First Place — Resident Clinical Science Award 1994: Early Effects of Cerebellopontine Angle Compression on Rabbit Distortion-Product Otoacoustic Emissions: A Model for Monitoring Cochlear Function during Acoustic Neuroma Surgery

A rabbit model was developed to simulate the effects of Ischemia that may occur during surgical removal of tumors Involving the cerebellopontine angle or internal auditory canal. Specifically, the internal auditory artery was visualized through a posterior craniotomy and mechanically compressed for repetitive 1-minute intervals with a micromanipulator-controlled glass pipet terminating in a smooth bead. The 2f1-f2 distortion-product otoacoustic emissions were used to monitor the susceptibility of cochlear function to compressive effects. Distortion-product otoacoustic emissions were measured during discrete preblock, block, and postblock periods to determine the time course of distortion-product otoacoustic emission reduction and its return to baseline levels after rapid obstruction and resumption, respectively, of the cochlear vascular supply. Comparisons during these times indicated that preblock distortion-product otoacoustic emission levels were very stable, often varying by less than 1 dB. Additionally, distortion-product otoacoustic emissions were very sensitive to brief vascular occlusions in that, within approximately 25 seconds of blockage onset, emission levels at all frequencies decreased at rates of about − 1.5 dB/second. On alleviation of the occlusion, distortion-product otoacoustic emissions rapidly and completely returned to preblock levels with a delay of about 4 seconds and recovery slopes of about 10.5 dB/second. A notable finding in some animals was that early and reproducible variations in distortion-product otoacoustic emission levels occurred within 5 to 8 seconds of internal auditory artery compression. When present, these transitory changes on distortion-product otoacoustic emission levels acted as early warning signs for vascular compromise of cochlear function.

[1]  R A Levine,et al.  Laser-Doppler Measurements and Electrocochleography during Ischemia of the Guinea Pig Cochlea: Implications for Hearing Preservation in Acoustic Neuroma Surgery , 1993, The Annals of otology, rhinology, and laryngology.

[2]  J. Miller,et al.  A case for further quantification of the stapedius reflex. , 1979, Archives of otolaryngology.

[3]  William E. Brownell,et al.  Outer Hair Cell Electromotility and Otoacoustic Emissions , 1990, Ear and hearing.

[4]  K. Maurer,et al.  Early auditory evoked potentials (EAEPs) in the rabbit. Normative data and effects of lesions in the cerebello-pontine angle. , 1983, Electroencephalography and clinical neurophysiology.

[5]  D. Lilly,et al.  Pressure-induced modifications of the acoustic nerve. Part I: The acoustic reflex. , 1990, American journal of otolaryngology.

[6]  D. Kemp Stimulated acoustic emissions from within the human auditory system. , 1978, The Journal of the Acoustical Society of America.

[7]  M. Whitehead,et al.  Distortion-product emissions in rabbit: I. Altered susceptibility to repeated pure-tone exposures , 1993, Hearing Research.

[8]  Yoshihiro Koseki,et al.  Evoked otoacoustic emissions in patients with acoustic neuromas , 1990 .

[9]  A. Carmona,et al.  Gross (mesoscopic) and applied anatomy of the anterior inferior cerebellar artery in man with special reference to its course through the cerebellopontine angle region. , 1992, Acta anatomica.

[10]  G. Rebillard,et al.  Effect of reversible hypoxia on the compared time courses of endocochlear potential and 2ƒ1−ƒ2 distortion products , 1992, Hearing Research.

[11]  B. Lonsbury-Martin,et al.  Acoustic distortion products in rabbit ear canal. I. Basic features and physiological vulnerability , 1987, Hearing Research.

[12]  David F. Wilson,et al.  The sensitivity of auditory brainstem response testing in small acoustic neuromas , 1992, The Laryngoscope.

[13]  G. K. Martin,et al.  Acoustic distortion products in rabbit ear canal. II. Sites of origin revealed by suppression contours and pure-tone exposures , 1987, Hearing Research.

[14]  B. Lonsbury-Martin,et al.  Endolymphatic hydrops in the rabbit: Auditory brainstem responses and cochlear morphology , 1983, Hearing Research.