- Email: [email protected]
Neurologic Deterioration Due to Brain Sag After Bilateral Craniotomy for Subdural Hematoma Evacuation
Accepted Manuscript Neurological Deterioration Due to Brain Sag Following Bilateral Craniotomy for Subdural Hematoma Evacuation James K.C. Liu, MD PII:
S1878-8750(18)30426-1
DOI:
10.1016/j.wneu.2018.02.153
Reference:
WNEU 7568
To appear in:
World Neurosurgery
Received Date: 9 November 2017 Revised Date:
23 February 2018
Accepted Date: 26 February 2018
Please cite this article as: Liu JKC, Neurological Deterioration Due to Brain Sag Following Bilateral Craniotomy for Subdural Hematoma Evacuation, World Neurosurgery (2018), doi: 10.1016/ j.wneu.2018.02.153. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT Liu 1 1 2 3 Neurological Deterioration Due to Brain Sag Following Bilateral Craniotomy for Subdural
5
Hematoma Evacuation
6 7 8
James K. C. Liu, MD
9 Department of Neuro-Oncology
11
Moffitt Cancer Center
SC
10
13 14 Corresponding Author:
16
James K. C. Liu, M.D.
17
Department of Neuro-Oncology
18
Moffitt Cancer Center
19
MCB 2nd Floor 12531
20
Tampa, FL 33612
21
[email protected]
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Keywords: bifrontal craniotomy; intracranial hypotension; brain sag; CSF hypovolemia;
25
subdural hematoma
26
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Abbreviations: SIH spontaneous intracranial hypotension, CSF cerebrospinal fluid, CT
28
computed tomography, MRI magnetic resonance imaging
29 30 31 32 33 34
Running Title: Brain sag following bilateral craniotomies
ACCEPTED MANUSCRIPT Liu 2 ABSTRACT
36
Background: Intracranial hypotension from cerebrospinal fluid hypovolemia resulting in
37
cerebral herniation is a rare but known complication that can occur following neurosurgical
38
procedures, usually encountered in correlation with perioperative placement of a lumbar
39
subarachnoid drain. Decrease in CSF volume resulting in loss of buoyancy results in downward
40
herniation of the brain without contributing mass effect, causing a phenomenon known as ‘brain
41
sag.’ Unreported previously is brain sag occurring without concomitant occult CSF leak or
42
lumbar drainage.
43
Case Description: This case report describes a patient who underwent bilateral craniotomies
44
for subacute on chronic subdural hematomas with successful decompression, but suffered from
45
an acute neurological deterioration secondary to brain sag. Despite an initial improvement in
46
neurological exam, he subsequently exhibited a progressive neurologic deterioration with
47
evidence of cerebral herniation on neuroimaging, without evidence of continued mass effect on
48
the brain parenchyma. After a diagnosis of ‘brain sag’ was determined based on imaging
49
criteria, the patient was placed in a flat position which resulted in a rapid improvement in
50
neurological exam without any further intervention.
51
Conclusions: This case is unique from previous reports of intracranial hypotension following
52
craniotomy in that the symptoms were completely reversed with positioning alone, without any
53
evidence of active or occult CSF drainage. This report emphasizes that the diagnosis of brain
54
sag should be taken into consideration when there is an unknown reason for neurologic decline
55
after craniotomy, particularly bilateral craniotomies, if the imaging indicates herniation with
56
imaging findings consistent with intracranial hypotension, without evidence of overlying mass
57
effect.
58 59 60
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ACCEPTED MANUSCRIPT Liu 3 61 Intracranial hypotension is the result of abnormally low intracranial pressure that most
63
commonly manifests as positional headaches[1]. The most common form is spontaneous
64
intracranial hypotension (SIH), a relatively rare but known pathology that results in brain
65
herniation or sagging due to CSF hypovolemia[2-5]. SIH can commonly be misdiagnosed,
66
having the pathology attributed to a chiari malformation, compression from a subdural
67
hematoma, or possible malignancy leading to leptomeningeal enhancement[6]. It is now known
68
that SIH is often secondary to cerebrospinal fluid (CSF) hypovolemia that is often the result of
69
an occult spinal CSF leak[7]. Symptoms are typically mild positional headaches, which are
70
relieved with bed rest or epidural blood patching[8]. A few reports have noted incidences of
71
intracranial hypotension following craniotomies, particularly for treatment of aneurysms[2, 9-11].
72
Unlike SIH, neurological decline is often rapid and much more severe in these cases. The
73
authors in these reports have noted that lumbar drainage was placed during these procedures
74
to assist in intraoperative brain relaxation, and patients developed unexplained neurological
75
decline with imaging evidence of brain herniation. Neurological examination was improved with
76
subsequent stopping of lumbar drainage and with Trendelenburg positioning, resulting in a
77
reversal of ‘brain sag.’[12] This case involves brain sag secondary following a bilateral
78
craniotomy without occult CSF drainage or lumbar drain.
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79 CASE REPORT
A 65-year-old male presented to the emergency department for a history of headaches
82
and unsteady gait. CT imaging showed bilateral frontal parietal subacute on chronic subdural
83
hematomas(cSDH) (Figure 1). Neurological examination on presentation was intact except for
84
mild lethargy and confusion. The patient was taken to the operating room for bilateral
85
craniotomies for evacuation of subdural hematomas with placement of bilateral subdural drains.
86
Immediately after the procedure, he was at his neurological baseline, with improvement of
ACCEPTED MANUSCRIPT Liu 4 headaches. The patient was kept in a recumbant supine position to help with drainage of
88
residual fluid. Approximately 12 hours after procedure, the patient became progressively
89
lethargic. Subsequent imaging revealed mild re-accumulation of subdural fluid with a large
90
amount of pneumocephalus, without significant brain expansion. Approximately 36 hours after
91
the initial procedure, while still in a recumbent position, the patient acutely declined requiring
92
intubation. He was taken to the operating room for re-exploration of his bilateral craniotomies
93
and re-exploration of recurrent subdural fluid/hematomas. There was no evidence of significant
94
mass effect from re-accumulated fluid or tension pneumocephalus. Subdural drains were not
95
placed after the second procedure for concern of air trapping within the subdural space.
96
Immediately following the procedure, the patient improved neurologically, was awake and
97
following commands. In the days following the second procedure, the patient demonstrated a
98
waxing and waning mental status, with an overall slow progressive neurological decline. He
99
stopped following commands and his pupils became minimallyreactive. CT imaging noted
100
persistent pneumocephalus without evidence of subdural mass effect and lack of brain re-
101
expansion. Magnetic resonance imaging (MRI) performed five days after the second
102
decompression demonstrated uncal herniation along with brain stem sagging without any
103
evidence of supratentorial mass effect causing the herniation (Figure 2). Given the imaging
104
evidence consistent with brain sag, the patient was placed with his head of bed flat. Within 24
105
hours, the patient started to improve neurologically. The patient’s pupils started to react briskly,
106
followed by spontaneous eye opening, followed by command following within several days and
107
verbal communication. The patient was kept flat for 4 days and then gradually progressed to an
108
upright position, with continued improvement in his neurological function. At his 6-week follow-
109
up, the patient was neurologically intact with imaging showing almost complete parenchymal
110
expansion and resolution of subdural fluid collections.
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DISCUSSION
ACCEPTED MANUSCRIPT Liu 5 Intracranial hypotension describes a pathology that results in brain herniation resulting in
114
neurological symptoms and potential deficits. Clinically, the syndrome manifests initially as
115
orthostatic headaches that improves with flat positioning, but may progress to further
116
neurological deterioration[13]. Several key imaging findings are pathognomonic. On MRI there
117
is often noted to be leptomeningeal enhancement secondary to venous engorgement, as well as
118
downward displacement of the cerebellar tonsils, sagging of the midbrain, effacement of the
119
pre-pontine cisterns, enlargement of the pituitary gland, and chiasmatic drooping[4, 14, 15]. As
120
a manifestation of the loss of buoyancy from the CSF on the brain and resultant downward
121
displacement, subdural hematomas may develop. Once commonly misdiagnosed, it is now
122
better understood to be most commonly secondary to CSF hypovolemia, defined as SIH,
123
resulting in loss of buoyancy and downward displacement of the brain, tethering neurologic
124
elements. The course is typically mild and reversed through application of an epidural blood
125
patch.
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Intracranial hypotension from CSF hypovolemia following craniotomy has been much
127
less noted in the literature, with only a few reports[11, 12, 16, 17]. Unlike spontaneous
128
intracranial hypotension, a rapid herniation of brain contents can occur leading to a progressive
129
neurological deterioration. All but two cases previously reported in the literature are related to
130
lumbar CSF drainage placed during the operative procedure, primarily in aneurysm surgery for
131
intraoperative brain relaxation[10-12]. These cases have a similar etiology to SIH but presenting
132
with a more rapid course due to the loss of CSF from the craniotomy in addition to continued
133
lumbar drainage. The idea of CSF hypovolemia is further supported by the fact that authors
134
have noted in the past that replacement of intrathecal fluid through the lumbar drain has
135
reversed the process[14, 18]. What those studies failed to mention was placing the patient in a
136
flat or Trendelenburg position to utilize gravity to reverse the brain herniation effect.
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137
The post craniotomy ‘brain sag’ was noted by Komotar et al., who developed a
138
radiographical criteria for brain sag on MRI and noted it to occur in eleven patients having
ACCEPTED MANUSCRIPT Liu 6 undergone surgery for aneurysm clipping, all with intraoperative spinal drainage[12]. The
140
patients demonstrated rapid neurological decline with pupillary changes indicative of uncal
141
herniation, and all symptoms were reversed by placing the patient in a Trendelenburg (-15 to -
142
30 degree) position. There are only two reports of brain sag following craniotomy without active
143
lumbar CSF drainage. Kelley and Johnson noted a patient having undergone a bilateral
144
craniotomy for evacuation of bilateral subdural hematomas[16]. Post operatively there was
145
noted to be pneumocephalus on imaging, and the patient suffered a progressive decline in
146
neurological exam. The patient recovered quickly after placement in the Trendelenburg position.
147
Subsequently, a CSF leak was found in the thoracic spine and an epidural blood patch was
148
placed. Schievink et al. reported a case of brain sag resulting in coma after aneurysm clipping
149
that was due to CSF hypovolemia from thoracic spinal CSF leak[17].
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The case reported here is the only case of brain sag following a craniotomy without
151
associated spinal drainage of CSF. During initial workup upon presentation, a magnetic
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resonance imaging (MRI) of the spine was not performed to look for occult CSF leak since the
153
subdural fluid density was more consistent with hematoma than hygroma, and there was not a
154
reported history of positional headaches. After the initial symptomatic improvement following the
155
first procedure, the patient suffered a progressive decline in his neurological status. Typically
156
following decompression for subdural hematoma, pneumocephalus is common but there is
157
usually some expansion of the brain parenchyma, which was not seen in this case. Concern for
158
tension pneumocephalus was considered, although the diagnosis was unclear as to how much
159
pressure was being placed as there was not the typical ‘Mount Fuji’ sign[19]. After the second
160
decompression, in which there was not found to be evidence of tension pneumocephalus or
161
mass effect from re-accumulated fluid, there was again an initial improvement with subsequent
162
progressive significant neurological decline. Without a clear etiology for the neurological decline,
163
the patient was kept flat for 48 hours following drainage of a chronic SDH, and then the head of
164
the bed was gradually elevated. Without evidence of overlying mass effect causing the brain
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ACCEPTED MANUSCRIPT Liu 7 165
herniation seen on MRI, a diagnosis of brain sag was considered and the patient was placed in
166
a flat position which resulted in a brisk recovery of his neurological function. CSF hypovolemia in the setting of an occult CSF leak or active spinal drainage is well
168
known at this point. Unique to this case was the lack of spinal CSF leak, and an acute resolution
169
of symptoms purely through positioning the patient flat. The reason for this occurrence is
170
unclear. Several hypothesis may indicate why this occurs. One is patients of slightly greater age
171
may have less compliant brain resulting in sustained subdural space. Brain expansion following
172
long term compression from chronic subdural hematoma is likely to be slower in elderly patients
173
compared to younger patients. This lack of expansion has been noted in the literature, and
174
techniques such as intrathecal saline injection have been described[20, 21]. This lack of
175
elasticity may contribute to the lack of buoyancy on the brain. There could also be a relation to
176
the patient sustaining a bilateral craniotomy. In the few reports of this occurrence, regardless of
177
the presence of CSF leaks or drainage, a large percentage of bifrontal craniotomies have been
178
noted [16, 22]. The correlation between bifrontal/bilateral craniotomies may be due to excessive
179
CSF loss from a bilateral perspective, but also from bilateral air trapping, albeit not to the extent
180
of causing a tension pneumocephalus.
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Patient positioning following surgical evacuation of chronic subdural hematoma remains
182
a controversial topic. The traditional approach is to place the patient in a recumbent position
183
post-operatively to facilitate brain expansion and decrease risk of hematoma recurrence[21, 23]
184
There is concern that this may lead to an increased risk of post-operative morbidity, including
185
pneumonia, deep vein thrombosis, and urinary tract infection[24] This is countered by studies
186
that have demonstrated an increase rate of hematoma recurrence after immediate
187
immobilization, without any benefit in post-operative morbidity[25]. Although there have been no
188
definitive studies to support the best positioning of a patient follow cSDH evacuation, the
189
concept of intracranial hypotension following surgical evacuation of cSDH has been noted in the
190
literature[21, 26]. These occurrences are relatively rare, and those studies have not introduced
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ACCEPTED MANUSCRIPT Liu 8 191
radiographically whether there was imaging findings consistent with brain sag and whether a
192
recumbent position may have been helpful. Most important to note from this case is that the natural neurosurgical response to a
194
decline in mental status thought to be from brain herniation includes elevation of the head. In
195
this case, this was likely contributing to further ‘brain sag’ and neurological decline, as in the
196
immediate post-operative period this patient’s head of bed was flat and he was subsequently
197
declined. It is important for neurosurgeon’s to be aware of this pathology as this maneuver
198
would be contraindicated and the treatment would be to place the patient flat or in the
199
Trendelenburg position. Searching for an occult CSF leak if there was not a history of lumbar
200
drainage should be considered in the workup.
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201 202
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Schievink, W.I., Spontaneous spinal cerebrospinal fluid leaks: a review. Neurosurg Focus, 2000. 9(1): p. e8. Bloch, J. and L. Regli, Brain stem and cerebellar dysfunction after lumbar spinal fluid drainage: case report. J Neurol Neurosurg Psychiatry, 2003. 74(7): p. 992-4. Ferrante, E., et al., Spontaneous intracranial hypotension syndrome: report of twelve cases. Headache, 2004. 44(6): p. 615-22. Miyazawa, K., et al., CSF hypovolemia vs intracranial hypotension in "spontaneous intracranial hypotension syndrome". Neurology, 2003. 60(6): p. 941-7. Park, E.S. and E. Kim, Spontaneous intracranial hypotension: clinical presentation, imaging features and treatment. J Korean Neurosurg Soc, 2009. 45(1): p. 1-4. Schievink, W.I., Misdiagnosis of spontaneous intracranial hypotension. Arch Neurol, 2003. 60(12): p. 1713-8. Schievink, W.I., et al., Spontaneous spinal cerebrospinal fluid leaks and intracranial hypotension. J Neurosurg, 1996. 84(4): p. 598-605. Hassan, K.M., et al., Two cases of medically-refractory spontaneous orthostatic headaches with normal cerebrospinal fluid pressures responding to epidural blood patching: Intracranial hypotension versus hypovolemia and the need for clinical awareness. Ann Indian Acad Neurol, 2013. 16(4): p. 699-702. Hirono, S., et al., Life-Threatening Intracranial Hypotension after Skull Base Surgery with Lumbar Drainage. J Neurol Surg Rep, 2015. 76(1): p. e83-6. Kim, Y.S., et al., Brain stem herniation secondary to cerebrospinal fluid drainage in ruptured aneurysm surgery: a case report. Springerplus, 2016. 5: p. 247. Samadani, U., et al., Intracranial hypotension after intraoperative lumbar cerebrospinal fluid drainage. Neurosurgery, 2003. 52(1): p. 148-51; discussion 151-2. Komotar, R.J., et al., Herniation Secondary to Critical Postcraniotomy Cerebrospinal Fluid Hypovolemia. Neurosurgery, 2005. 57(2): p. 286-292.
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Chung, S.J., J.S. Kim, and M.C. Lee, Syndrome of cerebral spinal fluid hypovolemia: clinical and imaging features and outcome. Neurology, 2000. 55(9): p. 1321-7. Binder, D.K., et al., Intrathecal saline infusion in the treatment of obtundation associated with spontaneous intracranial hypotension: technical case report. Neurosurgery, 2002. 51(3): p. 830-6; discussion 836-7. Savoiardo, M., L. Farina, and L. Chiapparini, Sagging and swelling of the midbrain suggest spontaneous intracranial hypotension rather than a malformation. Brain, 2010. 133(Pt 8): p. e148; author reply e149. Kelley, G.R. and P.L. Johnson, Sinking brain syndrome: craniotomy can precipitate brainstem herniation in CSF hypovolemia. Neurology, 2004. 62(1): p. 157. Schievink, W.I., et al., Spontaneous spinal cerebrospinal fluid leak as a cause of coma after craniotomy for clipping of an unruptured intracranial aneurysm. J Neurosurg, 2009. 110(3): p. 521-4. Pleasure, S.J., et al., Spontaneous intracranial hypotension resulting in stupor caused by diencephalic compression. Neurology, 1998. 50(6): p. 1854-7. Michel, S.J., The Mount Fuji sign. Radiology, 2004. 232(2): p. 449-50. Lalonde, A.A. and W.J. Gardner, Chronic subdural hematoma; expansion of compressed cerebral hemisphere and relief of hypotension by spinal injection of physiologic saline solution. N Engl J Med, 1948. 239(14): p. 493-6. Robinson, R.G., Chronic subdural hematoma: surgical management in 133 patients. J Neurosurg, 1984. 61(2): p. 263-8. Mayberg, M., Herniation Secondary to Critical Postcraniotomy Cerebrospinal Fluid Hypovolemia. Neurosurgery, 2005. 57(2): p. 286-292 (Comment). Sivaraju, L., et al., Routine placement of subdural drain after burr hole evacuation of chronic and subacute subdural hematoma: a contrarian evidence based approach. Neurosurg Rev, 2018. 41(1): p. 165-171. Kurabe, S., et al., Efficacy and safety of postoperative early mobilization for chronic subdural hematoma in elderly patients. Acta Neurochir (Wien), 2010. 152(7): p. 1171-4. Abouzari, M., et al., The role of postoperative patient posture in the recurrence of traumatic chronic subdural hematoma after burr-hole surgery. Neurosurgery, 2007. 61(4): p. 794-7; discussion 797. Holmes, J.M., Intracranial hypotension associated with subdural haematoma. Br Med J, 1953. 1(4824): p. 1363-6.
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ACCEPTED MANUSCRIPT Liu 10 271 272 273 FIGURE LEGENDS
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Figure 1. CT imaging of the brain pre-operatively (A,B) and post-operative day one(C). Note
276
the significant amount of pneumocephalus post operatively without significant brain expansion.
277
(D) Imaging on post-operative day 2 prior to neurological decline showed minimal re-
278
accumulation of subdural fluid with persistent pneumocephalus and lack of brain re-expansion.
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Figure 2. (A) MRI performed on post operative day 5 from the second procedure shows on the
281
sagittal imaging chiasmatic drooping (long arrow), effacement of the prepontine cisterns (short
282
arrow), decreased mammilopontine distance (arrowhead), and tonsillar ectopia (double arrows).
283
(B) Coronal view shows bilateral uncal herniation without overlying convexity mass effect. (C)
284
CT imaging 6 weeks post operatively shows re-expansion of the brain parenchyma with a small
285
amount of residual subdural fluid.
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ACCEPTED MANUSCRIPT
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ACCEPTED MANUSCRIPT
Highlights 1. Intracranial hypotension secondary to CSF hypovolemia following craniotomy occurs rarely, and all previous reports have been associated with an active or occult CSF drainage.
RI PT
2. This case report is the first report of a patient undergoing a craniotomy procedure that suffered significant neurological deterioration with imaging consistent for intracranial hypotension resulting in brain sag, without evidence of CSF drainage.
SC
3. The patient was able to recover from only positional changes to reverse brain sag.
4. Intracranial hypotension following craniotomy, particular bilateral or bifrontal craniotomy,
M AN U
needs to be considered if there is neurological deterioration and evidence of brain sag on neuroimaging. This is important to note as the treatment is contrary to usual protocol of head
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elevation for cerebral herniation.
S1878-8750(18)30426-1
DOI:
10.1016/j.wneu.2018.02.153
Reference:
WNEU 7568
To appear in:
World Neurosurgery
Received Date: 9 November 2017 Revised Date:
23 February 2018
Accepted Date: 26 February 2018
Please cite this article as: Liu JKC, Neurological Deterioration Due to Brain Sag Following Bilateral Craniotomy for Subdural Hematoma Evacuation, World Neurosurgery (2018), doi: 10.1016/ j.wneu.2018.02.153. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT Liu 1 1 2 3 Neurological Deterioration Due to Brain Sag Following Bilateral Craniotomy for Subdural
5
Hematoma Evacuation
6 7 8
James K. C. Liu, MD
9 Department of Neuro-Oncology
11
Moffitt Cancer Center
SC
10
13 14 Corresponding Author:
16
James K. C. Liu, M.D.
17
Department of Neuro-Oncology
18
Moffitt Cancer Center
19
MCB 2nd Floor 12531
20
Tampa, FL 33612
21
[email protected]
EP
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15
M AN U
12
23
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4
Keywords: bifrontal craniotomy; intracranial hypotension; brain sag; CSF hypovolemia;
25
subdural hematoma
26
AC C
24
27
Abbreviations: SIH spontaneous intracranial hypotension, CSF cerebrospinal fluid, CT
28
computed tomography, MRI magnetic resonance imaging
29 30 31 32 33 34
Running Title: Brain sag following bilateral craniotomies
ACCEPTED MANUSCRIPT Liu 2 ABSTRACT
36
Background: Intracranial hypotension from cerebrospinal fluid hypovolemia resulting in
37
cerebral herniation is a rare but known complication that can occur following neurosurgical
38
procedures, usually encountered in correlation with perioperative placement of a lumbar
39
subarachnoid drain. Decrease in CSF volume resulting in loss of buoyancy results in downward
40
herniation of the brain without contributing mass effect, causing a phenomenon known as ‘brain
41
sag.’ Unreported previously is brain sag occurring without concomitant occult CSF leak or
42
lumbar drainage.
43
Case Description: This case report describes a patient who underwent bilateral craniotomies
44
for subacute on chronic subdural hematomas with successful decompression, but suffered from
45
an acute neurological deterioration secondary to brain sag. Despite an initial improvement in
46
neurological exam, he subsequently exhibited a progressive neurologic deterioration with
47
evidence of cerebral herniation on neuroimaging, without evidence of continued mass effect on
48
the brain parenchyma. After a diagnosis of ‘brain sag’ was determined based on imaging
49
criteria, the patient was placed in a flat position which resulted in a rapid improvement in
50
neurological exam without any further intervention.
51
Conclusions: This case is unique from previous reports of intracranial hypotension following
52
craniotomy in that the symptoms were completely reversed with positioning alone, without any
53
evidence of active or occult CSF drainage. This report emphasizes that the diagnosis of brain
54
sag should be taken into consideration when there is an unknown reason for neurologic decline
55
after craniotomy, particularly bilateral craniotomies, if the imaging indicates herniation with
56
imaging findings consistent with intracranial hypotension, without evidence of overlying mass
57
effect.
58 59 60
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ACCEPTED MANUSCRIPT Liu 3 61 Intracranial hypotension is the result of abnormally low intracranial pressure that most
63
commonly manifests as positional headaches[1]. The most common form is spontaneous
64
intracranial hypotension (SIH), a relatively rare but known pathology that results in brain
65
herniation or sagging due to CSF hypovolemia[2-5]. SIH can commonly be misdiagnosed,
66
having the pathology attributed to a chiari malformation, compression from a subdural
67
hematoma, or possible malignancy leading to leptomeningeal enhancement[6]. It is now known
68
that SIH is often secondary to cerebrospinal fluid (CSF) hypovolemia that is often the result of
69
an occult spinal CSF leak[7]. Symptoms are typically mild positional headaches, which are
70
relieved with bed rest or epidural blood patching[8]. A few reports have noted incidences of
71
intracranial hypotension following craniotomies, particularly for treatment of aneurysms[2, 9-11].
72
Unlike SIH, neurological decline is often rapid and much more severe in these cases. The
73
authors in these reports have noted that lumbar drainage was placed during these procedures
74
to assist in intraoperative brain relaxation, and patients developed unexplained neurological
75
decline with imaging evidence of brain herniation. Neurological examination was improved with
76
subsequent stopping of lumbar drainage and with Trendelenburg positioning, resulting in a
77
reversal of ‘brain sag.’[12] This case involves brain sag secondary following a bilateral
78
craniotomy without occult CSF drainage or lumbar drain.
EP
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SC
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62
80 81
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79 CASE REPORT
A 65-year-old male presented to the emergency department for a history of headaches
82
and unsteady gait. CT imaging showed bilateral frontal parietal subacute on chronic subdural
83
hematomas(cSDH) (Figure 1). Neurological examination on presentation was intact except for
84
mild lethargy and confusion. The patient was taken to the operating room for bilateral
85
craniotomies for evacuation of subdural hematomas with placement of bilateral subdural drains.
86
Immediately after the procedure, he was at his neurological baseline, with improvement of
ACCEPTED MANUSCRIPT Liu 4 headaches. The patient was kept in a recumbant supine position to help with drainage of
88
residual fluid. Approximately 12 hours after procedure, the patient became progressively
89
lethargic. Subsequent imaging revealed mild re-accumulation of subdural fluid with a large
90
amount of pneumocephalus, without significant brain expansion. Approximately 36 hours after
91
the initial procedure, while still in a recumbent position, the patient acutely declined requiring
92
intubation. He was taken to the operating room for re-exploration of his bilateral craniotomies
93
and re-exploration of recurrent subdural fluid/hematomas. There was no evidence of significant
94
mass effect from re-accumulated fluid or tension pneumocephalus. Subdural drains were not
95
placed after the second procedure for concern of air trapping within the subdural space.
96
Immediately following the procedure, the patient improved neurologically, was awake and
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following commands. In the days following the second procedure, the patient demonstrated a
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waxing and waning mental status, with an overall slow progressive neurological decline. He
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stopped following commands and his pupils became minimallyreactive. CT imaging noted
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persistent pneumocephalus without evidence of subdural mass effect and lack of brain re-
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expansion. Magnetic resonance imaging (MRI) performed five days after the second
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decompression demonstrated uncal herniation along with brain stem sagging without any
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evidence of supratentorial mass effect causing the herniation (Figure 2). Given the imaging
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evidence consistent with brain sag, the patient was placed with his head of bed flat. Within 24
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hours, the patient started to improve neurologically. The patient’s pupils started to react briskly,
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followed by spontaneous eye opening, followed by command following within several days and
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verbal communication. The patient was kept flat for 4 days and then gradually progressed to an
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upright position, with continued improvement in his neurological function. At his 6-week follow-
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up, the patient was neurologically intact with imaging showing almost complete parenchymal
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expansion and resolution of subdural fluid collections.
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DISCUSSION
ACCEPTED MANUSCRIPT Liu 5 Intracranial hypotension describes a pathology that results in brain herniation resulting in
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neurological symptoms and potential deficits. Clinically, the syndrome manifests initially as
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orthostatic headaches that improves with flat positioning, but may progress to further
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neurological deterioration[13]. Several key imaging findings are pathognomonic. On MRI there
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is often noted to be leptomeningeal enhancement secondary to venous engorgement, as well as
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downward displacement of the cerebellar tonsils, sagging of the midbrain, effacement of the
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pre-pontine cisterns, enlargement of the pituitary gland, and chiasmatic drooping[4, 14, 15]. As
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a manifestation of the loss of buoyancy from the CSF on the brain and resultant downward
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displacement, subdural hematomas may develop. Once commonly misdiagnosed, it is now
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better understood to be most commonly secondary to CSF hypovolemia, defined as SIH,
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resulting in loss of buoyancy and downward displacement of the brain, tethering neurologic
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elements. The course is typically mild and reversed through application of an epidural blood
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patch.
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Intracranial hypotension from CSF hypovolemia following craniotomy has been much
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less noted in the literature, with only a few reports[11, 12, 16, 17]. Unlike spontaneous
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intracranial hypotension, a rapid herniation of brain contents can occur leading to a progressive
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neurological deterioration. All but two cases previously reported in the literature are related to
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lumbar CSF drainage placed during the operative procedure, primarily in aneurysm surgery for
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intraoperative brain relaxation[10-12]. These cases have a similar etiology to SIH but presenting
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with a more rapid course due to the loss of CSF from the craniotomy in addition to continued
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lumbar drainage. The idea of CSF hypovolemia is further supported by the fact that authors
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have noted in the past that replacement of intrathecal fluid through the lumbar drain has
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reversed the process[14, 18]. What those studies failed to mention was placing the patient in a
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flat or Trendelenburg position to utilize gravity to reverse the brain herniation effect.
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The post craniotomy ‘brain sag’ was noted by Komotar et al., who developed a
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radiographical criteria for brain sag on MRI and noted it to occur in eleven patients having
ACCEPTED MANUSCRIPT Liu 6 undergone surgery for aneurysm clipping, all with intraoperative spinal drainage[12]. The
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patients demonstrated rapid neurological decline with pupillary changes indicative of uncal
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herniation, and all symptoms were reversed by placing the patient in a Trendelenburg (-15 to -
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30 degree) position. There are only two reports of brain sag following craniotomy without active
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lumbar CSF drainage. Kelley and Johnson noted a patient having undergone a bilateral
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craniotomy for evacuation of bilateral subdural hematomas[16]. Post operatively there was
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noted to be pneumocephalus on imaging, and the patient suffered a progressive decline in
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neurological exam. The patient recovered quickly after placement in the Trendelenburg position.
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Subsequently, a CSF leak was found in the thoracic spine and an epidural blood patch was
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placed. Schievink et al. reported a case of brain sag resulting in coma after aneurysm clipping
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that was due to CSF hypovolemia from thoracic spinal CSF leak[17].
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The case reported here is the only case of brain sag following a craniotomy without
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associated spinal drainage of CSF. During initial workup upon presentation, a magnetic
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resonance imaging (MRI) of the spine was not performed to look for occult CSF leak since the
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subdural fluid density was more consistent with hematoma than hygroma, and there was not a
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reported history of positional headaches. After the initial symptomatic improvement following the
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first procedure, the patient suffered a progressive decline in his neurological status. Typically
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following decompression for subdural hematoma, pneumocephalus is common but there is
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usually some expansion of the brain parenchyma, which was not seen in this case. Concern for
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tension pneumocephalus was considered, although the diagnosis was unclear as to how much
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pressure was being placed as there was not the typical ‘Mount Fuji’ sign[19]. After the second
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decompression, in which there was not found to be evidence of tension pneumocephalus or
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mass effect from re-accumulated fluid, there was again an initial improvement with subsequent
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progressive significant neurological decline. Without a clear etiology for the neurological decline,
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the patient was kept flat for 48 hours following drainage of a chronic SDH, and then the head of
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the bed was gradually elevated. Without evidence of overlying mass effect causing the brain
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herniation seen on MRI, a diagnosis of brain sag was considered and the patient was placed in
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a flat position which resulted in a brisk recovery of his neurological function. CSF hypovolemia in the setting of an occult CSF leak or active spinal drainage is well
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known at this point. Unique to this case was the lack of spinal CSF leak, and an acute resolution
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of symptoms purely through positioning the patient flat. The reason for this occurrence is
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unclear. Several hypothesis may indicate why this occurs. One is patients of slightly greater age
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may have less compliant brain resulting in sustained subdural space. Brain expansion following
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long term compression from chronic subdural hematoma is likely to be slower in elderly patients
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compared to younger patients. This lack of expansion has been noted in the literature, and
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techniques such as intrathecal saline injection have been described[20, 21]. This lack of
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elasticity may contribute to the lack of buoyancy on the brain. There could also be a relation to
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the patient sustaining a bilateral craniotomy. In the few reports of this occurrence, regardless of
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the presence of CSF leaks or drainage, a large percentage of bifrontal craniotomies have been
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noted [16, 22]. The correlation between bifrontal/bilateral craniotomies may be due to excessive
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CSF loss from a bilateral perspective, but also from bilateral air trapping, albeit not to the extent
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of causing a tension pneumocephalus.
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Patient positioning following surgical evacuation of chronic subdural hematoma remains
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a controversial topic. The traditional approach is to place the patient in a recumbent position
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post-operatively to facilitate brain expansion and decrease risk of hematoma recurrence[21, 23]
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There is concern that this may lead to an increased risk of post-operative morbidity, including
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pneumonia, deep vein thrombosis, and urinary tract infection[24] This is countered by studies
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that have demonstrated an increase rate of hematoma recurrence after immediate
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immobilization, without any benefit in post-operative morbidity[25]. Although there have been no
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definitive studies to support the best positioning of a patient follow cSDH evacuation, the
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concept of intracranial hypotension following surgical evacuation of cSDH has been noted in the
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literature[21, 26]. These occurrences are relatively rare, and those studies have not introduced
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radiographically whether there was imaging findings consistent with brain sag and whether a
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recumbent position may have been helpful. Most important to note from this case is that the natural neurosurgical response to a
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decline in mental status thought to be from brain herniation includes elevation of the head. In
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this case, this was likely contributing to further ‘brain sag’ and neurological decline, as in the
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immediate post-operative period this patient’s head of bed was flat and he was subsequently
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declined. It is important for neurosurgeon’s to be aware of this pathology as this maneuver
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would be contraindicated and the treatment would be to place the patient flat or in the
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Trendelenburg position. Searching for an occult CSF leak if there was not a history of lumbar
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drainage should be considered in the workup.
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Figure 1. CT imaging of the brain pre-operatively (A,B) and post-operative day one(C). Note
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the significant amount of pneumocephalus post operatively without significant brain expansion.
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(D) Imaging on post-operative day 2 prior to neurological decline showed minimal re-
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accumulation of subdural fluid with persistent pneumocephalus and lack of brain re-expansion.
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Figure 2. (A) MRI performed on post operative day 5 from the second procedure shows on the
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sagittal imaging chiasmatic drooping (long arrow), effacement of the prepontine cisterns (short
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arrow), decreased mammilopontine distance (arrowhead), and tonsillar ectopia (double arrows).
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(B) Coronal view shows bilateral uncal herniation without overlying convexity mass effect. (C)
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CT imaging 6 weeks post operatively shows re-expansion of the brain parenchyma with a small
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amount of residual subdural fluid.
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Highlights 1. Intracranial hypotension secondary to CSF hypovolemia following craniotomy occurs rarely, and all previous reports have been associated with an active or occult CSF drainage.
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2. This case report is the first report of a patient undergoing a craniotomy procedure that suffered significant neurological deterioration with imaging consistent for intracranial hypotension resulting in brain sag, without evidence of CSF drainage.
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3. The patient was able to recover from only positional changes to reverse brain sag.
4. Intracranial hypotension following craniotomy, particular bilateral or bifrontal craniotomy,
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needs to be considered if there is neurological deterioration and evidence of brain sag on neuroimaging. This is important to note as the treatment is contrary to usual protocol of head
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elevation for cerebral herniation.