Some
patients suffering from such
brain injuries did not respond to treatment. After family discussion and
agreement, the doctors withdrew life-sustaining therapy while
neuromonitoring
continued as the patient died. What the neuroscientists observed was
striking, says
Jed Hartings.
“Previously, it was thought that
the end occurs when the brain stops its electrical activity and goes silent,”
he says. “But it doesn’t. We show that the brain remains in a viable state for
several minutes after this flatline. And then the final brain tsunami occurs: A
wave of depolarization sweeps through the cortex.”
This brain activity reflects what happens to the neurons as the heart
stops pumping fresh oxygen to it, explains Jens Dreier. “After cardiac arrest, blood
flow to the brain stops. Neurons and astrocytes detect that the oxygens levels
drop, even before their own metabolism is affected. The neurons then switch off
their function to get into an energy-saving mode: electrical activity stops,
the neurons no longer send any signals. This is the flatline.” But while the
neurons use less energy in this mode, they don’t use none--they still need some
to maintain their internal metabolism.
Normally, ion pumps monitor and
maintain a difference in charge between the inside and outside of neurons; this
difference is essential for neurons to send their signals. But the pumps need
energy, and this is where the system fails, Dreier says. “Eventually, there is
no longer enough energy to keep the ion pump going. The ion gradients collapse: Ions from inside the neurons stream
out, and those from the outside stream in.” As cells, and neurons in particular, have a carefully balanced
chemistry, this change in the concentrations has dramatic consequences.
“A massive depolarization occurs as the ion gradients collapse
completely, releasing a great amount of energy,” Dreier says. “The massive
depolarization isn’t localized though, waves of depolarization spread into the
neighboring regions. This is the brain tsunami, or spreading depolarization.”
First results in
humans
Spreading depolarizations, for all their dramatic impact, are nothing
new. In 1944, the Brazilian physiologist Aristides Le
o first
described seeing waves of suppressed function in the cortex of rats after he
stimulated the cortex intensely, in what he called “spreading depression.” From
the 1980s onwards, medics increasingly accepted that spreading depolarization
was relevant to brain injuries. By the 1990s, researchers had proven in animals
that brain tsunamis cause the death of
brain tissue, but because spreading depolarization is so hard to record, it
remained unobserved in humans until this century. Finally, in 2002, neuroscientists
demonstrated spreading depolarization in the human brain. Since then, COSBID, a clinical
research collaboration of which Dreier and Hartings
are members, and others have studied spreading depolarizations in brain
injuries in hospitals across Europe and the US.
Notably, spreading depolarization does not mark the onset of cell death,
but instead starts the clock counting
down to cell death. Leão
already showed that spreading depolarization is – in principle – reversible. If blood flow
isn’t restored after a certain time, neurons are unable to recover and will die
– this is the commitment point. However, even if depolarization is reversed, the neurons
don’t necessarily survive, says Dreier.
“After depolarization, there is complete chaos in the cells,” he says. “Calcium
levels, for example, increase a thousand-fold. These changes are highly toxic
to the neuron. However, when blood flow sets in again and energy is provided to
the brain, some cells can re-polarize and
may recover their function. But it is fiendish: Although the depolarization is
reversed, the neuron might still die from apoptosis.”
The commitment point, the beginning of the end, is elusive. “As
spreading depolarization is, in principle, reversible, the commitment point at
which neurons start dying and at which there is no going back is hard to define,”
Dreier says. “Actually, we can only define this point in retrospect. Death is a
process that takes some time.”
For Dreier and others, the findings have a concrete call to action.
“We see that patients live longer after a cardiac arrest if some
circulation remains. So resuscitation attempts are very important. Even if the heart
doesn’t start pumping again immediately, as long as the blood flow is kept
going, the brain is kept in a state in which it is able to survive for longer.”
Clues to hemorrhage mystery
Spreading depolarization could also explain the puzzling clinical course
seen in patients with sub-arachnoid
hemorrhage (aSAH), or bleeding in the space between the brain and the tissues
covering it, another recent
study by Dreier and Hartings suggests.
Patients
with aneurysmal sub-arachnoid haemorrhage are likely to develop a series of
complications about a week after the initial bleeding. “This condition has
remained enigmatic, as the causes for delayed deterioration were unknown,” Hartings says. “Previously, not much focus was
put on the brain damage that occurs soon after the aneurysm ruptures. This was
considered too early to medically intervene. But we found that the aneurysm itself causes a significant amount
of brain damage.”
Dreier
and Hartings analyzed recordings from 11
patients with aSAH and found that spreading depolarizations occur frequently in
the initial days after aSAH. “Just the bleeding in the subarachnoid space itself
is a trigger for brain tsunamis in humans, causing brain damage,” Hartings says.
“The spreading depolarizations signal that a brain infarct [stroke] is
developing.” In these patients, clusters of spreading depolarizations occurred
again and again. The spreading depolarizations lasted progressively longer and were
a marker of neurons dying.
These
results could also change treatment for aSAH, Hartings
hopes. “Through neuromonitoring, spreading depolarizations can act as an early
warning system for clinicians before brain damage is irreversible,” he says. “Clinicians
could, for example, pay close attention
to whether the brain receives enough blood flow and oxygen.”
The
two papers advanced the field of spreading depolarization significantly, says
Bill Shuttleworth, Regent’s Professor of Neurosciences at the University of New
Mexico, who is part of the COSBID consortium but not involved in the studies. “Previously,
the real impact of spreading depolarizations in humans was questioned, but
these studies take the step to real
relevance of spreading depolarization in the clinic.”
“Looking
at the end of life, the researchers tied together death and spreading
depolarization in a very controlled clinical setting with strong data. This is
an amazing observation, finding other ways in which spreading depolarizations
impact the brain,” Shuttleworth says. “And by looking at subarachnoid hemorrhages, the researchers found the first
electrophysiological signature for the events causing brain damage.”
“The spreading
depolarization shows that brain cells are dying, and gives a tremendously
useful marker in the clinic for when something is really hurting the brain,” he
says. This is not just a curiosity, but something actionable in intensive
care.”
Video: A recording of brain
electrical activity, played back 44x normal rate, in a patient who experienced a
traumatic head injury. The crackling sound is the normal activity of brain
cells; the periods of silence are short-circuits of electrical activity caused
by brain tsunamis, waves of depolarization that spread across injured areas of
the brain, causing a local loss of function. The brain’s electrical activity
recovers, but with each brain tsunami, damage to cells may worsen. Video posted to YouTube by Mayfield Brain & Spine
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