Josef M. Miller

Neurotrophins can enhance spiral ganglion cell survival after inner hair cell loss

Following destruction of sensory cells of the organ of Corti, spiral ganglion cells (SGC) in the guinea pig degenerate. Chronic electrical stimulation via cochlear prostheses can enhance their survival, with the effect blocked by stopping the electrically elicited action potentials with tetrodotoxin. Blocking action potentials in the normal hearing ear with tetrodotoxin, however, does not cause degeneration. This suggests that in the pathological ear VIII N activity acts as a survival factor, while in the normal ear there are other survival factors that maintain SGCs. We examined neurotrophins, as survival factors in the deafened ear. Two weeks of treatment with BDNF (brain derived neurotrophic factor) administered chronically via a mini‐osmotic pump into scala tympani at 50 ng/ml, provided a statistically significant enhanced SGC survival over untreated deafened ears or deafened ears treated with artificial perilymph. Neurotrophin 3 provided some enhanced survival, but this was not statistically significant over untreated deafened ears. These observations suggest there are survival factors in the inner ear, including those coupled to direct activation of the auditory nerve fibers, that may serve to maintain the auditory nerve. These factors may be applied following deafness to maintain and enhance neural populations and to increase benefits to the profoundly deaf receiving cochlear implants.

Delayed production of free radicals following noise exposure

Reactive oxygen and reactive nitrogen species (ROS, RNS) formed in the inner ear in response to high-intensity noise are thought to play an important role in noise-induced hearing loss (NIHL). ROS appear rapidly and transiently in the inner ear during and following noise exposure, while hair cell loss progresses over time stabilizing two or more weeks after insult. Although the delayed loss may, in part, reflect slowly progressing apoptotic or necrosis pathways, an alternate hypothesis is that a continued formation of free radicals contributes to cell death. To evaluate this hypothesis, we measured auditory brain stem responses (ABRs), hair cell loss, and free radical activity in the guinea pig following noise exposure (5 h, 120 dB SPL, 1 OCB). Nitrotyrosine (NT) and 4-hydroxy-2-noneal (4-HNE) were used as histochemical markers of RNS and ROS formation, respectively. Assessments were performed prior to and on Days 1, 3, 7, 10, 14 and 21 after exposure. Immunoreactivity to NT and 4-HNE was low initially, reached a maximum at 7 to 10 days, and then declined. ABR thresholds increased maximally immediately after exposure, with partial recovery stabilizing at 7 to 10 days. Correlating with the delayed formation of ROS/RNS, there was a progressive hair cell loss, stabilizing at approximately 2 weeks. Based on these findings, we suggest that initial hair cell damage after noise may primarily reflect mechanical events plus transient intense ROS formation, while continued formation of ROS/RNS contributes to the long-term hair cell loss. The late formation of free radicals may provide a window of opportunity for pharmacological rescue immediately following exposure, requiring both ROS and RNS scavengers.

Intense noise induces formation of vasoactive lipid peroxidation products in the cochlea.

This study investigates the correlation between the formation of reactive oxygen species (ROS) and auditory damage in noise-induced hearing loss. The noise exposure (4-kHz octave band, 115 dB SPL, 5 h) created permanent threshold shifts at frequencies from 2 to 20 kHz. The lipid peroxidation product, 8-isoprostane, was determined biochemically and histochemically as an indicator of ROS. Noise exposure increased 8-isoprostane levels in the cochlea in a time-dependent manner. After 5 h of exposure, 8-isoprostane levels were more than 30-fold greater than baseline, and decreased rapidly after the termination of noise. The immunoreactivity to 8-isoprostane was increased in the stria vascularis, spiral ganglion cells and the organ of Corti. In the organ of Corti, immunostaining was restricted to the second turn in a region 10-12 mm from the apex. This region sustained most of the permanent hair cell damage as revealed in surface preparations. Outer hair cells were more heavily immunostained than inner hair cells while Hensens cells showed still less immunostain. These data are consistent with the view that ROS are involved in noise-induced damage. However, the relationship between ROS formation and tissue damage appears complex. In the organ of Corti, the pattern of noise-induced lipid peroxidation correlates well with subsequent morphological damage. The stria vascularis, however, does not sustain permanent damage despite intense lipid peroxidation. Differences in endogenous antioxidant levels and commitment to different apoptotic or survival pathways may underlie such differential responses.

Mechanisms of noise-induced hearing loss indicate multiple methods of prevention.

Recent research has shown the essential role of reduced blood flow and free radical formation in the cochlea in noise-induced hearing loss (NIHL). The amount, distribution, and time course of free radical formation have been defined, including a clinically significant late formation 7-10 days following noise exposure, and one mechanism underlying noise-induced reduction in cochlear blood flow has finally been identified. These new insights have led to the formulation of new hypotheses regarding the molecular mechanisms of NIHL; and, from these, we have identified interventions that prevent NIHL, even with treatment onset delayed up to 3 days post-noise. It is essential to now assess the additive effects of agents intervening at different points in the cell death pathway to optimize treatment efficacy. Finding safe and effective interventions that attenuate NIHL will provide a compelling scientific rationale to justify human trials to eliminate this single major cause of acquired hearing loss.

Neurotrophic factor intervention restores auditory function in deafened animals

A primary cause of deafness is damage of receptor cells in the inner ear. Clinically, it has been demonstrated that effective functionality can be provided by electrical stimulation of the auditory nerve, thus bypassing damaged receptor cells. However, subsequent to sensory cell loss there is a secondary degeneration of the afferent nerve fibers, resulting in reduced effectiveness of such cochlear prostheses. The effects of neurotrophic factors were tested in a guinea pig cochlear prosthesis model. After chemical deafening to mimic the clinical situation, the neurotrophic factors brain-derived neurotrophic factor and an analogue of ciliary neurotrophic factor were infused directly into the cochlea of the inner ear for 26 days by using an osmotic pump system. An electrode introduced into the cochlea was used to elicit auditory responses just as in patients implanted with cochlear prostheses. Intervention with brain-derived neurotrophic factor and the ciliary neurotrophic factor analogue not only increased the survival of auditory spiral ganglion neurons, but significantly enhanced the functional responsiveness of the auditory system as measured by using electrically evoked auditory brainstem responses. This demonstration that neurotrophin intervention enhances threshold sensitivity within the auditory system will have great clinical importance for the treatment of deaf patients with cochlear prostheses. The findings have direct implications for the enhancement of responsiveness in deafferented peripheral nerves.

Guinea pig auditory neurons are protected by glial cell line-derived growth factor from degeneration after noise trauma

For patients with profound hearing loss, cochlear implants have become the treatment of choice. These devices provide auditory information through direct electrical stimulation of the auditory nerve. Prosthesis function depends on survival and electrical excitability of the cochlear neurons. Degeneration of the auditory nerve occurs after lesions of its peripheral target field (organ of Corti), specifically, including loss of inner hair cells (IHCs). There is now evidence that local treatment of the cochlea with neurotrophins may enhance survival of auditory neurons after aminoglycoside-induced deafness. Glial cell line-derived neurotrophic factor (GDNF) has recently been shown to be an important survival factor in other regions of the nervous system. By in situ hybridization, we now show that IHCs of the neonatal and mature rat cochlea synthesize GDNF and that GDNF-receptor alpha, but not c-Ret, is expressed in the rat spiral ganglion. We also show that GDNF is a potent survival-promoting factor for rat cochlear neurons in vitro. Finally, we examined GDNF efficacy to enhance cochlear-nerve survival after IHC lesions in vivo. We found that chronic intracochlear infusion of GDNF greatly enhances survival of guinea pig cochlear neurons after noise-induced IHC lesions. Our results demonstrate that GDNF is likely to be an endogeneous survival factor in the normal mammalian cochlea and it could have application as a pharmacological treatment to prevent secondary auditory nerve degeneration following organ of Corti damage.

Attenuation of cochlear damage from noise trauma by an iron chelator, a free radical scavenger and glial cell line-derived neurotrophic factor in vivo

Tissue injury by reactive oxygen species (ROS) may play a role in noise-induced hearing loss (NIHL). Since iron is involved in ROS generation, we studied if an iron chelator, deferoxamine mesylate (DFO), alone or in combination with mannitol, a hydroxyl scavenger and weak iron chelator, attenuates NIHL. Further, we investigated if glial cell line-derived neurotrophic factor (GDNF) provides additive or synergistic protection of the cochlea from acoustic trauma when given together with DFO and mannitol. Pigmented female guinea pigs were exposed to noise (4 kHz octave band, 115 dB SPL, 5 h). One hour before, immediately after, and 5 h after noise exposure, subjects received an injection of 5 ml saline/kg (control, group I), 100 mg DFO/kg (group II), 15 mg mannitol/kg (group III), or both DFO and mannitol (group IV and V). Animals in group V underwent implantation of an osmotic pump filled with GDNF (100 ng/ml) in the left ear 4 days before noise. Each treatment afforded some protection from noise damage. Group I showed significantly greater outer hair cell loss and threshold shifts at two or more frequencies compared to groups II through V. GDNF provided an additive functional, but not morphological, protection with DFO and mannitol. These findings indicate that iron chelators can attenuate NIHL, as do ROS scavengers, supporting the notion that ROS generation plays a role in NIHL. Additional functional protection provided with GDNF suggests that GDNF may attenuate noise-induced cochlear damage through a mechanism that is additive with antioxidants.

Relation of psychophysical data to histopathology in monkeys with cochlear implants.

Psychophysical measures of threshold and dynamic range for electrical stimulation were made in macaque monkeys that had electrodes implanted in the scala tympani. At the completion of psychophysical testing the monkeys were sacrificed and the cochleas and brain steins examined. Low thresholds and large dynamic ranges were associated with minimal damage to the organ of Corti and minimal brain stem degeneration. whereas thresholds were high and dynamic ranges small in subjects showing a high degree of sensorineural cochlear damage and brain stem degeneration. Three different implant orientations were observed. but orientation did not seem to have a major effect on threshold.

Role of glutathione in protection against noise-induced hearing loss.

A potential mechanism of hearing loss due to acoustic overstimulation is the generation of reactive oxygen species (ROS). ROS not removed by antioxidant defenses could be expected to cause significant damage to the sensory cells of the cochlea. We studied the influence of the antioxidant glutathione (GSH) on noise-induced hearing loss by using l-buthionine-[S,R]-sulfoximine (BSO), an inhibitor of GSH synthesis, and 2-oxothiazolidine-4-carboxylate (OTC), a cysteine prodrug, which promotes rapid restoration of GSH when GSH is acutely depleted. Pigmented female guinea pigs were exposed to broadband noise (102 dB SPL, 3 h/day, 5 days) while receiving daily injections of BSO, OTC, or saline. By weeks 2 and 3 after noise exposure, BSO-treated animals showed significantly greater threshold shifts above 12 kHz than saline-treated subjects, whereas OTC-treated animals showed significantly smaller threshold shifts at 12 kHz than controls. Histologically assessed noise-induced damage to the organ of Corti, predominantly basal turn row 1 outer hair cells, was most pronounced in BSO-treated animals. High performance liquid chromatographic analysis showed that OTC significantly increased cysteine levels, but not GSH levels, in the cochlea. These findings show that GSH inhibition increases the susceptibility of the cochlea to noise-induced damage and that replenishing GSH, presumably by enhancing availability of cysteine, attenuates noise-induced cochlear damage.

Direct inner ear infusion of dexamethasone attenuates noise-induced trauma in guinea pig

The protective effect of dexamethasone (DEX) against noise-induced trauma, as reflected in hair cell destruction and elevation in auditory brainstem response (ABR) sensitivity, was assessed in guinea pigs. The animals were administered DEX (1, 10, 100, and 1000 ng/ml) or artificial perilymph (AP) via a mini-osmotic pump directly into scala tympani and, on the fourth day after pump implantation, exposed to 120 dB SPL octave band noise, centered at 4 kHz, for 24 h. Animals receiving DEX demonstrated a dose-dependent reduction in noise-induced outer hair cell loss (significant at 1, 10 and 100 ng/ml DEX animals compared to AP control animals) and a similar attenuation of the noise-induced ABR threshold shifts, observed 7 days following exposure (significant at 100 ng/ml DEX animals compared to AP control animals). These physiological and morphological results indicate that direct infusion of DEX into the perilymphatic space has protective effects against noise-induced trauma in the guinea pig cochlea.