Rapid disruption of cochlear function and structure by trimethyltin in the guinea pig

Trimethyltin-induced cochlear degeneration in rat

Trimethyltin (TMT) is an occupational and environmental health hazard behaving as a potent neurotoxin known to affect the central nervous system as well as the peripheral auditory system. However, the mechanisms underlying TMT-induced ototoxicity are poorly understood. To elucidate the effects of TMT on the cochlea, a single injection of 4 or 8 mg/kg TMT was administered intraperitoneally to adult rats. The compound action potential (CAP) threshold was used to assess the functional status of the cochlea and histological techniques were used to assess the condition of the hair cells and auditory nerve fibers. TMT at 4 mg/kg produced a temporary CAP threshold elevation of 25–60 dB that recovered by 28 d post-treatment. Although there was no hair cell loss with the 4 mg/kg dose, there was a noticeable loss of auditory nerve fibers particularly beneath the inner hair cells. TMT at 8 mg/kg produced a large permanent CAP threshold shift that was greatest at the high frequencies. The CAP threshold shift was associated with the loss of outer hair cells and inner hair cells in the basal, high-frequency region of the cochlea, considerable loss of auditory nerve fibers and a significant loss of spiral ganglion neurons in the basal turn. Spiral ganglion neurons showed evidence of soma shrinkage and nuclear condensation and fragmentation, morphological features of apoptotic cell death. TMT-induced damage was greatest in the high-frequency, basal region of the cochlea and the nerve fibers beneath the inner hair cells were the most vulnerable structures.

A weight of evidence approach for the assessment of the ototoxic potential of industrial chemicals

There is accumulating epidemiological evidence that exposure to some solvents, metals, asphyxiants and other substances in humans is associated with an increased risk of acquiring hearing loss. Furthermore, simultaneous and successive exposure to certain chemicals along with noise can increase the susceptibility to noise-induced hearing loss. There are no regulations that require hearing monitoring of workers who are employed at locations in which occupational exposure to potentially ototoxic chemicals occurs in the absence of noise exposure. This project was undertaken to develop a toxicological database allowing the identification of possible ototoxic substances present in the work environment alone or in combination with noise exposure. Critical toxicological data were compiled for chemical substances included in the Quebec occupational health regulation. The data were evaluated only for noise exposure levels that can be encountered in the workplace and for realistic exposure concentrations up to the short-term exposure limit or ceiling value (CV) or 5 times the 8-h time-weighted average occupational exposure limit (TWA OEL) for human data and up to 100 times the 8-h TWA OEL or CV for animal studies. In total, 224 studies (in 150 articles of which 44 evaluated the combined exposure to noise and a chemical) covering 29 substances were evaluated using a weight of evidence approach. For the majority of cases where potential ototoxicity was previously proposed, there is a paucity of toxicological data in the primary literature. Human and animal studies indicate that lead, styrene, toluene and trichloroethylene are ototoxic and ethyl benzene, n-hexane and p-xylene are possibly ototoxic at concentrations that are relevant to the occupational setting. Carbon monoxide appears to exacerbate noise-induced hearing dysfunction. Toluene interacts with noise to induce more severe hearing losses than the noise alone.

Ototoxicity and noise trauma: electron transfer, reactive oxygen species, cell signaling, electrical effects, and protection by antioxidants: practical medical aspects

Ototoxins are substances of various structures and classes. This review provides extensive evidence for involvement of electron transfer (ET), reactive oxygen species (ROS) and oxidative stress (OS) as a unifying theme. Successful application is made to the large majority of ototoxins, as well as noise trauma. We believe it is not coincidental that these toxins generally incorporate ET functionalities (quinone, metal complex, ArNO(2), or conjugated iminium) either per se or in metabolites, potentially giving rise to ROS by redox cycling. Some categories, e.g., peroxides and noise, appear to operate via non-ET routes in generating OS. These highly reactive entities can then inflict injury via OS upon various constituents of the ear apparatus. The theoretical framework is supported by the extensive literature on beneficial effects of antioxidants, both for toxins and noise. Involvement of cell signaling and electrical effects are discussed. This review is the first comprehensive one based on a unified mechanistic approach. Various practical medical aspects are also addressed. There is extensive documentation for beneficial effects of antioxidants whose use might be recommended clinically for prevention of ototoxicity and noise trauma. Recent research indicates that catalytic antioxidants may be more effective. In addition to ototoxicity, a widespread problem consists of ear infections by bacteria which are demonstrating increasing resistance to conventional therapies. A recent, novel approach to improved drugs involves use of agents which inhibit quorum sensors that play important roles in bacterial functioning. Prevention of ear injury by noise trauma is also discussed, along with ear therapeutics.

On membrane motor activity and chloride flux in the outer hair cell: lessons learned from the environmental toxin tributyltin

The outer hair cell (OHC) underlies mammalian cochlea amplification, and its lateral membrane motor, prestin, which drives the cell's mechanical activity, is modulated by intracellular chloride ions. We have previously described a native nonselective conductance (G(metL)) that influences OHC motor activity via Cl flux across the lateral membrane. Here we further investigate this conductance and use the environmental toxin tributyltin (TBT) to better understand Cl-prestin interactions. Capitalizing on measures of prestin-derived nonlinear capacitance to gauge Cl flux across the lateral membrane, we show that the Cl ionophore TBT, which affects neither the motor nor G(metL) directly, is capable of augmenting the native flux of Cl in OHCs. These observations were confirmed using the chloride-sensitive dye MQAE. Furthermore, the compound's potent ability, at nanomolar concentrations, to equilibrate intra- and extracellular Cl concentrations is shown to surpass the effectiveness of G(metL) in promoting Cl flux, and secure a quantitative analysis of Cl-prestin interactions in intact OHCs. Using malate as an anion replacement, we quantify chloride effects on the nonlinear charge density and operating voltage range of prestin. Our data additionally suggest that ototoxic effects of organotins can derive from their disruption of OHC Cl homeostasis, ultimately interfering with anionic modulation of the mammalian cochlear amplifier. Notably, this observation identifies a new environmental threat for marine mammals by TBT, which is known to accumulate in the food chain.

Promotion of noise-induced hearing loss by chemical contaminants

Recent studies have underscored the ability of a wide range of chemical agents to potentate noise-induced hearing loss. Given the ubiquitous nature of noise exposure particularly in many work settings, the high rate of noise-induced hearing loss, the limited degree to which auditory function can recover following damage to the inner ear, and the disparate chemical structures that appear capable of impairing hearing, this issue appears to have great public health significance. A compendium of chemicals known to potentiate noise induced hearing loss is presented along with a hypothesis that might explain at least one basis for potentiation of noise-induced hearing loss by certain chemical toxicants. The use of benchmark dose analysis to undertake a risk assessment for promotion of noise-induced hearing loss by both carbon monoxide and hydrogen cyanide is described.

Disruption of lateral efferent pathways: functional changes in auditory evoked responses

The functional consequences of selectively lesioning the lateral olivocochlear efferent system in guinea pigs were studied. The lateral superior olive (LSO) contains the cell bodies of lateral olivocochlear neurons. Melittin, a cytotoxic chemical, was injected into the brain stem using stereotaxic coordinates and near-field evoked potentials to target the LSO. Brain stem histology revealed discrete damage to the LSO following the injections. Functional consequences of this damage were reflected in depressed amplitude of the compound action potential of the eighth nerve (CAP) following the lesion. Threshold sensitivity and N1 latencies were relatively unchanged. Onset adaptation of the cubic distortion product otoacoustic emission (DPOAE) was evident, suggesting a reasonably intact medial efferent system. The present results provide the first report of functional changes induced by isolated manipulation of the lateral efferent pathway. They also confirm the suggestion that changes in single-unit auditory nerve activity after cutting the olivocochlear bundle are probably a consequence of disrupting the more lateral of the two olivocochlear efferent pathways.

Differential ototoxicities induced by lead acetate and tetraethyl lead

Lead poisoning disrupts many biological structures and functions, including those of the auditory system. This study examined the ototoxic effects of lead acetate (LA) and tetraethyl lead (TEL) of equal lead content on cochlear function and the ability of alpha-phenyl-tert-butyl-nitrone (PBN) to attenuate such effects. Baseline 1.0 microV cochlear microphonic (CM) and compound action potential (CAP) responses were recorded and animals administered either PBN (100 mg/kg, i.p.) or an equal volume of 0.9% saline, followed by an i.p. injection of LA (50 mg/kg) in an ethanol vehicle, TEL (42.7 mg/kg) in a corn oil vehicle, corn oil or ethanol vehicle alone. Two hours after administration, post-exposure CM and CAP responses were recorded. CAP threshold shifts in the saline-LA group were elevated by 5-10 dB at mid to high frequencies relative to controls (20-24 kHz, P<0.05). Mean CAP threshold shifts in the saline-TEL were significantly greater than those of both control groups at all tested frequencies except 2 kHz (P<0.001). However, threshold shifts in the group receiving PBN prior to TEL were significantly smaller than shifts in the group receiving saline prior to TEL (P<0.01). These data suggest that TEL is more ototoxic than is LA and that free radicals partially mediate TEL-induced CAP disruption.

Protection against aminoglycoside otic drop-induced ototoxicity by a spin trap: I. Acute effects

Topical administration of aminoglycoside antibiotic drops containing neomycin and polymyxin B disrupts cochlear structure and function in rodents, possibly as a result of reactive oxygen species generation. This study investigated the ability of a spin trap, alpha-phenyl-tert-butyl-nitrone (PBN), to prevent acute aminoglycoside antibiotic drop-induced cochlear dysfunction. Guinea pigs were monitored for compound action potential thresholds and 1.0 microV root-mean-square cochlear microphonic isopotential curve values, then injected intraperitoneally with PBN (60 mg/kg) or saline solution. After 10 minutes, 50 microl of PBN (100 mmol/L) or artificial perilymph was applied to the round window membrane, followed after 10 minutes with artificial perilymph or aminoglycoside antibiotic drops (50 microl). From 10 to 60 minutes after exposure, mean compound action potential thresholds progressively increased in the artificial perilymph-aminoglycoside antibiotic drop group, beginning with high frequencies and later including ever-lower frequencies. These threshold shifts in compound action potentials were significantly greater (p<0.05) than those seen in the artificial perilymph-artificial perilymph or PBN-aminoglycoside antibiotic drop groups. This finding indicates that PBN provided protection against acute aminoglycoside antibiotic drop-induced compound action potential threshold sensitivity loss. Mean cochlear microphonic shift values at 60 minutes in the artificial perilymph-aminoglycoside antibiotic drop group significantly exceeded those of the other groups only at the highest frequencies. These data suggest that acute aminoglycoside antibiotic drop-induced cochlear disruption primarily affects high frequency compound action potential function and may be partially reactive oxygen species-mediated and preventable.

Toluene disrupts outer hair cell morphometry and intracellular calcium homeostasis in cochlear cells of guinea pigs

The aromatic hydrocarbon, toluene, has been demonstrated to disrupt auditory system function both in occupational epidemiological and in laboratory animal investigations. This agent, along with several other organic solvents, impairs hearing preferentially at middle frequencies-a finding that distinguishes these agents from the traditional high-frequency impairment observed with ototoxic drugs such as aminoglycoside antibiotics and cisplatin. Prior investigations have identified the outer hair cell as a probable target for toluene exposure, although studies designed to evaluate spiral ganglion cell impairment have not been reported. The purpose of this investigation was to determine directly whether outer hair cells isolated from the guinea pig cochlea show morphological alterations consistent with a toxic response to toluene exposure. Since slow adjustments of outer hair cell length can result from alteration in free intracellular calcium concentration, the effect of toluene on calcium homeostasis was monitored in both outer hair cells and spiral ganglion cells. A dose-response relationship was observed in the extent of outer hair cell shortening produced by toluene with a significant shortening observed at concentrations of 100 microM and higher. By contrast, the nonototoxic solvent, benzene, produced little shortening at 100 microM to 1 mM concentrations. Studies of calcium homeostasis conducted using the fluorescent probe, Fura-2, showed that toluene enhanced free intracellular calcium levels of both outer hair cells and spiral ganglion cells within 5 min of exposure at concentrations of 30 microM and higher. Intracellular calcium levels were elevated only slightly following benzene administration at 1 mM, but not at lower concentrations. Cells cultured in artificial perilymph nominally containing no calcium and those to which EGTA was added still showed a maximal increase in intracellular calcium level when treated with toluene. These data indicate that the elevation in free intracellular calcium levels produced by toluene results from release of calcium from intracellular stores.

Direct effects of intraperilymphatic reactive oxygen species generation on cochlear function

Reactive oxygen species (ROS) generation may play a role in ototoxicity, however, the specific effects of ROS generation upon cochlear function are unstudied. Therefore, guinea pig cochleas were instilled with artificial perilymph (AP), H2O2, or confirmed generating systems for the superoxide anion (O2-) or the hydroxyl radical (OH.), or with an ROS system plus its respective scavenger -catalase (CAT), superoxide dismutase (SOD) or deferoxamine (DEF). O2- generating system instillation led to significantly greater mean high frequency compound action potential (CAP) threshold shifts at 10 and 120 min post infusion than seen in AP control or SOD/O2- groups. H2O2 group CAP threshold shifts were significantly greater than control and CAT/H2O2 group values at 10 (16-30 kHz), and 120 min (above 12 kHz). OH generating system instillation led to significantly greater CAP threshold shifts at 10 (12-30 kHz) and 120 min (above 6 kHz) than seen in control or DEF/OH groups. No significant CAP differences were found between controls and scavenger/ROS groups. Mean 1.0 microV cochlear microphonic isopotential curve shift values did not systematically differ among groups. The rapid degradation of high frequency CAP threshold sensitivity seen here may provide insight into the portion of cochlear dysfunction which is ROS-mediated following noise, radiation or chemical exposures.

Direct detection of ototoxicant-induced reactive oxygen species generation in cochlear explants

The proposal that free-radical generation contributes to the ototoxicities of several chemical agents was studied utilizing electron paramagnetic resonance (EPR) spectrometry to detect directly ototoxicant-induced reactive oxygen species formation in cochlear tissue. Guinea pig cochlear explants in chelexed artificial perilymph (AP: 200 microliters) were exposed to an ototoxicant or AP for 10 min. Ototoxic agents included gentamicin sulfate (4.0 mM), kanamycin monosulfate (4.0 mM), ethacrynic acid (0.5 mM), furosemide (0.3 mM), cisplatin (0.1 mM), trimethyltin chloride (0.1 mM), and quinine HCl (3.0 mM). Following incubation, 20 microliters of AP/ototoxicant mixture was replaced by the filtered spin trap, 5,5-dimethylpyrroline-N-oxide (DMPO). After 10 min, the EPR spectrum of the mixture was obtained. Four line EPR spectra of relative intensities 1:2:2:1, associated with hydroxyl radical (OH)/DMPO adduct formation, were evidenced by reaction mixtures containing cochlear explants exposed to each ototoxicant. Cisplatin, quinine and the loop diuretics produced weak OH-associated EPR signals in the absence of a cochlear explant, which were amplified in its presence. Deferoxamine quenched all OH spectral peaks. Peroxide levels, assayed in parallel experiments, were diminished by each ototoxicant relative to those seen following AP exposure, suggesting possible H2O2 conversion to OH. These data support the proposal that various ototoxic agents are capable of reactive oxygen species generation or promotion in cochlear tissues.

Comparison of the effects of trimethyltin on the intracellular calcium levels in spiral ganglion cells and outer hair cells

Cochlear impairment by trimethyltin chloride (TMT), a potential contaminant of marine paints and polyvinyl chloride tubing, has been well demonstrated. Its toxic effect on the inner hair cells (IHC)-spiral ganglion cell (SGC) unit occurs almost immediately while disruption of outer hair cell (OHC) function does not occur until several hours after exposure. In this experiment, OHCs and SGCs from pigmented guinea pigs were tested in vitro to determine the role of enhanced intracellular calcium [Ca2+]i levels in TMT ototoxicity and to determine the sources of enhanced [Ca2+]i. The latter was determined by experiments using artificial perilymph without Ca2+ and by use of the Ca2+ channel blocker, nifedipine. The data show that TMT elevates [Ca2+]i in both OHC and SGC. The elevation of [Ca2+]i in SGC is much more rapid and larger than that in OHC. The elevation of [Ca2+]i in SGC can be attenuated by removing Ca2+ from artificial perilymph or pretreating with nifedipine, but neither of these treatments is effective in OHC. The results suggest that TMT disrupts intracellular storage of Ca2+ in OHCs and SGCs, but that is also enhancing influx of Ca2+ from extracellular sources in the SGCs.

Elevation of intracellular calcium levels in spiral ganglion cells by trimethyltin

The neurotoxicant, trimethyltin (TMT) produces cochlear impairment at far lower dose levels and far more rapidly than it does central nervous system effects. The initial effects of TMT in the cochlea, in vivo, are consistent with disruption of the inner hair cell type-1 spiral ganglion cell synapse although it is uncertain whether the effect is on presynaptic and/or postsynaptic units. This synapse is believed to be an excitatory glutamatergic one, providing the possibility that TMT could induce an excitotoxic process resulting in elevations in intracellular calcium ([Ca2+]i). The objective of this study was to determine whether TMT had direct toxic effects on the postsynaptic spiral ganglion cells studied in primary culture and to identify the role of extracellular calcium in such an effect. The marker of interest was the effect of this agent on [Ca2+]i levels as determined using quantitation of the fluorescent calcium dye, Fura-2. TMT did induce a marked and sustained elevation in [Ca2+]i level in the spiral ganglion cells that appeared to have a rapid initial phase and a slower saturating phase. Studies performed using calcium-free medium showed that elevation of [Ca2+]i in spiral ganglion cells by TMT was attenuated but not entirely blocked. Further, the L-type calcium channel blocker, nifedipine, was able to inhibit the initial increase in [Ca2+]i, suggesting that at least this phase of the TMT effect was mediated by calcium channels, although nifedipine had no significant effect on the time to reach the maximal [Ca2+]i level. Parallel control experiments performed using application of exogenous glutamate and depolarizing K+ concentrations also produced elevation in [Ca2+]i levels. The data indicate that TMT elevates [Ca2+]i in isolated spiral ganglion cells both by increasing extracellular uptake via Ca2+ channels and also by releasing Ca2+ from intracellular stores. Thus TMT ototoxicity appears to include a direct postsynaptic toxic event.

Direct effects of reactive oxygen species on cochlear outer hair cell shape in vitro

Reactive oxygen species (ROS) have been implicated in the ototoxicity of various agents. This study examines the effects of superoxide anion (O2), hydroxyl radical (OH.) and hydrogen peroxide (H2O2), on isolated cochlear outer hair cell (OHC) morphology. OHCs were superfused with artificial perilymph (AP) or AP containing a specific ROS scavenger, and then with AP, ROS system or scavenger plus ROS system for 90 min. The generation of ROS as well as the scavenging properties of other agents were confirmed by specific biochemical assays. Control cells decreased 4.8% in mean length, and showed no obvious membrane damage. Generation of O2. or OH. resulted in high rates (85.7 and 42.9%, respectively) of bleb formation at the synaptic pole, and decreased (O2., 15.2%; OH., 17.3%) mean cell length. Length change and bleb formation rate were H2O2 concentration-dependent. 20 mM H2O2 led to 33.3% decreased mean cell length, and only 20% bleb formation; 0.1 mM H2O2 led to 83.3% bleb formation, with no length decrease. Superoxide dismutase, deferoxamine and catalase protected against O2., OH. and H2O2 effects, respectively. Bleb formation and diminished cell length likely represent differential lipid peroxidative outcomes at supra- and infranuclear membranes, and are consistent with effects of certain ototoxicants.

Trimethyltin disrupts N1 sensitivity, but has limited effects on the summating potential and cochlear microphonic

Trimethyltin (TMT), a model neurotoxicant, has previously been demonstrated to disrupt auditory thresholds in laboratory subjects. In this experiment we characterized the potency of this ototoxicant by means of a dose response study and then evaluated the functional effects of TMT administration when tone-bursts were presented at supra-threshold levels. Guinea pigs were anaesthetized and prepared for electrophysiological measurement of the compound action potential (CAP) and cochlear microphonic (CM). Subsequently averaged wave forms generated by tone-bursts of 0-80 dB SPL were evaluated in order to calculate both a N1 and a summating potential (SP) input-output function. We show that TMT at doses as low as 0.2 mg/kg produce elevations in N1, but not in the CM isopotential curve. Using exposures to 0.5 mg/kg TMT we show a profound reduction in the slope of the N1 input-output curve, but no shift in the SP. The results are consistent with the hypothesis that TMT disrupts function at the synapse between the inner hair cell and the Type 1 spiral ganglion cell.

The sensitivity to 3,3'-iminodipropionitrile differs for high- and midfrequency hearing loss in the developing rat

3,3'-Iminodipropionitrile (IDPN) has been demonstrated to produce a loss of hearing following both neonatal and adult exposures. Adult exposure induces a full spectrum hearing loss, whereas early postnatal exposure produces a high-frequency loss only. The purpose of this work was to delineate the period of development during which the rat becomes sensitive to the full ototoxic effects of IDPN. Primiparous Long Evans rats or their offspring were exposed to either saline or 300 mg/kg IDPN for three consecutive days. Ages of exposure were as follows: gestational days 15-17 or postnatal days (PND) 1-3, 5-7, 15-17, 20-22, 25-27, 30-32, 40-42, or 70-72. All animals were tested as adults for auditory thresholds to 5- and 40-kHz tones using reflex modification audiometry. Results demonstrate that adult-like susceptibility to IDPN was not reached until approximately PND 30-32. Early exposures (PND 5-22) to IDPN will induce a highfrequency selective hearing loss, sparing the lower frequency. Prenatal or early neonatal (PND 1-3) IDPN exposure resulted in a high degree of mortality (> 70%). The long period of time between the susceptible period for the high frequency (PND 5-7) and the lower frequency (PND 30-32) does not correspond to the basal to apical ontogenic profile of any one physiological or anatomical process. These data suggest either a unique site of action for IDPN in the cochlea or the possibility of two different mechanisms, one operating at early postnatal ages and one at later ages.