Introduction
Spontaneous intracranial hypotension (SICH) is a clinical condition resulting from
reduced intracranial pressure that causes imbalances between the blood, cerebrospinal
fluid (CSF), and the brain parenchyma. This occurs more commonly secondary to spinal
CSF leak into the epidural space or to adjacent venous channels. Even though the name
suggests intracranial hypotension, hypotension is not always demonstrated on lumbar
puncture and the CSF leak at the skull base rarely results in intracranial hypotension
and hence it should be renamed as spontaneous spinal CSF leak syndrome. SICH can also
be termed as CSF hypovolemia, CSF volume depletion, and low CSF volume headache. Spinal
CSF leaks are increasingly recognized in recent times due to improved imaging techniques
and detection with increasing awareness.
The pathophysiology is understood by Monro-Kellie doctrine where the volume of CSF,
blood, and brain parenchyma remains constant in dynamic equilibrium. For instance,
in patients with CSF leak, there is reduction in the CSF volume, which results in
compensatory dilatation or engorgement of the intracranial and epidural venous structures
to maintain the intracranial pressure causing clinical symptoms accordingly ([Chart 1]). Buoyancy of the brain is also reduced in leak patients.[1] Reduced CSF in the brain causes stretching of the pain sensitive meningeal structures
and subsequent venous engorgement results in headache.
The knowledge of physiology of normal intracranial pressure is necessary to understand
the mechanism of hypotension in SICH .
patients. There are two points of neuroaxis that play major roles in maintaining the
equilibrium. These include hydrostatic indifference point (HIP) and zero CSF pressure
in sitting (ZPS). HIP is a point located in the lower cervical or upper thoracic region
spinal region, corresponding with the venous pressure at atmospheric level. At this
level, the pressure recorded in sitting and lying down position is same. ZPS is located
between occipital protuberance and spinous process of seventh cervical vertebra. CSF
pressure is negative above ZPS level and positive below this level.
The physiology of orthostatic headache in SICH is that when the person is upright,
the CSF pressure is more than the atmospheric pressure. In patients with spinal CSF
leaks, pressure point moves downwards, resulting in negative intracranial pressure
compared to the spine. However, on lying down, headache resolves on lying down as
the pressure attains equilibrium with the point coming back to the normal position.[2]
[3] This is the same reason why skull base leaks do not result in symptoms of SICH.
Clinical Features
SICH is the one of the most important and under diagnosed causes of daily disabling
headache with an incidence of 1 in 50000. Underdiagnosis of SICH has led to chronic
neurodisabilities despite being a treatable condition. Females are more commonly affected
than men. Headache in SICH worsen over the second half of the day and may also worsen
during Valsalva maneuver. Predisposing factors include connective tissue disorders
causing meningeal disruption, discal spur, and marginal osteophyte.
SICH is an elusive disorder and can mimic many other conditions. The commonest clinical
presentation is orthostatic headache, which aggravates against sitting or standing
and relieved on lying down. In rare and severe cases, patient may present with dementia,
symptoms of brain and/ or spinal cord herniation.[4]
[5]
[Table 1] summarizes the symptoms or presentations of SICH.
Table 1
Clinical presentations in SICH patients
|
Back/neck pain
|
Paresthesia/ facial numbness
|
|
Vomiting/nausea
|
Hemifacial spasm
|
|
Hearing loss
|
Personality changes
|
|
Tinnitus, vertigo
|
Gait ataxia
|
|
Muffled hearing
|
Frontotemporal dementia
|
|
Photophobia
|
Encephalopathy
|
|
Diplopia/blurred vision
|
Parkinsonian symptoms like tremors/ chorea
|
|
Isolated cranial nerve palsies
|
PRES/CVT/SDH
|
|
Amyotrophic symptoms like amyotrophic lateral sclerosis
|
Lethargy and coma
|
Abbreviations: CVT, cortical vein thrombosis; PRES, posterior reversible encephalopathy
syndrome; SDH, subdural hematoma; SICH, spontaneous intracranial hypotension.
Differential diagnoses include orthostatic hypotension, cervicogenic headache, postural
tachycardia syndrome, and migraine.[5] However, typical history and clinical examination would rule out other causes.
There are few imaging and clinical findings that form the diagnostic criteria for
SICH, and these include [Table 2].[6]
[7]
[8]
[9]
Table 2
Criteria for diagnosing SICH
|
1.
|
Brain and spine imaging signs of CSF leak
|
|
2.
|
CSF pressure less than 6 cm H2O
|
|
3.
|
Characteristic orthostatic headache
|
|
4.
|
Symptoms of headache developing in conjunction with low CSF pressure of CSF leak detection
|
|
5.
|
No causative mechanism that could be explained by another diagnosis
|
|
6.
|
Improvement following epidural blood patch
|
Abbreviations: CSF, cerebrospinal fluid; SICH, spontaneous intracranial hypotension.
As SICH is caused by CSF leaks in the spine, three types of leaks are described accordingly
depending on the site of leak and whether epidural collection is present or not ([Table 3]).[8]
[10]
[11]
Table 3
Types of spinal CSF leaks ([Fig. 1])
|
Type 1
|
Dural tear: SLEC positive
1A—Ventral tear
1B—Lateral tear
|
|
Type 2A
|
SLEC positive—proximal nerve root sleeve tear/ meningeal diverticular/ dural ectasia
|
|
Type 2B
|
SLEC negative—distal nerve root sleeve tear
|
|
Type 3
|
CSF venous fistula (CVF)
|
Abbreviations: CSF, cerebrospinal fluid; CVF, CSF venous fistula; SLEC, spinal longitudinal
epidural collection.
Leaks can be categorized as fast or slow leaks. Fast leaks are seen following ventral
dural tear. Slow leaks occur in nerve root sleeve tear and CSF venous fistula (CVF).
Tears in the dura can occur ventrally or laterally. An osteophyte or degenerative
disc microspur causes anterior longitudinal tears in the spinal dura and is more commonly
seen at upper thoracic levels due to minimal flexibility of the spine along this region,
although lower cervical and lumbar dural tears have also been reported. In type 1
spinal leak, there will be epidural collection due to the ventral dural defect that
is associated with a discal spur or an osteophyte at the site of leak. It occurs frequently
in middle aged females with lesser or normal resting metabolic rate, although the
incidence in men is not very uncommon in recent times.[10]
[12] Type 2 leaks are classified further as spinal longitudinal epidural collection positive
(SLEC-P) which means there is definite spinal longitudinal epidural collection and
SLEC negative (SLEC-N) where there is no epidural collection. SLEC-P type 2A leaks
occur due to lateral dural tear wherein nerve root sleeve tear occurs proximally with
positive SLEC. Other examples are the ruptured meningeal diverticulum and absent nerve
root sleeve. These occur between the epidural space and neural foraminal compartment,
resulting in definite epidural CSF collection. Meningeal diverticula are frequently
seen in patients with connective tissue disorders like Marfan syndrome, neurofibromatosis,
and Ehlers–Danlos syndrome. In type 2B SLEC-N leak, far lateral dural tear or nerve
root sleeve tear occurs distally and CSF leaks into the adjacent fascia or connective
tissue without any epidural collection. In type 3 leak, the CSF enters directly into
the venous channels and hence no epidural collection (SLEC-N).[9] CVFs are more commonly seen along the lower thoracic spine and in elderly.[12] They may be associated with meningeal diverticulum that is seen as perineural cyst.
Such cysts may give rise to CVFs acting as a nidus. CVFs lack dural defect and are
seen near nerve root sleeve diverticula close to paraspinal veins.[13]
Other or secondary causes of spinal CSF leaks include injuries to the dura mater following
lumbar puncture, spinal anesthesia or surgeries, trauma, and post-ventriculoperitoneal
shunt of which post-lumbar puncture intracranial hypotension is more common than other
causes.[14] The dural defect is posterior and lumbar in location in these causes as compared
to anterior or lateral in SICH, but the pathophysiology is the same regardless of
the cause. Post-dural puncture headache may appear as new daily onset headache after
many years of prior dural puncture. There can be an arachnoid bleb formation at the
puncture site. Use of atraumatic or pencil point needles over cutting edge needles
during lumbar puncture would reduce many complications including post-dural puncture
headaches.[15]
[16]
Imaging Features
There are few characteristic brain and spine imaging features that suggest intracranial
hypotension. Magnetic resonance imaging (MRI) including brain and spine with contrast
is the imaging investigation of choice where SICH is suspected clinically due to the
clinical symptoms. Computed tomography (CT) brain is not recommended as the temporal
resolution is lesser than MRI. However, in few cases, where there is no clinical suspicion
of SICH, CT may be the initial imaging modality by the clinicians to look for any
cause of headache. CT of the whole spine is important to detect the osteophyte or
the discal spur that may be the cause of SLEC-P SICH as CT is sensitive for any bone
pathology and serves as complimentary imaging to MRI study. Brain findings remain
the same for all cases of intracranial hypotension regardless the cause.
A description of the MRI protocol is given in [Table 4], which includes brain and spine sequences.[9]
Table 4
MRI brain and spine sequences recommended in SICH patients
|
Brain sequences (4–5 mm thickness or 3D sequences if available)
|
Spine sequences (3–4 mm thickness)
|
|
T2W axial 3D—Look for subdural collections/venous sinuses, look for sagging of brainstem&
SICH scoring
|
T2W sagittal (with and without fat suppression)Whole spine screening - to look for
epidural collection
|
|
Flair axial/3D sagittal—Look for collection/ venous sinuses
|
T2W axial—in the region of epidural collection
|
|
SWI—To look for hemorrhage including CVST and its complications if any
|
3D heavily T2W (FIESTA/CISS)—To look for meningeal diverticula, dural tear and extent
of epidural collection
|
|
T1W pre- and post-contrast—To look for pachymeningeal thickening and enhancement
|
|
Abbreviations: 3D, three-dimensional; CISS, constructive interference in steady state;
CVST, cerebral venous sinus thrombosis; FIESTA, fast imaging employing steady state
acquisition; MRI, magnetic resonance imaging; SICH, spontaneous intracranial hypotension;
SWI, sagittal-weighted imaging; T1W, T1-weighted.
Below are the distinctive intracranial and spine imaging characteristics.
Intracranial Findings (SEEPS)
-
Subdural collection (bilateral)
-
Enhancement of the pachymeninges
-
Engorgement of dural venous sinuses
-
Paucity of bilateral perioptic CSF
-
Pituitary hyperemia
-
Sagging of the brain
-
Superficial siderosis
The initial imaging finding is the venous sinus engorgement or distension that is
easily detected in the transverse and straight sinuses. These sinuses have flattened
or concave borders normally. The concave border of the transverse sinus is seen on
sagittal images. In patients with intracranial hypotension, the venous sinus borders
appear bulged and convex.[17] Pachymeningeal thickening with enhancement is the next imaging feature to appear.
The thickening is smooth/non-nodular and requires contrast imaging to be appreciated.
This is due to the noninflammatory fibrocollagenous proliferation of the meninges
because of persistent vascular engorgement and transudation of intravascular fluid
into the adjacent subdural space. On further progression/persistence of the CSF leak,
to maintain the volume within the intracranial space, subdural collection occurs secondary
to passive transudation from the intravascular space into the subdural space. The
collection may be hemorrhagic in nature but always bilateral and more commonly seen
along the frontoparietal convexities.[14] Among these signs, venous distension is very specific to diagnose low intracranial
pressure. Pituitary engorgement is another important imaging sign where it enlarges
up to 8 to 11 mm in height. However, while recovering, it reverses sooner than pachymeningeal
enhancement. Another important finding is sagging of the brain secondary to loss of
buoyancy of the brain. This is seen on imaging as down sloping of the floor of third
ventricle, mamillary body descent, and effaced basal cisternal spaces. Reduced perioptic
CSF fluid is another imaging finding that supports the diagnosis of intracranial hypotension.
All these findings reverse back to normal following treatment ([Fig. 2A–H]). [Fig. 3] illustrates other miscellaneous imaging features. All the findings are detected
on MRI. CT is not very sensitive to detect these findings other than subdural collection.
CT may also show pseudosubarachnoid hemorrhage when there is brain sagging and effaced
cisternal spaces.
Fig. 1 Types of spontaneous intracranial hypotension (SICH). (A) Type 1 SICH showing spinal ventral dural tear due to calcified discal spur (thick
arrows). Curved arrows point to the route of cerebrospinal fluid (CSF) leak into epidural
space. (B) Type 2 SICH showing proximal nerve root sleeve tear (thick arrows) points to the
meninges, diverticulum with tear. Short thin arrow points to the route of CSF leak.
(C) Type 3 SICH showing CSF venous fistula (thick arrow) points to site of CSF venous
fistula. (D) Type 2 SICH showing distal nerve root sleeve tear/ meningeal diverticular rupture/
dural ectasia (thick long arrow) leaked CSF (asterisk), and intact posterior dura
(thick short arrow).
Fig. 2 Sequence of magnetic resonance imaging findings in spontaneous intracranial hypotension.
(A) Sagittal T2 image through the brain showing enlarged tortuous straight sinus (white
arrow). (B) Sagittal T1 post-contrast image showing rounded venous sinuses with convexed inferior
borders (white arrow). (C) Axial T1-weighted post-contrast image showing non-nodular, diffuse supratentorial
pachymeningeal thickening with enhancement (white arrows). (D) Axial fluid-attenuated inversion recovery image showing bilateral cerebral convexity
subdural collections (white arrows). (E) Sagittal T1 image of the brain showing sagging of the parenchyma into the foramen
magnum (white arrow). (F) Axial T2 image showing increased anteroposterior diameter of the midbrain with squeezing
(white arrow). (G) Coronal T2-weighted image showing reduced cerebrospinal fluid around the bilateral
optic nerves (black arrows). (H) Sagittal T2 image showing pituitary engorgement seen as enlarged dome like pituitary
(white arrow).
Fig. 3 Miscellaneous imaging findings to diagnose spontaneous intracranial hypotension (SICH).
(A) Sagittal noncontrast T1 image through the brain showing flattened ventral pons (asterisk),
narrowing of prepontine cistern (long arrow), and reduced mamillopontine distance
(short arrow). (B) Axial T2 image showing narrowing of interpeduncular cistern (white lines). (C) Axial contrast T1 image showing slit-like ventricles (white arrows). (D) Patient with Arnold Chiari malformation type 1 reveals sagittal T1 non-contrast
image showing normal iter, tonsillar herniation with peg like tonsil (black arrow),
and normal pons and prepontine cistern (white arrow). (E) Patient with SICH showing iter below the incisura, tonsillar herniation with normal
shaped tonsil (black arrow), flattened pons with reduced prepontine distance (white
arrow).
The probability of CSF leak is assessed using Bern scoring system as low, intermediate,
and high with scores of 2 or less, 3 to 4, 5 and more, respectively. This system includes
only intracranial findings and does not consider SLEC. Bern scoring system is as follows[9] ([Table 5]).
Table 5
Major and minor criteria of Bern/SICH scoring system
|
Major criteria (2 points each)
|
Minor criteria (1 point each)
|
|
Venous sinus engorgement
|
Subdural collection
|
|
Pachymeningeal enhancement
|
Prepontine cistern of 5 mm or less
|
|
Suprasellar cistern of 4 mm or less
|
Mamillopontine distance of 6.5 mm or less
|
Abbreviation: SICH, spontaneous intracranial hypotension.
Spine Findings
-
Epidural collection (anterior / posterior)
-
Dural defect
-
Meningeal diverticulum/ Perineural cyst
-
Engorged vertebral venous plexus/epidural veins
-
Spinal cord signal intensity changes
Out of all the sequences, T2 is the most useful sequence to rule out SLEC and if present
is termed as SLEC-P SICH. SICH can also present without SLEC and is termed as SLEC-N
SICH. These SLEC-P SICH are fast leakers that are seen in type 1 and type 2 leaks.
Type 3 that includes CVF is a slow leaker without SLEC. The resolution of three-dimensional
heavily T2-weighted imaging may help in detecting the site of the dural tear in fast
leakers. However, MRI spine has limited outcome in patients with CVF as the fistula
is not seen in this modality. In a patient with high clinical suspicion of intracranial
hypotension without any brain or spine imaging features, CVF needs to be ruled out.
Further investigation of choice is digital subtraction myelography (DSM). Plain CT
scan of the whole spine is to be very useful in detecting the discal spur or osteophyte
responsible for the spinal leak ([Figs. 4] and [5]).
Fig. 4 Types of spontaneous intracranial hypotension (SICH) on cross-sectional imaging.
(A) Type 1 SICH with calcified disc spur (arrow). (B and C) Type 2 SICH showing multiple meningeal diverticula on both sides. (D) Type 3 SICH reveals cerebrospinal fluid venous fistula (arrow).
Fig. 5 Spinal imaging findings in spontaneous intracranial hypotension. (A) Sagittal short tau inversion recovery sequence of thoracic spine showing posterior
epidural collection (arrows). (B) Axial T2 image of the thoracic spine showing prominent epidural veins (thick arrows).
Patients with secondary causes of hypotension have similar intracranial imaging findings
and spine imaging findings include spinal epidural collection at the site of defect
depending on the respective causes.
Chronic SICH
Chronic complications/ findings in untreated patients of SICH include ([Fig. 6]):
Fig. 6 Imaging findings indicating chronicity of spontaneous intracranial hypotension. (A) Axial susceptibility-weighted image of the brain showing blooming in the region
of bilateral cerebellar folia, suggesting superficial siderosis (arrows). (B) Axial T2 weighted image of thoracic spine showing rounded spinal epidural collection
in the anterior aspect. (C) Axial plain computed tomography bone window of the head showing thickened cortex
(arrow).
-
Superficial siderosis is commonly seen in posterior fossa involving superior cerebellar
foliae and occurs due to bleeding from the friable epidural veins at the site of dural
tear.[9]
-
Bibrachial amyotrophy. This feature is seen in chronic SLEC-P patients as the collection
compresses the anterior horn cells of the spinal cord and stretches the cervical nerve
roots resulting in atrophy.[18]
[19]
-
The longitudinal spinal collection appears more loculated with rounded margins and
with or without thin septations like pseudomeningocele.
-
Calvarial thickening with/without prominent transosseous venous collaterals. Thickening
of the calvarium in SICH is a compensatory mechanism for the depleted CSF volume.
Typically, the thickening occurs along the inner table, more so involving the frontal
bone, giving rise to an appearance of layer cake skull.[20]
Uncommon Findings in SICH[21]
-
Ischemia is secondary to brain herniation.
-
Venous sinus thrombosis due to venous engorgement and stasis.
-
Spinal subarachnoid hemorrhage and hemosiderosis.
-
Dural calcifications may occur sequelae to chronic blood product deposition secondary
to repeated hemorrhage from the epidural venous plexus.
Mimics of SICH[22]
-
Arnold Chiari 1 malformation
-
Other causes of subdural collection
-
Other causes of pachymeningeal thickening
-
Postural orthostatic tachycardia syndrome (POTS)
-
Migraine
Arnold Chiari 1 is a very close mimicker of SICH. Few characteristic imaging findings
distinguish between the two and the differences are summarized in [Table 6].
Table 6
Differences between Arnold Chiari 1 and SICH
|
Arnold Chiari malformation 1
|
SICH
|
|
Tonsils
|
Peg like
|
Normal shape
|
|
Tonsillar ectopia
|
More
|
Less
|
|
Midbrain
|
No descent
|
Descent
|
|
Iter
|
Normal
|
Below incisura
|
|
Pons
|
Normal
|
Effaced prepontine effacement and flattened ventral pons
|
|
Corpus callosum
|
Normal
|
Drooping of splenium
|
|
Contrast
|
Nil
|
Pachymeningeal enhancement
|
|
SDH
|
Nil
|
Common
|
|
Syrinx and/or hydrocephalus
|
Associated
|
Rare
|
|
Third ventricular floor descent
|
> 15 degrees
|
< 15 degrees
|
|
Pontomesenchymal angle
|
> 45 degrees
|
< 45 degrees
|
Abbreviations: SDH, subdural hematoma; SICH, spontaneous intracranial hypotension.
Other causes of subdural collection may include trauma, bridging vein rupture in elderly
following minor trauma. However, these are frequently on one side and rarely bilateral
unlike SICH that is always bilateral. Pachymeningeal thickening can also be seen in
other conditions like IgG4-related disease, neurosarcoidosis, histiocytosis, other
autoimmune conditions, and infections including tuberculosis. In these conditions,
other sites, which include brain parenchyma, cranial nerves, and bone may also be
affected. In intracranial hypotension, the pachymeningeal thickening is smooth and
non-nodular.[24]
Clinically, few conditions mimic SICH and these are POTS, vestibular migraine, orthostatic
hypotension, and cervicogenic headache. POTS patients also develop headache worsening
in standing or upright position. Heart rate and blood pressure while sitting and standing
would help in diagnosing POTS as these patients typically have rapid increase in heart
rate on standing with relatively stable blood pressure. Cervicogenic headache is due
to osteoarthritic changes of the cervical spine. Vestibular migraine is diagnosed
by the presence of associated vertigo.[22]
Further Managing SICH
Dynamic CT myelogram (CTM) or DSM performed to confirm spinal leak. Both the techniques
involve expertise and radiation exposure. Myelogram confirms the site of dural tear,
detection of meningeal diverticulum and CVF. Both the techniques are invasive in nature.
Ultrafast CT Myelography Technique
Patient is positioned in prone Trendelenburg position. By using the lumbar puncture
technique, 10 mL of 300mg I/mL iodinated contrast is injected into the thecal sac
and real time serial images are taken while injecting the contrast. Back and forth
table movement in the CT gantry is accompanied by image acquisition every 10 to 20 seconds.
In case of SLEC-N leaks, lateral decubitus position is suitable, although CTM may
be negative in CVF and hence DSM is used.[23] In the event of contrast extravasation into the epidural space, the procedure must
be stopped.[14] In fast leakers, the contrast enters the epidural space. If the imaging is quickly
performed, the site of leak can be readily detected. In case of CVFs, CTM may show
prominent paraspinal vein with adjacent small foraminal radicular veins.
Digital Subtraction Myelogram
It has greater temporal resolution than convention techniques, but limited coverage
as DSM makes use of planar images.[25] Lateral decubitus position is preferred to demonstrate CVFs. A newer technique has
been recently described for better appreciation of CVF. It is a two-day procedure
carried out with right lateral decubitus on day 1 and repeating the same in left lateral
decubitus on the day 2. To increase the sensitivity of detection of CVF in DSM, few
modifications are suggested including respiratory modulation. It is based on the principle
of changes in venous pressure secondary to changes in the intrathoracic pressure during
different phases of respiration. This technique involves breathing continuously into
a 5 mL syringe between the lips and image acquisition during breathing into the syringe
and finally during Valsalva maneuver. There is disappearance of the prominent paraspinal
vein and appearance of a prominent external epidural vein during Valsalva.
On CTM, false localizing sign has been described. This sign depicts retrospinal fluid
collections at C1-C2 level in patients with intracranial hypotension that occurs as
the epidural fluid escapes into the retrospinal soft tissues.[27]
[28]
Treatment
Fig. 7 Computed tomography (CT) myelogram procedure. (A) Injecting CT contrast through lumbar puncture technique in Trendelenburg position.
(B) Sagittal CT myelogram showing bony spicule along the posterior aspect of the disc
(arrow). (C) Epidural air confirms the needle is in epidural space before injecting autologous
blood (yellow arrow). (D) Localized epidural blood patch (EBP) in prone position.
Conservative Approach
Hydration and absolute bed rest may be tried but do not respond in many cases. Oral
caffeine and abdominal binders may be tried but not at the expense of other definitive
management ([Fig. 7]).
Epidural blood patch (EBP) can be given empirically or targeted. This is done following
no more than 2 weeks of conservative management by performing CTM. Conventional CTM
is not useful in fast leakers especially those with type 1 SICH and requires ultrafast
dynamic CTM (UFCTM). As part of the radiological intervention for SLEC-P cases, UFCTM
is performed to localize the rent followed by 8 to 10 mL of autologous EBP mixed with
approximately 1 mL of iodinated contrast into the epidural space. EBP is targeted
at either the localized site or empirically if unsuccessful to locate the exact site
of leak. However, for all blind patches, lumbar region is used. Image-guided targeted
EBP is recommended over blind EBP. Fibrin glue maybe used instead of blood, only in
failed EBP cases or as the initial treatment if the treating doctor has experience
or expertise in using fibrin glue. Post-EBP instructions are to be followed to prevent
recurrence. Strict bed rest for at least 8 hours after blood patch. Immediate sitting
upright post EBP, long hours of travelling or lifting heavy weights and performing
maneuvers which tend to increase the intra-abdominal pressure are to be avoided for
few days following the patch as these activities may increase the chance of recurrence.
Recommended follow-up after blood patch is between 10 and 14 days and late follow-up
is between 3 and 6 months. In case of recurrence in clinical symptoms, multidisciplinary
meet is performed, and repeat imaging or intervention may be considered.[3]
-
Repeat EBPs recommended for recurrent cases. Image-guided targeted EBP is recommended
over empirical patches. CT-guided epidural fibrin glue patches may also be tried for
failed EBP cases.
-
CT-guided fibrin glue injection to meningeal diverticula and CVF.
-
CT-guided epidural fibrin glue injection or transvenous endovascular embolization
of foraminal veins using liquid embolic agents for CVF.
-
Neurosurgical role
-
- Subdural collections evacuation for causing significant mass effect or midline shift.
-
- Dural repair and excision of the bony spurs or microspecies.
-
- Microsurgical repair of the dura and ligation of foraminal vein in cases of CVF
and ligation repair of meningeal diverticulum.
Intrathecal Gadolinium MR Myelogram Remains Obsolete
Nuclear medicine cisternography used in patients with image-negative SICH. Lumbar puncture radionuclide tracer is
injected. After 24 hours, complete coverage of cerebral convexity is obtained. In
case of incomplete coverage after 24 hours, CSF flow dynamics are affected, and these
are considered as SICH-positive cases and are subjected to DSM/CTM to assess possible
SLEC-N leak.[29]
Anticoagulation in Case of Cerebral Venous Thrombosis
At places where there is no expertise to perform the UFCTM or DSM, two level nontargeted
autologous blood patch is preferred, one at the cervicothoracic junction and the other
at dorsolumbar junction, respectively.
Rebound Intracranial Hypertension
SICH may result in rebound intracranial hypertension following EBP or surgical repair,
where the patient presents with headache worsening on lying down and improves in upright
position. This is more commonly seen in patients with chronic SICH and is believed
to be caused by increased CSF production and disrupted CSF reabsorption during the
CSF leak period. It is treated by head end elevation and analgesics in mild cases,
acetazolamide orally or intravenously in moderate cases, and lumbar puncture to remove
the fluid in severely affected cases.[30]
Post-Treatment Imaging
Imaging findings are temporary and revert to normal. Intracranial features of venous
distension, pituitary engorgement, herniation, and pachymeningeal enhancement disappear
within a month following treatment. However, bilateral subdural collection may take
a few more weeks to resolve.
