Clinical Trial Details
— Status: Not yet recruiting
Administrative data
| NCT number |
NCT05794295 |
| Other study ID # |
1737425 |
| Secondary ID |
|
| Status |
Not yet recruiting |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
July 2024 |
| Est. completion date |
June 2028 |
Study information
| Verified date |
September 2023 |
| Source |
University of California, Davis |
| Contact |
Colleen Stone |
| Phone |
916-734-6472 |
| Email |
colstone[@]ucdavis.edu |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Temporal Lobe Epilepsy (TLE) patients and healthy controls will undergo a night of sleep at
the UC Davis Epilepsy Monitoring Unit (EMU) to characterize sleep architecture. A subset of
TLE patients will be randomly assigned to an Acoustic Stimulation (AS) or SHAM stimulation
night and return at least 7 days later for the other condition. Cognitive tests will be
conducted 90 minutes prior to sleep (learning and immediate recall) and again 1 hour after
awakening for 120 minutes (delayed recall and attention), while monitoring neural networks
using functional Magnetic Resonance Imaging (fMRI).
Description:
Temporal Lobe Epilepsy (TLE) is characterized by disordered neural network activity and
temporal lobe onset seizures. Individuals with TLE experience debilitating diseases and
medical conditions including sleep disruption and cognitive deficits, which compromise daily
activity and quality of life. While these conditions can be long-term consequences of
repeated seizures and anti-seizure medications, research demonstrates that these conditions
can occur before the first recognized seizure and worsen over time, even with successful
seizure treatment. This suggests that early neural network abnormalities may underlie seizure
development while simultaneously impairing sleep and cognitive development, even prior to the
added effects of long term disease and treatments. Individuals with TLE experience sleep
disruption, which impairs memory consolidation and sustained attention, both of which are
compromised in TLE. A prominent, yet untested hypothesis is that TLE-related neural network
activity including interictal epileptiform discharges (IEDs) interrupt non-rapid eye movement
(NREM) sleep architecture, interfering with memory consolidation and attention. However,
specific mechanisms by which abnormal neural network activity contributes to disordered sleep
and cognition in TLE remain elusive.
Pilot data demonstrate that new-onset TLE patients exhibit cognitive deficits that are linked
with reduced activation of key frontal-temporal neural networks, as measured by task-based
functional magnetic resonance imaging (fMRI), which positively correlates with poor sleep.
These new and exciting findings suggest that characterizing the sleep architecture patterns
that contribute to less effective cognitive processing in TLE is critical to identifying
modifiable sleep biomarkers, and ultimately improving cognitive function in TLE patients.
This study will begin to address the existing gap in knowledge by investigating sleep
architecture patterns in TLE that directly contribute to cognitive deficits using both an
observational and a mechanism-probing interventional approach. In NREM sleep, slow wave
oscillations on electroencephalogram (EEG) are phase-locked and coupled with sleep spindle
oscillations (SW-SSO), which facilitates memory consolidation and potentially improves
attention. In TLE, disordered networks leading to IEDs and seizures may contribute to altered
SW-SSO coupling during sleep, resulting in memory and attention deficits. A single night of
acoustic stimulation (AS) has been demonstrated to improve cognitive performance and enhance
SW-SSO coupling in healthy adults, but has not been studied in TLE. The central hypothesis
for this study is that disordered networks in newly diagnosed TLE patients result in altered
sleep patterns, disrupting memory consolidation and attention. This study will test this
hypothesis by: (1) characterizing TLE sleep patterns using computational EEG - sleep spindle
density, slow wave power, IEDs, and SW-SSO coupling, (2) linking these TLE-related sleep
architecture alterations to cognitive processing; (3) determining if AS enhances SW-SSO
coupling in TLE; and (4) determining if AS improves memory and attention in young adults with
TLE.
First, we will characterize sleep architecture patterns in TLE and determine the relationship
to cognitive processing. New-onset TLE patients and healthy controls will undergo one night
of scalp EEG-monitored sleep to characterize sleep spindle density, slow wave power, IEDs,
and SW-SSO coupling (i.e., phase-locking).
Hypothesis: Compared to controls, TLE patients will exhibit IEDs as well as reduced sleep
spindle density and slow wave power with reduced SW-SSO coupling. The next morning, I will
use fMRI to monitor network activation as participants perform an attention task and
declarative memory recall, learned the night prior.
Hypothesis: Compared to controls, reduced SW-SSO coupling during sleep in TLE patients will
be associated with reduced activation on task-based fMRI, as well as poorer memory and
attention.
Next, the study will determine the effect of AS on sleep architecture patterns and cognitive
processing in TLE. New-onset TLE patients will be randomly assigned to AS or SHAM stimulation
as the initial condition in a cross-over design and will undergo a night of scalp EEG
monitored sleep under each condition, separated by at least one week.
Hypothesis: AS will exhibit greater levels of SW-SSO coupling compared to SHAM. The next
morning, I will use fMRI to monitor network activation as participants perform an attention
task and declarative memory recall learned the night prior.
Hypothesis: Compared to SHAM, AS will show increased activation on task-based fMRI, and
improved memory and attention.
