Ignite Creation Date:
2025-12-25 @ 1:40 AM
Ignite Modification Date:
2025-12-26 @ 5:39 PM
Study NCT ID:
NCT06391294
Status:
ENROLLING_BY_INVITATION
Last Update Posted:
2025-09-09
First Post:
2024-04-05
Is NOT Gene Therapy:
True
Has Adverse Events:
False
Brief Title:
Neuronal and Network Mechanisms of Electrocortical Stimulation
Sponsor:
Northwestern University
Organization:
Study Overview
Official Title:
Neuronal and Network Mechanisms of Electrocortical Stimulation
Status:
ENROLLING_BY_INVITATION
Status Verified Date:
2025-09
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:
Electrocortical stimulation (ECS) mapping is a procedure used during brain surgeries, for example when treating diseases like epilepsy or when removing brain tumors. ECS mapping helps surgeons locate areas of the cerebral cortex (the outer part of the brain) that are important for everyday tasks like movement and speech. ECS mapping has been used for decades, and is considered the "gold-standard" tool for locating important areas of cortex. Despite this long history, there is still no clear understanding of exactly how ECS works.
The goal of this study is to learn details about the effects ECS has on the brain. The main questions the study aims to answer are: 1) how ECS affects the neurons of the cortex at the stimulation site; and 2) how ECS impacts brain regions that are critically important for human speech and language. These so-called "critical sites" can be physically distant from one another on the brain's surface, requiring extensive ECS mapping and long surgeries. Critical sites are thought to be part of a speech/language network of brain areas, and so the study's goal is to learn about how they are connected. In some participants, the brain's surface will also be slightly cooled. This is a painless procedure that does not harm the brain's function, but could provide insight as to which parts of the brain (the surface, or deeper parts) are responsible for the effects of ECS.
By improving the understanding of how ECS affects the brain and improving the ability to identify critical sites, this study could potentially lead to shorter surgeries and better outcomes for future individuals who need this care.
Participants will be recruited from among individuals who are undergoing brain surgery for epilepsy treatment or tumor removal. Participants will complete simple tasks like reading words or naming pictures, similar to standard testing that is already performed during their hospital stay.
The goal of this study is to learn details about the effects ECS has on the brain. The main questions the study aims to answer are: 1) how ECS affects the neurons of the cortex at the stimulation site; and 2) how ECS impacts brain regions that are critically important for human speech and language. These so-called "critical sites" can be physically distant from one another on the brain's surface, requiring extensive ECS mapping and long surgeries. Critical sites are thought to be part of a speech/language network of brain areas, and so the study's goal is to learn about how they are connected. In some participants, the brain's surface will also be slightly cooled. This is a painless procedure that does not harm the brain's function, but could provide insight as to which parts of the brain (the surface, or deeper parts) are responsible for the effects of ECS.
By improving the understanding of how ECS affects the brain and improving the ability to identify critical sites, this study could potentially lead to shorter surgeries and better outcomes for future individuals who need this care.
Participants will be recruited from among individuals who are undergoing brain surgery for epilepsy treatment or tumor removal. Participants will complete simple tasks like reading words or naming pictures, similar to standard testing that is already performed during their hospital stay.
Detailed Description:
Electrocortical stimulation (ECS) mapping has been used routinely for many decades to inform surgeons on brain areas to avoid when planning surgical resections for tumors or epilepsy. In particular, those areas that are "critical" for speech and language are important to identify. Yet, despite its long history of clinical use, the precise mechanisms of ECS are poorly understood. For example, it is not known how different cortical layers and cell types respond to ECS. Moreover, it is not even clear whether ECS' behavioral effects are due to affecting the underlying cortex alone, causing trans-synaptic activation of other cortices, or directly affecting both the cortex and underlying white matter.
A primary objective of this project is to determine the effects of ECS on the cortical network and subcortical white matter. This objective will be tested in two ways. First, the study will determine the relationship between ECS' effects and cortical connectivity patterns. This will be accomplished using graph theory metrics to analyze electrocorticography (ECoG) and functional magnetic resonance imaging (fMRI) from people with epilepsy or brain tumors. This will allow the recording of intracranial EEG (ECoG or stereo EEG) without adding substantial extra risk from the planned clinical treatment for these conditions. The study will investigate both static and dynamic network connectivity patterns, defined using static and dynamic graph metrics that measure connectivity at different scales (local, inter-regional, global). The study hypothesizes that structural (a.k.a. anatomical) and functional connectivity patterns of a cortical site determine its significance to the language network. To test this hypothesis, the study will use measures of structural and functional connectivity to predict which nodes are labeled critical by ECS.
Second, the study will test the hypothesis that ECS' behavioral effects also depend on directly perturbing cortico-cortical white matter. The study will use focal cortical cooling as a way to test the respective effects on language function of cooling (which inhibits only the cortex) compared to ECS (which may perturb cortex and underlying white matter), as well as combined ECS and cooling.
A primary objective of this project is to determine the effects of ECS on the cortical network and subcortical white matter. This objective will be tested in two ways. First, the study will determine the relationship between ECS' effects and cortical connectivity patterns. This will be accomplished using graph theory metrics to analyze electrocorticography (ECoG) and functional magnetic resonance imaging (fMRI) from people with epilepsy or brain tumors. This will allow the recording of intracranial EEG (ECoG or stereo EEG) without adding substantial extra risk from the planned clinical treatment for these conditions. The study will investigate both static and dynamic network connectivity patterns, defined using static and dynamic graph metrics that measure connectivity at different scales (local, inter-regional, global). The study hypothesizes that structural (a.k.a. anatomical) and functional connectivity patterns of a cortical site determine its significance to the language network. To test this hypothesis, the study will use measures of structural and functional connectivity to predict which nodes are labeled critical by ECS.
Second, the study will test the hypothesis that ECS' behavioral effects also depend on directly perturbing cortico-cortical white matter. The study will use focal cortical cooling as a way to test the respective effects on language function of cooling (which inhibits only the cortex) compared to ECS (which may perturb cortex and underlying white matter), as well as combined ECS and cooling.
Study Oversight
Has Oversight DMC:
True
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?: