Cervical Vestibular Evoked Myogenic Potential in Hypoglossal Nerve Schwannoma: A Case Report

• Abstract
• INTRODUCTION
• CASE REPORT
• RESULTS
• DISCUSSION
• REFERENCES

Abstract

Background:

Schwannoma of the hypoglossal nerve is rare. This case report documents an atypical abnormality of the cervical vestibular evoked myogenic potential (cVEMP) in a patient with schwannoma of the hypoglossal nerve. The observed abnormality was attributed to the proximity of the hypoglossal nerve to the spinal accessory nerve in the medullary cistern and base of the skull.

Purpose:

To report cVEMP abnormality in a patient with hypoglossal nerve schwannoma and provide an anatomical correlation for this abnormality.

Research Design:

Case report.

Study Sample:

A 44-yr-old woman.

Data Collection:

Pure-tone and speech audiometry, tympanometry, acoustic stapedial reflex, auditory brainstem response, and cVEMP testing were performed.

Results:

The audiological test results were normal except for the absence of cVEMP on the lesion side (right).

Conclusions:

A cVEMP abnormality indicating a compromised spinal accessory nerve was observed in a patient with hypoglossal nerve schwannoma. This case report highlights the importance of recording cVEMP in relevant neurological conditions and provides clinical proof for the involvement of the spinal accessory nerve in the vestibulocollic reflex pathway.

INTRODUCTION

The hypoglossal nerve is cranial nerve XII (CNXII), which innervates all muscles of the tongue except the palatoglossus ([Standring and Berkovitz, 2005]). CNXII controls tongue movements during swallowing and speech. Schwannoma of CNXII is rare, constituting only 5% of all nonvestibular intracranial schwannomas ([Boban et al, 2007]; [Osborn, 2013]). CNXII schwannomas can compromise the spinal accessory and other lower cranial nerves ([Sato et al, 1996]; [Hoshi et al, 2000]; [Awobuluyi, 2013]).

The cervical vestibular evoked myogenic potential (cVEMP) is an inhibitory potential recorded from the sternocleidomastoid muscle (SCM) ([Colebatch, 2001]). It reflects the integrity of the vestibulocollic reflex (VCR) pathway. Insights into the VCR pathway have primarily been gained through animal research. The otolith organs, vestibular nerve, vestibulospinal tract, cervical segment of the spinal cord, nucleus of the spinal accessory nerve, and SCM constitute the VCR pathway ([Shinoda et al, 1989]; [Sato et al, 1997]; [Uchino et al, 1997]; [Tsubota et al, 2007]; [Sheykholeslami et al, 2009]; [Curthoys et al, 2016]). Various neurological disorders in humans present with cVEMP abnormalities ([Colebatch and Halmagyi, 1992]; [Colebatch et al, 1994]; [Murofushi et al, 2001]; [Sartucci and Logi, 2002]; [Deftereos et al, 2008]; [Felipe et al, 2009]; [Pollak et al, 2009]; [Kim et al, 2010]; [Güven et al, 2014]; [Magnano et al, 2014]; [Ribeiro et al, 2015]). These patients had lesions at various levels of the VCR pathway; however, none had a cranial nerve XI (CNXI) lesion. Thus, CNXI involvement in the VCR pathway lacks clinical evidence in humans.

The present case study reports cVEMP abnormality in a patient with CNXI schwannoma. Furthermore, anatomical correlation provides clinical evidence for CNXI involvement in the VCR pathway.

CASE REPORT

A 44-yr-old woman presented with articulation difficulty and deviation of the tongue to the right side (on protrusion) lasting 3 mo. No other significant otological history such as hearing loss or vestibular symptoms was present. The patient underwent a neurological examination. The tongue showed fasciculations and left side atrophy. These findings indicated right lower motor neuron hypoglossal palsy. The rest of the cranial nerve examination was normal. Magnetic resonance imaging revealed a 2.6 × 2.14 × 2.2 cm³ lesion (schwannoma) arising from the right CNXII at the entrance of the right hypoglossal canal (HC). The lesion occupied the right jugular fossa (JF) and had a mild protrusion into the premedullary cisternal space ([Figure 1]).

The patient underwent audiological evaluation as part of routine presurgical documentation, and the following tests were performed: pure-tone and speech audiometry (speech recognition threshold and word recognition score), tympanometry and acoustic stapedial reflex (ipsilateral and contralateral), distortion product otoacoustic emissions, and auditory brainstem response (ABR). Words from standardized lists were presented in monitored live-voice mode to establish the speech recognition threshold ([Padmaja, 1987]) and word recognition score ([Mayadevi, 1978]). All audiological tests were carried out with calibrated equipment in sound-treated rooms.

cVEMP was recorded using IHS equipment (Intelligent Hearing Systems Inc., Miami, FL) to evaluate the integrity of the VCR pathway. Both the positive and negative electrodes were placed on the test side. The ground electrode was placed on the forehead. The stimulus and recording parameters are given in [Table 1]. The stimulus was presented through an insert earphone (ER-3A; Etymotic Research, Elk Grove Village, IL). The patient was seated in a comfortable reclining chair facing the equipment monitor and turned her head to the right or left side as instructed. Biofeedback was given to achieve appropriate and steady SCM tension. The appearance of a green bar and a smiling face on the monitor as well as a green light on the feedback indicator box confirmed appropriate muscle tension. A red bar and a frowning face on the monitor along with a red light on the indicator box implied inappropriate muscle tension. Electromyographic waveforms with amplitudes <50 μV or >500 μV were automatically discarded, and excessive muscle tension was monitored during testing.

RESULTS

The audiological tests revealed normal findings bilaterally except for cVEMP. Pure-tone averages for the right and the left ears were 15 and 13.3 dB HL, respectively ([Figure 2]). Speech recognition thresholds were 10 dB HL, and the word recognition score was 100% for both ears. Distortion product otoacoustic emissions were present bilaterally at all frequencies from 1 to 8 KHz.

Tympanometry revealed no abnormalities in either ear ([Table 2]). Acoustic stapedial reflexes were present at 500 Hz, 1 KHz, and 2 KHz bilaterally on ipsilateral and contralateral stimulation ([Table 2]). The ABR recording demonstrated good wave morphology and replicability, and the absolute and the interpeak ABR latencies were normal ([Table 2]). cVEMP was absent on the lesion side (right) and present on the nonlesion side (left). The cVEMP latency and amplitude values are given in [Table 2] and shown in [Figure 3].

DISCUSSION

The audiological tests (pure-tone audiometry, speech audiometry, tympanometry, acoustic reflex, and ABR) revealed normal bilateral findings in the patient. The only abnormality noted was the absence of cVEMP on the lesion side (right). Studies have reported cVEMP abnormalities in patients with unilateral brainstem tumors, vestibular schwannoma ([Welgampola et al, 2013]; [Chiarovano et al, 2014]), cerebellopontine angle schwannoma and meningioma ([Hu et al, 2009]; [Su et al, 2013]), and cerebellopontine angle epidermoid ([Chu et al, 2006]). To our knowledge, this clinical report is the first to describe a cVEMP abnormality in a patient with hypoglossal schwannoma. Based on their review, [Curthoys (2010)] posited that cVEMP recorded at SCM is predominantly a VCR output. Thus, VCR pathway dysfunction may be implicated in our patient. A mass lesion of CNXII can compromise CNXI ([Sato et al, 1996]; [Hoshi et al, 2000]; [Awobuluyi, 2013]) because CNXII lies close to CNXI in the cisternal space and at the base of the skull. Within the cranium, CNXI travels in the cerebellomedullary cistern, and CNXII travels in the premedullary cistern. These cisterns lie adjacent to each other. The cerebellomedullary cistern (which lies just in front of CNIX, CNX, and CNXI) forms the lateral border of the premedullary cistern ([Rhoton, 2000]). In our patient, the lesion extended into the premedullary cistern and therefore could have compromised CNXI. After transiting the cisternal space, CNXI and CNXII leave the cranium at the base of the skull. CNXI exits through the JF, and CNXII exits through the HC ([Osborn, 2013]). The HC is just 0.75 cm inferomedial to the JF, and they are separated by the jugular tubercle ([Roche et al, 2008]; [Karasu et al, 2009]). Furthermore, CNXII lies medial to the JF ([Gupta et al, 2014]). In our patient, the tumor occupied the right JF and thus could have compromised CNXI.

The absence of cVEMP could be related to VCR pathway dysfunction owing to CNXI compromise. In animals, cVEMP involves motor neurons of the neck (equivalent to CNXI) ([Shinoda et al, 1989]; [Uchino et al, 1997], [Sheykholeslami et al, 2009]). Similar findings demonstrating CNXI involvement in cVEMPs are unavailable in humans. CNXI is the primary motor supplier to the SCM ([Standring and Berkovitz, 2005]), which further strengthens our implication of CNXI compromise. Therefore, this case report provides clinical evidence of CNXI involvement.

In conclusion, this case report highlights subclinical VCR pathway compromise in a patient with a CNXII schwannoma. Furthermore, it provides clinical evidence of CNXI involvement in the VCR pathway. This report may also expand the scope of cVEMP test procedures.

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Corresponding author

• REFERENCES

• Awobuluyi MT. 2013. Tumors of cranial/spinal nerves. In: Naidich TP, Castillo M, Cha S, Smirniotopoulos JG. Imaging of the Brain. Philadelphia, PA: Saunders; 826-836
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  CrossrefPubMedSuche in Google Scholar
• Colebatch JG, Halmagyi GM, Skuse NF. 1994; Myogenic potentials generated by a click-evoked vestibulocollic reflex. J Neurol Neurosurg Psychiatry 57 (02) 190-197
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  CrossrefPubMedSuche in Google Scholar
• Colebatch JG. 2001; Vestibular evoked potentials. Curr Opin Neurol 14 (01) 21-26
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• Curthoys IS. 2010; A critical review of the neurophysiological evidence underlying clinical vestibular testing using sound, vibration and galvanic stimuli. Clin Neurophysiol 121 (02) 132-144
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  CrossrefPubMedSuche in Google Scholar
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• Hoshi M, Yoshida K, Ogawa K, Kawase T. 2000; Hypoglossal neurinoma—two case reports. Neurol Med Chir (Tokyo) 40 (09) 489-493
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  CrossrefPubMedSuche in Google Scholar
• Hu YF, Cheng PW, Young YH. 2009; Comparison of vestibular function between large cerebellopontine angle meningioma and schwannoma. Acta Otolaryngol 129 (02) 161-165
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  CrossrefPubMedSuche in Google Scholar
• Karasu A, Cansever T, Batay F, Sabanci PA, Al-Mefty O. 2009; The microsurgical anatomy of the hypoglossal canal. Surg Radiol Anat 31 (05) 363-367
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  CrossrefPubMedSuche in Google Scholar
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  CrossrefPubMedSuche in Google Scholar
• Magnano I, Pes GM, Pilurzi G, Cabboi MP, Ginatempo F, Giaconi E, Tolu E, Achene A, Salis A, Rothwell JC, Conti M, Deriu F. 2014; Exploring brainstem function in multiple sclerosis by combining brainstem reflexes, evoked potentials, clinical and MRI investigations. Clin Neurophysiol 125 (11) 2286-2296
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  MissingFormLabel

  Suche in Google Scholar
• Murofushi T, Shimizu K, Takegoshi H, Cheng PW. 2001; Diagnostic value of prolonged latencies in the vestibular evoked myogenic potential. Arch Otolaryngol Head Neck Surg 127 (09) 1069-1072
  MissingFormLabel

  CrossrefPubMedSuche in Google Scholar
• Osborn AG. 2013. Cranial nerves and nerve sheath tumors. In: Osborn AG. Osborn’s Brain: Imaging, Pathology and Anatomy. 1st ed. Manitoba, Canada: Amirsys Inc; 613-644
  MissingFormLabel

  Suche in Google Scholar
• Padmaja B. 1987. ISHA spondee word list-7. In: Kacker SK, Basavaraj V. Indian Speech, Language and Hearing Tests: The ISHA Battery. Mysore, India: Indian Speech and Hearing Association;
  MissingFormLabel

  Suche in Google Scholar
• Pollak L, Prohorov T, Kushnir M, Rabey M. 2009; Vestibulocervical reflexes in idiopathic Parkinson disease. Neurophysiol Clin 39 4–5 235-240
  MissingFormLabel

  CrossrefPubMedSuche in Google Scholar
• Rhoton Jr AL. 2000; The posterior fossa cisterns. Neurosurgery 47 (Suppl 3) S287-S297
  MissingFormLabel

  CrossrefPubMedSuche in Google Scholar
• Ribeiro RS, Pereira MM, Pedroso JL, Braga-Neto P, Barsottini OGP, Manzano GM. 2015; Cervical and ocular vestibular evoked potentials in Machado-Joseph disease: functional involvement of otolith pathways. J Neurol Sci 358 1–2 294-298
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  CrossrefPubMedSuche in Google Scholar
• Roche PH, Mercier P, Sameshima T, Fournier HD. 2008; Surgical anatomy of the jugular foramen. Adv Tech Stand Neurosurg 33: 233-263
  MissingFormLabel

  CrossrefPubMedSuche in Google Scholar
• Sartucci F, Logi F. 2002; Vestibular-evoked myogenic potentials: a method to assess vestibulo-spinal conduction in multiple sclerosis patients. Brain Res Bull 59 (01) 59-63
  MissingFormLabel

  CrossrefPubMedSuche in Google Scholar
• Sato H, Imagawa M, Isu N, Uchino Y. 1997; Properties of saccular nerve-activated vestibulospinal neurons in cats. Exp Brain Res 116 (03) 381-388
  MissingFormLabel

  CrossrefPubMedSuche in Google Scholar
• Sato M, Kanai N, Fukushima Y, Matsumoto S, Tatsumi C, Kitamura K, Ozaki M, Hayakawa T. 1996; Hypoglossal neurinoma extending intra- and extracranially: case report. Surg Neurol 45 (02) 172-175
  MissingFormLabel

  CrossrefPubMedSuche in Google Scholar
• Sheykholeslami K, Megerian CA, Zheng QY. 2009; Vestibular evoked myogenic potentials in normal mice and Phex mice with spontaneous endolymphatic hydrops. Otol Neurotol 30 (04) 535-544
  MissingFormLabel

  CrossrefPubMedSuche in Google Scholar
• Shinoda Y, Ohgaki T, Sugiuchi Y, Futami T. 1989; Comparison of the branching patterns of lateral and medial vestibulospinal tract axons in the cervical spinal cord. Prog Brain Res 80: 137-147 , discussion 127–128
  MissingFormLabel

  PubMedSuche in Google Scholar
• Standring S, Berkovitz KB. 2005. Neck. In: Standring S. Gray’s Anatomy: The Anatomical Basis of Clinical Practice. 39th ed. Spain: Elsevier Churchill Livingstone; 531-566
  MissingFormLabel

  Suche in Google Scholar
• Su CH, Chen CM, Young YH. 2013; Differentiating cerebellopontine angle meningioma from schwannoma using caloric testing and vestibular-evoked myogenic potentials. J Neurol Sci 335 1–2 155-159
  MissingFormLabel

  CrossrefPubMedSuche in Google Scholar
• Tsubota M, Shojaku H, Hori E, Fujisaka M, Hayashi N, Kurimoto M, Hatakeyama N, Yamazaki M, Nishijo H, Ono T, Yamamoto H, Watanabe Y. 2007; Effects of vestibular nerve section on sound-evoked myogenic potentials in the sternocleidomastoid muscle of monkeys. Clin Neurophysiol 118 (07) 1488-1493
  MissingFormLabel

  CrossrefPubMedSuche in Google Scholar
• Uchino Y, Sato H, Sasaki M, Imagawa M, Ikegami H, Isu N, Graf W. 1997; Sacculocollic reflex arcs in cats. J Neurophysiol 77 (06) 3003-3012
  MissingFormLabel

  CrossrefPubMedSuche in Google Scholar
• Welgampola MS, Ramsay E, Gleeson MJ, Day BL. 2013; Asymmetry of balance responses to monaural galvanic vestibular stimulation in subjects with vestibular schwannoma. Clin Neurophysiol 124 (09) 1835-1839
  MissingFormLabel

  CrossrefPubMedSuche in Google Scholar