Stroke Researchers Aim to Stem the “Ischemic Cascade”
What took them so long to figure this out? How much shouting needs to be done before doctors finally come to an understanding of the basis of where research should go? Dr. Moskowitz wrote extensively about this earlier here:
A stroke may be
sudden, but much stroke damage is not. While brain cells completely
deprived of blood at the core of an ischemic stroke (the most common
kind) die within minutes, in the broader “penumbra” where circulation
is down but not out, the process is gradual—and reversible.
Neuroscientists
speak of the “ischemic cascade:” Without the energy from oxygen and
glucose required to maintain neurotransmitter storage, neurons release
massive amounts of glutamate. The resulting excitotoxicity
allows a flood of calcium, sodium, and water into the cell, producing
excessive nitric oxide and leading to inflammation, free radical
formation, and, ultimately, the death of the cell.
“Cells in the penumbra stay for hours, maybe days in a meta-stable state,” says Michael A. Moskowitz, professor of neurology at Harvard. “They don’t function normally and don’t carry impulses, but they are alive and rescuable.”
The
one approved treatment for ischemic stroke, tissue plasminogen
activator (tPA), saves brain in the penumbra in the most direct way: by
dissolving the clot and restoring circulation. The drug must be given
within 3-4 hours of symptoms to do any good, though, and restoring
circulation can bring problems of its own, including hemorrhage. In
practice only 5 percent of patients benefit.
In recent years,
researchers have sought to widen the window of therapeutic opportunity
by targeting the ischemic cascade itself—halting the destructive process
through neuroprotective strategies. Their activity has been
intense: More than a thousand compounds have been considered, and more
than one hundred tested in clinical trials—but none has yet succeeded. What are they?
“An
enormous amount of energy has been put into this, but no one has hit
pay dirt,” says Moskowitz. “It’s been a very bad time for people
interested in neuroprotection.” More than the innate difficulty of the
problem, he suggests, the failure reflects serious flaws in the science
behind screening: “Proof of concept has been lacking for most drugs
chosen for clinical trials. They were tested without any demonstration
that they could actually get into the brain, bind to their receptors,
and do what they were intended to do.”
On the other hand, poor
experimental design may have meant promising possibilities were
overlooked. “We may have thrown the baby out with the bathwater in some
previous studies,” Moskowitz says.
He emphasizes that this dismal
history by no means discredits the concept of neuroprotection. “There
shouldn’t be so much doom and gloom. This isn’t an easy business, but
there’s no theoretical reason why we can’t do a better job of rescuing
cells. We need to reinvent the field.”
A most promising study
Asked about current research, Moskowitz mentioned Michael Tymianski.
“He’s a very good, thoughtful investigator. I’d say, from the
excitement point of view, [his work] may be the most encouraging thing
we’ve seen.”
Tymianski’s research involves the excessive release
of glutamate that occurs early in the ischemic cascade, the first step
toward catastrophic excitotoxicity. Attempts to abort this process by
blocking the NMDA glutamate receptor itself haven’t worked because
glutamate neurotransmission is essential to normal neuron function.
Tymianski’s approach is more selective: to inhibit a protein, PSD-95,
that links the receptor to molecular events within the cell that promote
overproduction of nitric oxide and the influx of calcium.
Tymianski,
a senior scientist at Toronto Western Research Institute, and his
colleagues have been developing a PSD-95 inhibitor for 15 years, testing
it in cell cultures and rodent models of stroke. In his most recent
study, reported in the March 8 issue of Nature, they administered the compound, Tat-NR2B9, to macaques, non-human primates whose brain closely resemble ours.
Findings
were encouraging: the drug reduced the area of brain loss, compared
with placebo, when given 1-3 hours after a large cerebral artery was
blocked to simulate a stroke. The animals also fared significantly
better in tests of neurological function up to two weeks later,
confirming that the simulated stroke had done less damage.
“Our
results show that neuroprotection is unequivocably feasible in the
complex brain,” Tymianski says. “The challenge now is to design a human
trial to show clinical benefit.”
The compound has already been
shown to be safe in a recent clinical trial in which it was given to
patients just after surgery to repair a brain aneurysm, a procedure that
carries a high risk of stroke. Although he could not discuss further
results in detail, Tymianski called them favorable, suggesting that
ischemic damage had been reduced in patients who had strokes after the
procedure.
Next, he hopes to test the compound in patients with
acute ischemic stroke. Because the drug is apparently safe even in the
face of hemorrhagic stroke, it might be given by emergency medical
personnel en route to the hospital without the expert screening needed
for tPA, dramatically shortening the time to potential neuroprotection.
[Tymianski heads a company established to develop the drug in question.]
Tymianski’s
success has led researchers to seek other ways to block the PSD-95
pathway. “His work is really impressive, but we like to think we’ve made
a better compound,” said Anders Bach,
a postdoctoral fellow at University of Copenhagen. The molecule
developed by his group has a much higher affinity for PSD-95, and
results of a study in mice, published in Proceedings of the National Academy of Sciences in February 2012, suggests that this enhanced its ability to protect the brain.
Other routes to neuroprotection
Researchers elsewhere are addressing other parts of the ischemic cascade.
“In my lab we’ve used two approaches to promote survival in the penumbra,” says Nicolas G. Bazan,
director of the Neuroscience Center of Excellence at Louisiana State
University and a member of the Dana Alliance for Brain Initiatives.
“We’ve devised new molecules that can cross the blood-brain barrier and
block bad things happening. And we’ve looked inside the brain to piece
out the intrinsic mechanisms that the brain sets in motion to protect
itself.”
Much of his research over the past several decades has
involved the release of free fatty acids in stroke, with a particular
eye toward an endogenous molecule derived from the fatty acid DHA,
neuroprotectin-D1, which appears to reduce the impact of ischemia.
A
recent focus of his attention has been platelet activating factor
(PAF), a compound that normally aids in blood clotting but when released
in large amounts by ischemia apparently participates, along with
glutamate, in the cascade of excitotoxicity and its consequences.
In a study reported in the March 2012 issue of Translational Stroke Research,
Bazan and his colleagues showed that timely administration of a PAF
antagonist, LAU-0901, to rats reduced the area of brain damage after
experimental stroke, limited inflammation, and improved neuron survival.
Animals treated with LAU-0901 showed significantly less behavioral and
neurological impairment up to a week later, compared to those given
placebo. [Louisiana State University holds the patent on LAU-0901]
Another
conspicuously active area of neuroprotection research is hypothermia.
Lowering body temperature by just a few degrees appears to slow multiple
destructive processes unleashed by ischemia—excitotoxicity,
inflammation, free radical release— simultaneously, according to Midori A. Yenari, professor of neurology at University of California, San Francisco.
Hypothermia
has been shown to protect the brain against disrupted circulation in
conditions other than stroke—it is recommended for resuscitation of
cardiac arrest survivors, for example—and animal experiments have been
encouraging.
What’s more, its benefits may persist long after the
immediate post-stroke period. “There are a few studies suggesting a
positive downstream effect on recovery— when cooling [is initiated] the
first day, restorative processes like neurogenesis are improved months
later,” Yenari says.
Like other stroke interventions, hypothermia
would probably be used along with thrombolytic therapy, but how the two
interact remains an open question. “[Some] studies suggest that
thrombolysis doesn’t work as well when the brain is cooled, but other
research indicates that if tPA is given, the risk of hemorrhage is
reduced,” she says.
The most imposing barriers to hypothermia for
acute stroke are practical: Lowering body temperature can induce
uncomfortable shivering, disturb electrolyte balance, and raise the risk
of pneumonia or cardiac complications, particularly in older patients
with other illnesses.
Researchers have used surface cooling,
circulating ice water to cool blood vessels internally, and measures
like helmets to cool the brain selectively. “People are now trying to
identify drugs to cool the body instead of mechanical measures” in hopes
of avoiding complications, says Yenari.
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