Deafening noise down-regulates dopamine transmission in the hub of the central auditory system.

The cumulative effects of noise are experienced across society regardless of occupation and age. Previous research has connected noise induced hearing disorders to neuronal changes within auditory brain regions, such as the inferior colliculus (IC), where the ascending and descending auditory neurons converge. Nevertheless, the neurochemical adaptations in the central auditory system underlining these disorders are not fully understood. Based on existing body of evidence that implicates dopamine (DA) in the central auditory processes, we hypothesized that alteration in the DA neurotransmission in the IC is a major neuroadaptation associated with noise-induced hearing loss. Using adult Sprague Dawley rat model in conjunction with an electrochemical method and immunoassay, this hypothesis was explored by characterizing the impact of noise on the DA system in the IC. Herein, slice fast scan cyclic voltammetry (FSCV) data revealed attenuation in stimulated DA release in the subjects exposed to deafening noise (10 kHz, 118 dB SPL, 1/3 octave band noise for 4 h) 24 h prior to the neurochemical measurements. DA receptor 2 (D2) functionality was also investigated as part of a possible negative feedback mechanism for the noise induced alteration, however no significant difference was observed between the noise exposed versus the control subjects. On the other hand, immunocytochemistry of the IC displayed marked difference in D2 receptor distributions overall and specifically, in the central and external nucleus of the IC. Taken together, these data link decrease DA neurotransmission in the IC to noise-induced hearing loss and show that while deafening noise does not directly impact the functionality of the D2 receptors, it does diminish the receptor density. Overall, these changes in the IC were demonstrated to be long-term and could be mediated by oxidative stress.

Repeated toluene exposure leads to neuroadaptation in dopamine release mechanisms within the nucleus accumbens core.

BACKGROUND: Intentionally inhaling volatile organic solvent like toluene for its intoxicating effects continues to be a public health concern. While repeated abuse of toluene has deleterious behavioral and health effects, little is known about the actions of toluene on the dopaminergic neurotransmitter system within the central nervous system. METHOD: The present study employed complementary neurochemical techniques of slice fast-scan cyclic voltammetry (FSCV) and in vivo microdialysis, to assess dopamine (DA) dynamics immediately after repeated exposure to 2000- or 4000-ppm toluene. DA D3 autoreceptor functionality, measured by FSCV with pharmacological manipulations and brain tissue content analysis with high performance liquid chromatography, were also used to account for the changes in the DA dynamics. RESULTS: Toluene-exposed mice had decreased stimulated DA release only in the nucleus accumbens core immediately after seven days of repeated exposure. DA uptake was decreased in the core only after 2000-ppm exposure. The differences in stimulated DA release were not attributed to alterations in intraneuronal DA levels as measured by tissue content analysis. Basal extracellular DA levels were not significantly different between the air- and toluene-treated mice. However, following an additional toluene exposure, mice had elevated extracellular DA levels in the nucleus accumbens during recovery. This potentiation in extracellular accumbal DA levels was further heightened following potassium stimulation. The accumbal DA D3 autoreceptor function did not appear to play a role as a potential mediator for these differences. CONCLUSION: Our FSCV and microdialysis results suggest a neuroadaptation in DA release mechanics within the nucleus accumbens, but the exact neuronal mechanism of toluene's impact remains elusive.

Publisher Correction: Novel QUEST MRI In Vivo Measurement of Noise-induced Oxidative Stress in the Cochlea.

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Novel QUEST MRI In Vivo Measurement of Noise-induced Oxidative Stress in the Cochlea.

Effective personalized therapeutic treatment for hearing loss is currently not available. Cochlear oxidative stress is commonly identified in the pathogenesis of hearing loss based upon findings from excised tissue, thus suggesting a promising druggable etiology. However, the timing and site(s) to target for anti-oxidant treatment in vivo are not clear. Here, we address this long-standing problem with QUEnch-assiSTed Magnetic Resonance Imaging (QUEST MRI), which non-invasively measures excessive production of free radicals without an exogenous contrast agent. QUEST MRI is hypothesized to be sensitive to noise-evoked cochlear oxidative stress in vivo. Rats exposed to a loud noise event that resulted in hair cell loss and reduced hearing capability had a supra-normal MRI R1 value in their cochleae that could be corrected with anti-oxidants, thus non-invasively indicating cochlear oxidative stress. A gold-standard oxidative damage biomarker [heme oxidase 1 (HO-1)] supported the QUEST MRI result. The results from this study highlight QUEST MRI as a potentially transformative measurement of cochlear oxidative stress in vivo that can be used as a biomarker for improving individual evaluation of anti-oxidant treatment efficacy in currently incurable oxidative stress-based forms of hearing loss.

MRI compatible MS2 nanoparticles designed to cross the blood-brain-barrier: providing a path towards tinnitus treatment.

Fundamental challenges of targeting specific brain regions for treatment using pharmacotherapeutic nanoparticle (NP) carriers include circumventing the blood-brain-barrier (BBB) and tracking delivery. Angiopep-2 (AP2) has been shown to facilitate the transport of large macromolecules and synthetic nanoparticles across the BBB. Thus, conjugation of AP2 to an MS2 bacteriophage based NP should also permit transport across the BBB. We have fabricated and tested a novel MS2 capsid-based NP conjugated to the ligand AP2. The reaction efficiency was determined to be over 70%, with up to two angiopep-2 conjugated per MS2 capsid protein. When linked with a porphyrin ring, manganese (Mn2+) remained stable within MS2 and was MRI detectable. Nanoparticles were introduced intracerebroventricularly or systemically. Systemic delivery yielded dose dependent, non-toxic accumulation of NPs in the midbrain. Design of a multifunctional MRI compatible NP platform provides a significant step forward for the diagnosis and treatment of intractable brain conditions, such as tinnitus.

Tinnitus and temporary hearing loss result in differential noise-induced spatial reorganization of brain activity.

Loud noise frequently results in hyperacusis or hearing loss (i.e., increased or decreased sensitivity to sound). These conditions are often accompanied by tinnitus (ringing in the ears) and changes in spontaneous neuronal activity (SNA). The ability to differentiate the contributions of hyperacusis and hearing loss to neural correlates of tinnitus has yet to be achieved. Towards this purpose, we used a combination of behavior, electrophysiology, and imaging tools to investigate two models of noise-induced tinnitus (either with temporary hearing loss or with permanent hearing loss). Manganese (Mn2+) uptake was used as a measure of calcium channel function and as an index of SNA. Manganese uptake was examined in vivo with manganese-enhanced magnetic resonance imaging (MEMRI) in key auditory brain regions implicated in tinnitus. Following acoustic trauma, MEMRI, the SNA index, showed evidence of spatially dependent rearrangement of Mn2+ uptake within specific brain nuclei (i.e., reorganization). Reorganization of Mn2+ uptake in the superior olivary complex and cochlear nucleus was dependent upon tinnitus status. However, reorganization of Mn2+ uptake in the inferior colliculus was dependent upon hearing sensitivity. Furthermore, following permanent hearing loss, reduced Mn2+ uptake was observed. Overall, by combining testing for hearing sensitivity, tinnitus, and SNA, our data move forward the possibility of discriminating the contributions of hyperacusis and hearing loss to tinnitus.

Toluene's effects on activity and extracellular dopamine in the mouse are altered by GABAA antagonism.

The abuse of inhalants like toluene continues to be widespread around the world, especially among children and teenagers. Despite its frequency of misuse, the dynamics between dopamine (DA) and gamma-aminobutyric acid (GABA) in response to toluene exposure remains unclear. To further decipher toluene's actions, we used a dynamic exposure system in combination with microdialysis to examine in vivo the effects of acutely inhaled toluene on DA release within the mouse caudate putamen (CPu). Results show that toluene inhalation produced increases in DA levels and locomotor activity. In mice that were pretreated with the GABAA antagonist, bicuculline, there was no change in the locomotor response during toluene but activity was potentiated following toluene exposure. Bicuculline pretreatment increased extracellular DA levels during toluene exposure, suggesting that DA and GABA-releasing neuron interaction may play a role in the rewarding properties of toluene.

Striatal dopamine dynamics in mice following acute and repeated toluene exposure.

RATIONALE: The abused inhalant toluene has potent behavioral effects, but only recently has progress been made in understanding the neurochemical actions that mediate the action of toluene in the brain. Available evidence suggests that toluene inhalation alters dopamine (DA) neurotransmission, but toluene's mechanism of action is unknown. OBJECTIVE: The present study evaluated the effect of acute and repeated toluene inhalation (0, 2,000, or 4,000 ppm) on locomotor activity as well as striatal DA release and uptake using slice fast-scan cyclic voltammetry. RESULTS: Acutely, 2,000 and 4,000 ppm toluene increased locomotor activity, while neurochemically only 4,000 ppm toluene potentiated electrically evoked DA release across the caudate-putamen and the nucleus accumbens. Repeated administration of toluene resulted in sensitization to toluene's locomotor activity effects. Brain slices obtained from mice repeatedly exposed to toluene demonstrated no difference in stimulated DA release in the caudate-putamen as compared to control animals. Repeated exposure to 2,000 and 4,000 ppm toluene caused a concentration-dependent decrease of 25-50 % in evoked DA release in the nucleus accumbens core and shell relative to air-exposed mice. CONCLUSIONS: These voltammetric neurochemical findings following repeated toluene exposure suggest that there may be a compensatory downregulation of the DA system. Acute or repeated toluene exposure had no effect on the DA uptake kinetics. Taken together, these results demonstrate that acute toluene inhalation potentiates DA release, while repeated toluene exposure attenuates DA release in the nucleus accumbens only.

Probing the ability of presynaptic tyrosine kinase receptors to regulate striatal dopamine dynamics.

Brain-derived neurotrophic factor (BDNF) modulates the synaptic transmission of several monoaminergic neuronal systems. Molecular techniques using synapatosomes in previous studies have suggested that BDNF's receptor, tyrosine kinases (Trk), can quickly regulate dopamine release and transporter dynamics. Our main objective in this study is to determine whether slice fast scan cyclic voltammetry can be used to investigate the role of the TrkB receptor on dopamine release and uptake processes in the caudate-putamen. Fast scan cyclic voltammetry measured dopamine release and uptake rates in the presence of BDNF, or its agonist 7,8-dihydroxyflavone, or a TrkB inhibitor K252a. Superfusion of BDNF led to partial recovery of the electrically stimulated dopamine release response in BDNF(+/-) mice which is blunted compared to wildtype mice, with no effect in wildtype mice. Conversely, infusion of 7,8-dihydroxyflavone increased electrically stimulated dopamine release in wildtype mice with no difference in BDNF(+/-) mice. Overall, BDNF and 7,8-dihydroxyflavone had no effect on dopamine uptake rates. Concentrations greater than 3 µM 7,8-dihydroxyflavone affected dopamine uptake rates in BDNF(+/-) mice only. To demonstrate that BDNF and 7,8-dihydroxyflavone modulate dopamine release by activating the TrkB receptor, both genotypes were pretreated with K252a. K252a was able to block BDNF and 7,8-DHF induced increases during stimulated dopamine release in BDNF(+/-) and wildtype mice, respectively. Fast scan cyclic voltammetry demonstrates that acute TrkB activation potentiates dopamine release in both genotypes.

Presynaptic dopamine dynamics in striatal brain slices with fast-scan cyclic voltammetry.

Extensive research has focused on the neurotransmitter dopamine because of its importance in the mechanism of action of drugs of abuse (e.g. cocaine and amphetamine), the role it plays in psychiatric illnesses (e.g. schizophrenia and Attention Deficit Hyperactivity Disorder), and its involvement in degenerative disorders like Parkinson's and Huntington's disease. Under normal physiological conditions, dopamine is known to regulate locomotor activity, cognition, learning, emotional affect, and neuroendocrine hormone secretion. One of the largest densities of dopamine neurons is within the striatum, which can be divided in two distinct neuroanatomical regions known as the nucleus accumbens and the caudate-putamen. The objective is to illustrate a general protocol for slice fast-scan cyclic voltammetry (FSCV) within the mouse striatum. FSCV is a well-defined electrochemical technique providing the opportunity to measure dopamine release and uptake in real time in discrete brain regions. Carbon fiber microelectrodes (diameter of ~ 7 µm) are used in FSCV to detect dopamine oxidation. The analytical advantage of using FSCV to detect dopamine is its enhanced temporal resolution of 100 milliseconds and spatial resolution of less than ten microns, providing complementary information to in vivo microdialysis.