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Table of Contents
caudal - towards the tail; in this case CSF flow from the brain to
the spine
cephalad - towards the
head; in this case CSF flow from the spine to the brain
cerebellar tonsils -
portion of the cerebellum located at the bottom, so named because of their
shape
cerebellum - part of
the brain located at the bottom of the skull, near the opening to the spinal
area; important for muscle control, movement, and balance
cerebrospinal fluid
(CSF) - clear liquid in the brain and spinal cord, acts
as a shock absorber
Chiari malformation -
condition where the cerebellar tonsils are displaced out of the skull area
into the spinal area, causing compression of brain tissue and disruption of
CSF flow
cine MRI - type of MRI
which can show CSF flow, also known as phase contrast MRI
craniectomy - surgical
technique where part of the skull is removed
decompression surgery -
general term used for any of several surgical techniques employed to
create more space around a Chiari malformation and to relieve compression
dura - tough, outer
covering of the brain and spinal cord
duraplasty - surgical
technique where the dura is opened and expanded by sewing a patch into it
flow - the amount of a
fluid which moves across a space in a given amount of time; for example one
milliliter per second
foramen magnum -
opening at the bottom of the skull where the brain and spinal cord meet
laminectomy - surgical
technique where part of a vertebra is removed
magnetic resonance imaging
(MRI) - diagnostic device which uses a strong magnetic field to create
images of the body's internal parts
posterior fossa -
depression on the inside of the back of the skull, near the base, where the
cerebellum is normally situated
syringomyelia (SM)
- neurological condition where a fluid filled cyst forms in the spinal
cord
syrinx - fluid filled
cyst in the spinal cord
tonsillar herniation -
descent of the cerebellar tonsils into the spinal area; often measure in mm
velocity - how far
something travels in a given amount of time; for example miles per hour, or
centimeters per second
voxel - a single point
in an MRI image; like a pixel on a TV or computer screen
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In recent years both researchers and clinicians
have turned their attention to the role that the flow of cerebrospinal fluid
(CSF) plays in Chiari and syringomyelia. CSF is a clear liquid which
bathes both the brain and spinal cord (under the dura, in the subarachnoid
space) and acts as a shock absorber. In a healthy person, CSF flows
freely from the skull area to the spinal area and back, driven by the
heartbeat. More specifically, when the heart beats, blood rushes into
the brain and forces CSF out and into the spine area. In the second
phase of the cardiac cycle, this is reversed and CSF flows from the spine
back into the brain.
When the cerebellar tonsils descend out of their
natural position, past the foramen magnum and into the spinal area, their
physical presence disrupts - or blocks - the natural flow of CSF. It
is believed that the disrupted CSF flow is the cause of many symptoms,
including syrinx formation, and one of the goals of surgery is to restore
the natural flow of CSF.
The recent focus on CSF flow is in contrast to the
early definition of Chiari. When MRI's were first introduced, they could produce
only static, anatomical images. Using standard MRI's Chiari
malformations were assessed based on the amount of tonsillar herniation
below the skull. Someone with 3mm of herniation would be considered to
have mild, or borderline Chiari; while someone with 1 cm or more would be
considered to have a severe case. The problem with this method is that
research has shown time and again that the amount of herniation is not
related to either symptoms or clinical outcomes.
With this in mind - and the notion that CSF flow plays
a critical role - the development of cine MRI, which is able to show CSF
flow timed to the heartbeat and not just static images, appeared to offer a
new way to assess Chiari cases. Indeed, cine MRI has become a routine
diagnostic tool for many surgeons; however, despite it's growing popularity,
some have begun to question the usefulness and value of looking at overall
flow. Research studies have shown wide variations depending on how and
where flow is measured and to date no single parameter, such as total flow
or average velocity, has been found which strongly correlates with symptoms
or surgical outcome.
In a November, 2004 supplement to the Journal of
Neurosurgery, three researchers from the University of Wisconsin, Dr.
Iskandar, Dr. Quigley, and Dr. Haughton, propose that using cine MRI to look
at measures such as total flow are not sufficient and that more complex
measures must be used to accurately characterize the Chiari state.
Iskandar and his colleagues carefully analyzed the CSF
flow of 8 children with Chiari, both pre and post surgery, and 2 children
without Chiari. Instead of measuring average velocity and total flow,
they focused on specific characteristics at many discrete points - or voxels
- around the foramen magnum at 14 different times during the cardiac
cycle. At each point in space and time, they looked at four different
parameters:
-
An increase in the peak CSF velocity in both the caudal and cephalad
direction
-
Differences in velocities of regions close together - in other words CSF
flowing at different speeds
-
CSF flowing in both directions at the same time in regions close to each
other, quantified on a scale of 0-6
-
Tendency for CSF to flow more in one direction than the other
Each patient had a Chiari of at least 3mm in length
and represented a range of symptom severity. They all underwent
similar surgeries and were evaluated both before and several times after
surgery. Seven of the eight improved after the initial surgery, but
one child required a second surgery where part of a tonsil was removed.
In analyzing the results of the flow studies, the
Wisconsin team found that before surgery the CSF flow of the Chiari
patients was very fast in some areas and slower in others. These high
speed jets, tended to disappear after surgery.
In addition, in 6 of the 8 patients, the peak CSF velocity was higher before
surgery than after surgery (see Table 1). The team also found in these
patients that CSF would flow in both directions at the same time (see Table
2).
Perhaps most interesting to note is the fact that
while these parameters decreased after surgery for most of the patients, in
the one child for whom the surgery failed there was no change in the CSF
characteristics. However, after the second, successful surgery, the
CSF velocity and bidirectionality did decrease.
Also, in the healthy children, the CSF velocity was
lower and more uniform, and there were no cases where CSF was flowing in
both directions at once. Taken together, the results would indicate
that Chiari malformations result in uneven, disrupted CSF flow characterized
by high speed jets, uneven speed, and uneven direction of flow.
From this, the authors conclude that more complex
analysis than is generally used right now is necessary in looking at CSF
flow across the foramen magnum and that quantitative parameters should be found
which correlate with symptoms and clinical outcomes.
Because this research is on the cutting edge, it does
have several limitations. Most notably, the small number of cases are not enough to draw strong conclusions. In
addition, the team only looked at data at the foramen magnum. Finally,
no attempt was made to tie the imaging findings back the symptoms of the
patients. It could be that herniated tonsils can cause CSF flow
disruption, without causing real problems. To rule out that
possibility, the team proposes analyzing the flow characteristics of an
asymptomatic Chiari patient.
Despite the early nature of this work, it is very encouraging
to see imaging techniques and technology continue to progress. It will
be interesting to watch where this line of research takes us in the next few years.
--Rick Labuda
Back to Table of Contents |
Key Points
-
Research has shown that the amount
of tonsillar herniation (mm) is not related to symptoms or clinical outcome
-
Cine-MRI, which can show CSF flow,
is becoming a more common measure
-
Not all surgeons are convinced of
usefulness of cine MRI
-
Some question the value of measuring
overall flow
-
Study looked at flow characteristics
of specific points at specific times in 8 Chiari children, pre and post
surgery, plus two healthy children
-
Found that the flow pre surgery had
higher velocity peaks at certain points and often exhibited flow in two
directions at the same time
-
These were not seen in the healthy
subjects
-
Authors believe that more complex
characteristics of CSF flow are required in evaluating Chiari
Table 1
Peak Velocities Of Chiari Patients, Pre and Post Op
| |
Cephalad (cm/s) |
Caudal (cm/s) |
| # |
Pre |
Post |
Pre |
Post |
| 1 |
9.9 |
4.2 |
-2.3 |
-2.7 |
| 2 |
3.6 |
4.5 |
-2 |
-2.4 |
| 3 |
10.1 |
3.3 |
-5.4 |
-2.1 |
| 4 |
4.5 |
17.9 |
-3.1 |
-5.1 |
| 5 |
9.9 |
4.8 |
-5.2 |
-2.8 |
| 6 |
3 |
3 |
-2.7 |
-2 |
| 7 |
14.2 |
4 |
-4.5 |
-4 |
| 8 |
22.2 |
11.3 |
-16 |
-6 |
Table 2
Bidirectionality Score of Chiari Patients, Pre and Post Op
| # |
Pre |
Post |
| 1 |
5 |
4 |
| 2 |
5 |
4 |
| 3 |
5 |
2 |
| 4 |
6 |
4 |
| 5 |
6 |
4 |
| 6 |
4 |
4 |
| 7 |
4 |
2 |
| 8 |
6 |
5 |
Note: Bidirectionality
was quantified on a scale of 0-6 Source: Iskandar
BJ, Quigley M, Haughton VM. Foramen magnum cerebrospinal fluid flow
characteristics in children with Chiari I malformation before and after
craniocervical decompression.
J Neurosurg. 2004 Nov;101(2 Suppl):169-78.
Related C&S News Articles:
Studying CSF Flow To Predict
Surgical Outcome
The Importance Of Cine MRI
Decompression Surgery Reduces CSF Velocity |