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Literature DB >> 17343918

Cortical electrode localization from X-rays and simple mapping for electrocorticographic research: The "Location on Cortex" (LOC) package for MATLAB.

Kai J Miller¹, Scott Makeig, Adam O Hebb, Rajesh P N Rao, Marcel denNijs, Jeffrey G Ojemann.

Abstract

Medically refractory epilepsy accounts for more than 30% of the epilepsy population. Scalp EEG electrodes have limited ability to localize seizure onset from deep structures and implantation of subdural electrodes with long term monitoring provides additional information. Apart from clinical application, this patient population provides a unique opportunity for acquiring electrocorticography data in research paradigms. We present a method for rapid localization of electrodes using lateral and anterior-posterior X-rays. Skull landmarks and proportions are used for co-registration with the standardized Talairach coordinate system. This MATLAB-based "Location on Cortex" (LOC) package facilitates rapid visualization of clinical and experimental data in a user-friendly manner.

Entities: Disease Species

Mesh：

Year: 2007 PMID： 17343918 DOI： 10.1016/j.jneumeth.2007.01.019

Source DB: PubMed Journal: J Neurosci Methods ISSN： 0165-0270 Impact factor: 2.390

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Cited

47 in total

Cortical electrode localization from X-rays and simple mapping for electrocorticographic research: The "Location on Cortex" (LOC) package for MATLAB.

1. Cortical activity during motor execution, motor imagery, and imagery-based online feedback.

2. Stable and dynamic cortical electrophysiology of induction and emergence with propofol anesthesia.

3. γ-oscillations modulated by picture naming and word reading: intracranial recording in epileptic patients.

4. Decoding vowels and consonants in spoken and imagined words using electrocorticographic signals in humans.

5. Identifying functional networks using endogenous connectivity in gamma band electrocorticography.

6. Characterization of the effects of the human dura on macro- and micro-electrocorticographic recordings.

7. Decoding three-dimensional reaching movements using electrocorticographic signals in humans.

8. Utility of independent component analysis for interpretation of intracranial EEG.

9. Corticocortical evoked potentials reveal projectors and integrators in human brain networks.

10. Power-law scaling in the brain surface electric potential.