiform bursts.
5
We discuss the concept that gammaoscillation abnormalities in schizophrenia often occur in the background of oscillation abnormalities of lower frequencies.
6
Can we dissociate gammaoscillations related to unconscious learning and to conscious perception?
7
Explicit memory encoding, in particular, relies on enhanced gammaoscillations.
8
Induced gammaoscillations and evoked potentials were not systematically co-localized.
9
Stimulation of BF PV projection neurons preferentially generated time-locked gammaoscillations in frontal cortices.
10
However, circuit dysfunction persists, indicated by alterations in kainate-induced gammaoscillations and impaired nest building.
11
As a consequence, the firing of pyramidal neurons was desynchronized and gammaoscillations were impaired.
12
Subsequent gammaoscillations produced by attended stimuli were smaller than those produced by unattended, irrelevant stimuli.
13
In LO, attention increased the baseline level of gammaoscillations during the expectation period preceding the stimulus.
14
Our results thus suggest that the functional role of gammaoscillations depends on the area in which they occur.
15
The background of this study is a recent debate about the functional meaning of evoked and induced gammaoscillations.
16
Cooling from 34 to 21 degrees C reversibly abolished gammaoscillations in all slices tested.