Ignite Creation Date:
2024-05-06 @ 8:23 PM
Last Modification Date:
2024-10-26 @ 3:27 PM
Study NCT ID:
NCT06368310
Status:
NOT_YET_RECRUITING
Last Update Posted:
2024-04-16
First Post:
2024-03-20
Brief Title:
FIH Clinical Investigation of Graphene Electrodes for Brain Mapping
Sponsor:
University of Manchester
Organization:
University of Manchester
Study Overview
Official Title:
First in Human FIH Clinical Investigation of Safety and Feasibility of a Novel Graphene Micro-electrocorticography Array for Brain Mapping in Neuro-oncology
Status:
NOT_YET_RECRUITING
Status Verified Date:
2024-04
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 goal of this clinical investigation of a medical device is to test the safety of graphene based electrodes when used during surgery for resection of brain tumors The main questions that it aims to answer are
To understand the safety of these new electrodes when used during brain tumor surgery primary objective
To assess the quality of the brain signals recorded with the new electrodes their ability to stimulate the brain how stable their function is over the duration of an operation and their suitability for use in the operating theatre secondary objectives
Participants will undergo tumor surgery as usual with the study electrodes being tested alongside a standard monitoring system If they are awake for part of their surgery they may be asked to complete specific tasks such as naming objects from a list modified for the study They will be monitored subsequently for any complications including undergoing an additional MRI scan 6 weeks after their surgery
To understand the safety of these new electrodes when used during brain tumor surgery primary objective
To assess the quality of the brain signals recorded with the new electrodes their ability to stimulate the brain how stable their function is over the duration of an operation and their suitability for use in the operating theatre secondary objectives
Participants will undergo tumor surgery as usual with the study electrodes being tested alongside a standard monitoring system If they are awake for part of their surgery they may be asked to complete specific tasks such as naming objects from a list modified for the study They will be monitored subsequently for any complications including undergoing an additional MRI scan 6 weeks after their surgery
Detailed Description:
During surgical operations within the brain such as the removal of a tumor electrodes are commonly used to map specific brain functions or monitor brain activity These are most commonly flexible plastic devices with embedded metallic contacts that allow electrical activity in the brain to be detected and measured They may also be used to stimulate precise areas of the brain to either trigger or block a response such as the contraction of a muscle This allows the surgeon to define which regions of the brain are involved in controlling critical functions such as movement or speech so that these areas can be protected during the operation
There remain limitations with the design and physical characteristics of commercially available electrodes for use during brain operations These include the limited ability of conventional materials to fold over the complex shape of the brain and the need to use comparatively large metallic contacts to detect the tiny electrical signals This study will be the first to introduce a new generation of electrodes which have been designed to overcome these limitations They are extremely thin and flexible allowing them to follow the surface of the brain and to be used in locations within and around the brain for which the standard electrodes are unsuitable The contact surfaces that detect electrical activity and enable and stimulate the brain have been replaced with graphene which is a novel carbon-based material The use of graphene allows electrodes to be made that are more sensitive to the tiny electrical signals of the brain This means that they can be much smaller and closer together providing increased detail in the recording and potentially enabling signals to be detected that would previously have required such long recordings that they could not be used to guide decision making during surgery
There remain limitations with the design and physical characteristics of commercially available electrodes for use during brain operations These include the limited ability of conventional materials to fold over the complex shape of the brain and the need to use comparatively large metallic contacts to detect the tiny electrical signals This study will be the first to introduce a new generation of electrodes which have been designed to overcome these limitations They are extremely thin and flexible allowing them to follow the surface of the brain and to be used in locations within and around the brain for which the standard electrodes are unsuitable The contact surfaces that detect electrical activity and enable and stimulate the brain have been replaced with graphene which is a novel carbon-based material The use of graphene allows electrodes to be made that are more sensitive to the tiny electrical signals of the brain This means that they can be much smaller and closer together providing increased detail in the recording and potentially enabling signals to be detected that would previously have required such long recordings that they could not be used to guide decision making during surgery
Study Oversight
Has Oversight DMC:
None
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?:
None
Secondary IDs
| Secondary ID | Type | Domain | Link |
|---|---|---|---|
| 23WM0166 | OTHER | NHS Research Ethics Committee Reference | None |