Maureen Fallon

Effects of adenosine 5'-triphosphate and related agonists on cochlear function.

Several lines of evidence implicate a neurotransmitter/modulator role for ATP in the cochlea. Most of the work supporting such a notion has been accomplished using in vitro preparations of sensory hair cells or other cochlear tissues. Little is known regarding the functional consequences of ATP receptor activation in vivo. In the present experiments, we tested ATP and related agonist analogs for their effects on sound-evoked responses of the cochlea (cochlear microphonic, CM; summating potential, SP; distortion product otoacoustic emissions, DPOAE) and auditory nerve (compound action potential, CAP) in vivo and on outer hair cell (OHC) currents and cell length in vitro. In vivo, local application of these compounds was associated with concentration- and intensity-dependent response alterations. The slowly-hydrolyzable P2y agonist, ATP-gamma-S, was clearly of greatest in vivo potency: At low to moderate stimulus intensities, micromolar concentrations of this drug reduced all responses, in particular CAP and DPOAEs, which fell to the level of the noise floor. At high intensities, response suppression was smaller and SP was increased. In vivo effects of ATP, ATP-alpha-S and 2-Me-S-ATP were qualitatively similar to, but smaller in magnitude and requiring higher concentrations than those observed for ATP-gamma-S. Adenosine was without significant effect on responses of the cochlea and auditory nerve. In vitro, effects of ATP-gamma-S and ATP were similar: both induced inward currents in OHCs held at -60 mV without producing observable (> 0.3 micron) changes in OHC length. Results suggest that endogenous ATP influences cochlear function through receptors at several sites in the cochlea. Results suggest further that these response alterations are mediated, at least in part, by receptors of the P2y subtype.

Salicylate, mefenamate, meclofenamate, and quinine on cochlear potentials

The perilymphatic spaces of guinea pig cochleae were perfused with artificial perilymph, with and without drug, at a rate of 2.5 μl/minute for 10 minutes. The compound action potential of the auditory nerve, cochlear microphonics, and the summating potential evoked by 10 kHz tone bursts of varying intensities were recorded from a wire inserted in the basal turn scala vestibull. The endocochlear potential was recorded from the scala media. Sodium salicylate (1.25 to 10 mmol/L) reduced the magnitude of the compound action potential evoked by low-sound intensities without affecting the compound action potential evoked by high-sound intensities. Sodium salicylate also reduced cochlear microphonics and had no effect on summating potential. Cochlear perfusions of prostaglandin synthesis inhibitors, mefenamate (200 μmol/L), and meclofenamate (200 μmol/L), had no effect on the cochlear potentials. Quinine (10 to 100 μmol/L) reduced the compound action potential input-output function in a parallel fashion rather than selectively affecting the low-intensity compound action potential. Quinine (100 μmol/L) reduced cochlear microphonics and summating potential. Neither quinine (100 μmol/L) nor salicylate (5 mmol/L) affected endocochlear potential. These results suggest that salicylate-induced hearing loss is not caused by either antagonism of the hair cell transmitter or cyclooxygenase inhibition, nor is it caused by the same mechanism that causes quinine-induced hearing loss.

A nicotinic-like receptor mediates suppression of distortion product otoacoustic emissions by contralateral sound.

The purpose of this investigation was to provide in vivo pharmacologic characterization of a cholinergic receptor mediating the suppressive effects of medial olivocochlear (MOC) efferent activation. MOC neurons were activated by contralateral sound and the resulting suppression of ipsilateral distortion product otoacoustic emissions (DPOAEs) was monitored before and after intracochlear perfusions of cholinergic antagonists. Results revealed a dose-dependent blockade of contralateral suppression of DPOAEs by a wide variety of nicotinic and muscarinic cholinergic receptor antagonists, as well as by non-traditional antagonists of cholinergic activity. The nicotinic antagonists, alpha-bungarotoxin, curare and kappa-bungarotoxin, and the glycine antagonist, strychnine, blocked contralateral suppression at nanomolar concentrations and demonstrated similar potencies. IC50 values were 2.38 x 10(-7), 2.79 x 10(-7), 3.81 x 10(-7) and 2.96 x 10(-7) M, respectively. These agents were followed in potency by the nicotinic antagonist, trimethaphan (1.75 x 10(-6) M), the M3 muscarinic antagonist, 4-DAMP (1.88 x 10(-6) M) and the GABAA antagonist, bicuculline (2.39 x 10(-6) M). Increasingly greater concentrations of the muscarinic antagonists, atropine (9.52 x 10(-6) M), AF-DX 116 (2.72 x 10(-5) M) and pirenzepine (8.24 x 10(-4) M) were necessary to block contralateral suppression of DPOAEs. The in vivo pharmacology of this putative outer hair cell cholinergic receptor suggests that it may be a member of the nicotinic family of receptors.

Contralateral sound suppresses distortion product otoacoustic emissions through cholinergic mechanisms

Presentation of an acoustic signal to one ear can suppress sound-evoked activity recorded at the opposite ear. The suppression appears to be mediated by medial olivocochlear (MOC) efferent neurons synapsing with outer hair cells (OHCs) and acting through the MOC neurotransmitter, acetylcholine (ACh). The purpose of the present investigation was to study the suppression of distortion product otoacoustic emissions (DPOAEs) by contralateral sound and to examine whether the suppression could be blocked by known antagonists of olivocochlear (OC) efferent activity. Urethane-anesthetized guinea pigs were used. Perilymph spaces of ipsilateral cochleae were alternately perfused with artificial perilymph and drugs at 2.5 microliters/min for 10 min. After each period of perfusion, DPOAEs were measured before, during and after contralateral wideband noise (WBN) stimulation. Pre-perfusion, contralateral WBN attenuated the ipsilateral DPOAEs between 1-3 dB. This suppression was blocked reversibly by strychnine (10 microM), curare (10 microM) and atropine (20 microM), known antagonists of OC efferent activity. These results confirm the findings of Puel and Rebillard (1990) that contralateral WBN can suppress DPOAEs in anesthetized guinea pigs. Furthermore, results suggest that this efferent control of the cochlear mechanical response can either be mediated by both nicotinic and muscarinic cholinergic receptors, or that a single receptor with as yet undescribed structure and pharmacology mediates effects seen.

Intracochlear salicylate reduces low-intensity acoustic and cochlear microphonic distortion products ☆

Salicylate is well-known to produce reversible hearing loss and tinnitus. The site and mechanism of salicylates ototoxic actions, however, remain unresolved. Recent experiments demonstrating primarily low-intensity effects on cochlear afferent outflow and effects on otoacoustic emissions (OAEs) suggest that salicylate acts to compromise active, energy-enhancing processes within the cochlea (i.e., the active process). We tested this hypothesis by examining the effect of salicylate on distortion product emissions. Distortion product responses to two-tone stimulation were monitored in the guinea pig before, during, and after intracochlear administration of increasing concentrations of salicylate (0.6-5 mM). These responses were recorded as acoustic signals in the ear canal spectrum (ADP), and as present in the cochlear microphonic (CM) recorded from a wire in basal turn scala vestibuli (CMDP). We also recorded the CM response to a single tone. Cochlear perfusion of salicylate resulted in a dose-responsive reduction in ADPs that was greater for low intensities of stimulation. CMDPs also demonstrated a concentration-dependent reduction at low intensities, but were increased slightly, though not significantly, by salicylate when elicited by high intensity primaries. CM was essentially unchanged by intracochlear salicylate. These results are consistent with an action of salicylate that involves the outer hair cells (OHCs) and are in harmony with the hypothesis that salicylate may selectively compromise the active process.

The quinoxalinediones DNQX, CNQX and two related congeners suppress hair cell-to-auditory nerve transmission

We tested 6,7-dinitroquinoxaline-2,3-dione (DNQX); 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX); 6,7-dichloro-3-hydroxy-2-quinoxalinecarboxylic acid (DHQC); and 3-hydroxy-2-quinoxalinecarboxylic acid (3HQC), new kainate and quisqualate receptor antagonists, upon cochlear potentials in guinea pig. Perilymph spaces of guinea pig cochleae were perfused with artificial perilymph solutions containing up to 1000 microM concentrations of DHQC and 3HQC, and 500 microM concentrations of DNQX and CNQX, at a rate of 2.5 microliters/min for 10 min. Cochlear potentials evoked by 10 kHz tone bursts of varying intensity were recorded from the basal turn scala vestibuli. Cochlear perfusion of the four drugs resulted in a dose-related suppression of the compound action potential of the auditory nerve (CAP; N1-P1), a prolongation of N1 latency at suprathreshold levels, an elevated CAP threshold, and a decreased N1 latency at CAP threshold. None of the drugs had significant effects on cochlear microphonics (CM) or the summating potential (SP). EC50 values (concentrations causing a 50% reduction in CAP amplitude at 68 dB SPL) were 8 microM for DNQX, 30 microM for DHQC, 35 microM for CNQX, and 1 mM for 3HQC. Results support the hypothesis that kainate and quisqualate receptors are involved in neurotransmission between the hair cell and afferent nerve.

Nimodipine, an L-channel Ca2+ antagonist, reverses the negative summating potential recorded from the guinea pig cochlea.

Nimodipine, an L-type Ca2+ channel antagonist, was tested using sound-evoked cochlear potentials in guinea pigs to investigate whether these channels are involved in cochlear function. Perilymph spaces of guinea pig cochleae were perfused with artificial perilymph solutions containing 0.1-10 microM nimodipine at a rate of 2.5 microliters/min for 10 min. The cochlear potentials evoked by 10 kHz tone bursts of varying intensities were recorded from the basal turn of the scala vestibuli. Cochlear perfusion of nimodipine resulted in reversible, dose-related suppression of the compound action potential of the auditory nerve (CAP; N1-P1), a prolongation of N1 latency at suprathreshold levels, an elevated CAP threshold, a decrease in N1 latency at a constant amplitude measured at CAP threshold, a reduction in cochlear microphonics (CM), and a reduction of the negative summating potential (SP) to a point where it became positive (i.e., a reversal of SP). The endocochlear potential (EP) was not affected. These results support the hypothesis that L-type Ca2+ channels are directly involved in the operation of the organ of Corti. We speculate that L-type Ca2+ channels are integrally involved in generation of a negative summating potential and the dc motion of the cochlear partition described by others.

Intracochlear application of acetylcholine alters sound-induced mechanical events within the cochlear partition

Activation of olivocochlear (OC) efferent fibers has been suggested to alter micromechanical events occurring within the cochlear partition, possibly through an effect of the efferent neurotransmitter (acetylcholine; ACh) on outer hair cells (OHCs). Based on the widely-accepted assumption that otoacoustic emissions reflect OHC activity, we investigated the in vivo influence of ACh on OHCs by studying alterations in emission amplitude with local ACh application. Distortion product otoacoustic emissions (DPOAEs) were measured in anesthetized guinea pigs before, during, and after intracochlear application of ACh (250 microM) with the cholinesterase inhibitor, eserine (20 microM). Perfusion of ACh/eserine was associated with a desensitizing reduction in DPOAE amplitude of approximately 4.4 dB. This reduction was intensity-dependent, with greater and more consistent reductions observed for DPOAEs elicited by low- than by moderate-intensity primaries. The response reduction was not seen during consecutive ACh perfusions performed without an intervening artificial perilymph wash, and was effectively blocked in the presence of pharmacologic antagonists of OC efferent activity (curare, 50 microM; strychnine, 50 microM). Finally, a similar alteration in DPOAE amplitude was never seen during perfusion of the control (artificial perilymph) solution alone. It is argued that these results support the hypothesis that OC efferent activation can alter sound-induced cochlear mechanical events.

The active process is affected first by intense sound exposure

Evidence exists to suggest that intense sound releases excess neurotransmitter from the inner hair cells. However, it has been previously reported that intense sound affects the cochlear micromechanics by altering the stereocilia. Therefore, we tested the hypothesis that intense sound affects structures involved in transduction before it affects the nerve endings. In order to test this hypothesis, we examined the interaction of intense sound with kynurenate which blocks the action of the neurotransmitter on the afferent nerve endings. Intracochlear perfusion of artificial perilymph containing 5 mM kynurenate did not reduce the effect of intense sound when we compare the results with a control group perfused with artificial perilymph alone. These results show that blockade of afferent transmitter receptors did not reduce the effect of acoustic trauma, and the acoustic trauma used herein affected structures involved in transduction before it affected the postsynaptic structures. We speculate that the active process is affected first during acoustic trauma. This interpretation is consistent with the notion that stereocilia are structures that make up part of the active process.

Acetylcholine, carbachol, and GABA induce no detectable change in the length of isolated outer hair cells

The mechanical and electrical properties of cochlear outer hair cells (OHCs) are suggested to modulate transduction by inner hair cells. These properties of OHCs are presumably regulated by efferent neurons which use several transmitters including acetylcholine (Ach) and gamma aminobutyric acid (GABA). Since it had been suggested that Ach causes isolated OHCs to shorten visibly, this study was designed to investigate whether GABA also alters the length of OHCs. OHCs were isolated from the guinea pig cochlea by mechanical dispersion after collagenase treatment. Cells were initially selected by strict morphological criteria. In addition they were only included in further studies if they attained a constant length during 10 min of superfusion with buffer solution. Neither GABA (20 microM: 100 microM), Ach (5 mM; 10 microM with 10 microM eserine) or carbachol (10 microM; 100 microM) altered OHC length when applied in iso-osmotic Hanks balanced salt solution (total number of cells tested, 72). If a change in length occurred it must have been smaller than 0.3 microns, our detection ability. In contrast, high potassium and variations in osmolarity changed hair cell length by 3-10% in agreement with other reports.