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An aneurysm occurs when a weakness in the wall of an artery leads
to the swelling, or “ballooning” of that artery. It is estimated
that up to 5 million Americans have cerebral aneurysms, although
most do not experience any symptoms.1 Aneurysms likely occur at a
higher rate in women than men, and about 20% of people who have had
an aneurysm will have at least one more develop at some point in
their lives.
Most brain aneurysms —up to 85%—typically occur in the anterior
or front part of the brain’s blood vessel system, whereas
approximately 15% occur in the posterior or back section of the
brain’s blood vessel network. Most aneurysms occur along vessels
that comprise the “circle of Willis” or the set of collateral blood
vessels that link right to left and front to back.
Risk factors for aneurysm development include smoking, obesity
and hypertension. Some people may also be born with a predisposition
to experience an aneurysm, although most people develop them after
the age of 40. Certain genetic conditions that lead to familial
aneurysm formation include fibromuscular dysplasia and polycystic
kidney disease. Aneurysms can also occur due to infections, drug
abuse, or head trauma.
When aneurysms develop along the arteries in the brain, they can
rupture into the fluid spaces (subarachnoid space) that surround the
brain with devastating results. This subarachnoid hemorrhage may
cause stroke and, ultimately, death in a high percentage of patients
if not treated expeditiously at expert treatment centers. Aneurysms
may also press against the nearby brain tissues or cranial nerves
causing neurological symptoms or even seizures. New neurological
changes due to an aneurysm can be an ominous sign that the aneurysm
is suddenly expanding and may rupture causing hemorrhage. Patients
with new neurological deficits due to aneurysm should receive urgent
medical attention in most cases.
Warning signs
The majority of people with aneurysms do not experience warning
signs that they are at risk of having aneurysmal hemorrhage. About
40% of patients with aneurysms, however, may experience the
following symptoms:
- Nausea or vomiting
- Pain above and behind the eye
- Numbness or weakness
- Neck pain
- Headache confined to a specific area
- Visual difficulties
- Apeech difficulties
- Memory problems
- Seizures
When these symptoms are present, assessment procedures should
include a computed tomography scan (CT) or magnetic resonance
imaging (MRI). These techniques can help to identify aneurysms
before they rupture. A more accurate diagnosis, however, is still
typically made using catheter cerebral cerebral angiography. This
involves the injection of dye into the blood vessels through a
catheter or tube. These images define the anatomy and location of an
aneurysm with great detail and form the basis on which treatment
planning using either can be performed. Treatment using either open
surgery with craniotomy and surgical clipping of the aneurysm or
endovascular surgery with internal occlusion of the aneurysm can
then be undertaken. There are benefits and risks to either approach
and the treatment team must comprise members with expertise in both
types of procedures in order to achieve optimal patient outcomes.
Descriptions of aneurysms
There are 3 different shapes of aneurysms:
- Berry – the most common type of aneurysm, these are
small and shaped like a blister, balloon, sac or even a little red
“berry” appearance at the time of craniotomy and direct surgical
exposure. These aneurysms most often arise at a blood vessel
branch point or bifurcation where a relatively weak point is
subject to high stress factors from the flowing blood.
- Fusiform – this type of aneurysm is elongated and
shaped like a spindle. I often liken the appearance to a snake
that swallowed a rat. Rather than a balloon or bulge from one side
of the blood vessel wall, the entire circumference of the blood
vessel has become involved in the formation of a fusiform
aneurysm.
- Dissecting – this type of aneurysm occurs when blood
passes through a tear in the inner layer of the blood vessel wall
that causes the wall to split weakening its ability to contain the
flow of blood. The result can be aneurysmal dilatation of the
blood vessel, narrowing of the main flow channel for blood to
reach the brain causing stroke, or even rupture through the
weakened blood vessel wall causing subarachnoid hemorrhage.
Aneurysms are further characterized by size. A small aneurysm is
considered to be less than 7-10 millimeters. An aneurysm between 10
and 25 millimeters is classified as large, and a giant aneurysm is
greater than 25 millimeters.
Rupture of aneurysms
The rupture of aneurysms, also known as aneurysmal bleed or
subarachnoid hemorrhage (SAH), is believed to occur at a rate of
1-2% per year and the risk is cumulative over time. The hemorrhage
rate is the subject of ongoing debate based upon the available
epidemiological data, but most physicians still agree on this range
for hemorrhage risk. Various factors influence whether an aneurysm
is at risk of rupture, including its size, type, location, and
previous history of rupture. Common warning signs of a subarachnoid
bleed include an extremely painful headache, drowsiness, and nausea
or vomiting. We do not yet fully understand what causes aneurysms to
form, grow, and rupture. Conditions over which we have control in an
effort to prevent aneurysmal hemorrhage include strict control of
high blood pressure and strict abstinence from all tobacco use or
exposure.
When a rupture of a brain aneurysm does occur, the blood
typically seeps into the fluid space closely surrounding the brain
called the subarachnoid space. The subarachnoid space is filled with
cerebrospinal fluid and is mostly one continuous area although
filamentous bands of fibrous tissue may compartmentalize certain
parts of the subarachnoid space and limit flow from one part to
another. Blood may also travel directly into the brain substance,
although this is less common. In more severe hemorrhages, blood may
back up into the ventricles or caverns deep within the brain where
the spinal fluid is originally produced.
It cannot be overstated that the rupture of a brain aneurysm is a
true medical emergency and warrants immediate medical attention; it
is estimated that 25% of patients with this condition will die
before arrival in the emergency room, and that 45% of patients will
die within 30 days of the bleed.2 Furthermore, once an aneurysm has
ruptured, it is at greater risk for additional bleeding in the first
minutes, to hours, and days following the initial hemorrhage. In
hindsight, some patients who experience subarachnoid hemorrhage will
recall a back headache days to weeks before the big hemorrhage. This
is often referred to as a “sentinel” headache and is thought to
represent an early small hemorrhage that went unrecognized.
A CT scan can usually diagnosis bleeding in the brain and
subarachnoid area. If necessary, a lumbar puncture, commonly
referred to as a spinal tap, may also be conducted to examine if
blood is present in fluid around the brain. In this procedure, a
thin needle is inserted into the lower part of the spinal column to
obtain a small fluid specimen to examine for evidence of bleeding
not apparent on the CT scan. Lumbar puncture is required in the vast
minority of patients who have experienced acute subarachnoid
hemorrhage.
Treatment of aneurysm
In the past, treatment of brain aneurysm has entailed a surgical
procedure.. First, a small opening in the skull called a craniotomy
is made so that the surgeon can dissect away the tissues surrounding
the aneurysm and apply a clip to the aneurysm. A clip looks somewhat
like a tiny clothes pin that pinches the walls of the blood vessel
together at the base of the aneurysm and prevents flowing blood from
access to the aneurysm. If the flowing blood cannot get into the
aneurysm, then it also cannot leak out. Although this procedure can
be effective, it is invasive, requiring exposure and retraction of
the brain. Newer methods of treating aneurysm are always in
development. One relatively newer method of treatment is known as
endovascular embolization or occlusion of the aneurysm from within
the blood vessel. In the same way that the surgical clip pinches
closed an aneurysm preventing flowing blood from access to the
aneurysm, tiny platinum coils can be placed into the aneurysm that
also prevent flowing blood from access to the aneurysm and allow
aneurysm healing.
Endovascular aneurysm treatment from start to finish
Prior to undergoing an endovascular surgery, patients are expected
to sign a consent form and will have the opportunity to have any
questions answered. The anesthesiologist will administer medications
and fluids through the use of an intravenous line (IV) into a vein
in the hand or arm. Usually, endovascular procedures are also
performed under general anesthesia not so much for pain control but
rather so that the patient will be completely still for the entire
procedure. Aneurysms are very small and measured in millimeters. The
treatment coils are also small, delicate, and measured in
millimeters. Precision is very important for the success of the
endovascular procedure, and general anesthesia facilitates this
success. Otherwise, the procedure is essentially painless.
Blood pressure can be monitored through the catheters used to
perform the aneurysm treatment. An electrocardiogram (EKG) will
monitor heart rate and rhythm and a pulse oxymeter monitors oxygen
levels. A specific type of catheter known as a Foley catheter will
be placed through the urethra into the bladder to allow urine to
drain. Anesthesiologists often monitor urine output as a simple
indicator that the body’s major systems are functioning well.
Very simply, endovascular treatment of a cerebral aneurysm is an
extension of the diagnostic arteriogram used to diagnose the
aneurysm. Special training is required to perform this type of
treatment procedures, however. For the diagnostic arteriogram, the
catheter is passed into the arteries that lead to the brain, but the
catheter is usually positioned within the blood vessel around the
level of the collar bones or voice box. The x-ray contrast material
is injected through the catheter into the blood vessels in the neck,
and x-ray images are obtained over the head as blood flows through
brain arteries.
Endovascular treatment requires passage of a tiny, “hair-like”
catheter through a supporting catheter positioned within the blood
vessels in the neck. The tiny catheter is then navigated through the
brain blood vessels on high resolution “road-map” images. These
images obtained from two different directions allow the physician to
monitor the progress of the catheter toward the aneurysm and control
its ever movement. Finally, the tiny catheter is positioned in the
orifice or hole leading into the aneurysm.
Again, under high resolution road-map imaging, the physician
carefully passes delicate detachable platinum-base coils into the
aneurysm. For a number of years, there was only one type and one
vendor of cerebral aneurysm coils: Guglielmi Detachable Coils (GDC)
by Target Therapeutics, Inc. Now, there are an increasing variety of
coils with unique properties suited to aneurysm treatment. Each coil
is carefully sized to the specific aneurysm under treatment based
upon three-dimensional computer reconstructions of the aneurysm.
Once placed into the aneurysm, each coil is carefully detached from
its delivery device, and the aneurysm is progressively filled with a
succession of smaller coils until it is completely occluded. When
the coils are inserted, the aneurysm becomes tightly packed to
prevent blood from flowing into it, with the ultimate goal of
preventing the aneurysm from rupturing. The newest coils approved by
the FDA for aneurysm treatment even appear to promote aneurysm
healing for durable and long-lasting results.
Some aneurysms have relatively wide apertures or holes leading
into the aneurysm. These present a challenge to coil placement
because it can be difficult to place the coils within the aneurysm
without blocking the blood vessel from which the aneurysm arises. To
facilitate endovascular treatment of these aneurysms, adjunctive
tools and techniques have been developed. In some cases, a small
balloon is used to create a temporary buttress to help hold the
coils in the aneurysm during their deployment. In these cases, the
coils develop a stable configuration that does not require any
further support following occlusion of the aneurysm. In a small
number of cases, the aneurysm orifice is too broad even for balloon
remodeling. In these cases, the FDA approved a specialize brain
stent that allows placement of a tiny stent in the brain artery that
acts as a permanent scaffolding to hold the artery open while the
aneurysm is occlude with coils outside the confines of the stent.
Once the procedure is complete, the patient will be transferred
from the operating room to either the Neurological Intensive Care
Unit (NICU) or the Post-Anesthesia Care Unit (PACU). In the
intensive care setting, patients are carefully monitored for any
neurological changes that might require urgent medical attention.
For patients who underwent treatment of a ruptured aneurysm, their
stay in the NICU often lasts for up to two weeks as they recover
from their hemorrhage. For patients who undergo treatment of an
unruptured or incidental aneurysm, the hospitalization is often as
short as one day. Some patients can even be discharged home right
from the intensive care unit on the morning after endovascular
surgery.
Follow-up procedures may include an x-ray, MRI, or angiogram to
assess the effectiveness of the procedure. Although there is no
absolute concensus, arteriographic surveillance is usually performed
for two main reasons. 1.) Surveillance arteriography allows the
treating physician to confirm durable occlusion of the aneurysm or
plan further treatment if necessary. Over time in a small minority
of aneurysms, the coil mass can compact itself so that a portion of
the aneurysm reopens. A brain aneurysm is a very delicate structure
and so are the coils used to occlude the aneurysm. The treating
physician can only push so many coils into an aneurysm before the
risk of rupturing the aneurysm increases dramatically. After
treatment, however, continuous blood flow and beating of the heart
and pack or compress the coils into a smaller bundle than at the
time of the original treatment procedure. In these cases additional
coils can be added to refill the aneurysm. If retreatment is
required, a few extra coils is all that is necessary to permanently
block the aneurysm. The newest coils that promote aneurysm healing
are meant to preclude this problem by encouraging scar formation in
the aneurysm and permanently sealing off the aneurysm orifice or
hole. 2.) We have said that up to 20% of patients will develop a
second or multiple aneurysms during the course of their lives. This
is another way of saying that whatever conditions caused the
development of an aneurysm at one location, these same conditions
exist at many other branch points in the blood vessel network.
Surveillance arteriography also allows the treating physician to
evaluate for development of other aneurysms that could pose a risk
to the patient and may require treatment or periodic observation.
Medication may also be prescribed in the form of aspirin or other
blood thinner after treatment.
Once at home, certain activities such as heavy lifting and
driving must be avoided until the physician provides approval. Most
patients, however, can begin resuming normal activity after a
relatively brief period.
Although the GDC method was once only used to treat high-risk
aneurysms only, its high success rate has led to its recent approval
for use in treating all types of brain aneurysms. It is also linked
to a reduction in the incidence of future episodes of bleeding.3 Age
is believed to be a factor that influences the outcome of treatment.
The younger the patient, the more likely surgical treatment is to be
successful.2 Smaller aneurysms are also associated with better
outcomes. If aneurysmal bleeding has occurred, recovery is most
closely tied to the degree of injury caused by the hemorrhage or any
further bleeding episodes.
The International Subarachnoid Aneurysm Trial (ISAT) was a
multinational study comparing surgical clipping with endovascular
aneurysm occlusion in patients with subarachnoid hemorrhage. In
summary, ISAT found that patients who underwent endovascular
treatment of their aneurysms recovered far better (up to 25% better
in the first year) than patients who underwent surgical clipping of
comparable aneurysms. In fact, the safety monitoring committee
prematurely terminated the study because the primary endpoint
(neurological outcome) was reached before the required number of
patients were enrolled in the study.4 As time continues since the
end of the difference in outcomes between the surgical and
endovascular groups continues to increase. Similar differences have
been suggested by other smaller trials for both ruptured and
unruptured aneurysms. This is not to say that all aneurysms should
be or can be treated by endovascular methods. The decision to treat
an aneurysm and the method by which treatment will be performed
requires the recommendation of neurosurgeons skilled at skull base
and cerebrovascular surgery and endovascular surgeons skilled at
endovascular procedures performed under x-ray fluoroscopic guidance. |
