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Table of Contents
brainstem - base of the brain which connects to the spinal cord
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 Chiari
II - more severe form of malformation which involves descent of parts of
the brainstem and is usually associated with Spina Bifida cisterna
magna - CSF filled space below the cerebellum
craniosynostosis - premature fusion of the sutures of the skull in an
infant; results in an abnormally shaped head
decompression surgery - common term for any of several variations of
a surgical procedure to alleviate a Chiari malformation
dura - thick outer layer covering the brain and spinal cord
duraplasty - surgical procedure where a patch is sewn into the dura
foramen magnum - opening at the base of the skull, through which the
spinal cord passes
laminectomy - surgical removal of part (the bony arch) of one or more
vertebrae
stent - tube used to support an opening in the body
suboccipital
craniectomy - surgical removal of part of the skull, or cranium, in the
back of the head, near the base
syringomyelia - neurological condition where a fluid filled cyst
forms in the spinal cord vertebra - segment
of the spinal column ventricle
- CSF filled space in the brain, 4th ventricle drains into the spinal system |
A Harvard pediatric neurosurgeon has weighed in on the important question of
why decompression surgeries fail. Dr. R Michael Scott, Director of
Clinical Pediatric Neurosurgery at Children's Hospital Boston, along with
his colleague Dr. David Sacco, reviewed the hospital records, medical
imaging, operative reports, and follow-up data of patients who were
undergoing a reoperation for Chiari malformation during the past 14 years
and compared the data to patients who were undergoing their first operation.
The researchers specifically were trying to determine if age at time of
first surgery, type of Chiari malformation (I vs. II), bony abnormalities,
and/or initial operative technique contribute to the need for reoperation.
They published their results in the October issue of the journal Pediatric
Neurosurgery.
Of 133 operations for Chiari I or II that
were performed, 22 (17%) represented reoperations. This failure rate
is in-line with other reported failure rates (which go as high as 30%).
Interestingly, the reoperation rates for Chiari I and Chiari II were almost
identical, with 16 out of 100 Chiari I surgeries being reoperations and 6
out of 33 Chiari II surgeries being reoperations. Also of note is the
fact that exactly half of the reoperations (11) were required within 1 year
of the initial surgery and half (11) were not performed until more than a
year from the time of the initial surgery. Reasons for reoperation
included a persistent syrinx in 11 patients, continued neurological symptoms
in 9 patients, and problems with stent placement in 2 patients.
Although not stated explicitly in the research paper, the reporting
surgeon's failure rate (for initial surgeries) can be deduced as 12.6% -
this assumes patients for whom the surgery failed returned to see him.
The surgical procedure used was
similar for most patients and for Chiari I patients included a suboccipital
craniectomy, C1 laminectomy, duraplasty, and reduction of the cerebellar
tonsils. In patients who also had syringomyelia, the outlet of the 4th
ventricle was carefully examined and any scarring or blockage was removed.
In addition, in most syringomyelia patients, a stent was placed in the 4th
ventricle to allow for adequate drainage of CSF. In the first several
years of the series, the top of the central canal - the obex - was also
plugged. Chiari II patients underwent a similar procedure although
with a more limited craniectomy and a more expansive laminectomy.
In looking at patient age at time of
initial surgery, the researchers found that of the 43 patients whose initial
surgery occurred when they were younger than 5 years old, 11 required
reoperation (26%). In contrast, of the 90 patients who were older than
5, only 10 required additional surgery (11%). True statistical
analysis was not possible given the nature of the study, however these
results do indicate that a young age at time of initial surgery may play a
role in the need for further operations. The authors point out that
patients at a very young age are able to regrow bone which can cause
compression again. They also point out that some surgeons try to
remove a minimal amount of bone when decompressing a young child, and while
this may seem like a good idea, it may also lead to the need for further
operations.
The researchers also found an apparent
association between skull anomalies - craniosynostosis - and the need for
reoperation. There is an established link between abnormal skull shape
and Chiari malformation, but this study also found that out of 9 patients
with craniosynostosis, 5 were undergoing a reoperation. The authors
speculate that a complicated - and confusing - bone structure around the
foramen magnum can lead to an inadequate decompression unless it is
carefully studied and understood by the neurosurgeon. In addition,
craniosynostosis likely leads to abnormal CSF dynamics and may cause
persistent problems that are difficult to resolve with decompression
surgery.
The final factor the researchers examined
as a cause of surgical failure was operative technique. Five of the
reoperations that were performed were necessitated by problems with a fourth
ventricle catheter - or stent. While the authors believe in using a
catheter in patients with syringomyelia, they acknowledge that problems can
develop if the tubing is too long or is not placed properly.
Although somewhat downplayed by the
authors, it is disheartening to note that 6 patients failed to improve even
after reoperation. This means the failure rate among the reoperations
was 28%. 3 patients with a persistent syrinx did not improve, 2
patients continued to experience their main neurological problem, and one
Chiari II patient developed new neurological problems 4 years later -
although the authors do not believe the new problems were due to Chiari.
So why do surgeries fail? While this study
is far from conclusive, it does appear that for pediatric
patients young age at time of initial surgery, bony abnormalities, and stent
failure may contribute to surgical failure. It also provides more evidence
that absolute failure - meaning an explicit need for additional surgery -
occurs between 10%-20% of the time.
Back to Table of Contents |
Key Points
-
Goal of study was to identify
characteristics of patients who required a second surgery for CM
-
Of 133 surgeries - over the past
14 years - 17% (22) were second, or reoperations
-
Reasons for reoperation included:
persistent syrinx, continued neurological symptoms, and misplaced shunts
-
Factors influencing need for
reoperation include: misshaped skull (craniosynostosis), young age
at first surgery, and problems with initial surgical technique -
specifically, failure to ensure proper CSF flow out of 4th ventricle
-
Second surgeries did not always
help; 3 out of 10 reoperations for persistent syrinx didn't work and 2 out
of 5 reoperations for neurological symptoms were not successful
Meet The Surgeon
R Michael Scott, MD
Professor of Neurosurgery, Harvard University
Clinical Title:
Director of Clinical Pediatric Neurosurgery, Children's Hospital
Boston Education:
-
Fellowship -
Boston City Hospital; Boston, MA '73
-
Residency -
Massachusetts General Hospital; Boston, MA '69-'73
-
Internship -
Boston City Hospital; Boston, MA '66-'67
-
Medical School
- Temple University School of Medicine; Philadelphia, PA '66
Areas of
Expertise:
-
Vascular
malformations
-
Congenital
malformations
-
Myelodysplasia
-
Brain tumors
-
General
neurosurgery
Source:
Children's Hospital Boston web site |