tumors of auditory nervous system
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Tumors of the auditory nervous system
Presentation: 19 Giten George
Definitions
1. Neoplasm: The word neoplasm literally means a new growth, from the Greek neo-,new + plasma, that which is formed, or a growth. Neoplasms can be benign or
malignant.
2. Malignant: Any malignant growth or tumor is caused by abnormal and uncontrolledcell division; it may spread to other parts of the body through the lymphatic system or
the blood stream, cancerous.
3. Benign tumor: Tumor that is not cancerous4. Metastasis: An active process by which tumor cells move from the primary location
of a cancer. Malignant tumors have no enclosing capsule, cells escape, become
emboli, and are transported by the lymphatic circulation/ the bloodstream to implant
in lymph nodes and other organs far from the primary tumor.
5. Secondary (metastatic) brain tumor occurs when cancer cells spread to the brain froma primary cancer in another part of the body. Secondary tumors are about three times
more common than primary tumors of the brain. Multiple tumors may develop.
6. Enchondral -Situated, formed or occurring within cartilage.7. Extraaxial- Off the axis; applied to intracranial lesions that do not arise from the brain
itself. External to the pia. Meninges, nerve sheath etc.
8. Intra-axialIntra axial is a term that denotes lesions that are within the brainparenchyma, Internal to the pia.
9. Infratentorial region of the brain is the area located below the tentorium cerebelli. Thearea of the brain above the tentorium cerebelli is the supratentorial region. The
infratentorial region contains the cerebellum, while the supratentorial region contains
the cerebrum.
Relevant Brain anatomy
Two types of neural cells in the nervous system:
Neurons - For processing, transfer, and storage of information NeurogliaFor support, regulation & protection of neurons
I. CNS neuroglia 1) Astrocytes 2) Oligodendrocytes 3) Microglia 4) Ependymal cellsII. PNS neuroglia 1) Schwann cells (neurolemmocytes) 2) Satellite cells
Glial cellsIn the CNS, there are 2 types of glia distinguished by size and embryonic origin.
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Macroglia, including astroglia and oligodendroglia, are the larger glial cells which originate
from the neural plate.
The astrocytes form glial end feet on the blood vessels, the processes of astrocytes insinuate
themselves into the spaces between neurons, cell bodies, axons dendrites and synapses.
The Oligodendrocytes are smaller than the astrocytes and have fewer and smaller processes.
Microglia, smaller and originate from mesoderm. Macrophagic function, they can migrate in
the mature CNS, play an important function in the removal of degeneration debris following
injury.Phagocytize cellular wastes & pathogensEpendymal cells line the ventricles, one cell thick. The cells contact one another through gap
junctions, and their ventricular faces have numerous microvilli and cilia.
Arachnoid layer and space: A delicate, spiderweb-like membrane/tissue.
Literally from Latin "spider web-like". One of the three meninges. It is interposed between
the two other meninges, the more superficial dura mater and the deeper pia mater, and is
separated from the pia mater by the subarachnoid space.
Posterior skull base
1) Cerebellopontine angle 2) Clival 3) Jugular foramen 4) Foramen magnumCerebellopontineAngle - Space filled with cerebrospinal fluid. It has the brain stem as its
medial boundary, the cerebellum as its roof and posterior boundary, and the posterior surface
of the temporal bone as its lateral boundary. The floor of the cerebellopontine angle is formed
by the lower cranial nerves (IX-XI) and their surrounding arachnoid investments. The
flocculus of the cerebellum may lie within the cerebellopontine angle and may be closely
associated with cranial nerves VIII and VII as they cross the cerebellopontine angle to enter
the internal auditory canal.
Types of glial cells N- Neuron, O-
Oligodendrocyte, A- Astrocyte, BV-
Blood vessel.
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Borders
MedialLateral surface of the brainstem LateralPetrous bone SuperiorMiddle cerebellar peduncle & cerebellum InferiorArachnoid tissue of lower cranial nerves PosteriorInferior cerebellar peduncle
Tumor types
1. Chloroma - Malignant, green-colored tumor arising from myeloid tissue, associatedwith myelogenous leukemia; it can occur anywhere in the body but has an affinity for
the central nervous system, bone, and soft tissues of the head and neck.
2. Myeloid- Derived from, or resembling bone marrow or the spinal cord. Tumor -Myeloma
3. Neurinoma: Tumor (usually benign) of the sheath surrounding a nerve. 'Neuroma':'nerve tumor (Greek)
4. Lymphoma - a cancer in the lymphatic system;5. Ependymoma - Glial tumors that arise from ependymal cells within the central
nervous system (CNS)
6. Astrocytoma- Neoplasms that develop from astrocytes.7. ChordomaMalignant tumor arising in the axial skeleton from embryonic remains of
the notochord
8. Chondrosarcoma - Malignant cartilage tumor that originates from enchondral bones.When it develops in the skull base, it usually arises in the parasellar area,
cerebellopontine angle, or paranasal sinuses.
9. Hemangioma- Abnormal buildup of blood vessels in the skin or internal organs.10.Hemangioblastoma - Tumors of the central nervous system that originate from
the vascular system usually during middle-age.
11.Medulloblastoma - Highly malignant primary brain tumor that originates inthe cerebellum or posterior fossa.
12.Papilloma- Benign epithelial tumor growing exophytically (outwardly projecting) infinger-like fronds. In this context papilla refers to the projection created by the tumor,
not a tumor on an already existing papilla.
13.Lipoma - Tumors containing fat. Clinically, CPA lipomas can cause slowlyprogressive neurological symptoms and signs affecting cranial nerves or brain stem.
Because these lesions usually are strongly attached to the surrounding structures, any
surgical attempts of complete resection can result in neural or vascular damage.
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14.Chondrosarcoma- Skull base tumor, rare, slow-growing with a potentially lethaloutcome due to compression of adjacent tissues, such as the carotid artery and cranial
nerves.
15.Arachnoid cysts - Cerebrospinal fluid-filled sacs that are located between the brainand the arachnoid membrane. Primary arachnoid cysts are present at birth and are the
result of developmental abnormalities in the brain and spinal cord that arise during the
early weeks of gestation. Secondary AC develops as a result of head injury,
meningitis, or tumors, or as a complication of brain surgery. The majority of
arachnoid cysts form outside the temporal lobe of the brain in an area of the skull
known as the middle cranial fossa.
16.Epidermoid cyst - Connsist of epidermal and connective tissue structures usually inthe form of a sac. They have the capacity for independent progressive growth often at
the expense of neighbouring bone and have a tendency to reform after removal. The
cerebellopontine angle is the most common site of occurrence of intracranial
epidermoids.
17.Cholesterol granulomas- Occur in the pneumatized petrous apex of the temporal bonebut also may be seen in other pneumatized portions of the temporal bone, including
mastoid air cells and middle ear space. It is not a neoplasm but a descriptive term used
for a granulomatous reaction to blood breakdown products, primarily cholesterol.
They are thought to arise secondarily following disease states where normally
ventilated air-containing bony spaces are obstructed, such as in chronic or acute otitis
media, cholesteatoma, or mastoiditis
Cerebellopontine Angle Tumors can be grouped into 7 categories.
This classification is conductive to differential diagnosis based on location.
1) Extra-axial lesions2) Intra- axial lesions3) Extra-dural lesions
I. Extra axial lesions can be further divided into the following sub categoriesa. Vestibular Schwannomab. Meningioma and simulants
- Leptomeningeal metastases- Primary meningeal Lymphoma- Primary meningeal melanoma- Meningeal sarcoidosis- Hypertrophic pachymeningitis
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c. Epidermoid and other cysts- Arachnoid cyst- Cysticercal cyst
d.Nonvestibular Posterior Fossa schwannomasV, VII, IX, X, XI, XII
II. Intra- axial lesionsa. Brainstem tumor
- Astrocytoma- Lymphoma- Hemangioma
b. Cerebellar tumor- Astrocytoma- Hemangioblastoma- Metastases- Lymphoma- Hemangioma- Medulloblastoma
c. Forth ventricular tumor- Ependymoma- Choroid plexus- Papilloma-
III. Extradural Lesionsa.Bone lesions
- Cysts, e.g., Cholesterol cyst, Epidermoid cyst, Mucocele
b.Tumors, e.g., Chordoma, chondroma, giant cell tumor, myeloma, metastases
c. Paragangliomas (Glomus Jugulare tumor)
INTRACANALICULAR LESIONS
Acoustic & facial schwannoma, Hemangioma, Meningioma, Metastasis, Glioma, Lipoma,
Osteoma
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Classification based on source of lesion
Primary tumors of the CPA
Vestibular Schwannoma
Meningioma
Arachnoid cyst
Epidermoid cyst
Schwannoma of V, VII, IX, X, XI nerves
Primary melanoma
Hemangioma
Lipoma, dermoid, teratoma
Secondary tumors of the CPA
Paraganglioma
Ceruminoma
Chondroma-chondrosarcoma
Chordoma
Extension of cerebellar and petrous bone tumors
Metastases
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Neurofibromatosis
Von Recklinghausens disease (1882) occurs in three forms (overlap of forms also occurs).
I. Central forms, known as neurofibromatosis-II (NF-II)
A. Multiple intracranial and intraspinal tumors
B. Bilateral acoustic schwannomas
II. Peripheral form (NF-I) (today, only NF-I is referred to as von Recklinghausens disease)
A. Cafe ole spots
III. Visceral form
NF-II
Microscopically, NF-II schwannomas are histologically identical to sporadic acute unilateral
acoustic schwannomas. In some cases they may show an intermediate pattern between
meningioma and schwannoma (the cells of schwannomas and meningiomas originate from
the neural crest).
Bilateral acoustic tumors are a principle clinical feature of neurofibromatosis type II,
although other manifestations, including peripheral neurofibroma (tumor on nerve sheath of
peripheral nerves), meningioma, glioma are often present as well. Multiple schwannomas
involving an individual nerve, or involving numerous nerves, as well as multiple
meningiomas.
NF-II tumors may be more invasive and may infiltrate the cochlear nerve as compared to the
sporadic acoustic neuroma. This infiltration may be responsible for low success rate with
tumor removal in hearing preservation.
There are three clinical subtypes of NF-II.
Gardners subtype (milder form)
1. Onset of symptoms, usually HL from bilateral vestibular schwannomas.
2. Few or other associated brain or spinal cord tumors.
3. Main age of onset is 27 years, only 12% have meningiomas
Wisharts subtype (severe form)
1. Multiple intracranial and spinal tumors.
2. Developed at an early age with rapid progression of signs and symptoms.
3. Average age of presentation 17.4 years, 70% with meningiomas.
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Third subtype, called theLee/Abbott subtype
1. Childhood cataracts and early death due to cranial and spinal meningiomas and
schwannomas.
2. Average age of presentation 14 years, 70% incidence of meningiomas.
von HippelLindau disease (Features related to hearing)
VHL disease is a complex multisystem disorder, the autosomal dominantly inherited disorder
von HippelLindau disease (VHL) is caused by germline mutations in the VHL tumor
suppressor gene (TSG). VHL mutations predispose to the development of a variety of tumors
(most commonly retinal and central nervous system haemangioblastomas).
CNS haemangioblastomas are a cardinal feature of VHL disease and are the presenting
feature in 40% of cases. Overall CNS haemangioblastomas occur in 6080% of VHL patients
and most commonly occur in the cerebellum, spinal cord and brain stem with supratentorial
lesions being rare.
Patients with cerebellar haemangioblastomas typically present with symptoms of increased
intracranial pressure and limb or truncal ataxia (depending on the precise location of the
tumour) and the clinical presentation of CNS haemangioblastomas reflects their mass effect.
Haemangioblastomas with an associated cyst tend to become symptomatic sooner.
Endolymphatic sac tumors (ELST) can be detected by MRI or CT imaging in up to 11% of
patients. (Heffner, 1996). Bilateral ELSTs are considered pathognomonic for VHL disease.
Although often asymptomatic, the most frequent clinical presentation is hearing loss (mean
age 22 years), but tinnitus and vertigo also occur in many cases.
Differentiating extra axial and intra axial lesions
Summery of extra-axial and intra-axial brainstem auditory disorders-Jerger and Jerger.
(1975)
Pure tone audiogram In intra-axial lesion average threshold levels were 1-15 dB at all
frequencies plus good PB max scores. This data closely approximated observations by other
investigators (Liden, 1969; Parker, 1968; Jerger, 1960a).
Normal acoustic reflex contractions. Auditory symptoms in both ears or the contralateral ear
only.
verage s for the extra axial lesion patients were 60 dB for 500, 1000 and 2000 Hz,
and 80 dB for 4000 Hz, they also had poor PB max scores. Absent/decaying acoustic
reflexes. Auditory symptoms on the ipsi-lateral ear only
All audiometric test results showed an overall between the 2 groups, the degree of overlap is
relatively small for pure tone sensitivity measures, but more extensive for acoustic reflex, PB
max scores and roll over.
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In contrast to the flat audiometeric configuration in IA lesions, the EX lesion group showed a
steeply sloping audiometric contour. The same have also been reported by Flower in 1965
and Johnson in 1969, 1972. The roll over phenomenon was observed in both the groups, but
could not differentiate the groups.
If the intra-axial mass produces an exophytic extension into the CPA, the extra-axial
symptomatology caused by the exophytic extension may mask the primary intra-axial site.
Correlation of Audiological and histopathological findings
Vestibular Schwannoma (Extra axial lesion)
80% of tumors arising in the CPA are vestibular schwannomas(VS). The tumor arises from
the Schwann cells, which surround the sheath of the CN VIII, not from the nerve itself.
Vestibular schwannoma (also known as acoustic neuroma, acoustic neurilemoma, or acoustic
neurinoma) is a slow growing, intracranial extra-axial benign tumor that usually develops
from the vestibular nerve or very rarely from the cochlear nerve (less than 5 percent).
There are 2 major types of VS. The sporadic type, occurs in 95% of all cases, is unilateral,
and usually affects individuals 40 to 60 years old. VS associated with neurofibromatosis type2 are typically bilateral, autosomal dominant, and usually affects teens and young adults. (Ho,
2002)
Because vestibular schwannomas arise from the investing Schwann cell, tumor growth
generally compresses vestibular fibers to the surface. Destruction of vestibular fibers is slow
and gradual and the reduced vestibular function is compensated for by central cerebral
mechanisms.
Consequently, many patients experience little or no imbalance. Once the tumor has grown
sufficiently large to fill the internal auditory canal, it may continue to grow either by erodingor expanding the bone and/or by extending out into the cerebellopontine angle. Vestibular
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schwannomas, like other space occupying lesions, produce symptoms by any of four
recognizable mechanisms: (1) blockage of the cerebrospinal fluid spaces, (2) displacement of
the brainstem, (3) compression of vessels or (4) compression of nerves.
Vestibular schwannomas can continue to grow until they reach 34 cm in intracranial size
before symptoms of major mass effect develop.
Thefacial nerve is quite resistant to the stretching imposed by tumor growth without
clinically apparent deterioration of function until the tumor has reached a very large size. The
cochlear and vestibular nerves, on the other hand, are much more sensitive to this stretching
and compression so that even small tumors confined to the internal auditory canal may
produce early symptoms in the form of hearing loss or vestibular disturbance.
As the tumor approaches 1.5 cm in intracranial diameter, it generally begins to abut the
lateral surface of the brainstem. Further growth can occur only by compressing or displacing
the brain stem toward the contralateral side.
A 2.0 cm tumor usually extends sufficiently far anteriorly and superiorly to compress the
trigeminal nerve and sometimes produces facial hypoesthesia (impairment of sensitivity).
Growth over 4.0 cm generally results in progressive effacement of the cerebral aqueduct and
fourth ventricle with eventual development of hydrocephalus. However, other mechanisms
may be responsible for the occasional development of hydrocephalus in tumors as small as
2.0 cm. A known factor of importance is the increase (up to 1015 fold) of cerebrospinal
fluid protein content in the presence of a vestibular schwannoma (Rogg, 2005)
Etiology
Merlin is defined as a tumor suppressor gene because its inactivation or loss of expression
was found in all NF2 tumors as well as 6080 % of sporadic meningiomas and
schwannomas.
Both unilateral and bilateral vestibular schwannomas may form due to malfunction of a gene
on chromosome 22, which produces a protein (merlin) that controls the growth of Schwann
cells. In NF2 patients, the faulty gene on chromosome 22 is inherited and is present in all or
most somatic cells. However, in individuals with unilateral vestibular schwannoma, for
unknown reasons this gene loses its ability to function properly and is present only in the
schwannoma cells (Lanser, 1992).
Vestibularsymptoms
Vestibular symptoms are uncommon as the presenting symptom of a VS, despite the fact that
the tumor originates on the vestibular nerve. This partly may be due to the slow-growing
nature of the tumor so that an episode of vertigo years prior may be forgotten. Sudden
vertigo with nausea and vomiting, similar to vestibular neuritis, is reported to occur in 5% to
19% of patients. This presenting symptom mainly occurs in patients with small tumors.
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Compensation can be complete with no residual symptoms. Dysequilibrium or unsteadiness
is a more common symptom later in the course of VS.
Patients may note the symptoms on rapid motion of the head or body only or as a constant
state. Constant symptoms are associated with increasing tumor size, with impingement on the
cerebellum and brainstem occurring in addition to encroachment on the vestibular nerves.
Phases of tumor growth - 1) Intracanalicular 2) Cisternal 3) Compressive 4) Hydrocephalic
-Jackler (2000)
Treatment
Watchful waiting has been recommended for the elderly and for infirm patients with tumors
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Audiological test results
The signs and symptoms present at diagnosis are almost exclusively auditory, and only rarely
are other neurologic symptoms found in the absence of auditory symptoms.
A number of authors (Chandrasekhar, 1995; Salesnick, 1992; Thomson, 1990) verified that
the initial or presenting symptom is hearing loss with or without tinnitus in about 80% of
patients. Tinnitus onlyabout 7% of patients, and hearing loss only - 60% to 70%.
The percentage of patients with hearing loss or tinnitus (or both) at the time of diagnosis is
about 95% or greater in AN patients even in patients with small tumors.
Correlation between degree of HL & time since symptoms started
A small correlation may exist between the degree of hearing loss and the amount of timesymptoms have been present, but such a wide variation exists that generalization is difficult.
Correlation between degree of HL & tumor size
The symptoms of hearing loss or tinnitus are independent of tumor size, but there is a definite
trend toward better hearing in tumors less than 1 cm. (Stipkovits, 1998)
Pure Tone Audiometry
Progressive, unilateral, sensorineural hearing loss, which typically begins in the highfrequencies and progresses to involve the lower frequencies.
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20% of the patients will present with sudden sensorineural hearing loss (Sauvaget et al,2005).
Additionally, 20% will present with recurrent fluctuating hearing loss. Less common are the vestibular complaints. As the tumor enlarges, neurological changes
may be evidenced as decreased function of CN VII and V. With continued growth, apatient may develop hydrocephalus from brainstem compression.
10 - 25% of patients have severe to profound hearing losses, with PTA greater than 80 dBat the time of their initial audiogram.
Duration
Can be either progressive or sudden.
Sudden sensorineural hearing loss (SSHL) has been defined as a sensorineural hearing loss of
> 30 dB over at least 3 contiguous audiometric frequencies that develop in a period of a few
hours to 3 days. (Brackmann, 1981)
Characteristics of acoustic neuroms (AN) with sudden HL differed from other AN
presentations in several ways: (1) smaller tumor, (2) shorter duration after onset, (3) lower
incidence of dizziness or other neurologic symptoms, (4) a trough-type audiogram
configuration, and (5) a higher incidence of a normal caloric response on
electronystagmography. A higher incidence of the subjective symptom of aural fullness was
also noted. Of 14 patients with intracanalicular tumors, 5, or 36%, had a sudden hearing loss.
A vascular cause or a cause from nerve compression, due to the high incidence of
midfrequency loss and the low incidence of dizziness. (Ogawa, 1991).
Configuration of hearing loss
Classically, the patient with an VS or other CPA tumor has been described as having a high-
frequency sloping SNHL.
The U-shaped configuration has the greatest hearing loss at 2000 Hz. Generally, no typical
shape is found for any one type of tumor; however, Kanzaki, 1991 and Dornhoffer, 1994
noted that 20% to 22% of small and intracanalicular tumors had a U-shaped audiometric
configuration.
The peak configuration has the best hearing thresholds at 2000 Hz, with increasing losses at
the low and high frequencies (HF)
Majority of losses are of the HF nature with abrupt HF losses a major proportion.
Cause of the hearing loss
1) Direct VIII nerve compression explains slowly progressive hearing loss.Most vestibular schwannomas arise from one of the vestibular nerves at the junction of the
proximal and distal nerves (also the junction of the Olivodendroglia and the Schwann cells).For tumors that originate in the cochlear nerve, they originate more distally. These slowly
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growing lesions within the confines of the bony IAM will cause slow compression of the
cochlear nerve. The hearing loss will reflect this compression of the cochlear nerve. The rate
and amount of hearing loss will vary depending on the rate of growth of the tumor, the
plasticity of the verve, the consistency of the tumor, the location within the IAC and the
amount of early expansion into the CPA.
The pure tone loss may be seen quiet late in the course of the tumor growth, because as
Woellner (1955) demonstrated, if the organ of corti is intact, 75% of the auditory nerve fibers
need to be destroyed before pure tone hearing is affected.
This mechanism also partially explains the middle- and high- frequency losses associated
with VIII nerve tumors.
2) Location of high and low frequency fibers to explain high frequency loss.Sando (1964) demonstrated anatomically that the high frequency auditory fibers from thebasal turn of the cochleaare located inferiorly and laterally all the way from the spiral
ganglion to the cochlear nuclei in the brainstem, whereas the middle and apical fibers twist
about the axis from the spiral ganglion to the cochlear nuclei. The apical fibers actually make
1 turns about the long axis before reaching the brainstem. They are also more centrally
located in the nerve. These differences in position within the nerve, allow for earlier
involvement of the high-frequency basal fibers and a variable involvement of the middle- and
low- frequency fibers.
3) Increased pressure in the IAC (Badie and colleagues, 2001)They measured intracanalicular pressure in 15 patients undergoing tumor resection. The
pressure directly correlated with the size of the tumor within the IAC. There was a strong
trend toward lower IAC pressure in patients with better pre-operative hearing, but the
differences were not statistically significant.
4) Vascular compression ( Explains sudden HL)Anterior inferior cerebellar artery loops into the internal auditory meatus a variable distance,
and the internal auditory artery arises from the loop of the Anterior inferior cerebellar artery,
the blood supply to the cochlea should be at risk with expanding lesions of the IAC. The
internal auditory artery further divides into its vestibular branches. So lesions in the internal
artery should result in vertigo, or in very rapid deterioration of cochlear function, especially
in the low frequency since blood supply to the cochlear apex is more tenuous (Perlman, 1955;
Kimura, 1955)
But the symptoms are not typically seen in vestibular schwannoma. Also, acute
vascular compression should cause electrocochleographic changes identified by a decreased
cochlear microphonic, which is also not seen often.
The mechanism for sudden hearing loss is thought to be a vascular occlusive event.
5) Myelin and axon compression damage (Lehnhardt, 1990)
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Early in the course of compression, the myelin damage might be the only lesion, allowing for
tone decay and acoustic reflex decay without recruitment. Auditory brainstem evoked
responses would also be delayed. This would be the typical picture of AN. Later on, as
myelin and axon compression both become involved, the ABR would be delayed, still
without recruitment. If the tumor compression changes, for instance, in cessation of tumorgrowth or recovery from intratumor hemorrhage, enough axons may remain to allow for
adequate nerve conduction and remyelinization may occur. Therefore recruitment may be
positive, the ABR may be positive, but tone decay may not occur.
6) Lesions of the olivocochlear system or auditory efferentsHas been implicated in early hearing losses with auditory distortion, but little pure tone
threshold increase. Deficits of the efferent system will affect the OCs of the cochlea
causing difficulty with speech understanding in noise and the subjective sensation of
distortion while having little effect on the pure tone perception. Outer hair cell function as
evaluated by OAE should be reduced or absent in ears affected by cochlear hearing losses
(Telischi, 2000) Distortion product otoacoustic emissions (DPOAEs) should be normal in VS
patients if the hearing thresholds are better than 45 to 50 dB HL and the loss is purely
retrocochlear (neural compression), and DPOAEs should be abnormal in losses that have a
cochlear (vascular or inner ear biochemical) component.
Telischi(2000) reported on 97 patients with VS who underwent DPOAE testing. He
found that from 37% to 57% of tumors were classified as having a cochlear loss pattern, and
41% to 59% had a retrocochlear pattern depending on the analysis method used. Heconcluded that the majority showed evidence of reduced outer hair cell function in at least
one frequency. The effects on the OAEs did not reverse after tumor resection even when
other behavioral and objective hearing measures improved, implying a nonreversible cochlear
or efferent pathway damage. These findings are compatible with previous studies that have
demonstrated biochemical and magnetic resonance image (MRI) changes in the ipsilateral
cochlea of some VS patients.
7) Biochemical changes within the perilymph of the cochlea ( Explains cochlear HL)As early as 1950, Dix and Hallpike found changes in the characteristics of perilymph
in VS patients. Somers and coworkers (2001) reported on MRI studies in AN and
meningiomas, and showed increased postoperative hearing preservation in ears with normal
intralabyrinthine and lateral IAC fluid characteristics versus ears with hypointense perilymph
and fundus cerebrospinal fluid (CSF) images. They theorized that an arterial vascular
compromise in the IAC secondary to mechanical obstruction by the tumor leads to reversible
and irreversible intracochlear changes. Some MRI changes returned to normal after tumor
removal, but many times OAEs do not revert to normal, again suggesting possible reversible
biochemical changes but permanent hair cell injury.
8) High Tumor volume
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Grabel and colleagues (1991) suggested that the chronic effect of high tumor volume
within the infratentorial compartment may also play a role in VS hearing loss when they
showed a strong positive correlation between maximum tumor volume and prolonged ABR
interpeak latencies for waves III through V following stimulation of the nontumor side. Thissuggests tumor volume-generated distortion as an additional factor in tumors that extend into
the CPA.
9) Traction of the VIIIth CNSekiya and colleagues (1986) demonstrated in dogs that gentle traction on the eighth
nerve in the CPA could lead to hemorrhages within the nerve and secondary auditory deficits.
This mechanism may help explain the hearing loss associated with other tumors within the
CPA that cause nerve distortion without significant compression. It may also help explain the
tinnitus and hearing loss that may accompany neurovascular compression of the eighth nerve
in the CPA.
The hearing losses associated with neurotologic entities, and especially those of VS,
most likely involve multiple mechanisms, any or all of which may be seen in any one lesion.
The variety of mechanisms possible for the hearing loss of neurotologic lesions also helps
explain the variety of hearing losses that may be seen.
The cochlear nucleus is a unique brainstem structure, only its afferent input is ipsilateral,
coming from the cochlea by way of the auditory nerve. Consequently, damage to the nucleuscan mimic VIIIth nerve dysfunction. (Jerger & Jerger, 1974), because it may only produce
ipsilateral pure tone deficits (Dublin, 1976). Tumors situated in the CPA region may affect
the cochlear nucleus and produce central auditory deficits.
Speech Audiometry
The very poor SDS for the tumors in general supports a HL mechanism of neural
compression. Thomsen and colleagues discussed the concept that discrimination at high
presentation levels is primarily an inner hair cell function, and 95% of the fibers in the
auditory nerve originate in the inner hair cells. Therefore, the neural compression would
inhibit inner hair cell function with the resultant poor discrimination, especially at increasing
presentation levels. (This can also be used to explain rollover phenomenon, which occurs at
higher levels)
Speech discrimination
Speech discrimination scores will be reduced out of proportion to the level of the hearing
loss.
Reason - An anatomic correlation indicates in humans between the degree of auditory nerve
fiber loss and the level of speech discrimination. Woellner (1955) found that up to 75% of the
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nerve fiber loss could still leave a patient with nearly normal pure tone hearing, but that
complex speech processing suffered.
The roll over phenomenon defined as a decrease of greater than 20% in SDS on affected side
when the stimulus intensity is progressively increased. Its sensitivity to tumors is only 65%.
(McFarland, 1989).
In central lesions rollover can be present on the side opposite to the lesion, and VIIIth nerve
on affected side.
Discrepancy between recognition of words and sentences.
Rollover presentDecreased ability to understand words as the intensity is increased.
The degree of hearing loss and speech discrimination deficits varies widely, but historically
patients have had moderate to severe pure tone losses with poor speech discrimination scores
(SDS) on presentation.
Acoustic Reflexes
95% - Absent stapedial reflexes.
In 1952, Metz first noted the absence of acoustic reflex as a marker for RCP. Subsequently,
the sensitivity of the acoustic reflex in diagnosis of acoustic neuroma has been reported to be
as low as 17% and as high as 90%. (Hardy, 1989; Anderson, 1980)
R L (Probe ear)
Horizontal
Unibox
Diagonal
Inverted L-shape
Acoustic reflex decay
Acoustic reflex decay, defined as decay of 50% of a tone administered at 10 dB over
threshold, was originally described by Anderson in 1969 and was found to have a sensitivity
of 85% in predicting the presence of an AN (McFarland, 1989). Variability in sensitivity in
various reported series has ranged from 36% to 100% (Anderson, 1980; Hardy, 1989).
Auditory Brainstem Response (ABR)
Intra axial and/or extra axial brainstem disorder.
Intra axial brainstem disorder eccentric to one side (left)
Intra axial and/or extra axial brainstem disorder.
Right nerve disorder (left side)/severe cochlear loss (in left ear)
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The 4 main parameters that can be used are 1) High rate versus low rate of stimulation
(Pratt and Sohmer, 1976) 2) IT 5 3) Wave V/I amplitude 4) Inter peak latencies
For high rates of stimulation in ABR, due to the presence of tumor, there occurs brainstem
distress which leads to increased recovery time as compared to normals. Therefore there is
a longer than normal latency difference between the high and the low rates of stimulation.
Tumors within the brainstem can result in degraded waveforms, increased latencies, and
absent waves generated rostral to the site of lesion (Jerger et al., 1978; Starr and Achor, 1975)
Incase of large tumorsabnormal recordings from contralateral side have been recorded
(Nodar & Kinney, 1980)
For wave V/I amplitude ratio, both the waves need to be found for a ear. Wave V is expected
to be greater than wave I by a ratio of at least 1 if the ratio falls below 1 v - this is an
indication of RCP. Tumors have been observed in patients when the wave V/I amplitude ratiois less than 0.5 (Starr & Hamilton, 1976)
A reliable parameter in the diagnosis of CPA tumor is the interaural wave V
latency differences (IT5). Using the Selters and Brackmann [1977] 0.2 ms criterion for the
IT5 delay (i.e. abnormal IT5 > 0.2 ms), if one ear has normal hearing and the involved ear has
hearing better than 50 dB at 4kHz. To correct for the HL at 4kHz, for each 10dB increase
above 50 dB, a 0.1 msec should be subtracted from the wave V latency when comparing the
results between the 2 ears (Brackmann, 1990) When the hearing threshold is greater than 50
dB at 4 kHz, the ABR is of reduced diagnostic power.
There were a few cases where the IT5 measure for the lower intensity click detected a tumor
missed by the IT5 measure for the higher intensity click and vice-versa. Thus, it appears that
for an individual case, click level may affect the results of the IT5 measure.
Smaller tumors tend to manifest IT5 abnormalities, whereas larger tumors lead to a total loss
of waveforms (Jackler, 1992).
Unfortunately, ABR misses a significant number of tumors, especially those of a non-
acoustic origin.
(1) High-frequency fibers dominate the standard click-evoked ABR latency measure,
(2) Tumors will be missed if these high-frequency fibers are not sufficiently affected by the
tumor
(3) Small tumors do not always affect the subset of high-frequency fibers sufficiently.
Stacked ABR (Don et al., 1997)
The derived-band ABR technique consists of recording ABRs first to broad-band clicks
presented alone then to a series of simultaneous ipsilateral presentations of the clicks and
high-pass filtered pink noise with varying cutoff frequencies.
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The cut-off frequency of the high-pass noise is successively lowered from one run to the next
in octave steps from 8 kHz to 500 Hz. This process masks progressively lower frequency
regions of the cochlea. Subtracting the response for one run from the previous one forms a
derived-band response. The theoretical CFs of the five derived-band ABRs are 11.3, 5.7, 2.8,
1.4, and 0.7 kHz. It can be shown that the sum of these derived-band ABRs is essentially thesame as the click alone ABR (ABR to clicks presented alone).
However, much of the activity in the derived-band ABRs is not seen in the click alone ABR
due to phase cancellation of activity.
A -ABR responses to clicks and high-pass masking noise
B -Derived band ABRs with center frequencies noted
C -Aligned derived-band ABRs into above to form the Stacked ABR.
D - The Stacked ABR on the tumor side is reduced by over 50% in comparison to the non-
tumor side.
A B C
D
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The stacked ABR is obtained by (1) temporally aligning the derived-band ABR waveforms
so that the peak latencies of wave V in each derived band coincide, (2) adding together these
aligned derived-band ABR waveforms. The wave V peaks of the derived-band ABRs are
aligned to the wave V peak latency for the arbitrarily selected 5.7 kHz CF derived band.
By temporally aligning the peak activity initiated from each segment of the cochlea, we
synchronize the total activity and remove the phase-cancelling effect that occurs in the
standard response.
The stacked ABR amplitude is the peak to- trough measure of wave V in the stacked ABR.
Thus, compared to standard ABR amplitude measures, the amplitude of the stacked ABR
wave V reflects more directly the total amount of activity initiated across the cochlea
When activity initiated from any part of the cochlea is blocked or desynchronized by a tumor
at the 8th nerve level, then the stacked ABR amplitude will be reduced. As demonstrated by
Don et al. (1997), such reduction may not occur for the standard ABR wave V amplitude.
Many small tumor cases have clinically normal hearing. One possible explanation for such
cases is that the small tumor mainly desynchronizes but does not block the activity of some
fibers. This would reduce their synchronous contribution to the stacked ABR but allow
simple nonsynchronous activation by audiometric tones presented at normal threshold levels.
This leads to the hypothesis that the amount of reduction in the stacked ABR measured from
patients having both a small tumor and hearing loss should be greater than expected from the
hearing loss alone.
The frequency specific responses can also be evoked using tone burst ABR, wherefrequency specific tone bursts can be presented, and then the responses can be summed
similar to stacked ABR.
The Advantages of an ABR Test over an MRI Scan for Small Tumor Screening
These problems of high cost, unavailability (rural areas), patient discomfort, and risks to
patients with metal implants, are circumvented by using ABR tests.
Interaural SABR (ISABR) amplitude difference measure
To improve the sensitivity and specificity of the SABR amplitude measures ability to detect
small unilateral acoustic tumors.
The variability between ears of a given individual is small.
Immune to variables that affect the absolute SABR amplitudes because it is a relative
measure.
It is better at assessing tumor patients with very large and non-tumor patients with very small
absolute SABR amplitudes. In the study by Don et al. [2005], the mean reduction observed for
the 54 small acoustic tumor patients relative to the 78 non tumor normal hearing subjects was
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approximately 50%. That is, by the time the patient seeks medical attention for his/her
symptoms, synchronous neural activity has been reduced, on average, by 50%.
Even with this average amount of reduction, it is conceivable that in individuals with
normally very large SABR amplitudes, a tumor may still not reduce the SABR amplitude
below the criterion level.
For example, if an individual who would normally have a SABR that is twice as large as the
mean for NTNH subjects had a small tumor that reduced the SABR by 50%, the SABR
amplitude would then be equivalent to the mean of NTNH subjects and fall within the normal
criterion limits. Thus the tumor would be missed and the tests sensitivity would be
compromised.
If the average reduction is 50%, there will obviously be a number of cases where the
reduction is less than as well as greater than 50%. Those tumors that reduce the SABR
amplitude by less than 50% may be missed as well. This problem of missing tumors in
individuals with normally very large SABRs or reductions of less than 50% can be minimized
if it can be shown that the SABR is typically very similar between ears such that an interaural
comparison can be used, much like the standard IT5 latency measure developed by Selters
and Brackmann (1977).
Likewise, specificity could be improved for individuals who would normally have low SABR
amplitudes or amplitudes that are low due to either hearing loss or age (Don et al., 2005).
In these individuals, with the exception of bilateral tumor cases, equal but below criterion
SABR amplitudes in both ears would be suggestive of a non-tumor subject.
However, when feasible and valid, the interaural measure may be helpful because it uses the
individual patient as his/her own control rather than absolute values of the SABR amplitude
generated by a specific population.
Hearing loss (HL) reduces synchronous neural output and thus, the SABR amplitude. If there
is HL in a tumor ear, the sensitivity of the SABR measure improves because both the tumor
and the HL reduce the SABR amplitude. But if there is a significantly greater HL in the non-
tumor ear of a tumor patient, the reduction in the SABR amplitude due to the tumor may be
matched by the reduction due to the hearing loss in the non-tumor ear. As a result, not onlywill the specificity of the SABR measure be adversely affected due to the significantly
reduced SABR amplitude in the non-tumor ear, but the interaural amplitude difference will be
reduced and the sensitivity of the ISABR measure will be compromised.
A method of compensating for the HL would be valuable in these cases. Each dB difference
in the interaural clinical PTA reduced the SABR amplitude by an additional 1.35%. It can be
used as a general guideline in compensating for the effect of HL in small tumor cases.
Clinically, the IT5, SABR, and ISABR measures can be used together to maximize efficient
detection of small unilateral acoustic tumors.
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Electronystagmography
Lesions involving the vestibular end-organs and the vestibular nerve are classified as
"peripheral". Lesions beginning at the vestibular nuclei and proceeding centrally through the
brain stem and cortex are classified as "central". For example, an internal auditory canal
(IAC) acoustic neuroma would be considered "peripheral" for vestibular test purposes,
although it would not be considered peripheral for audiologic purposes.
Acoustic neuroma primarily affects the vestibular nerve whereas Mnire's disease has its
primary effect in the vestibular end-organs. A cerebellopontine angle tumor would be an
example of a "central" vestibular lesion if its primary impact and presence involved the
vestibular pathways in the brain stem or cerebellum. More commonly, acoustic neuromas
tend to create both peripheral (caloric weakness) and central (gaze nystagmus, poor pursuit,
or saccadic dysmetria) vestibular test abnormalities depending primarily on the site and size
of the lesion.
The central vestibular system and its cerebellar connections may be affected by a metastatic
tumors - hemangioblastomas (Tognetti,1986), hemangiomas (Eller,1976), and germ cell
line tumors,. The same tumors that affect the peripheral vestibular nerve in the
cerebellopontine angle may also compress the brainstem, resulting in central vestibular
pathology. In addition, primary intra-axial tumors, such as gliomas, ependymomas, and
medulloblastomas (Watson,1981) in young patients may produce central vestibular
dysfunction.
Two relatively pure isolated forms ofcentral nystagmus are downbeat and upbeat nystagmus.In the case of downbeat nystagmus pathology usually interrupts the fibers crossing in the
dorsal tegmentum of the medulla. This relatively selective involvement of information
coming from the posterior canals leads to a slow phase drift of the eyes up and a secondary
correctional movement with a fast phase down. Clinically, downbeat nystagmus is usually
seen with cerebellar degeneration or pathology at the cervical medullary junction.
- Gaze (fixation) testRotary gaze nystagmus usually is consistent with a brain stem lesion, often involving the
vestibular nuclei (Cogan, 1977). It is observed in such disease processes as large, space-occupying lesions that distort the floor of the fourth ventricle wherein the vestibular nuclei
are housed. Rotary gaze nystagmus has been reported in cerebellar disease as well (Zee,
1987). It should be noted that in very early stages of an acute, unilateral peripheral vestibular
lesion, a rotary component to the predominantly horizontal nystagmus may be present. This
should be considered whenever a patient is in an acute stage of vertigo secondary to a
unilateral peripheral vestibular lesion where a strong spontaneous nystagmus is present.
Direction-fixed, horizontal - Peripheral vestibular (end-organ or nerve); weakened ear usually
is away from fastcomponent of nystagmus (that is, right-beating nystagmus suggests left ear
weakness; left beating suggests right ear weakness); nystagmus enhanced with eye closure
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Direction-changing, horizontal - Brain stem; cerebellar lesions
Vertical - Upbeating gaze nystagmus suggests lesion in brain stem or cerebellum; down-
beating gaze nystagmus suggests lesion in cerebellum or cervicomedullary junction
Rotary - Brain stem (vestibular nuclei); also seen in cerebellar disease
Periodic alternating - Cerebellum, brain stem, or cervicomedullary junction
- Saccade testSaccadic abnormality is seen as small catch-up eye movements in both directions in order for
the eyes to reach the target. This is referred to as hypometric saccadic eye movement and is
seen in brain stem/cerebellar disease.
Ipsilateral dysmetria - Cerebellopontine angle lesions on same side as dysmetria
Bilateral dysmetria - Cerebellum or brain stem lesions
- Ocular pursuit test (sensitive test for CNS dysfunction within the ENG battery)When a patient's visual pursuit system is impaired, rapid corrective eye movements replace
the smooth pursuit movement so the eye can "catch up" with the moving target.
When the cath-up movements form a "stair-step" pattern consisting of small saccadic
movements, the defect is referred to as saccadic pursuit. Saccadic pursuit is seen frequently in
patients with cerebellar disease.
Visual pursuit abnormalities are usually caused by lesions in the brain stem, cerebellum, or
cerebral cortex. However, acute peripheral vestibular lesions that cause a spontaneous
nystagmus also may affect the smooth pursuit test unilaterally and must be considered. In this
situation a unilateral pursuit tracing abnormality may be secondary to a peripheral lesion
when there is no actual deficit within the pursuit per se.
- Optokinetic testThe purpose of the optokinetic test (OKN) system is to maintain visual fixation when the
head is in motion.
Isolated OKN abnormalities are thought to reflect cerebral cortex disease, and when they
appear in conjunction with a direction-changing gaze nystagmus, they are thought to
represent brain stem or cerebellar dysfunction (Coats, 1975).
When the lesion is in the BS, an abnormal OKN response is more commonly asymmetric not
because of dysfunction within the OKN system, but because of the presence of the gaze
nystagmus.
- Static positional test
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The purpose of static positional testing is to determine if changes in head position create
nystagmus or modify already existing nystagmus. When a spontaneous nystagmus is present,
the direction of the fast phase and the intensity of the slow phase should be noted. This allows
the clinician to monitor changes over time. Nystagmus that beats toward the undermost ear is
called geotropic, and nystagmus that beats toward the uppermost ear is referred to asageotropic. It has been suggested that ageotropic nystagmus is seen more commonly in
central vestibular disease, and geotropic is seen more commonly in peripheral vestibular
disease. But, both types are caused by peripheral vestibular disease more often than central
disease.
- Caloric test (most specific test within the ENG battery)Used to induce endolymph flow in the semicircular canals (primarily the horizontal canal) by
creating a temperature gradient from the lateral to the medial part of the canal.
Failure of fixation suppression (FFS) - Cerebellum; ensure that patient has sufficient visual
acuity to allow fixation on target.
Unilateral or bilateral weakness. Almost always peripheral vestibular disease
ENG tests the function of the horizontal SCC, which is innervated by the superiorvestibular nerve, a normal test suggests that the tumor if present, may be originating from
the inferior vestibular nerve.
In 1990, Welling et al found an ENG sensitivity of 70% in their series of patients with AN,
and concluded that the ENG was not cost effective.
Small acoustic neuromas manifest ipsilateral reduced vestibular responses and spontaneous
nystagmus opposite to the side of the tumor. Large tumors frequently manifest additional
finding such as failure of fixation suppression, bilateral slowing of optokinetic nystagmus,
saccadic pursuit and occational bilateral horizontal gaze nystagmus.
It is also frequent for large tumors to not manifest any ENG abnormalities. (Nedzelski, 1983)
Otoacoustic emissions
The diagnostic value is limited. From a review of several reports Robinette and Durrant
(1997) found that only 20% of 316 patients with surgically confirmed CN VIII tumors had
mild or greater hearing loss with EOAE present to support the diagnosis of RCP. This lack of
diagnostic precision can be attributed to cochlear hearing losses that frequently accompany
CN VIII tumors. The cochlear loss is thought to be due to the restriction of blood supply to
the cochlea related to the tumor growth. (Levine et al, 1984) + (Point 6causes of hearing
loss)
Cochlear Origin of Early Hearing Loss in VS (Victor, Mann (2009))
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A group of 19 VS patients with normal/symmetrical hearing and a group of 20 VS patients
with mild HL (threshold at any tested frequency better than 45 dB HL) on the tumor ear side.
DPOAE amplitude between the tumor & nontumor ear were studied at frequenciesof 1, 1.4, 2, 2.8, and 4 kHz.
Tumor size did not differ significantly between the two groups. Results: DPOAE amplitudes do not differ strongly between the ears in VS patients
with normal/symmetrical hearing but are decreased compared with the nontumor ear
at frequencies 1, 1.4, 2, and 2.8 kHz in VS.
Conclusion: Amplitudes of DPOAEs begin to decrease even at the early stages of HLin VS patients, which suggest a cochlear origin of early HL in these patients.
DPOAEs may be used in a clinical setting to monitor progression of cochlear damageat the early stages of HL in VS patients.
Telischi, 1995
Studied effect of acoustic neuromas (N) on the amplitudes of evoked OAEs and to
compare these findings with tumor-induced hearing levels.
Tests of behavioral audiometry, DPOAE & TEOAE were performed on 44 patients with AN.
Results - Majority of ears with AN displayed one of two patterns: a cochlear pattern (OAE
amplitude decreased or absent OEs) or a noncochlear pattern (where OEs were present)
Although behavioral hearing thresholds were higher with larger tumors, OAE levels exhibited
no clear relationship to tumor size.
The findings support the notion that ANs may cause HL according to two types of influence
that act at different levels of the peripheral auditory system.
The tumor's cochlear effect on evoked OAE activity is most likely caused by an indirectly
mediated compromise of the organ of Corti's vascular supply.
It is probable that the direct pressure of the tumor on the eighth cranial nerve is responsiblefor the observed noncochlear effects.
Using DPOAEs and TEOAEs, Telischi et. al. (1995) found that HL involved the cochlea in
71 % and neural elements in 41% of the 44 patients with AN.
When DPOEs and PTs were compared in 97 patients with N Telischi (2) assigned
55 (57%) to the cochlear damage group, 40 (41%) to the noncochlear damage group, and 2
(2%) to an intermediate group.
Colleaux, 1998 (Prognosis)
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TEOAEs in ears with AN are found in younger patients with a lower preoperativemean PTA loss and are accompanied by fewer functional complaints.
TEOAEs (when present) indicate a better preservation of inner ear vasculature.
TEOAE presence in the pathological ear could provide an additional criterion orpredictive factor for the successful outcome of attempted hearing-conservation
surgery in ears with ANs.
Contralateral suppression of OAE
Maurer et al (1995) recorded TEOAE in 6 of 20 patients with unilateral VS. The amplitudes
of these emissions were significantly smaller than those in a normal control group.
The application of contralateral white noise (40, 50, 60 dB HL) did not suppress the
amplitude of the TEOAE in the tumor ears, but in the ear without tumor greater suppression
effects were noted than in the control group.
Maurer tentatively suggested that the VS had reduced efferent function on the affected side,
and that some counterintuitive effect was present contralaterally.
This study contained the suggestion that a VS compressing the vestibular divisions of the
VIIIth nerve, specifically the inferior, affects the efficacy of the efferent function on that side.
It should be noted however that this effect was demonstrable in only a minority of patients.
Ryan et al. (1991) did a study in which they found intact OAEs in the affected ear, but no
suppression effect, suggesting blockage of efferent conduction on the side of the tumor.
Contralateral Suppression of TEOAE in Patients with CPA Tumor (Ferguson et al. (2001))
Aim: Investigate the effect of CPA tumor on the medial efferent nerve pathways to both
tumor and non-tumor ears by examining alterations in TEOAE amplitude that result from
contralateral acoustic stimulation.
Design: Contralateral suppression of TEOAEs using broadband noise was measured
preoperatively in 17 patients with unilateral CPA tumor and 17 normally hearing controls,
matched for age and gender.
Results: Control ears sig. more suppression than the tumor and non-tumor ears in the patient
group.
There was, however, no significant difference in suppression between the tumor and non-
tumor ears, and the statistical correlation for suppression between them was high.
Effect of age on suppression in both the control and patient groups where suppression
reduced as age increased.
Four of the 17 patients had TEOAEs, which were clearly present in the tumor ear despite
substantial hearing loss, three of which had no measurable hearing.
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Conclusions: Neural compression by CPA tumor disrupts the medial efferent nerve control
mechanism to the OHCs of tumor ears.
Also reduces transmission of afferent nerve impulses from the tumor ear, which cross over to
the medial olivo-cochlear complex and reduce the inhibitory control of OHC function in the
non-tumor cochlea.
These findings show that for a majority of the patients, there is a cochlear involvement,
although the tumor occurs on the nerve.
Vestibular Evoked Myogenic Potential
Click-evoked myogenic potentials can be recorded with surface electrodes over each
sternocleidomastoid muscle. Latencies and amplitudes of responses will be measured.
VEMPs were absent or decreased in 77% with acoustic neuroma (n=48). Thirty-nine of the
62 patients showed absence of responses on the affected side, 9 showed decreased responses,and 14 showed normal responses. In other words, 48 patients (77%) showed abnormal
amplitudes.
All patients with AN who showed latency prolongation had large tumors that compressed the
brainstem. These results suggest that brainstem lesions, especially those in the vestibulospinal
tract, are required for the prolongation of p13. From the practical viewpoint, p13 showed
prolongation of the latency more frequently than n23. The SD of n23 was greater than that of
p13, resulting in a wider normal range of n23 than p13. Therefore, p13 is a better parameter
for evaluation of the latency of VEMP.
VEMP testing could still be a useful neurophysiological test for diagnosing acoustic neuroma
because VEMP testing and caloric testing could classify ANs according to the involved
nerves: the inferior vestibular nerve or the superior vestibular nerve.
Tests used previously
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Because up to 20% of the acoustic neuroma patients manifest a cochlear type HL rather than
retrocochlear HL (Flood, 1984), the accurate diagnosis of RCP is of limited clinical value.
Tone decay test (TDT)
Anderson(1980) found a sensitivity of 46% and Hardy (1989) found a sensitivity of 45% tothe detection of acoustic neuroma.
Suprathreshold Adaptation Test (STAT)
Sensitivity is in the range of 45% towards acoustic neuroma (McFarland, 1989).
Mechanism through which tumors cause symptoms
Tinnitus
Mechanism for tinnitus is thought to be the same as that of hearing loss, neural or vascularcompression. Because tinnitus, like hearing loss can be considered to be a manifestation of a
dysfunctional auditory nerve, the two may occur concurrently. (Edwards, 1951). Unilateral
tinnitus in the absence of hearing loss warrants investigation, because few patients with VS
present with tinnitus in the absence of hearing loss.
Ephaptic Coupling
It has been suggested that as a VS grows and takes up space within the internal auditory
canal it compresses auditory nerve fibers causing them to cross talk by ephaptic coupling.
(Moller, 1984) Sunderland (1991) noted that the formation of such artificial synapses was
characteristic of any injury that leads to failure of the insulating properties of the nerve
sheath, whether it is nerve section, crushing by ligature, or even moderate compression,
introduces an artificial synapse created where denuded axons are in contact. This
phenomenon would mean that the random firing of one or more nerve fibers would generate a
pattern across many fibers of the auditory nerve, this being perceived as a tinnitus sound.
CochlearDysfunction
The finding that a proportion of patients with VS have an associated cochlear hearing
loss may suggest cochlear involvement in tinnitus generation.
Moffat et al (1989) noted audiological findings that were indicative of a cochlear or mixed
cochlear/retrocochlear lesion in 36 of a series of 49 patients with sporadic unilateral VS
(73%). Prasher et al(1995) reported absent transient evoked otoacoustic emissions (TEOAE)
in 19 of 26 patients with VS (73%) in all patients in whom TEOAE was absent, a hearing loss
of 40 dB HL (hearing loss) or greater was present, and this was assumed to be cochlear in
origin.
There has been little specific consideration in the literature of the pathophysiological
mechanisms of cochlear hearing loss in VS.
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Schucknecht(1993) proposed the mechanisms of ischemia causing atrophy of the cochlea and
the vestibular labyrinth by compromising blood flow in the internal labyrinthine artery which
runs through the internal auditory canal (IAC) and/or biochemical degradation of the cochlea
and the vestibular labyrinth. Evidence for ischemic and biochemical vestibular labyrinth
injury in VS has been reported by Jahnke and Neuman (1992) who studied specimens takenfrom nine patients during translabyrinthine surgery. Examination with electronmicroscopy
demonstrated significant degenerative changes that were thought to be the result of prolonged
protein intoxication of the labyrinth (via increased perilymph protein concentrations) and by
compression of labyrinthine blood vessels by the tumor. Similar mechanisms were suggested
for cochlear dysfunction in such cases. O'Connor and colleagues(1981) had earlier identified
high protein levels in the perilymph of patients with VS, though not in a patient group with
meningioma in the IAC, and suggested that this may be a mechanism specific to VS.
Efferent System Dysfunction
An alternative hypothesis considers the presence of medial and lateral efferent fibers within
the inferior division of the vestibular nerve. Sahley (1997) A VS arising from or impinging
upon the inferior vestibular nerve might be expected to reduce the effectiveness of efferent
influence upon the cochlea, and thus perhaps cause signals in the afferent peripheral auditory
pathway to be perceived as more intense than would otherwise be the case. Thus a tinnitus
signal might appear more intense as a result of the lesion in the internal auditory meatus.
Baguley et al (2002) reviewed the effect upon tinnitus of vestibular nerve section, which
involves section of the auditory medial efferent fibers which run in the inferior vestibular
nerve.
While this procedure is almost exclusively applied to patients with Meniere's disease that has
proved refractory to medical treatment, it does represent an opportunity to determine if
ablation of the medial efferent system influences tinnitus.
Reviewing 18 papers reporting surgical series involving a total of 1318 patients, the authors
reported that there was no evidence of a consistent exacerbation of tinnitus following
vestibular nerve section, causing them to question the influence of the efferent system upon
tinnitus.
Cortical Reorganization
There is a good evidence of plastic change in the central auditory system following change in
peripheral function in both animals and humans. Further, there is a hypothesis that a
consequence of such change may be overrepresentation of certain auditory frequencies
Moore (2003) and of spontaneous bursting at boundary areas in the primary auditory cortex;
there is a growing body of evidence that these may be mechanisms of tinnitus.
Given that a VS is associated with a hearing loss in the majority of cases, and that this is due
to change in cochlear and/or cochlear nerve function, some cortical plastic change should be
expected as a consequence. In this event any associated tinnitus should be similar in
generation to tinnitus in general that is associated with hearing loss. It would also follow that
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if the peripheral status were to change further, such as with destructive (translabyrinthine)
surgery, then the tinnitus would change as a consequence.
Vertigo
Occurs due to loss of peripheral vestibular input via the vestibular nerve.
The distorted, diminished or absent vestibular information from the side of the tumor is
gradually compensated for by the central vestibular nuclei.
Acute vestibular dysfunction can occur as a result of early intracanalicular compression of
functioning vestibular nerve by the tumor, and adequate contralateral compensation strategies
have not yet developed.
Disequilibrium
The cerebellum is responsible for integration of sensory information, including visual,proprioceptive, tactile, and vestibular input. Disequilibrium occurs when insufficient or
conflicting orientation information is obtained or when normal peripheral inputs are not well
integrated centrally. Large VSs cause cerebellar or Bs compression and adversely affects the
ability of the central vestibular system to compensate for vestibular nerve dysfunction and
may eventually lead to a decompensation of the previously adapted deficit.
Cerebellar dysfunction
Incoordination, ataxia - Symptoms
The cerebellum is functionally divided into lateral and midline structures. The midline is
composed of flocculus and nodulus, both of which receive vestibular nerve input. The
flocculus, which is frequently compressed by the VS is thought to play a large role in
coordination of the vestibule-ocular reflex. Cerebellar dysfunction is usually caused by
gradual lateral compression, so midline structures are rarely involvedwith slow growing VSs.
Trigeminal nerve dysfunction
Occurs secondary to compression of the nerve high in the CPA between the superior aspect
of the tumor and the tentorium. Trigeminal neuralgia may be caused by a vascular loop
compressing the Vth nerve at its root entry zone. And this may also occur due to extrinsic
tumor compression on the loop and trigeminal nerve. Large tumors are capable of displacing
the BS to the contralateral side, which in turn may lead to compression of the opposite
trigeminal nerve and subsequent dysfunction.
Headaches
Cephalgia may be caused due to compression and localized irritation of the neural, vascular
or dural contents of the IAC or petrous face. This is a local phenomenon distinct from
hydrocephalus, and may be mediated by direct dural innervations by the branches of the
trigeminal nerve.
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Increasedintracranialpressure
Raised ICP occurs as a result of obstruction of the forth ventricle by the compressive effects
of the tumor transmitted through the cerebellum and the brain stem. Diplopia associated with
increased ICP is thought not to occur by the direct compression by the tumor but rather by
stretching of the abducens nerve.
Facial nerve dysfunction
Compression begins within the bony confines of the IAC. When the tumor gets larger the
nerve gets thinned and ribbon like as the anterior surface of the cisternal portion of the tumor
compresses the nerve against the porus acousticus, thereby stretching it at its root entry zone.
The nerve is highly resistant to compression and stretch, as noted by the low frequency of
facial nerve clinical dysfunction as compared to the VIII nerve.
Findings in the 2 most common lesionsMeningiomas and Epidermoids
Meningiomas
A meningioma is one of the most common primary brain tumors. Arises from cells of the
arachnoid membrane. Therefore, these tumors actually arise outside the brain itself, but
because of their close proximity to nervous system structures, they are often touching or
pushing into parts of the brain or spinal cord
Most meningiomas are benign and very slow growing, rarely malignant.
Most meningiomas are named for their site of origin. Example - skull base,
cerebellopontine, foramen magnum to name a few, all referring to various anatomical
locations around the central nervous system. When small, most meningioma are
asymptomatic. Depending on their location, as they enlarge, they can start to invade or cause
compression of neurological structures.
Can be suspected when a patient presents with a large tumor and relatively normal hearing.
They do not deform the bony auditory canal.
Audiological Findings
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Clinically, an intracranial meningioma may remain silent until it penetrates the temporalbone, most commonly causing progressive hearing loss, vertigo, tinnitus, otalgia etc.
Recurrent otitis media with otorrhea and the development of granulation tissue may be seen.
The incidence of tinnitus and hearing loss is somewhat lower than in VS patients, with only
60% to 75% of patients showing an auditory symptoms at the time of diagnosis, compared
with 95% or more of patients with VS. The patients with meningioma also showed a higher
percentage with hearing loss less than 20 dB and discrimination greater than 80% than did
VS patients; otherwise, the configuration of the loss and appearance audiometrically is
identical with that for patients with AN. Marangos (2001) demonstrated a higher incidence of
normal hearing, binaural symmetry, and normal ABR in patients with meningiomas thanthose with acoustic neuroma.
PTA findings
Laird (1985) identified 8 of 15 patients with meningioma, or 53%, as having a PTA of 0 to 20
dB.
Granick (1995) identified 6, or 26%, of their group with a PTA of 0 to 20 dB. Both these
studies considered posterior fossa meningiomas.
Hearing loss or tinnitus was found in 60% of meningioma patients by Laird (1985) and in
75% by Granick (1995).
Epidermoid cyst
Linthicum(1974) reported involvement of the 7th cranial nerve as the most common sign and
first lesion to occur followed by an unilateral hearing loss. Unilateral HL has also been
reported as the first presenting sign.
Mechanism - It tends to "strangle" the 7th
nerve and reduce its blood supply, therefore it is
the first presenting sign. An acoustic neuroma in contrast may stretch the nerve but impulsescan still be conducted.
Meningioma, in this
diagram, extends along theinternal auditory canal,
causing total destruction of
all nerves.
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Trigeminal neuralgia- Cause may be either local irritation from cholesterol seeping through
the cyst wall or compression from a vascular loop against the nerve root entry zone.
Audiological tests confirm the presence of a retrocochlear lesion and determines the function
of the 7th and 8th cranial nerves. Auditory brainstem responses have been found to be useful
in differentiating various lesions of the cerebellopontine angle.
Secondary tumors
Glomus tumors
Glasscock et al. clarified the definitions of glomus tympanicum tumors as those in the
tympanic cavity and the mastoid, and glomus jugulare tumors as those involving the jugular
bulb and the base of the skull.
Glomus jugulare tumors originate from the chief cells of the paraganglia, or glomus bodies,
located within the wall (adventitia) of the jugular bulb, and can be associated with either the
auricular branch of the vagus nerve (Arnold nerve) or the tympanic branch of the
glossopharyngeal nerve (Jacobson nerve). Paraganglia are small (< 1.5 mm) masses of tissue
composed of clusters of epithelioid (chief) cells within a network of capillary and
precapillary caliber vessels.
Neural infiltration by paragangliomas following a sequence of the tumor approaching the
nerve, contacting the epineurium, invading the perineurium along the perivascular spaces of
the neural capillary supply, and penetrating the endoneurium.
Intracranial extension, according to Spector and colleagues (1979) is most likely to occur
within two dangerous triangles: the hypotympanic and the protympanic.
These slow-growing tumors that extend along anatomic planes of least resistance (along
blood vessels and mastoid air-cell tracts and through cranial nerve foraminae).
The hypotympanic triangle is delimited by the inferior petrosal sinus, the sigmoid sinus, and
the internal jugular vein. Extension from the hypotympanic triangle may occur intraluminally
The protympanic and hypotympanic
of paraganglioma. (From Spector GJ,
et al; Glomus jugulare tumors of the
temporal bone.
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in the great veins of the triangle, extraluminally along the carotid sheath into the neck, or
along the cranial nerves at the base of the skull.
The protympanic triangle is determined by the Eustachian tube opening, the tensor tympani
tendon, and the zygomatic root cells. Further growth may then progress along the lumen of
the eustachian tube to the nasopharynx, within air cell tracts to the petrous apex, or along the
IAC into the middle cranial fossa.
In glomus jugulare tumors, the hearing loss can be either sensorineural or conductive. As
described by Alford and Guilford (1962) and Brammer (1984) more than 90% of patients
with glomus tumors present with hearing loss. In lfords series 2 patients were examined;
13 had infralabyrinthine tumors and 12 had glomus tympanicum tumors. All the patients in
this series with SNHL had infralabyrinthine tumors. Only one of the patients with
infralabyrinthine tumors had normal hearing, but the ABR was positive in this case.
Hearing loss occurs in 90% of patients with glomus tympanicum tumors and in 70% of
patients with glomus jugulare tumors, but only rarely in patients with glomus vagale tumors.
The hearing loss is more often conductive than sensorineural. Pulsatile tinnitus, an audible
bruit, or spontaneous aural bleeding can be seen in 60% to 70% of patients with
tympanicumor jugulare tumors and in 30% of those with vagale paragangliomas
(Briut is the term for the unusual sound that blood makes when it rushes past an obstruction -
turbulent flow in an artery).
Mechanism - HL and VII CN deficit
Paragangliomas can grow laterally, producing otologic symptoms (conductive hearing loss,
pulsatile tinnitus, or a retrotympanic mass), and medially, resulting in the jugular foramen (or
Vernets syndrome), consisting of glossopharyngeal, vagus, and spinal accessory deficits.
Involvement of the facial nerve occurs in approximately 20% of patients with tympanicum or
jugulare tumors. The vertical mastoid segment is the usual site of compression, although
compression in the soft tissue of the stylomastoid foramen may also be the cause.
Metastatic tumors
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Metastatic tumors most commonly gain access to the temporal bone by hematogenous spread.
(Schuknecht, 1968). Breast, lung, kidney, prostate, and stomach carcinoma, in descending
order of frequency, have been reported as metastasizing to the temporal bone.
Deposition of tumor cells occurs predominantly in thepetrous marrow; the sluggish flow in
the sinusoidal capillaries promotes filtering of the tumor cells from the circulation.
(Schuknecht, 1968) Involvement of the petrous apex can be found nearly uniformly (Nelson,
1991). Metastatic deposition within the air cell spaces of the temporal bone is also quite
common and leads to tympanic cavity and facial nerve involvement. Invasion of the otic
capsule is uncommon, reflecting its resistance to neoplastic invasion. (Berlinger, 1980)
Lymphomas and leukemias infiltrate the petrous apex almost without exception, subsequently
following the submucosal plane of the mastoid air cells, the ossicles, the middle ear muscles
and tendons, the eustachian tube, the IAC, and the subcutaneous tissues of the external
auditory canal. (Berlinger, 1980)
Regional, extracranial neoplasms, most commonly pharyngeal carcinoma, extend directly
into the temporal bone by preformed pathways such as the eustachian tube, the carotid canal,
the foramen lacerum, the foramen ovale, and the jugular foramen (Nelson, 1991). Similarly,
malignant intracranial tumors may secondarily involve the temporal bone by routes described
in the discussion of meningiomas, paragangliomas, and vestibular schwannomas.
Leptomeningeal extension, in which the malignant tumor cells diffusely proliferate in a
lamellar manner along the pia-arachnoid of the brain and spinal cord, may develop both with
distant primary neoplasms and primary intracranial tumors, especially medulloblastomas.
Bilateral IAC invasion with disruption of the facial and cochleovestibular nerves is
characteristic and may lead to transgression of the cribrose areas and membranous labyrinth.
(Berlinger, 1980)
Example : Leptomeningial metastasis
While 30% of the cases with unilateral metastases are asymptomatic, in the remainder the
common symptoms were facial nerve paralysis, HL and tinnitus, all of progressive onset,
although 32% of the patients experienced a sudden onset of these symptoms accompanied by
vertigo and disequilibrium.
Suzuki et al. (1997) discussed four patients with gastric carcinoma all of whom presented
with sudden bilateral hearing loss. Diffuse leptomeningeal carcinoma was detected in two of
the cases and inner ear hemorrhage in the other two.
Although the mechanism of sudden hearing loss due to inner ear hemorrhage is not clearly
understood, it may be due to biochemical changes in inner ear fluids (Suzuki, 1997). Many of
the audiological and vestibular symptoms found with leukemia are probably referable to
changes in the biochemistry of these sensitive structures.
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This may stem from altered blood vessel permeability secondary to deficient platelets and
alterations in the selective ion concentrations between the endolymph and the perilymph
(Adams, 1980).
Maddox (1976) emphasized the triad of symptoms of otalgia, periauricular swelling, and
facial nerve paresis as being highly suspect for malignant involvement of the temporal bone,
otorrhea may be absent and the tympanic membrane appears normal. Thus, pain and CN VII
paralysis in a chronically draining ear must immediately arouse a suspicion of malignant
disease (Adams, 1971).
Other tumors
Schuknecht and associates (1968) emphasized hearing loss as a common early manifestation
of hematogenous or directly extending metastatic tumors of the temporal bone, with
conductive hearing loss reflecting eustachian tube dysfunction and secondary serous otitis
media; less frequently, ossicular destruction, mucosal invasion, and tympanic membrane
infiltration precipitated the conductive hearing loss. SNHL is a manifestation of cochlear
nerve compression or destruction, or cochlear invasion along the IAC. Rapidly progressive
uni- or bilateral SNHL, especially if associated with uni- or bilateral facial paresis, vertigo,
and widespread neurologic signs, is suggestive of leptomeningeal temporal bone
involvement.
Chloromas are localized, green masses of leukemic cells, associated particularly with acute
myeloblastic leukemia. Shanbrom and Finch (1958) have cited data indicating that of those
patients with chloromas, approximately half will have temporal bone involvement. Leukemic
infiltrations in general may precipitate recurrent otitis and acute symptomatology related to
hemorrhage. Chloromas have been associated with compressive effects on the facial and
cochleovestibular nerves, tympanomastoiditis, otalgia, hearing loss, and vertigo.
Lipomas (Kitamura, 1990) are rare but are also associated with hearing loss in at least two
thirds of the cases.
Cranial nerve Schwannomas
Summary diagram of the
effect of an astrocytoma
(glioblastoma) of the pons
on the facial, cochlear, and
vestibular nerves.
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1) Trigeminal Nerve Schwannomas ( Can be either Ganglionic / Trigeminal root)Trigeminal schwannomas of the ganglionic segment result in facial numbness or pain and
corneal hypesthesia in 80% to 90% of patients, which are the initial complaints in about 60%
of these patients. Few patients (10% to 20%), however, never develop trigeminal dysfunction.
Tumors of the ganglionicsegment are more frequently associated with facial pain (52%) than
those of the trigeminal root(28%) (Mc Cormick et al., 1988). Diplopia is present in 50% by
the time of diagnosis and is usually due to an abducens palsy. Facial weakness and hearing
loss are rare symptoms of this lesion.
Tumors of the trigeminal root account for 20% to 30% of trigeminal schwannomas and are
usually confined to the posterior fossa (Jeffersons type B tumors). The clinical presentation
is usually a combination of hearing loss, tinnitus, and facial nerve and cerebellar dysfunction.
6% of patients with trigeminal schwannomas initially complain of hearing loss.
2) Facial Nerve SchwannomasSlowly progressive facial weakness is the typical clinical presentation of a facial nerve
schwannoma. Facial spasms may also be observed.
Patients with schwannomas of the facial nerve in the CPA are known to present with hearing
loss that can be conductive, sensorineural, or mixed (Lee,1989). Hearing loss of a conductive,
sensorineural, or mixed nature occurs in approximately 50% of patients. Facial schwannomas
located in the middle ear may cause conductive hearing loss, whereas tumors in the labyrinth
and internal auditory channel usually result in cochlear or retrocochlear hearing dysfunction,
respectively. Tinnitus and vertigo, or dizziness, occur in 13% and 10%, respectively. Externalmanifestations of the tumor such as a mass, pain, or otorrhea occur in 30% or more of
patients (Lipkin et al., 1987).
These tumors are rare, accounting for only 1.5% of cerebellopontine angle tumors (Baker and
Ojemann, 1993). May involve the tympanic or vertical segments in most patients (58% and
48%, respectively) and multiple segments are almost always affected.
3) Jugular Foramen SchwannomasSchwannomas of the caudal cranial nerves are rare. Jugular schwannomas, which include
schwannomas from the glossopharyngeal, vagus, and spinal accessory nerves are not
distinguishable from one another.
They have been classified into 3 types according to their location:
(1) Type A tumors grow predominantly intracranially,
(2) Type B tumors grow predominantly at the jugular foramen, and
(3) Type C tumors grow predominantly extracranially.
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Type A tumors tend to cause acoustic or cerebellar symptoms, and type B and C tumors tend
to be associated with the jugular foramen syndrome.
Labyrinthine Neoplasms
Labyrinthine Schwannoma
Other tumorsMalignant neoplasms like Squamous cell carcinoma, Adenoid cystic
carcinoma in adult or rhabdomyosarcoma of the temporal bone in the child may extend to the
labyrinth. Metastasis may extend perineurally along the cochlear nerve and penetrate the
cochlea.
Endolymphatic sac tumors are rare, low-grade malignant neoplasms of the temporal bone,
which may be hemorrhagic and invade the vestibule and cochlea.
Labyrinthine Schwannoma
Most common benign neoplasm of the labyrinth. Histologically identical to those found in the
IAC. They can be found either in the cochlea or in the vestibule. In patients with
neurofibromatosis they are more frequent in the vestibular system. (Babin & Harker, 1980 )
Isolated intralabyrinthine schwannomas are more common in the cochlea. Branches of these
nerves reach the ampullae of the semicircular canals and large schwannomas will eventually
grow into the ampullae.
Presenting symptoms- SNHL , Vertigo (or both) Can be stable or progressively worsening.
[Clinically indistinguishable from Menieres disease] In the past these lesions were diagnosed
during destructive labyrinthectomy for