Ignite Creation Date:
2026-03-26 @ 3:18 PM
Ignite Modification Date:
2026-03-31 @ 2:27 AM
Study NCT ID:
NCT07350551
Status:
NOT_YET_RECRUITING
Last Update Posted:
2026-02-13
First Post:
2025-12-16
Is NOT Gene Therapy:
True
Has Adverse Events:
False
Brief Title:
Pediatric Epilepsy
Sponsor:
University of Texas Southwestern Medical Center
Organization:
Study Overview
Official Title:
Pediatric Epilepsy
Status:
NOT_YET_RECRUITING
Status Verified Date:
2026-01
Last Known Status:
None
Delayed Posting:
No
If Stopped, Why?:
Not Stopped
Has Expanded Access:
False
If Expanded Access, NCT#:
N/A
Has Expanded Access, NCT# Status:
N/A
Acronym:
None
Brief Summary:
The purpose of the research is to better understand how the human brain accomplishes the basic cognitive tasks of learning new information, recalling stored information, making decisions or choices about presented information and self-control. These investigations are critical to better understand human cognition and to design treatments for disorders of learning, memory, decision making and cognitive control.
Detailed Description:
The knowledge gained from these experiments furthers the understanding of the brain's electrical activity and its relation to epilepsy and to human cognition. This increased knowledge base may lead to insights regarding better treatments for cognitive deficits and to improve epilepsy surgery and other therapies for seizure disorders. Functional mapping is an important element of planning for resection surgery because it enables the surgeon to avoid the resection of brain regions that could be especially crucial to cognitive function. By uncovering the iEEG (Intracranial Electroencephalography) signatures of memory function, functional mapping may be improved, and the risk of post-surgical cognitive impairment following resection could be reduced.
Hypotheses being tested (conceptual: see "Data Analysis" section for specific hypotheses) The study team hypothesizes that specific electrophysiological correlates of successful memory encoding can be identified from the local field potentials recorded from subdural and intracranial depth electrodes. The study team believes that an analysis of local field potentials can provide insight into the organization of functional brain networks involved in memory encoding and retrieval.
Theta Oscillations and Behavior in Rodents Scientists have theorized, based predominantly on research in rodents, that brain oscillations - cyclic changes in the electrical activity recorded from electrodes - play a fundamental role in memory function. In particular, theories of the role of oscillations in cognitive function have focused on a slow rhythm in the 3- to 12-Hz frequency range, which is termed the theta rhythm. These slow oscillations appear prominently in recordings from the rat hippocampus, a region known to be important in learning and memory function across species.
The theta rhythm increases during movement, orienting, a simple form of learning called conditioning, short-term memory, and spatial learning. In addition, the phase within the theta cycle (i.e., whether you are at the peak or the trough of the wave) is important for memory function. When information is presented to the animal at the peak of the theta cycle, learning is enhanced. Although most research in the rat has focused on the hippocampal theta rhythm, theta oscillations have also been found in numerous other brain regions in both rats and other animals, suggesting that they play a very general role in the way brain networks operate.
Human Intracranial Recordings Although one can crudely measure the human brain's electrical signals by recording from the scalp, the ability to actually observe and measure oscillations generated in local regions of the brain requires recordings taken from electrodes implanted in the brain (i.e., invasive EEG, or iEEG recording). Such iEEG recordings are often clinically required in the surgical treatment of severe medication-resistant epilepsy (i.e., seizure disorders that are not controlled by standard drug therapies). The location of electrodes is selected for each patient on the basis of clinical needs. This often includes electrodes in the mesial temporal lobe, including the hippocampus and entorhinal cortex along with cortical surface electrodes. At UTSW (UT Southwestern Medical Center), the use of stereo encephalography provides the unique opportunity to record from multiple deep brain locations and examine properties of electrical activity suggesting communication between these areas.
iEEG recordings taken during treatment for intractable epilepsy (as described above) have already been used to greatly enhance our knowledge of the physiology of human cognition. First, iEEG recordings sample from much smaller brain volumes than scalp-recorded EEG or magnetoencephalographic (MEG) signals, are not subject to distortions produced by the human skull, and are relatively impervious to movement artifacts because of their high signal-to-noise ratio. iEEG recordings also offer far better temporal resolution than functional magnetic resonance imaging (fMRI).
Hypotheses being tested (conceptual: see "Data Analysis" section for specific hypotheses) The study team hypothesizes that specific electrophysiological correlates of successful memory encoding can be identified from the local field potentials recorded from subdural and intracranial depth electrodes. The study team believes that an analysis of local field potentials can provide insight into the organization of functional brain networks involved in memory encoding and retrieval.
Theta Oscillations and Behavior in Rodents Scientists have theorized, based predominantly on research in rodents, that brain oscillations - cyclic changes in the electrical activity recorded from electrodes - play a fundamental role in memory function. In particular, theories of the role of oscillations in cognitive function have focused on a slow rhythm in the 3- to 12-Hz frequency range, which is termed the theta rhythm. These slow oscillations appear prominently in recordings from the rat hippocampus, a region known to be important in learning and memory function across species.
The theta rhythm increases during movement, orienting, a simple form of learning called conditioning, short-term memory, and spatial learning. In addition, the phase within the theta cycle (i.e., whether you are at the peak or the trough of the wave) is important for memory function. When information is presented to the animal at the peak of the theta cycle, learning is enhanced. Although most research in the rat has focused on the hippocampal theta rhythm, theta oscillations have also been found in numerous other brain regions in both rats and other animals, suggesting that they play a very general role in the way brain networks operate.
Human Intracranial Recordings Although one can crudely measure the human brain's electrical signals by recording from the scalp, the ability to actually observe and measure oscillations generated in local regions of the brain requires recordings taken from electrodes implanted in the brain (i.e., invasive EEG, or iEEG recording). Such iEEG recordings are often clinically required in the surgical treatment of severe medication-resistant epilepsy (i.e., seizure disorders that are not controlled by standard drug therapies). The location of electrodes is selected for each patient on the basis of clinical needs. This often includes electrodes in the mesial temporal lobe, including the hippocampus and entorhinal cortex along with cortical surface electrodes. At UTSW (UT Southwestern Medical Center), the use of stereo encephalography provides the unique opportunity to record from multiple deep brain locations and examine properties of electrical activity suggesting communication between these areas.
iEEG recordings taken during treatment for intractable epilepsy (as described above) have already been used to greatly enhance our knowledge of the physiology of human cognition. First, iEEG recordings sample from much smaller brain volumes than scalp-recorded EEG or magnetoencephalographic (MEG) signals, are not subject to distortions produced by the human skull, and are relatively impervious to movement artifacts because of their high signal-to-noise ratio. iEEG recordings also offer far better temporal resolution than functional magnetic resonance imaging (fMRI).
Study Oversight
Has Oversight DMC:
False
Is a FDA Regulated Drug?:
False
Is a FDA Regulated Device?:
False
Is an Unapproved Device?:
None
Is a PPSD?:
None
Is a US Export?:
None
Is an FDA AA801 Violation?: