People sometimes mistakenly think of general anesthesia as just a really deep sleep but in fact, anesthesia is really four brain states unconsciousness, amnesia, immobility and suppression of the body's damage sensing response, or "nociception."
The study was published in Anesthesia & Analgesia. MIT neuroscientist and statistician Dr. Emery Brown and colleagues argue that by putting nociception at the top of the priority list and taking a principled neuroscientific approach to choosing which drugs to administer, anesthesiologists can use far less medication overall, producing substantial benefits for patients.
They have come up with strategies that allow us to dose the same drugs that are generally used but in different proportions that allow us to achieve an anesthetic state that is much more desirable.
A major anesthetic drug affects the nociceptive circuits of the nervous system. Nociception is the body's sensing of tissue damage. It is not pain, which is a conscious perception of that.
Then the authors show how in four different surgical cases they were able to use neuroscience to guide their choice of a "multimodal" combination of drugs to target nociceptive circuits at several different points.
That way they didn't have to use much of any individual drug. Because reduced arousal is a byproduct of the strategy, they also didn't have to administer much medicine to ensure unconsciousness, a state they scrupulously monitor in the operating room by watching brainwaves captured by electroencephalography (EEG).
Reducing opioids has become a major goal of anesthesiologists in recent years as an epidemic of overdoses has ravaged the United States.
Opioids, after all, are hardly the only option. Opioids combat nociception in the spinal cord and brainstem by binding to opioid receptors, while decreasing arousal by blockading connections involving the neurotransmitter acetylcholine between the brainstem, the thalamus, and cortex.
By contrast, ketamine targets glutamate receptors both on peripheral nervous system neurons that connect to the spinal cord and on neurons in the brain's cortex, where they also, therefore, decrease arousal.
In all, they review the distinct antinociceptive actions of six classes of drugs: opioids, ketamine, dexmedetomidine, magnesium, lidocaine, and NSAIDs (like ibuprofen). They also discuss how anesthetic drugs that primarily impact arousals, such as propofol, or mobility, such as cisatracurium, work in the central and peripheral nervous systems.
The approaches contrast with more traditional approaches in that they feature a combination of drugs to affect nociception, rather than a single drug that primarily affects consciousness.
Because these primarily create unconsciousness and have less effect on nociception, the state of general anesthesia they create has an imbalance that means that patients are profoundly unconscious with less good antinociceptive control.
If the anesthesiologist is not monitoring the EEG to track unconsciousness and uses no principled way to distinguish antinociception from unconsciousness, patients will have prolonged wake ups.
Our framework lays the groundwork for two things: a clearer head post-operatively manifest by quicker recoveries and the fact that less of the anesthetic required for unconsciousness is used and better, more complete post-operative pain control.
Ultimately, the authors wrote, it comes back to a principled focus on the nervous system and how to disrupt nociception comprehensively by intervening at multiple points.