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Table of Contents
bone marrow - soft tissue inside of
bones which produces blood cells
central canal - the
tube like center of the spinal cord; the central canal is open in childhood
and slowly closes as people age
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
chimera - an animal
which contains the cells, or tissue, from another animal; named after the
mythological creature
decompression surgery -
general term used for any of several surgical techniques employed to
create more space around a Chiari malformation and to relieve compression
immune response - how
the immune system reacts to foreign substances
kaolin - a fine white
clay, used to create syrinxes in rats
macrophage - type of
immune cell which scavenges dead tissue by engulfing it
microglia - fine,
connective tissue in the brain and spinal cord which turns phagocytic
phagocytic - a cell
that engulfs and digests debris and foreign invaders
parenchyma - in this
case, the actual tissue of the spinal cord
spleen - an organ
which plays an important role in the immune system and is a reservoir for
macrophages
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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In trying to
understand how and why syrinxes form, many researchers have focused on the
large-scale role that CSF flow plays. While this is understandable given that fluid must somehow collect in a
syrinx cavity, other researchers have focused their attention on the
microscopic world instead; choosing to study what role the body's own immune
system might play in the poorly understood world of syrinxes.
Over the years, both autopsy and animal studies have
shown that there is marked immune system activity near syrinxes.
Specifically, researchers believe - especially with post-traumatic
syringomyelia - that some type of inflammation response might be involved.
Macrophages, a type of immune cell which acts as a scavenger and essentially
eats dead tissue, have been identified as being present in large number near
syrinxes, however their exact role in syrinx formation and progression is
not yet known.
If macrophages, or some other type of immune cell, turn
out to play an important role in the formation of syrinxes, not only would
it shed light on the underlying process, but it could potentially provide
for a new avenue of treatment. If the type and origin of the immune
cells can be identified, it may also be possible to reduce their presence
and limit the development and growth of syrinxes.
With this in mind, Dr. Gabriel Yin Foo Lee and his
colleagues at the Royal Adelaide Hospital and the University of Adelaide, in
Australia, decided to create syrinxes in rats and then examine them for the
presence of macrophages. They published their work in the January 15,
2005 issue of the journal Spine.
Dr. Lee suspected that the macrophages which had
previously been seen near syrinxes were coming from bone marrow, the source
of many types of immune cells. In order to differentiate bone marrow
macrophages from other sources of immune cells, Dr. Lee's team created what
are known as bone marrow chimeras. In Greek mythology, the chimera was
a fire-breathing monster with the head of lion, the body of a goat, and the
tail of a serpent. In the modern laboratory, a chimera is an animal
which contains cells or tissue from another animal.
Dr. Lee's group destroyed the immune producing bone
marrow of their rats using radiation and then replaced it with genetically
distinct bone marrow from different rats. This way, they would be able
to tell the difference between immune cells produced from the bone marrow
and those from other sources.
After letting the rats recover for six weeks, the research
team used a well-recognized method to create syrinxes in the rats.
Namely, they injected kaolin into their spinal cords. The rats were
then divided into three groups (10 rats each) and their spinal cords and
spleens were removed for examination at 3 days after the injection, 1 week
after the injection, and 4 weeks after the injection.
The team found that the rats did indeed show signs of
swelling in the central canal at 1 week, and at 4 weeks the central canals
of some rats were actually blocked by large aggregates of the kaolin covered
in macrophages.
In studying the spinal tissue more closely, the
research team used special stains to help identify different immune cells
and counted them manually. They found significant evidence of
inflammation and immune response at the 3-day mark, with the inflammation
peaking at the 1 week mark. They also found two distinct types of
immune cells. One type was standard macrophages created by the bone
marrow, but they also identified a second, smaller type of microglial cells.
Microglial cells are cells from the fine, connective tissue in the spinal
cord which have turned into cells that engulf and digest foreign invaders.
Perhaps most importantly, the team found that after 4 weeks,
in a number of rats, their immune response - the action of the macrophages
and microglial cells - had essentially created an obstruction in the central
canal. The authors speculate - and take pains to point out this is a
theory - that the immune cells that respond to the kaolin injection in the
tissue of the spinal cord (the parenchyma) are carried into the central
canal via the natural CSF flow. This then obstructs the local flow of
CSF and the central canal starts to swell. Macrophages then continue
to accumulate, causing more swelling. Eventually, when the macrophages
disperse, a syrinx cavity remains.
While their theory remains just that, it does seem likely
given the accumulating evidence that the immune system - perhaps in the form
of macrophages and/or microglial cells - plays a role in the formation of
some type of syrinxes. Dr. Lee and his team plan to continue their
work by seeing what happens in terms of syrinx formation if they deplete the
number of macrophages at the site.
If they are successful in showing that they can impact the
formation of a syrinx by reducing the presence of specific immune cells,
they may open up a new avenue of treatment, especially for the difficult to
treat post-traumatic syringomyelia.
--Rick Labuda
Back to Table of Contents |
Key Points
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In studying how syrinxes form,
researchers have looked at the large picture of CSF flow and at the
molecular level, the role the immune system might play
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Study created syrinxes in 30 rats by
injecting kaolin into their spinal cords
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Rats were killed and their spinal
cords examined at 3 days, 1 week, and 4 weeks after injection
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Found large number of macrophages in
the central canal near the injection site
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Authors speculate that this immune
response plays a key role in the formation of syrinxes
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Future research will look at what
happens if the production of macrophages is suppressed
Related C&S News Articles
New Theory
Speculates That Compliance Is Key To Syringomyelia And Alzheimer's
Another New Theory On How Syrinxes Form
New Theory On How Syrinxes Form
Predicting Post-Traumatic Syringomyelia.
For More Information On The Immune System: http://www.thebody.com/step/immune.html
http://health.yahoo.com/ency/adam/000821/overview
www.cs.unm.edu/~immsec/html-imm/summary.html
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