Trigeminal Neuralgia Clinical Trial
Official title:
A Comparison of the EEGo and BIS Monitors to Assess Emergence From Neuroanesthesia
A highly desired result in neuroanesthesia is a prompt, controlled emergence following a neurosurgical procedure. Considerable strides have been made in this direction with volatile anesthetic agents such as sevoflurane or desflurane administered in association with the narcotic remifentanil. It is characteristic that patients will emerge within 5 to 10 minutes of cessation of these agents at the end of a neuroanesthetic. However, there are cases where emergence is delayed, especially after periods of deep anesthesia for i) cerebral protection with temporary clipping of cerebral aneurysms and ii) with microvascular decompression for trigeminal neuralgia. Deep levels of anesthesia are standard for these procedures in the posterior fossa, which utilize motor evoked potentials to assess cranial nerve function. In these cases, EEG monitoring is standard. Using the EEG to monitor emergence to aid its progress makes sense. A monitor which could predict emergence in these patients would be valuable. EEG monitoring engineered to provide this information is now available in the form of the EEGo. This study is designed to test the hypothesis that the EEGo monitor will be superior to the BIS monitor to assess emergence following neuroanesthesia.
Objective: This study is designed to test the hypothesis that the EEGo monitor will be
superior to the BIS monitor to assess emergence following neuroanesthesia. The EEGo will be
able to more accurately indicate emergence and direct therapy at the end of the operative
procedure. The EEGo will be superior because the raw EEG signal is processed using phase
delay analysis, with each patient's raw EEG analyzed instead of a proprietary but generic
signal processing approach on a linear scale as with the BIS monitor. Phase delay analysis
is a standard approach to display nonlinear signals. A highly reproducible signal transition
occurs from deep anesthesia to emergence. It is this transition that permits acute
assessment of emergence. The ability to process the EEG and display phase delay plots in 50
msec is what makes the EEGo monitor attractive to acutely assess emergence from
neuroanesthesia. Accurate emergence will allow better anesthesia management.
This pilot study will be done to assess a nonlinear EEG monitor (EEGo) to direct therapy and
predict prompt emergence from neuroanesthesia where EEG monitoring is done in neurosurgical
cases. In our centre we routinely monitor the EEG, SSEP and/or MEP during temporary aneurysm
clipping and during microvascular decompressive surgery. It is just these cases where
emergence can be delayed despite following standard neuroanesthesia techniques. The EEGo
processes the standard EEG signal by nonlinear analysis of the raw signal by 3 dimensional
phase delay plots. A cascade from a point attractor, periodic attractor, toroidal attractor
to a 3-D chaotic attractor occurs from burst suppression to the awake state. These resemble
phase transitions and occur rapidly from one state to the next. An analogy is the phase
transition that occurs when water changes to ice and vice versa. Monitoring these
transitions should permit a rational approach to therapy during anesthesia emergence, better
predict emergence, facilitate extubation based on the awake state, allow titration of
vasoactive agents during emergence to smooth hemodynamic control and permit more rapid
emergence at end procedure. The EEGo will be compared directly in real time to the
bispectral (BIS) monitor re goal directed emergence. If efficacy is shown with the EEGo, a
more formal comparison to BIS and clinical judgement will be studied.
BIS monitoring can aid emergence in outpatient procedures, both with time to wakening and
time in the recovery room. These results also impact on the cost of anesthetic drugs and OR
and Recovery Room costs. Work demonstrating accelerated emergence from desflurane with BIS
do not highlight the manner in which the BIS directs the emergence. The depth of anesthesia
is adjusted to 50 - 60 ABU during maintenance and then emergence is tracked. A specific BIS
number to indicate emergence is not suggested. In fact, a correlation between the BIS in the
awake state and with movement and eye opening appears poor with the emergence BIS usually
being lower than the pre-induction BIS. The BIS may also on occasion be very low during
emergence - deemed artifactually so and in this work it is suggested that the raw EEG be
observed to aid emergence. It would seem that significant issues relate to intra and
interpatient variability with this processed EEG signal. Recent work suggests significant
discrepancy of BIS signals between hemispheres and even recording from two sites in the same
hemisphere. In addition, BIS correlates poorly with end-tidal desflurane and awake state.
Thus, it would seem that while the BIS can aid management of depth of anesthesia during
maintenance, it is not ideally suited to direct a facilitated emergence. In contrast, the
EEGo monitor uses nonlinear analysis techniques to provide a visual output related to depth
of anesthesia.
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Allocation: Randomized, Endpoint Classification: Efficacy Study, Intervention Model: Single Group Assignment, Masking: Double Blind (Subject, Caregiver, Investigator), Primary Purpose: Diagnostic
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