Keywords
oculorrhea - cranio-orbital fistula - cerebrospinal fluid - rhinorrhea - traumatic
brain injury - surgical management - pseudoepiphora - cerebrospinal fluid fistula
Introduction
The Roman physician Galen first surveyed cerebrospinal fluid (CSF) leakage mechanisms
when he described how fluid stored in the ventricles escaped through the nose.[1] Modern medicine has since refined and broadened this understanding of CSF fistulas
to recognize them as a potential complication of craniocerebral injury. The most common
sites of traumatic CSF fistulae are the anterior and middle skull base, resulting
in rhinorrhea or otorrhea.[2] In addition, CSF can occasionally migrate into the orbit or through the scalp and
into the eyelid and form a cranio-orbital fistula and pseudomeningocele, in which
there is no outward leakage of CSF. In rare cases, however, CSF can transverse the
orbit and exit via the eye, mimicking tear formation. Salame et al described this
phenomenon as oculorrhea.[3]
[*]
A variety of mechanisms can cause orbital CSF fistulas, including orbital tumors with
intracranial extension into subarachnoid space, orbital surgery that compromises the
integrity of the cribriform plate, or craniocerebral trauma. The overall incidence
of CSF fistulas following craniocerebral injury is 0.5 to 3%, with rates upwards of
25% for midfacial injuries.[4] Traumatic cranio-orbital CSF fistulas, however, are exceedingly rare, with fewer
than 30 cases reported in the English literature.[3]
The paucity of reported oculorrhea cases, especially compared with the frequency of
other types of CSF fistulas developing after traumatic injury, suggests that cranio-orbital
fistulas are rare and may be underdiagnosed complications. Periorbital swelling from
the accompanying head injury, misidentification of leaked CSF, and low clinical suspicion
can delay proper identification of this entity, thereby potentially increasing the
chance for hazardous complications including meningitis, intracranial hypotension,
seizures, and encephalocele development. In the current study, we present the case
of a young man involved in a motor vehicle accident who developed refractory oculorrhea
in association with an orbital roof fracture that ultimately required surgical intervention.
To further characterize the presenting features, diagnostic challenges, and treatment
options for traumatic oculorrhea, we aimed to perform a systematic review of the literature
pertaining to cranio-orbital fistulas.
Materials and Methods
A systematic review of the literature was performed in the database during the month
of November 2012 to identify any articles published in the English language pertaining
to traumatic oculorrhea. A search including the terms oculorrhea cranio-orbital CSF fistula, orbital fistula, and pseudoepiphora yielded 480 search results. Pertinent abstracts were screened. Trials were included
in this review if the aim of the paper: (1) described clinical studies pertaining
to mechanisms, diagnosis, and/or management of traumatic cranio-orbital fistulas and/or
oculorrhea; (2) reported cases of traumatic cranio-orbital fistulas and/or oculorrhea;
and (3) did not describe oculorrhea resulting from a nontraumatic orbital or lacrimal
surgery. In addition, references of all included articles were reviewed to search
for additional studies. Overall, 46 relevant studies meeting the criteria for preliminary
analysis were identified. Of these, 24 were excluded for the following reasons: relevance,
lack of clinical data reported, inability to acquire the original article, and lack
of evidence of oculorrhea occurring. Following exclusion, 22 cases of traumatic oculorrhea
were included in the review ([Table 1]). Each study was thoroughly reviewed, and pertinent clinical data including demographics,
mechanism and patterns of injury, diagnosis, treatment, and follow-up were extracted
and entered in a database. Given the rarity and heterogeneity of cases, no meta-analyses
were performed.
Table 1
Cranio-orbital Fistula Case Series List, Clinical Description, Treatment, and Outcome
|
Author
|
Year
|
Age
|
Sex
|
Mechanism of injury
|
Findings from ophthalmologic and neurologic exam
|
Fluid leakage
|
Onset
|
Treatment
|
Result
|
|
Arslantas
|
2003
|
3 YO
|
M
|
Trauma: falling injury
|
Pulsatile upper eyelid swelling
|
No
|
Cyst formation
|
Surgical
|
Resolved
|
|
Bagolini
|
1956
|
9 MO
|
|
Motor vehicle
|
Comatose responding to stimulation by crying; contusion and hematoma of upper lid;
left eye larger pupil and unreactive to light; edema
|
No
|
Cyst formation
|
Surgical
|
Resolved with ophthalmological deficit
|
|
Bard
|
1963
|
36 YO
|
M
|
Trauma: stabbing wound
|
Laceration; no abnormal neurological signs
|
Yes
|
Immediate
|
Conservative
|
Resolved
|
|
Barker-Griffith
|
2007
|
14 YO
|
M
|
Trauma: potato gun injury
|
Multiple lacerations and ecchymosis of lids; globe collapse; potato fragments
|
Yes
|
Immediate
|
Surgical
|
N/A
|
|
Bongartz
|
1981
|
2 YO
|
M
|
Trauma: falling injury
|
Swelling of right eyelid
|
Yes
|
Immediate
|
Surgical
|
Resolved
|
|
Brawley
|
1967
|
48 YO
|
M
|
Motor vehicle
|
Meningitis 3 years postaccident
|
No
|
Discovered at autopsy 4+ years
|
Conservative at time of accident
|
Death
|
|
Civelek
|
2006
|
7 YO
|
M
|
Trauma: stabbing wound
|
Proptosis; diplopia; orbital cellulitis; periorbital abscess
|
Yes
|
Immediate
|
Surgical
|
Resolved
|
|
Dryden
|
1986
|
4 YO
|
M
|
Motor vehicle
|
Right inferior oblique overreaction; meningeal signs 2 weeks post
|
Yes
|
Immediate
|
Surgical
|
Resolved with meningitis
|
|
Garza-Mercado
|
1982
|
20 YO
|
M
|
Trauma: assault
|
Edema of eyelids; ecchymosis in both orbital areas; right pupil dilated and fixed;
limited extraocular movements
|
Yes
|
Immediate
|
Surgical
|
Resolved with ophthalmological deficit
|
|
Joshi
|
1978
|
8 MO
|
F
|
Motor vehicle
|
Unconscious responding to painful stimuli; dilated left pupil; unreactive to light;
laceration
|
Yes
|
5 days postadmission
|
Surgical
|
Resolved with ophthalmological deficit
|
|
Joshi
|
1978
|
5 YO
|
|
Trauma: undisclosed
|
N/A
|
Yes
|
immediate
|
N/A
|
N/A
|
|
Kjer
|
1954
|
3 YO
|
M
|
Trauma: stabbing wound
|
Deteriorated into clonic spasms and loss of consciousness; upper lid edema; eyes fixed
to light; stiff neck
|
Yes
|
Immediate
|
Surgical
|
Death
|
|
Markovic
|
2006
|
41 YO
|
F
|
Motor vehicle
|
Exophthalmos and painless proptosis; eyes poor reaction to light with normal size;
laceration
|
No
|
Cyst formation
|
Initial conservative treatment, then cyst correction surgery
|
Resolved
|
|
Pereira
|
2011
|
7 MO
|
F
|
Trauma: gunshot
|
Luxation of the globe with complete restriction of ocular motility; dilated left pupil
|
Yes
|
Immediate
|
Surgical
|
Resolved with blindness
|
|
Rao
|
1999
|
78 YO
|
M
|
Trauma: stabbing wound
|
Meningeal signs; no other focal deficits
|
Yes
|
2 weeks postadmission
|
Patient left against medical advice
|
Resolved
|
|
Rha
|
2012
|
56 YO
|
M
|
Motor vehicle
|
Unconscious; no periorbital ecchymosis, papilledema, proptosis; right pupil normal
size with sluggish reaction to light; left pupil dilated without response
|
Yes
|
2 weeks postadmission
|
Conservative for 2+ weeks, then surgery
|
Resolved
|
|
Salame
|
2000
|
20 YO
|
F
|
Trauma: sports
|
Left periorbital swelling and ecchymosis; laceration; left pupil mydriatic
|
Yes
|
Immediate
|
Conservative treatment
|
Resolved
|
|
Sibony
|
1985
|
27 YO
|
M
|
Motor vehicle
|
Eyes reactive to light; proptosis; right eye frozen in primary position
|
No
|
Cyst formation
|
Conservative treatment
|
Resolved
|
|
Terao
|
1975
|
10 MO
|
M
|
Trauma: falling injury
|
Supraorbital ecchymosis, swelling of left eyelids; uncooperative; left unilateral
pupil dilation
|
No
|
Cyst formation
|
Surgical
|
Resolved
|
|
Till
|
1987
|
14 MO
|
M
|
Trauma: stabbing wound
|
Laceration; normal eye exam
|
|
|
Surgical
|
Discharge after 13 days
|
|
Twaij
|
2009
|
3 YO
|
M
|
Trauma: stabbing wound
|
Ecchymosis; proptosis of right eye; complete restriction of right eye extraocular
movement; normal pupils
|
No
|
Cyst formation
|
Conservative
|
Resolved
|
|
Pease
|
2012
|
22 YO
|
M
|
Motor vehicle
|
Laceration; diminished extraocular eye movements
|
Yes
|
Immediate
|
Surgical
|
Resolved
|
Case Report
A 22-year-old restrained male driver fell asleep while driving and struck a parked
car, hitting his head on the steering wheel of his car. He did not lose consciousness.
Although he had a previous history of seizures, he had been seizure free for 7 years
without antiepileptic medications. The patient was transferred to the Keck-USC Medical
Center for further care.
Examination
The blood pressure was 127/68, pulse 64, and respiratory rate was 16. He was alert,
oriented, and cooperative. A left forehead abrasion was evident, in addition to a
3-cm laceration on his left eyelid. The left eye was severely swollen and ecchymotic.
Upon assisted opening of the left eye, the pupils were round, equal and reactive to
light with a visual acuity of 20/20 in the right eye and 20/40 in the left eye. The
following extraocular movements were noted in the left eye: 100% adduction, 90% abduction,
80% infraduction, and 30% supraduction. The right eye examination was normal. In addition,
spontaneous clear fluid was noted to be draining from the eye, and was exacerbated
when leaning the patient forward. No rhinorrhea or otorrhea was present on exam. The
remainder of the cranial nerve and neurological examination was within normal limits.
A noncontrast, thin-slice computed tomography (CT) of the brain and orbits with coronal
and sagittal reconstructions showed a displaced fracture involving the left orbital
roof and lateral ethmoid sinus, with an 8-mm superior migration of the dominant fragment
into the left gyrus rectus, and small amount of intracranial pneumocephalus, hyperdense
hemorrhage, and edema ([Fig. 1]). The left ocular globe appeared to be intact with a small amount of stranding within
the intraconal space. A blowout fracture involving the orbital floor with prolapse
of orbital fat and inferior rectus muscle into the maxillary sinus was also evident.
A small amount of blood products were present within the maxillary sinus. The left
lamina papyracea was fractured with hemorrhage into multiple ethmoid air cells. A
moderate amount of soft tissue edema was noted overlying the left preorbital soft
tissue.
Fig. 1 Thin-cut preoperative and postoperative computerized tomography scans of the orbits
with reconstructions. (A) Coronal view displaying superior orbit blowout fracture.
(B) Axial view displaying bone fragment. (C) Sagittal view displaying superior displacement
of bone fragment. (D) Coronal view showing interval resection of the displaced bone
fragment. The red arrow denotes the pedicled pericranial flap. (E) Another coronal
view showing both the integrity of the sinuses and the result of the surgical repair.
The red arrow delineates the pericranial flap. (F) Sagittal view demonstrating the
results of the surgical repair.
Despite initial efforts at conservative management in an attempt to allow spontaneous
resolution of the oculorrhea, fluid leakage from the eye persisted. Given the refractory
oculorrhea, bony fragment extending into the frontal lobe, pneumocephalus, and risk
for infection and/or seizure, surgical resection of the bony fragment and repair of
the cranio-orbital fistula was recommended.
Operation
The patient underwent a left frontal supraorbital craniotomy on hospital day 4. The
patient was positioned in supine position and the head was placed in three-pin fixation
with the head slightly extended. A left frontotemporal curvilinear incision was made
behind the hairline. The temporalis fascia and muscle were preserved. A vascularized
pericranial flap was harvested and preserved for subsequent reconstruction. A small
3 × 2 cm craniotomy was made in the supraorbital region following single bur hole
placement in the left anatomical keyhole. The posterior orbital rim was flattened
using a high-speed drill. No frontal sinus breach was noted. The complex fracture
was approached extradurally using gentle upward retraction of the left frontal lobe.
A comminuted fracture of the left orbital roof was identified with severe herniation
of the intraorbital contents (periorbital fat and muscle) into the frontal fossa.
The sharp bony fragment displaced from the orbital roof had penetrated the dura and
created a clear CSF fistula at this site. The bony fragment was gently resected from
within the gyrus rectus parenchyma, and hemostasis was achieved using bipolar coagulation
and oxidized cellulose. Following this, additional resection of the orbital roof was
performed to further decompress the orbital contents. The large dural defect was repaired
using a multilayer approach consisting of a synthetic dural graft inlay and overlay,
in addition to application of a dural sealant (DuraSeal, Covidien, Mansfield, Massachusetts,
USA). The vascularized pericranial flap was then placed as an overlay. The bone flap
was replaced using standard low-profile titanium microplates. The wound was closed
in standard multilayer fashion. Following this, the orbital floor fracture was repaired
via a transconjunctival approach and reduction/fixation with titanium plates.
Postoperative Course
Fluid leakage ceased after completion of the surgery and repair of the dural compromise.
The patient had a transient left third nerve palsy, which gradually improved over
the next few weeks. At most recent follow-up 5 months later, the third nerve palsy
had improved nearly completely with the exception of mild left ptosis, and the extraocular
movements returned to normal with retention of full visual acuity in both eyes.
Results
A systematic review identified 22 cases of traumatic oculorrhea, which were included
in the current analysis[1]
[2]
[3]
[4]
[5]
[6]
[7]
[8]
[9]
[10]
[11]
[12]
[13]
[14]
[15]
[16]
[17]
[18]
[19]
[20] ([Table 1]). The patient population had a mean age of 18.2 years with a median age of 7.5 years.
Oculorrhea development was caused by a motor vehicle accident in eight patients, stab
wounds through the orbit in six patients, falls in three patients, gunshot wounds
in two patients, and one each of sports injury and undisclosed. Overall, the mechanism
for oculorrhea formation was blunt head injury in 14 patients (64%) and penetrating
injury in 8 patients (36%). Following ophthalmologic and neurologic exam, authors
described the following relevant symptoms/signs: visible trauma to the face or orbit
including lacerations, contusions, edema, ecchymosis (16), dilated pupil (7), unreactive
to light (6), diminished ocular movements (6), altered consciousness (5), proptosis
(5), meningitis signs (4), and diplopia (1). Seven patients underwent initial conservative
treatment, with three patients ultimately needing surgical correction. Thirteen patients
underwent initial surgical intervention. One patient left against medical advice,
and one patient's outcome was not reported.
Discussion
Anatomical Considerations and Mechanisms of Injury
The diagnosis of CSF oculorrhea may be challenging and go undetected despite careful
neurological, orbital, and roentgenographic examinations.[15] CSF leakage is often obfuscated by bleeding or severe ocular injury that commands
the attention of the physician.
Some cases of oculorrhea are easily diagnosed. Of the 22 relevant cases, 8 were caused
by penetrating wounds with obvious etiologies: 6 stab wounds and 2 gunshot wounds.
For these cases, recognizing a penetrating injury as the mechanism is pivotal, and
the diagnosis is typically made more easily. The foreign body passes through the orbit
and into the cranium to directly penetrate the meninges and create a CSF fistula.[6]
[9]
[19]
[20] Transorbital stab wounds are often fatal if no specific intervention is made.[13] Characteristically, stab wounds have small external lesions with a long tract. This
tract is often irregular from transient displacement of the tissue at the time of
injury, creating an ideal location to grow anaerobic bacteria like Clostridium tetani. Appropriate antibiotics should be given immediately. Depending on the type and size
of the penetrating wound, surgical intervention may be necessary to repair damage
to the orbit and/or cranium.
In cases of blunt traumatic injury, unfamiliarity and complicated mechanisms frequently
leave oculorrhea off of the physician's differential diagnosis. Several clues in the
history may raise the suspicion for oculorrhea. Patients with cranio-orbital fistulas
from blunt traumatic injury tended to be involved in high-impact injuries, be young
(median age 14 years), have an impaired ophthalmologic exam, and have variable onset
of CSF oculorrhea.
The mechanism of injury provides some insight into the likelihood for a cranio-orbital
fistula. Overall, most ocular injuries occur in home environments or car accidents.[14] In this series, nine (56%) occurred via a motor vehicle accident, six due to stab
wounds (27%), three (19%) via a young-child falling accident, two via a gunshot wound
(13%), and one each of assault and sports trauma. Not surprisingly, these percentages
closely follow reported mechanisms for injury in case series for CSF rhinorrhea.[1] As expected, motor vehicle accidents and other high-impact mechanisms make up a
majority of the overall cases for cranio-orbital fistulas.
The anatomy of the cranium and orbit provides some insight into the cause of cranio-orbital
fistulas. The brain is enswathed from the exterior world by an anatomical barrier
of skin, sinus mucosa, periosteum, skull bones, dura mater, and arachnoid membrane.
Fistulas may develop when significant orbitocranial injuries breach the integrity
of these barriers to permit the escape of CSF fluid. For true oculorrhea to occur
with CSF exiting the orbit anteriorly, the continuity of both the meningeal and conjunctival
layers must be compromised.[15] This most frequently occurs in four anatomical locations along the skull base that
may become structurally compromised: the frontal sinus, the cribriform plate/ethmoid
roof, the sphenoid sinus, and the petrous bone.[21]
Four primary mechanisms provide an avenue for cranio-orbital CSF communication. All,
however, have anatomical considerations that seem to protect against the development
of oculorrhea.
First, an orbital roof fracture provides a direct channel to the intracranial cavity.
Bone fragments may frequently tear the dura and arachnoid but often leave the conjunctiva
intact. In a majority of cases, CSF communicates between the two compartments but
does not leak out of the eye.[3] After severe breakage of this anatomical barrier, arachnoid membrane or frank brain
tissue can herniate into the orbit, or orbital contents can herniate into the frontal
fossa. In addition, during various orbital operations in which bone is removed from
the skull base (such as invasive orbital tumor resection), development of CSF fistulas
may occur.[3]
Second, concurrent damage to the cribriform plate and the medial wall of the orbit
allows CSF to gain access to the orbit via the ethmoid air cells. The cribriform plate
is a comparatively weak anatomical location susceptible to traumatic injury. The bone
is thin and the dura invests from the olfactory fissure where the olfactory nerve
penetrates the skull. Bone fragments from the ethmoid roof or orbital wall can easily
tear the dura when fractured.[10] CSF leaking through the cribriform plate, however, generally escapes into the paranasal
sinuses and cavity to manifest as rhinorrhea rather than oculorrhea. This primarily
derives from anatomical considerations: the bony walls of the air sinuses are thinner
and break more easily than the orbital walls.[3] The close proximity between the roof of the ethmoid and the nasal ostium, with only
5 mm separating the two, further encourages rhinorrhea as the predominant pathway
of CSF leakage. Physiologically, the pressure gradient between the intracranial space
and air sinuses is significantly greater than the gradient between the intracranial
and intraorbital pressure. This further promotes development of rhinorrhea rather
than oculorrhea as the “path of least resistance.” Furthermore, patient age seems
to be associated with the development of a cranio-orbital fistula. Overall, male children
are the most likely group to have eye injuries.[14] Most of the age-specific injuries, however, occur as a result of accidental trauma
rather than the motor vehicle accidents prevalent in this series. Although younger
children are at a high comparable risk for ocular injury, CSF rhinorrhea leaks are
rare in children below the age of 2, potentially resulting from the flexibility of
the cranial base and the relative immaturity of the paranasal sinuses.[10] Indeed, patients with larger sinuses are more at risk of developing rhinorrhea.[4] In the current case series, three of the four youngest patients who developed oculorrhea
in the non–stab wound category had an injury related to a fall, with an average age
just under 2 years. Underdeveloped sinuses may anatomically promote cranio-orbital
fistulas compared with rhinorrhea by altering the route of CSF leak after damage to
the cribriform plate. Galzio et al reported the case of a patient with frontal sinus
agenesis who experienced cranio-orbital CSF leakage after a fracture of the anterior
roof caused by blunt trauma.[22] They hypothesized that the absence of a frontal sinus allowed the direct egress
of CSF into the upper lid. A similar phenomenon may occur with underdeveloped sinuses
in young children. Alternatively, the cribriform plate fracture is more likely to
extend to the underdeveloped sinuses, as one case noted that the fracture line of
the cribriform plate extended into the ethmoid air sinuses.[12] The trend in this data may be an artifact of a small sample size or may indicate
that underdeveloped sinuses alter the route of CSF leakage after traumatic injury.
This may help to explain why three pediatric patients presented with this rare condition
and why the median age of patients in our series reviews was so young.
Third, a CSF leak can remain trapped within the orbit as either an orbitocele or within
the soft tissue of the eyelid itself.[2]
[4]
[5]
[18] This is a very rare phenomenon, with only five cases reported in the English literature.
This can occur via accumulation of fluid in the orbit without conjunctival damage
or through damage to another part of the calvarium with CSF seeping under the skin
through a path into the eyelid. Cranio-orbital fistulas should be considered in patients
presenting with orbitoceles or eyelid cysts who have a history of frontobasilar or
superior orbital roof fractures. This is a complex diagnosis with many differential
considerations, including a retrobulbar hematoma, orbital abscess, mucocele, or foreign
body cyst.[3] Lastly, CSF can leak via the optic canal when the arachnoid is damaged along with
an orbital roof or apex injury. This is an uncommon mechanism and was not reported
in this review.
Clinical Presentation
Symptoms and signs vary greatly in patients developing cranio-orbital fistulas. All
but two patients had impaired ophthalmologic exams. The most common presenting symptoms/signs
were visible trauma to the face or orbit including lacerations, contusions, edema,
ecchymosis (81%); epiphora or serous drainage from the eye (73%); impaired papillary
reflex and/or pupil dilation (47%); orbital cyst formation (24%); meningeal signs
(19%); loss of consciousness (19%); loss of extraocular movements; and proptosis (19%)
([Table 2]). No distinct pattern of clinical findings, however, can unequivocally exclude or
include a CSF cranio-orbital fistula.[17] Meningeal signs may point to some type of fistula and may present without any focal
neurological deficits.[10] A history of prior surgery, especially if a portion of the orbital roof was removed,
places patients at a higher risk for development of cranio-orbital fistulas from subsequent
trauma or surgeries.[23]
Table 2
List of Clinical Symptoms and Signs in Cranio-orbital Fistula Cases
|
Symptom
|
Percent Presenting
|
|
Loss of ocular movement
|
19%
|
|
Proptosis
|
19%
|
|
Orbital cyst formation
|
24%
|
|
Epiphora
|
73%
|
|
Visible damage
|
81%
|
|
Meningeal signs
|
19%
|
|
Loss of consciousness
|
19%
|
|
Impaired pupillary reflex or pupillary dilation
|
47%
|
A major cause of concern for cranio-orbital fistulas is external fluid leakage, as
this increases the risk for meningitis or intracranial hypotension. The time course
of CSF leakage can be quite variable. Due to the sparse oculorrhea data, clinical
data of rhinorrhea onset is somewhat illustrative. Lewin et al showed that when CSF
leakage occurred after head trauma, two thirds of the cases occurred within the first
48 hours.[24] Most cases start within 3 months, but onset delays can range up to 30 years. In
this review, 12 of the 15 cases presenting with oculorrhea had fluid leakage within
48 hours (80%); one case presented at 5 days postadmission, and the other two cases
presented at 2 weeks postadmission.[8]
[12]
[16] Additional delayed imaging after fractures of the anterior skull base extending
to the orbital roof or orbital walls may help identify delayed presentation of oculorrhea.
This will help determine if a cranio-orbital fistula has developed after initial trauma.
Even in cases with immediate oculorrhea, identifying the discharged fluid as CSF may
prove to be a challenge. In one case, the authors initially diagnosed posttraumatic
fluid leak as epiphora due to lacrimal duct outflow.[10] The 4-year-old boy had a compromised lacrimal examination with drainage obstruction.
His tearing failed to resolve after corrective lacrimal surgery, suggesting a cranio-orbital
fistula as a possible underlying etiology or consequence of the lacrimal surgery.
CSF fistulas should be a concern for all patients with excess tearing after anterior
skull fractures or motor vehicle accidents.
Several means exist to differentiate epiphora from oculorrhea. First, analysis of
the fluid for glucose content is illustrative. CSF normally has approximately two
thirds of the serum glucose concentration, whereas tear glucose levels are insignificant
(2.5 to 4.1 mg/dL).[19] Glucose levels of 30 mg/dL or higher are diagnostic for oculorrhea.[3] Each eye should be tested and compared, with any differences in glucose concentration
noted. To date, no case of bilateral oculorrhea has been reported. Also, increased
flow in the forward-tilting or otherwise head-dependent position may indicate a cranio-orbital
fistula resulting from positional pressure differences. Some authors discredit the
use of glucose testing, claiming it is not as specific as immunoassays for β2-transferrin.
The latter test is both more specific and requires a smaller amount of fluid (< 1
mL). Tears and nasal secretions lack protein, whereas CSF has significant levels.
Together, these four indicators should aid to discriminate whether epiphora results
from excess tear formation or a CSF leak.
The next step toward proper diagnosis is the selection of an appropriate imaging modality.
CT imaging is the preferred method to screen for anterior skull base fractures with
intracranial penetration.[15] Thin-cut CT imaging with coronal and sagittal reconstructions provides an optimized
view of the integrity of the skull base and is most useful for diagnosing orbital
roof or other skull base fractures. In addition, CT scans are capable of detecting
less than 0.5 mL of air within the cranial cavity (pneumocephalus), which is highly
suggestive of a CSF fistula. Although localization of the CSF fistula may be a challenge,
every effort to do so should be done prior to an operation. This can also be accomplished
through metrizamide or iopamidol cisternography followed by thin-section coronal-view
CT scanning.[3] Radionucleotide cisternography is also reliable, yet not as sensitive of a method.
Treatment of Cranio-Orbital Fistulas
Treatment of Cranio-Orbital Fistulas
The optimal management of CSF orbital fistulas remains controversial based on the
sparse frequency of this entity. The goal of fistula treatment is ideally to seal
the hole in the dura/arachnoid, but this may not be necessary as long as there is
no communication with the outside world or a sinus space. In a case of an orbital
roof and superior orbital rim fracture without involvement of the paranasal sinuses,
some CSF leakage may be reasonably expected into the orbit.[18] For minor cases of CSF leakage, conservative treatment can often be attempted with
success. Spontaneous healing and resolution of the CSF leak is more likely to occur
if the dural edges remain in apposition without a major rent or if sinus mucosa bridges
the dural defect. This allows for a plug to form in the dural hole.[10] Conservative fistula management results in closure rates of 85% with bed rest alone,
and up to 95 to 100% with spinal drainage in larger case series of rhinorrhea.[3] In many cases of CSF oculorrhea, an attempt at conservative management is warranted.
Twenty-five percent (5) of the patients in the current review were successfully treated
with conservative management. Three patients resolved without complications, one patient
experienced personality changes, and the last patient had meningitis 3 years postaccident.
The small population size and large differences in diagnostic tools available allow
little inference from this conservative treatment series.
In the current series, 14% of the patients (3) with initial conservative management
failed and required subsequent surgery. Although some clinicians propose surgical
intervention for all cases of external CSF leak to prevent later-onset infections
of the central nervous system, the severity of the case typically determines the most
appropriate treatment modality.[3] Bony spicules protruding through a dural tear or brain herniation almost exclusively
fail to heal conservatively and warrant surgical intervention. Additionally, coughing
and straining may result in delayed CSF leakage or exacerbate a current CSF leakage,
especially if the dura is injured and the arachnoid is at risk for delayed injury.[10] Perhaps due to publication bias, most cases in the published English literature
were severe cases that frequently necessitated surgical intervention as the primary
intervention (60%; 12 patients). All of these cases resolved the CSF leak, with complications
including ophthalmological deficits (4), blindness (1), and meningitis (1).
Surgical intervention can involve either extracranial or intracranial approaches.
The intracranial intradural approach is preferred for traumatic CSF fistulas to enable
careful patching of the defect with autologous, pericranium, and/or fascia lata.[15] During the surgery, accurate localization of the CSF fistula can be challenging
task.[25] The use of intraoperative intrathecal fluorescein (IF) may facilitate the localization
of skull base defects and CSF leakage, as well as confirming a watertight closure
of the leak after completion of the repair. In the patient presented in the current
study, a large bone fragment derived from the fractured orbital roof was piercing
the dura and gyrus rectus of the frontal lobe, which posed a major risk for subsequent
seizures, a nonhealing fistula, and meningitis. The refractory nature of his CSF oculorrhea
after 5 days of conservative management, in combination with the fracture pattern,
made surgical intervention warranted. Based on this review, conservative management
is appropriate for less severe cases of oculorrhea, with surgical management as the
preferred method for all severe or refractory cases characterized by the predescribed
criteria above.
Conclusion
Patients with craniofacial injury and fractures involving the anterior skull base
and orbit may develop oculorrhea. The case presented in this paper provides an exemplar
for diagnosing and surgically repairing refractory cranio-orbital fistulas with oculorrhea.
Physicians should remain aware of cranio-orbital fistulas as a possible complication
of severe anterior skull based fractures or iatrogenic surgical injury. Although attempted
conservative management is warranted in a majority of cases, severe cases with displaced
bone penetrating the dura and/or parenchyma or refractory oculorrhea should be treated
surgically. Prompt diagnosis and correction should minimize the occurrence of complications
including meningitis postinjury.
