View clinical trials related to Auditory Processing Disorder.
Filter by:Every year, approximately 100,000 Veterans seek help at VA Audiology clinics for hearing and communication difficulties only to learn that they have normal hearing sensitivity. Unfortunately, there are very few established options to improve hearing and listening for these patients. To address this need, audiologists are increasingly prescribing hearing aids set to provide a small amount of amplification. Patients may benefit from the amplification or from modern hearing aid features such as noise reduction technology and the ability to stream sounds from a desired sound source directly to their ears thus reducing the background noise. This project will help to determine if prescribing hearing aids to patients without hearing loss is, in fact, beneficial and if so, why. It will also help to determine if some patients benefit more from hearing aids than others so that in the future, rehabilitation strategies can be better targeted toward individuals.
The purpose of this study is to learn more about how bilingual individuals process sound in challenging listening environments and how testing language may impact results on auditory processing assessments. Auditory processing evaluations assess specific auditory skills necessary to hear and understand complex auditory signals, but many of these tests rely heavily on language. This poses an issue for individuals with native languages other than English because the test results may not clearly identify whether performance is due to an auditory processing problem or to the language used in the test materials. This study aims to identify whether auditory processing performance differs in Spanish-English bilinguals based on the language of the test materials used (English vs. Spanish). Ultimately, the results of this study may aid in more accurate diagnoses and treatment of auditory processing disorders in bilingual individuals.
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.
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.
There are currently no cognitive tests that have been validated as screening tools for people with dementia and comorbid hearing loss. This is particularly important given the high prevalence of hearing impairment in older adults presenting to memory services and the risk of misdiagnosis of dementia in this population as outlined above. Cognitive tests validated in hearing impaired populations will also be important as outcome tools for interventional research aiming to find out if treating hearing loss may reduce dementia risk in the longer term.
Auditory Processing Disorder (APD) is a disorder where the functions of the ear are normal, but the person has difficulty identifying or discriminating sounds and experiences listening difficulties in noise. Remote Microphone Hearing Aids (RMHAs) are wireless listening devices that pick up the speaker's voice and transmit it to a receiver in the listener's ear. In this way, the negative effects of ambient noise, distance from speaker and reverberation are reduced. The research questions are whether RMHAs improve classroom listening, listening in noise performance, listening in spatialised noise and auditory attention, in children with APD. We hypothesize that RMHA use will lead to improved classroom listening and improved speech-in-noise skills after 6 months of RMHA use. Additionally, we hypothesise that listening in spatialised noise and attention skills will remain unchanged following the intervention period. Twenty-six (26) children aged 7-12 with a diagnosis of an APD from the Great Ormond Street Hospital Audiology clinic were included in the study.
In the management and remediation of students with specific performance deficits in speech-in-noise intelligibility, most often, a "triad" approach for treatment is used, which includes direct therapy, compensatory strategies, and environmental modifications. The purpose of the study is to determine whether a new hearing aid, the Phonak EduLink-FM System, can improve specific performance deficits in speech-in-noise intelligibility. Participants will complete a test battery related to auditory processing, as well as some psychological tests and questionnaires. One group of participants with specific performance deficits in speech-in-noise intelligibility will receive the hearing aid for use in school; a second group will not. The effect of this treatment on auditory performance, school performance and satisfaction, attention and verbal learning and memory, self concept, behavior and listening effort following 26 weeks of hearing aid use will be compared across the groups.