The importance of interaural time differences and level differences in spatial release from masking

Numerous studies have described improvements in speech understanding when interaural time differences (ITDs) and interaural level differences (ILDs) are present. The present study aimed to investigate whether either cue in isolation can elicit spatial release from masking (SRM) in a speech-on-speech masking paradigm with maskers positioned symmetrically around the listener. Twelve adults were tested using three presentations of the Listening in Spatialized Noise-Sentences Test, with each presentation modified to contain different interaural cues in the stimuli. Results suggest that ILDs provide a similar amount of SRM as ITDs and ILDs combined. ITDs alone provide significantly less benefit. (C) 2013 Acoustical Society of Americ

Real-Time Contrast Enhancement to Improve Speech Recognition

An algorithm that operates in real-time to enhance the salient features of speech is described and its efficacy is evaluated. The Contrast Enhancement (CE) algorithm implements dynamic compressive gain and lateral inhibitory sidebands across channels in a modified winner-take-all circuit, which together produce a form of suppression that sharpens the dynamic spectrum. Normal-hearing listeners identified spectrally smeared consonants (VCVs) and vowels (hVds) in quiet and in noise. Consonant and vowel identification, especially in noise, were improved by the processing. The amount of improvement did not depend on the degree of spectral smearing or talker characteristics. For consonants, when results were analyzed according to phonetic feature, the most consistent improvement was for place of articulation. This is encouraging for hearing aid applications because confusions between consonants differing in place are a persistent problem for listeners with sensorineural hearing loss

Age-Related Changes of Myelin Basic Protein in Mouse and Human Auditory Nerve

Age-related hearing loss (presbyacusis) is the most common type of hearing impairment. One of the most consistent pathological changes seen in presbyacusis is the loss of spiral ganglion neurons (SGNs). Defining the cellular and molecular basis of SGN degeneration in the human inner ear is critical to gaining a better understanding of the pathophysiology of presbyacusis. However, information on age-related cellular and molecular alterations in the human spiral ganglion remains scant, owing to the very limited availably of human specimens suitable for high resolution morphological and molecular analysis. This study aimed at defining age-related alterations in the auditory nerve in human temporal bones and determining if immunostaining for myelin basic protein (MBP) can be used as an alternative approach to electron microscopy for evaluating myelin degeneration. For comparative purposes, we evaluated ultrastructural alternations and changes in MBP immunostaining in aging CBA/CaJ mice. We then examined 13 temporal bones from 10 human donors, including 4 adults aged 38–46 years (middle-aged group) and 6 adults aged 63–91 years (older group). Similar to the mouse, intense immunostaining of MBP was present throughout the auditory nerve of the middle-aged human donors. Significant declines in MBP immunoreactivity and losses of MBP+ auditory nerve fibers were observed in the spiral ganglia of both the older human and aged mouse ears. This study demonstrates that immunostaining for MBP in combination with confocal microscopy provides a sensitive, reliable, and efficient method for assessing alterations of myelin sheaths in the auditory nerve. The results also suggest that myelin degeneration may play a critical role in the SGN loss and the subsequent decline of the auditory nerve function in presbyacusis

Transient-Evoked Otoacoustic Emissions Reflect Audiometric Patterns of Age-Related Hearing Loss

Distinct forms of age-related hearing loss are hypothesized based on evidence from animal models of aging, which are identifiable in human audiograms. The Sensory phenotype results from damage (e.g., excessive noise or ototoxic drugs) to outer hair cells and sometimes inner hair cells, producing large threshold increases predominately at high frequencies. The Metabolic phenotype results from a decline in endocochlear potential that can reduce outer hair cell motility throughout the cochlea, producing gradually sloping thresholds from lower to higher frequencies. Finally, the combined Metabolic + Sensory phenotype results in low-frequency losses similar to the Metabolic phenotype and high-frequency losses similar to the Sensory phenotype. Because outer hair cell function appears to be affected differently in each phenotype, this study used audiograms from 618 adults aged 50 to 93 years ( n  = 1,208 ears) to classify phenotypes and characterize differences in transient-evoked otoacoustic emission (TEOAE) data. Significant phenotype differences were observed in frequency-band TEOAEs and configuration (intercept and slope), including large and broadly distributed TEOAE reductions for Metabolic and Metabolic + Sensory ears and more focused high-frequency TEOAE reductions for Sensory ears. These findings are consistent with metabolic declines that reduce cochlear amplification across a broad range of frequencies and more basally situated, high-frequency declines in sensory hearing loss. The results provide further validation for the classification of age-related hearing loss phenotypes based on audiograms and show human TEOAE declines that are highly consistent with animal models

Classifying Human Audiometric Phenotypes of Age-Related Hearing Loss from Animal Models

This find is registered at Portable Antiquities of the Netherlands with number PAN-0002989