The present report provides an overview of terminology studies in audiology including topics and study characteristics, as well as categorizing the main issues. The goals are to improve the understanding of the current issues for terminology in audiology and to provide some basic information that will be useful to develop an international standard. Search procedures were completed over two phases. Phase 1 included a systematic electronic searches using MEDLINE (PubMed), Excerpta Medica Database, Cumulative Index to Nursing and Allied Health Literature, and International Organization for Standardization with keywords related to terminology of audiology. The studies were initially identified according to the titles of 2921 publications following careful abstract examination. Of these, whole texts of 16 publications were retrieved. Five papers met the inclusion criteria were further investigated. In phase 2, a manual search was conducted to collect additional publications with keywords related to terminology project in audiology. A total of 16 papers were found. The essential terminology issues classified included 'appropriateness,' 'classification/framework,' 'inconsistency of terminology,' 'multilingual and international aspects,' and 'service quality/delivery including communication and accessibility.' This was indicative of the paucity of terminology research in audiology, despite recurring terminology issues. Establishment of standardized terminology in audiology may minimize current challenging terminology issues by improving appropriateness and consistency of terminology as well as communication among relevant stakeholders at national and international levels.
Audiology* ; Nursing

Audiology ; education

Introduction: This discussion paper reviews and synthesises the literature on simulated learning environment (SLE) from allied health sciences, medical and nursing in general and audiology specifically. The focus of the paper is on discussing the use of high-fidelity (HF) SLE and describing the challenges for developing a HF SLE for clinical audiology training. Methods: Through the review of the literature, this paper discusses seven questions, (i) What is SLE? (ii) What are the types of SLEs? (iii) How is SLE classified? (iv) What is HF SLE? (v) What types of SLEs are available in audiology and their level of fidelity? (vi) What are the components needed for developing HF SLE? (vii) What are the possible types of HF SLEs that are suitable for audiology training? Publications were identified by structured searches from three major databases PubMed, Web of Knowledge and PsychInfo and from the reference lists of relevant articles. The authors discussed and mapped the levels of fidelity of SLE audiology training modules from the literature and the learning domains involved in the clinical audiology courses. Results: The discussion paper has highlighted that most of the existing SLE audiology training modules consist of either low- or medium-fidelity types of simulators. Those components needed to achieve a HF SLE for audiology training are also highlighted. Conclusion: Overall, this review recommends that the combined approach of different levels and types of SLE could be used to obtain a HF SLE training module in audiology training.
Audiology ; Hearing

Audiology ; China ; Congresses as Topic

Audiology ; trends ; China

Audiology ; China ; Congresses as Topic

Audiology ; Humans ; Tinnitus ; therapy

Audiology ; Auditory Threshold ; Humans

Background: Establishing clinic-specific normative data for auditory brainstem response (ABR) tests is important due to variability in stimulus parameters and equipment. Objective: To establish normative values for ABR measurements in infants aged 3 to 6 months. Design: Descriptive study. Participants: 12 normal-hearing male and female infants, aged 3 to 6 months, who underwent ABR tests. Setting: Audiology Unit, Department of Otorhinolaryngology - Head and Neck Surgery, Southern Philippines Medical Center, Davao City, January 2021 to December 2022. Main outcome measures: Absolute latency readings for waves I, III, and V, and interpeak latencies for waves I-III, III-V, and I-V using Interacoustics Eclipse EP15 apparatus with a RadioEar IP30 Insert Earphone transducer at a stimulus intensity of 60-90 dBnHL and a rate of 45.1 clicks/sec. Main results: All normative ABR ranges were computed with a threshold of ± 2 SD from the means. The computed means (normative ranges) for absolute latencies for waves I, III, and V were 1.49 ± 0.15 (1.19-1.78) msec, 4.45 ± 0.32 (3.81-5.10) msec, and 6.65 ± 0.26 (6.12-7.17) msec, respectively. The computed normative values for interpeak latencies for waves I-III, III-V, and I-V were 2.80 ± 0.22 (2.36-3.23) msec, 2.19 ± 0.21 (1.78-2.61) msec, and 4.99 ± 0.29 (4.41-5.57) msec, respectively. Conclusion In our study, we have established normative values for ABR test measurements for infants aged 3 to 6 months.
Hearing Loss ; Audiology

Audiology ; Humans ; Speech-Language Pathology ; Voice