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Table of Contents
Terms Used In This Article
cardiac cycle - one heartbeat
catheter - a thin flexible tube which can be inserted into the body and
guided to a specific location; usually used to insert or remove
things from the body
foramen magnum - opening at the base of the skull where the spine
comes in
in vitro - in an artificial environment
in vivo - in the body
pressure - the amount of force applied to a specific surface area
subarachnoid space (SAS) - enclosed space through which CSF
circulates
transducer - type of device which can convert one type of energy into
another; can be used for sensing
Common Chiari Terms
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 I -
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
decompression surgery -
general term used for any of several surgical techniques employed to
create more space around a Chiari malformation and to relieve compression
MRI - magnetic
resonance imaging; large device which uses strong magnetic fields to produce
images of soft tissue inside the human body
syringomyelia (SM)
- neurological condition where a fluid filled cyst forms in the spinal
cord
syrinx - fluid filled
cyst in the spinal cord
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March 20, 2006 -- The cerebrospinal fluid (CSF) system is a central player
in the Chiari drama. A Chiari malformation blocks the natural flow of
CSF - which is driven by the heartbeat - between the skull and spine.
This leads to not only abnormal CSF dynamics, such as elevated velocity and
pressure, but to Chiari related symptoms and, in some people, the
development of a syrinx as well.
Because of this, doctors look at CSF flow, using cine
MRI, to help diagnose Chiari, monitor its progression and evaluate the
results of treatment. While cine MRI can provide some data on the CSF
system, because it is completely contained inside the body, the dynamics of
the CSF system can be difficult to analyze for research purposes. Two
recent studies, from two different research groups, have used innovative
approaches to studying the CSF system in order to further our understanding
of the relationship between Chiari, CSF, and syringomyelia.
In the first study, published in the February, 2006
issue of the Journal of American Neuroradiology, a group from the University
of Wisconsin (Turk, Iskandar, Haughton, Consigny) used a pressure sensing
transducer and a catheter to analyze CSF pressure at the foramen magnum in
four dogs. A transducer is a device which converts one form of energy
into another. In this case, the transducer converts the pressure it
feels from the CSF into an electrical signal which can then be recorded and
reflects the actual pressure in the CSF. The specific transducer used
by the Wisconsin team has been widely used to measure pressure in veins and
arteries and has been shown to be nearly 100% accurate.
For their experiment, the team inserted a catheter into
the subarachnoid space of each dog and threaded it up to a level just below
the foramen magnum. The catheter - which is a thin tube - was then
used to guide a wire, with the transducer at its tip, to the same level.
Finally, another catheter was inserted with an inflatable balloon at its end
and placed at the level of the foramen magnum. It should be noted that
the animals were anesthetized and monitored during the procedure and
suffered no adverse effects from it.
The researchers were able to take CSF pressure
measurements and found, much as they expected, that while the CSF pressure
varied during each cardiac cycle, it was essentially the same from one cycle
to the next. In other words the pressure varied within a small,
well-defined range during each heartbeat. However, when the balloon
was inflated to simulate the blockage of a Chiari malformation, the CSF
pressure increased significantly. When the balloon was deflated, which
restored normal CSF flow, the pressure returned quickly to the normal range.
The Wisconsin team feels that the value of their work
lies not in the actual data they collected, but rather with the potential
applications for the technique they demonstrated. They believe the
same approach can be used during decompression surgery to monitor the effect
of each stage (craniectomy, opening the dura, etc.) on the CSF pressure and
help guide the surgery. Similarly, the technique could potentially be
used in humans to analyze the pressure dynamics associated with Chiari and
syringomyelia to further investigate issues such as symptom onset,
progression, and syrinx formation.
In the second study, published in the December, 2005
issue of the Journal of Biomechanical Engineering, a team from the
University of Illinois-Chicago and Emory University (Martin, Kalata, Loth,
Royston, Oshinski) took a different approach to studying the pressure
dynamics associated with a syrinx.
The mechanisms underlying syrinx formation are not
completely understood, but one leading theory, known as the piston theory,
holds that with each heartbeat the cerebellar tonsils are driven down into
the spinal area like a piston. This in turn creates a pressure wave in
the CSF which then drives fluid into the spinal tissue itself, creating a
syrinx.
Critics of this theory have pointed out that since a
syrinx cavity tends to expand over time (like a balloon) and push the spinal
tissue out into the CSF space, the pressure inside the syrinx must be higher
than the pressure of the CSF outside the syrinx in the SAS. One way to
think of this is that you can't blow up a balloon by forcing air into it
from the outside; you blow it up by putting air inside of the balloon which
exerts pressure on the balloon and expands it. However, for the piston
theory to be true, and for CSF to be forced into the syrinx from the
outside, the pressure inside the syrinx must be less than the pressure
outside of the syrinx.
Based on the detailed MRI analysis of a volunteer with
Chiari and syringomyelia, the Chicago team built a physical model - also
known as an in vitro model - to simulate and analyze pressure and movement
in the subarachnoid space (SAS) and the syrinx cavity itself. The
syrinx, subarchnoid space, and CSF were represented using co-axial, water
filled, elastic tubes. A computer controlled pump was used to simulate
the CSF motion as measured in the volunteer (see Figure 1, below).
Figure1: In Vitro Model Of Syringomyelia
To make sure the model accurately represented the human body, the entire
apparatus was placed into the same MRI which was used on the volunteer and
the CSF velocity was matched accordingly.
Once it was calibrated, pressure transducers were
placed at four different locations both inside the syrinx and outside the
syrinx in the SAS space. In addition, a special laser tool was used to
measure the movement of the syrinx wall at several locations.
While the detailed, technical results of this
experiment are beyond the scope of this publication, the researchers did
find that for a period of time during each simulated cardiac cycle, the
pressure inside the syrinx was less than the pressure outside the syrinx.
This period of time would allow for CSF to be driven into the spinal cord to
form and expand a syrinx.
Interestingly, the team also was able to record small
movements of the simulated syrinx wall which were too small to be picked up
by an MRI. One has to wonder if repeated vibrations of the spinal wall
can lead to a weakening of the tissue and facilitate the growth of a syrinx.
While neither of these studies are likely to have an
immediate impact on patients, they both represent exciting new avenues of
research which may yield results for years to come.
[Ed. Note: Dr. Frank Loth and Dr. John Oshinski, cited above, are both
Scientific Advisors to the C&S Patient Education Foundation, the publisher
of Chiari & Syringomyelia News.]
-- Rick Labuda
Back to Table of Contents |
Key Points
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The cerebrospinal fluid system (CSF)
plays a critical role in Chiari and syringomyelia
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While cine MRI is used clinically to
help make diagnoses, studying the CSF system can be difficult
-
Two new studies developed innovative
approaches to studying CSF in Chiari/SM
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First study used a catheter to place
a pressure transducer into the SAS of 4 dogs at the level of the foramen
magnum; a balloon was inflated to simulate Chiari
-
Found that CSF pressure increased
significantly when the balloon was inflated; this technique has potential to
be used during decompression surgery and to further study CSF pressure in
people
-
Second study built a physical model
of the SAS and a syrinx based on the MRI of a patient
-
Model was used to measure pressure
and spinal wall movement
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Found that for a period of time
the pressure inside the syrinx is lower than outside, allowing for CSF to be
driven into the syrinx
-
Both approaches have future
potential
Sources: Martin BA, Kalata W, Loth F, Royston TJ,
Oshinski JN. Syringomyelia hydrodynamics: an in vitro study based on in vivo
measurements.
J Biomech Eng. 2005 Dec;127(7):1110-20.
Turk A, Iskandar BJ, Haughton V, Consigny D.
Recording CSF pressure with a transducer-tipped wire in an animal model of
Chiari I.
AJNR Am J Neuroradiol. 2006 Feb;27(2):354-5.
Related C&S News Articles:
New Theory
Speculates That Compliance Is Key To Syringomyelia And Alzheimer's
New Theory On How Syrinxes
Form
New
Theory On How Syrinxes Form (yes, another one)
In The
Spotlight: Frank Loth, Bioengineer
CSF Flow In Children Before & After Surgery
Decompression Surgery Reduces CSF Velocity |