Loss of Consciousness Clinical Trial
Official title:
Alteration of Temporal Organization of EEG Microstate Sequences During Propofol-induced Loss of Consciousness
Temporal dynamics of the EEG microstates show scale-free monofractal properties. This means that information is encoded in the same way at different scales. It may be postulated that these monofractal properties of the EEG microstate sequences constitute a necessary prerequisite of consciousness. We postulate that clinical variations of consciousness may also be linked to alterations of fractal properties of EEG microstates.
- Aim of the study: Assess the alteration of temporal organization of EEG microstate
sequences during propofol-induced loss of consciousness
- Methods: Prospective clinical trial. 20 right-handed adult patients, aged between 18
and 40 years, scheduled for elective surgery under general anaesthesia, will be
included.
Patients will not receive any preoperative oral anxiolysis. After arrival in the operation
theatre and a resting period of 10 minutes, the baseline EEG will be recorded (5 minutes
duration). Then, after a three minutes proxygenation period with 100% oxygen, patients will
receive an intravenous induction with propofol using the pharmacokinetic model by Schnider
et al. The initial cerebral concentration will be 0.5 µg ml-1, which will be increased
stepwise by 1.0 µg ml-1 until 2.5 µg ml-1, and then by 0.5 µg ml-1 until loss of
consciousness. During the induction procedure, the patient's lungs will be gently ventilated
using 100% oxygen through a face mask.
Five minutes after reaching each equilibration of the blood-brain propofol concentration,
clinical sedation (using the validated six points Observer Assessment of Alertness/Sedation
[OAA/S] scale) will be annotated. Raw EEG, used later for fractal analysis, will be
continuously recorded during the procedure. Corresponding OOA/S scores will be recorded on
raw EEG. The study ends 10 minutes after the patient has lost consciousness (absence of
response to "mild prodding or shaking" corresponding to OAA/S <2).
The fractal analysis of EEG will be performed with a delay after anaesthesia by
neuroscientists
- Hypothesis: We hypothesise that the fractal properties of EEG microstates will be
modified in parallel with the propofol-induced loss of consciousness.
- EEG and DATA analysis Microstate analysis First, we will determine the maxima of the
global field power (GFP). Because topography remains stable around peaks of the GFP,
they are the best representatives of the momentary map topography in terms of
signal-to-noise ratio.18 All maps marked as GFP peaks (i.e., the voltage values at all
electrodes at that time point) will be extracted and submitted to a modified spatial
cluster analysis using the atomize-agglomerate hierarchical clustering (AAHC) method19
to identify the most dominant map topographies. The optimal number of template maps
will be determined by means of a cross-validation criterion.20 We will then submit the
template maps identified in every single subject into a second AAHC cluster analysis to
identify the dominant clusters across all subjects. Finally, we will compute a spatial
correlation between the templates identified at the group level and those identified
for each subject in every run. We will so label each individual map with the group
template it best corresponds to, to use the same labels for the subsequent group
analysis.
Then, we will compute the spatial correlation between the four template maps and the
instantaneous EEG21 using a temporal constraint criterion of 32 ms. We will then use these
spatial correlation time courses to select the dominant microstate m(k)∈{} at each time
instant k and submit those time series to the fractal analysis.
- Fractal analysis We will split the microstate sequence into bipartitions and perform a
random walk (on those bipartitions). After having integrated this random walk, we will
analyse the integrated random walk by means of the wavelet transform and extract the
fractal parameters: Hurst exponent and higher order cumulants.
- Fractal hypothesis One can either expect a decrease of the long-range dependency of the
microstate sequences, i.e. one would expect lower Hurst exponents with deeper
anaesthesia and hence loss of consciousness. Alternatively, we could also expect a
transition from mono- to multifractality, i.e. the scaling of the temporal dynamics of
the microstate sequences can be described at the expense of using multiple parameters,
i.e. the Hurst exponent and higher-order cumulants that deviate from zero.
;
Intervention Model: Single Group Assignment, Masking: Open Label, Primary Purpose: Basic Science
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