Spectrographic data represent brain-wave frequencies from 44 electrodes attached to the scalp of a volunteer undergoing propofol anesthesia.
Since the mid-1800s, doctors have used drugs to induce general anesthesia in patients undergoing surgery. However, little is known about how these drugs create such a profound loss of consciousness.
In a recent study that tracked brain activity in human volunteers over a two-hour period as they lost and regained consciousness, researchers from MIT and Massachusetts General Hospital (MGH) identified distinctive brain patterns associated with different stages of general anesthesia. Those brain-wave signatures could help anesthesiologists better monitor patients during surgery and make sure they don’t wake up.
Such unintended waking occurs once or twice in 10,000 operations, says Emery Brown, an MIT professor of brain and cognitive sciences and health sciences and technology, who is also an anesthesiologist at MGH.
“It’s not something that we’re fighting with every day, but when it does happen, it creates this visceral fear, understandably, in the public,” he says. “And anesthesiologists don’t have a way of responding, because we really don’t know when you’re unconscious.”
Anesthesiologists now rely on a monitoring system that converts electroencephalogram (EEG) information into a single number between 0 and 100. However, the researchers say, that index actually obscures the information that would be most useful.
In the new study, Brown and Patrick Purdon, an instructor of anesthesia at MGH and Harvard Medical School, worked with colleagues to monitor subjects as they received propofol, a common anesthestic. As the subjects began to lose consciousness, the EEG showed that brain activity in the frontal cortex oscillated in both the low-frequency (0.1 to 1 hertz) and alpha-frequency (8 to 12 hertz) bands. The researchers also found a specific relationship between the oscillations in those two frequency bands: alpha oscillations peaked as the low-frequency waves were at their lowest point.
When the brain reached a slightly deeper level of unconsciousness, a marked transition occurred: the alpha oscillations flipped so their highest points occurred when the low-frequency waves were also peaking.
As the researchers slowly decreased the dose of propofol to bring the subjects out of anesthesia, they saw that brain activity patterns flipped again, so that the alpha oscillations were at their peak when the low-frequency waves were at their lowest point.
Purdon and Brown are now starting a training program at MGH that will help doctors interpret EEG information to better monitor how deeply a patient is anesthetized.