Active clinical trials for "Auditory Perceptual Disorders"

The purpose of this study was to determine the effects of hormone replacement therapy (HRT) on hearing in post-menopausal women.

The objective of the study is to validate a screening tool for auditory processing disorder in children of 7 to 13 years old. This screening tool was created based on literature and combines a questionnaire and a mini-battery of tests composed of verbal and nonverbal assessments.

Some children with certain language disorders may not properly process the sounds they hear, resulting in language impairments. The purpose of this study is to determine if deficits in auditory temporal processing the way the brain analyzes the timing and patterns of sounds are an inherited trait. Families with auditory temporal processing deficits are sought in order to identify the genes responsible for auditory temporal processing deficits. Children and adults with a diagnosis or history of language impairment in the family and their family members both affected and non-affected are eligible for this two-part study. In Part 1, participants undergo a series of language tests and listening tests to measure various characteristics of how they perceive sound. In Part 2, they are interviewed about language disorders, learning disabilities, and other medical problems of family members. This information is used to construct a pedigree (family tree diagram) showing the pattern of inheritance of family traits. Study subjects whose pedigree indicates that language disorders may be hereditary in their family will provide either a small blood sample (1 to 2 tablespoons) or a tissue specimen obtained from a cheek swab (rubbing the inside of the cheek with a small brush or cotton swabs). The sample will be used to isolate DNA for genetic analysis.

The cochlea, the sensory organ of hearing, is a structure of the temporal bone on the skull. In everyday life sounds are heard via air conduction. This means that vibrations in the air are conducted through our ear canals, via the eardrum and the middle-ear bones, to the cochlea. However, vibrations can be conducted to the cochlea via the bones of the head. Bone-conduction headsets have become popular for recreational use (for example cyclists and runners wear them to listen to music while exercising). When in a noisy environment, if a speech signal is delivered to a microphone connected via Bluetooth to the bone conduction headset, the person wearing the headset receives the speech signal as if the talker were closer to them. The ratio between the speech level and the noise level (SNR, signal-to-noise ratio) is increased, so that it is easier to understand the spoken message. A previous study carried out by the investigators has shown that this may help children with hearing loss due to otitis media with effusion ('glue ear'). The aim of the current study is to explore the potential of the headset to help children with auditory processing disorder (APD). Typically, children with APD have normal audiograms, but, in spite of this, they struggle to understand speech in a background noise. The headset can deliver the speech message to them. Currently, FM systems are used for children with APD in the classroom. These systems are effective, but their cost is high and provision may be limited. The feasibility of the use of the headset in a group of children with normal audiometric thresholds will be assessed. The study hypothesis is that using a bone-conduction headband improves speech recognition in noise and decreases listening effort even when air-conduction hearing thresholds are normal. Measures of speech recognition and listening effort will be done in quiet and in noise with and without the bone-conduction headset in order to measure the effect of using the headset on speech recognition when hearing thresholds are normal.