ライフサイエンスコーパス: intracranial EEG

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1 all clinical and EEG information (including intracranial EEG).

2 p electroencephalography (EEG), MRI, PET and intracranial EEG.

3 egions with accuracy comparable with that of intracranial EEG.

4 6 and 1994, 28 patients had IBTL seizures on intracranial EEG.

5 f high-gamma activity recorded using MEG and intracranial EEG.

6 t outcomes, only 9 of 31 patients undergoing intracranial EEG (29%) and only 9 of 85 patient with non

7 24 of these 31 patients undergoing long-term intracranial EEG (77%), a seizure focus was identified a

8 We recorded intracranial EEG activity in 12 epileptic human patients

9 was compared with the seizure onset zone at intracranial EEG and with surface IED-related potentials

10 Here, we recorded direct intracranial EEG as human participants performed an asso

11 ed MRI and functional imaging and subsequent intracranial EEG confirmation of the seizure-onset zone

12 found to have partially dissociable resting intracranial EEG correlates, reflecting different underl

13 In this study, we acquired intracranial EEG data from rare patients (Ps) with medic

14 In this study, we collected intracranial EEG data from rare patients with medically

15 h bilateral temporal seizures independent of intracranial EEG data.

16 FC and DLPFC in human epilepsy patients with intracranial EEG electrodes during an auditory Stroop ex

17 vious exposure of the images while recording intracranial EEG from the higher-order visual cortex of

18 ngs, whose relationship to standard clinical intracranial EEG (iEEG) has not been explored.

19 We addressed this question with intracranial EEG (iEEG) recordings designed to identify

20 tional magnetic resonance imaging (fMRI) and intracranial EEG (iEEG) recordings to delineate place-se

21 atial pattern similarity analysis in MEG and intracranial EEG in a context-match paradigm.

22 ICE can provide high-fidelity intracranial EEG in an intensive care unit setting, can

23 improving surgical outcome and accelerating intracranial EEG investigations.

24 iated with better chance of concordance with intracranial EEG localization, and with excellent postsu

25 Intracranial EEG localized seizure onset to the area of

26 d 31 of these 47 patients (66%) proceeded to intracranial EEG monitoring.

27 To record HFOs, the intracranial EEG needs to be sampled at least at 2,000Hz

28 In follow-up after surgery, intracranial EEG or video-EEG monitoring (or both) has c

29 f epileptic foci and assist in the design of intracranial EEG recording strategies.

30 nvestigate these questions here by examining intracranial EEG recordings as 28 participants with elec

31 We analyzed continuous 3- to 14-day intracranial EEG recordings from five patients with mesi

32 Using intracranial EEG recordings from rare patients with medi

33 C]AMT uptake in 4 children (including 2 with intracranial EEG recordings).

34 ing a multimodal analysis of functional MRI, intracranial EEG recordings, and large-scale neural popu

35 By comparison with an intracranial EEG standard of localization, SPECT subtrac

36 EEG was localizing in 35 patients (66%) and intracranial EEG was localizing in 22 patients (85%) (of

37 Using intracranial EEG, we observed significant changes in osc

38 Using intracranial EEG, we recorded ventral striatum activity

39 Using tools combining MEG and intracranial EEG with brain connectivity analyses, we pr

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