Arousal Pathways and Emergence From Sedation

Sedation and general anesthesia are at the hub of modern medicine. The practice of the administration of anesthesia and sedation has evolved considerably and is now considered safe and reproducible. Still, one of the critical parts of anesthesia practice is the emergence: with the phenomenological variability of the clinical presentations of emergence, and its increased inherent risks of airway patency, insufficient respiratory mechanics, hyperreflexia and altered mental state.

Our understanding of the underlying mechanisms of sedation and anesthesia is still somewhat lacking: The body of evidence concerning induction and maintenance is more evolved[1-4], whereas the most profound gaps of knowledge concern emergence.

While anesthetic agent exert a global effect on the brain, it is clear that some foci are more sensitive[5] and more relevant to the achievement of the anesthetic goals of hypnosis, amnesia, and reduced responsiveness.

Mechanisms of unconsciousness induced by general anesthesia[1] can be broadly dissected to two elements: consciousness and arousal: Current consciousness theories[6,7] ascribe to consciousness the ability to experience. To achieve that goal, information complexity and information integration are paramount. These faculties reside mainly in the neocortex. Arousal on the other hand, resides mainly in the thalamus, hypothalamus, midbrain and pons with the neural machinery of physiological sleep[8,9]. We tend to associate consciousness with arousability. Dreaming however - is a straightforward example of consciousness without arousal.

A given level of arousal is the output of the balance of the mutual inhibition between the sleep promoting locus - the ventrolateral preoptic nucleus - and the multiple arousal loci, commonly known as the ARAS (Ascending Reticular Activating System)[10,11]. Shortly, this dispersed system is comprised of multiple nuclei with different neurotransmitters. Some of the nuclei have thalamic projections and some are extra-thalamic with direct and diverse cortical projections. The transition between sleep and wakefulness is further enhanced by the Orexigenic neurons in the hypothalamus[12,13], which serve as a flip flop mechanism.

The research into consciousness has made some progress[14] using anesthetic approaches and most specifically, emergence from sedation and anesthesia, to describe the neural core of consciousness. Recently, publications by Purdon et al.[15,16] identified an EEG signature of consciousness transition state.

The body of evidence concerning arousal pathways is less formidable, possibly due to the dispersed array of nuclei, and their "deep" subcortical locations, complicating their evaluation in less invasive methods (such as scalp EEG). The classic research tool of this field is lesions studies (both in animal models and unfortunate patients)[17,18] in discrete loci with an observed change in sleep-wake physiology. Recently, pioneering ex vivo (rat pups midbrain slices) research by Garcia-rill and Charlesworth[19], using intracellular recordings provided compelling data supporting electrical coupling and coherence of neurons within nuclei of the ARAS. However, to the best of our knowledge to this date there has been no explicit trial to capture or characterize the dynamic changes in the ARAS of human subjects emerging from sedation.

Research objectives

1. To characterize the spatiotemporal signature sequence of the arousing brain, focusing (but not restricted to) on deep brain structures. Arousal signature may include the following:

   • A conserved sequence of brain structures mobilization.
   • Summation of foci activations (without an explicit order).
   • Hierarchy between different loci (cholinergic vs. monoaminic components of the ARAS).

2. To identify a reproducible signal heralding imminent return of consciousness.

Methods:

The proposed study has been submitted to the Institutional Review Board committee for approval.

Experiment summary:

The proposed study is an interventional, single center study, conducted on 20 volunteers. A sample size of 20 was chosen in light of the relatively low signal to noise ratio inherent to fMRI imaging. subjects will be healthy males age 20-40, who are not taking chronic medications or using illicit drugs. All subjects, after signing the informed consent form, will fill a standard MRI questionnaire for the detection of metallic implants and will undergo medical evaluation and examination by the anesthesiologist. During the study period volunteers will be monitored by non invasive standard patient ASA monitoring: ECG, blood pressure, pulse oximetry, and exhaled CO2 levels. Each subject will be connected to an EEG recording cap, and will be placed in the magnet. Baseline recordings of EEG, MRI and fMRI will be taken. Then sedation will be induced with continuous IV propofol infusion with a Target Controlled Infusion pump - TCI, using the Marsh model[14,20,21]. Depth of sedation will be titrated to deep sedation (Ramsay scale 5)[22]. Subsequently, propofol administration will be discontinued, and continuous EEG and fMRI recordings will be taken until emerging from sedation to an awake calm/light sedation (Ramsay 2-3), as verified by a response to the subject's given name. At this point EEG monitoring and fMRI scans will cease. The subject will be helped out of the magnet and transferred to a post anesthesia care unit (PACU).

All subjects will be monitored until reaching discharge criteria ascertained by an examination performed by an anesthesiologist.

Brain monitoring

1. Functional Magnetic Resonance (fMRI): brain BOLD fMRI - blood oxygen level dependent fMRI - harnessing the magnetic properties of the ferric ion of hemoglobin to image changes in blood flow to metabolically active brain loci. The underlying assumption of the imaging modality (similar to Positron Emission Tomography) is the metabolic coupling of cellular activity and blood flow. Analyses will focus but will not be restricted to subthalamic structures involved in the RAS.
2. EEG (electroencephalogram), while in the MRI - EEG-fMRI. Combining the superior temporal resolution of the EEG with the localizing resolution of the MRI. The EEG will serve as an adjunct to the level of sedation and as source for data concerning thalamocortical pathways or arousal.

Expected results:

The results from this research project may help improve patient safety through the prediction of his/her arousal status. Anesthesia/Arousal level monitors have yet to prove their contribution to patient safety. Integration of deep brain structures data may prove to be the missing link to improving monitors' performance. Additionally, a thorough understanding of the arousal process can potentially help develop agents to hasten arousal, as it may serve as a screening paradigm for known pharmaceuticals (expanding their clinical indications) as well as new chemical entities (NCEs).

Feasibility and perceived strengths:

The feasibility of the proposed research project is very high. The project will be performed in Tel Aviv Medical Center in the Wohl Center for Advanced Imaging. The Wohl Center involves a prominent neuroscience research group with a significant number of publications related to emotional and cognitive processing in health and disease. Some of these studies include volunteers[23,24] and the use of fMRI and EEG to follow propofol induced sedation[25,26]. The proposed project will enjoy a full collaboration with the research center. In this light, the completion of the proposed imaging sessions and their subsequent analyses is realistic.

A thorough characterization of the emergence process warrants careful, dedicated attention to deep brain structures while designing the experiment throughout its execution and during analyses. As stand-alone scalp EEG recordings have fallen short of finding the "emergence fingerprint" (as EEG signal represent mostly cortical activity) we contest that a combined EEG-fMRI carries more hopes for the characterization of emergence from sedation.