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The role of gamma oscillatory activity in magnetoencephalogram for auditory memory processing
(2010)
Recent studies have suggested an important role of cortical gamma oscillatory activity (30-100 Hz) as a correlate of encoding, maintaining and retrieving auditory, visual or tactile information in and from memory. It was shown that these cortical stimulus representations were modulated by attention processes. Gamma-band activity (GBA) occurred as an induced response peaking at approximately 200-300 ms after stimulus presentation. Induced cortical responses appear as non-phase-locked activity and are assumed to reflect active cortical processing rather than passive perception. Induced GBA peaking 200-300 ms after stimulus presentation has been assumed to reflect differences between experimental conditions containing various stimuli. By contrast, the relationship between specific oscillatory signals and the representation of individual stimuli has remained unclear. The present study aimed at the identification of such stimulus-specific gamma-band components. We used magnetoencephalography (MEG) to assess gamma activity during an auditory spatial delayed matching-to-sample task. 28 healthy adults were assigned to one of two groups R and L who were presented with only right- or left-lateralized sounds, respectively. Two sample stimuli S1 with lateralization angles of either 15° or 45° deviation from the midsagittal plane were used in each group. Participants had to memorize the lateralization angle of S1 and compare it to a second lateralized sound S2 presented after an 800-ms delay phase. S2 either had the same or a different lateralization angle as S1. After the presentation of S2, subjects had to indicate whether S1 and S2 matched or not. Statistical probability mapping was applied to the signals at sensor level to identify spectral amplitude differences between 15° and 45° stimuli. We found distinct gamma-band components reflecting each sample stimulus with center frequencies ranging between 59 and 72 Hz in different sensors over parieto-occipital cortex contralateral to the side of stimulation. These oscillations showed maximal spectral amplitudes during the middle 200-300 ms of the delay phase and decreased again towards its end. Additionally, we investigated correlations between the activation strength of the gamma-band components and memory task performance. The magnitude of differentiation between oscillatory components representing 'preferred' and 'nonpreferred' stimuli during the final 100 ms of the delay phase correlated positively with task performance. These findings suggest that the observed gamma-band components reflect the activity of neuronal networks tuned to specific auditory spatial stimulus features. The activation of these networks seems to contribute to the maintenance of task-relevant information in short-term memory.
Aim: The aim of this study was to measure cortico-cortical connectivity in multiple sclerosis (MS) patients by TMS-evoked potential (TEP) latencies in EEG evoked by transcranial magnetic stimulation (TMS) of the hand area of the primary motor cortex of one hemisphere. TEPs were recorded on the stimulated- and at the homologue site in the non-stimulated contralateral hemisphere. Both interhemispheric directions were tested. Interhemispheric latencies of the two main reproducible TEPs, the positive component at 60 ms and the negative component at 100 ms (P60 and N100, respectively), were expected to be significantly prolonged in MS-patients compared to healthy volunteers.
Material and methods: The study compared interhemispheric propagation of P60 and N100 in groups of 12 patients with early-stage relapsing-remitting MS (RRMS) and 16 age- and gender-matched healthy controls. The study was approved by the Ethics Committee of the Medical Faculty of the Goethe-University of Frankfurt/Main and conformed to the latest revision of the Declaration of Helsinki of 2008. TEPs were recorded by means of EEG and their latencies were statistically evaluated in 10 channels around the stimulation site and in 10 corresponding electrodes in the non-stimulated contralateral hemisphere. Interhemispheric conduction time was calculated by the difference of TEP latency in non-stimulated vs. stimulated hemisphere.
Results: An ANOVA on interhemispheric conduction time showed a significant prolongation for the N100 from left to right hemisphere in MS compared to controls, while no group differences were found for the P60 and the N100 from right to left hemisphere.
Conclusion: The results provide first evidence that the N100 may constitute an interesting marker to measure interhemispheric conduction delays in early-stage RRMS. The specificity of the present finding and its relation to fiber tract pathology should be examined in further correlative analyses with diffusion tensor imaging and other structural MRI data.
Transcranial magnetic stimulation (TMS) is a non-invasive technique which can be used to study different intracortical excitatory and inhibitory neuronal circuits in the intact human being. In the primary motor cortex, there are essentially three different TMS measures of inhibitory neuronal circuits as determined by paired-pulse TMS: short-interval intracortical inhibition (SICI), long-interval intracortical inhibition (LICI) and interhemispheric inhibition (IHI). It was hypothesized that SICI is a GABAA receptor mediated inhibition (Ilic et al., 2002) whereas LICI and IHI are mediated by GABAB receptors (Daskalakis et al., 2002; McDonnell et al., 2006). Additionally, it was shown that these inhibitory circuits interact negatively, possible due to presynaptic GABAB receptor mediated inhibition (Sanger et al., 2001; Daskalakis et al., 2002). Which neuronal populations exactly underlie SICI, LICI and IHI, is not completely clear and by which mechanism these inhibitory circuits interact has never been tested pharmacologically so far. Thus, the effects of a single oral dose of Diazepam (DZP), a specific positive allosteric modulator at the GABAA receptor, and of Baclofen (BAC), a specific GABAB receptor agonist, on SICI, LICI and IHI as well as their interactions were tested here in a randomized, placebo controlled, double-blinded crossover study. SICI significantly increased after intake of DZP whereas BAC did not change SICI. Conversely, LICI significantly increased after intake of BAC but did not change after intake of DZP. IHI showed only a trend towards a decrease after intake of DZP but no change after intake of BAC. The interactions IHI-SICI, LICI-IHI and LICI-SICI were all negative at baseline. SICI and IHI were partially suppressed in the presence of IHI and LICI, respectively, and SICI in the presence of LICI was almost completely blocked. BAC did not change any of these interactions, whereas DZP significantly increased SICI in the presence of LICI. This study is the first to examine by means of pharmacological testing the complex interactions between different inhibitory circuits in the human motor cortex. The effects of DZP and BAC on SICI and LICI confirmed the notion that SICI is a GABAA receptor mediated intracortical inhibition whereas LICI depends on GABAB receptor mediated neurotransmission. The pharmacology of IHI at short interstimulus intervals of < 20 ms (12 ms in this study) remains still inconclusive and warrants further investigation. Findings further suggest that SICI, LICI and IHI represent three different inhibitory neuronal circuits which can be tested non-invasively by means of paired-pulse TMS. Furthermore, the data support the idea that the negative interactions IHI-SICI, LICI-IHI and LICI-SICI are most likely due to presynaptic GABAB receptor mediated autoinhibition.