Project description:Noise-induced hidden hearing loss (HHL) is a new type of hearing loss that has been identified in recent years and leads to insidious damage to the cochlea, unlike the well-known noise-induced hearing loss (NIHL). However, the cellular and molecular basis for it remains to be elucidated. Here, we established a single-cell transcriptome profile of the C57BL/6J mouse cochlea, in which we describe the transcriptome changes of individual cell types within the cochlea with HHL and NIHL. Mice in the HHL group were exposed to 110 dB of noise for 2 hours, and those in the NIHL group were exposed to 115 dB of noise for 4 hours for 3 days. The cochlea was taken 6 hours after the last noise exposure. The control group was not exposed to noise, with other conditions being the same as those in the noise-exposed group. The results of sequencing at the single-cell level help us gain a deeper understanding of the mechanisms of the development of HHL and NIHL.

Project description:Exposure to excessive noise levels is considered one of the main etiologies of acquired hearing loss. Noise-induced hearing loss (NIHL) affects a large number of people during the productive years of life, and imposes a large impact on quality of life and a high socioeconomic burden. Here, we tested the effect of the ISL1 in NIHL. We used an inbred mouse strain (CBA/CaJ) and carried out single-cell RNA sequencing to examine the gene expression profiles comparing (AAV-ISL1) with (NIHL-only).

Project description:Hearing functions through the mechanical transduction of inner ear sensory cells, hair cells, and their connections to the auditory neurons, which convert the stimuli into electrical signals to be detected by the brain. Noise-induced hearing loss (NIHL) caused by exposure to excessively sounds cannot be medically corrected. Strategies to overcome the apparently irreversible noise-induced hearing loss (NIHL) in mammals become paramount for hearing treatment. The drug has been reported in attenuating inflammation in different species. Here, we tested the effect of the drug in acoustic trauma. We carried out single-cell RNA sequencing to examine the gene expression profiles comparing Drug group with Untreated group in response to the acoustic trauma.

Project description:The molecular mechanisms underlying the great differences in susceptibility to noise-induced hearing loss (NIHL) exhibited by both humans and laboratory animals are unknown. Using microarray technology, the present study demonstrates that the effects of noise overexposure on the expression of molecules likely to be important to the development of NIHL differ among inbred mice that have distinctive susceptibilities to NIHL including B6.CAST, 129X1/SvJ, and 129S1/SvImJ. The noise-exposure protocol produced, on average, a permanent loss of about 40 dB in sensitivity for auditory brainstem responses in susceptible B6.CAST mice, but no threshold elevations for the two resistant 129S1/SvImJ and 129X1/SvJ substrains. Measurements of noise-induced gene expression changes 6 h after the noise exposure revealed significant alterations in the expression levels of 48 genes in the resistant mice, while by these same criteria, there were seven differentially expressed genes in the susceptible B6.CAST mice. Differentially expressed genes in both groups of mice included subsets of transcription factors. However, only in the resistant mice was there a significant induction of proteins involved in cell-survival pathways such as HSP70, HSP40, p21, GADD45, Ier3, and Nfi. Moreover, increased expression of three of these factors after noise was confirmed at the protein level. Drastically enhanced HSP70, GADD45, and p21 immunostaining were detected 6 h after the noise exposure in subsets of cells of the lateral wall, spiral limbus, and organ of Corti as well as in cochlear nerve fibers. Upregulation of these proteins after noise exposure likely contributes to the prevalence of survival cellular pathways and thus to the resistance to NIHL that is characteristic of the 129X1/SvJ mice. Experiment Overall Design: Female 10-wk-old mice of the B6.CAST and 129X1/SvJ strains were divided randomly into non-noise control and noise-exposure groups. The non-noise mice served as controls in the gene-profiling experiments to control for the stress induced by experimenter handling and/or confinement of the mice in the noise-exposure chamber that was not directly related to the noise. This mice were in the noise chamber for a sham exposure. In contrast, the ‘noise’ groups were exposed to a 105-dB SPL, 10-kHz octave band of noise for 1 h and sacrificed 6 h after the exposure. Of each of these major groups, eight mice were used for each of three 129X1/SvJ control and three noise-exposed 129X1/SvJ arrays and two B6.CAST control and two noise-exposed B6.CAST arrays. Consequently within each subgroup the arrays are biological replicates.

Project description:The molecular mechanisms underlying the great differences in susceptibility to noise-induced hearing loss (NIHL) exhibited by both humans and laboratory animals are unknown. Using microarray technology, the present study demonstrates that the effects of noise overexposure on the expression of molecules likely to be important to the development of NIHL differ among inbred mice that have distinctive susceptibilities to NIHL including B6.CAST, 129X1/SvJ, and 129S1/SvImJ. The noise-exposure protocol produced, on average, a permanent loss of about 40 dB in sensitivity for auditory brainstem responses in susceptible B6.CAST mice, but no threshold elevations for the two resistant 129S1/SvImJ and 129X1/SvJ substrains. Measurements of noise-induced gene expression changes 6 h after the noise exposure revealed significant alterations in the expression levels of 48 genes in the resistant mice, while by these same criteria, there were seven differentially expressed genes in the susceptible B6.CAST mice. Differentially expressed genes in both groups of mice included subsets of transcription factors. However, only in the resistant mice was there a significant induction of proteins involved in cell-survival pathways such as HSP70, HSP40, p21, GADD45beta, Ier3, and Nf-kappaB. Moreover, increased expression of three of these factors after noise was confirmed at the protein level. Drastically enhanced HSP70, GADD45beta, and p21 immunostaining were detected 6 h after the noise exposure in subsets of cells of the lateral wall, spiral limbus, and organ of Corti as well as in cochlear nerve fibers. Upregulation of these proteins after noise exposure likely contributes to the prevalence of survival cellular pathways and thus to the resistance to NIHL that is characteristic of the 129X1/SvJ mice. Keywords: effects of noise exposure in distinct inbred mice

Project description:<h4><strong>INTRODUCTION:</strong> Noise-induced hearing loss (NIHL) is an increasing problem in society and accounts for a third of all cases of acquired hearing loss. NIHL is caused by formation of reactive oxygen species (ROS) in the cochlea causing oxidative stress. Hydrogen gas (H₂) can alleviate the damage caused by oxidative stress and can be easily administered through inhalation.</h4><h4><strong>OBJECTIVES:</strong> To present a protocol for untargeted metabolomics of guinea pig perilymph and investigate the effect of H₂ administration on the perilymph metabolome of noise exposed guinea pigs.</h4><h4><strong>METHODS:</strong> The left ear of guinea pigs were exposed to hazardous impulse noise only (Noise, n = 10), noise and H₂ (Noise + H2, n = 10), only H₂ (H2, n = 4), or untreated (Control, n = 2). Scala tympani perilymph was sampled from the cochlea of both ears. The polar component of the perilymph metabolome was analyzed using a HILIC-UHPLC-Q-TOF-MS-based untargeted metabolomics protocol. Multivariate data analysis (MVDA) was performed separately for the exposed- and unexposed ear.</h4><h4><strong>RESULTS:</strong> MVDA allowed separation of groups Noise and Noise + H2 in both the exposed and unexposed ear and yielded 15 metabolites with differentiating relative abundances. Seven were found in both exposed and unexposed ear data and included two osmoprotectants. Eight metabolites were unique to the unexposed ear and included a number of short-chain acylcarnitines.</h4><h4><strong>CONCLUSIONS:</strong> A HILIC-UHPLC-Q-TOF-MS-based protocol for untargeted metabolomics of perilymph is presented and shown to be fit-for-purpose. We found a clear difference in the perilymph metabolome of noise exposed guinea pigs with and without H₂ treatment.</h4>

Project description:The purpose of this study is to investigate the therapeutic effect of MSC-derived apoVs treatment on NIHL and the potential mechanism of resisting oxidative stress damage in hair cells, as well as the distribution of apoptotic vesicles in the inner ear. The study provided a new direction for the treatment of noise-induced hearing loss and inner ear delivery.

Project description:Therapeutic Restoration of miR-96 Prevents Hearing Loss in Mice through Modulation of Noise-Induced and Genetic Pathways

Project description:Hair cells (HCs) are the mechanoreceptors responsible for hearing and balance in the inner ear. Multiple factors cause HC loss including aging, noise exposure and genetic predisposition. A barrier to hearing restoration after HC loss is the inability of mammalian auditory HCs to spontaneously regenerate. Multiple factors are shown to be crucial for HC development and represent good candidates for regenerative studies. Atoh1 is widely accepted to be necessary and contextually sufficient for driving HC fate. Furthermore, the miRNA-183 family is known to be expressed at the time of HC differentiation, and mutations in miR-96 (one member of the family) can cause deafness both in mouse and human. Our goal is to identify and compare the impact of Atoh1/miR-183 family alone and in combination on the transcriptome of two different developmental cell models; mouse embryonic stem cells (mESCs) and immortalized multipotent otic progenitors (iMOPs)

Project description:In order to elucidate molecular mechanisms of noise-induced hearing loss in the cochlea (inner ear), transcriptome of the cochlear sample was analyzed after induction of hearing loss by exposure to intense noise in mice. Cochlear transcriptome was analyzed at 3 hours following the noise exposure.