1.川北医学院/川北医学院附属医院耳鼻咽喉头颈外科 南充 637000
2.解放军总医院第六医学中心耳鼻咽喉头颈外科医学部/听觉与平衡觉全国重点实验室/国家耳鼻咽喉疾病临床医学研究中心/聋病教育部重点实验室 北京 100048
3.解放军总医院第七医学中心耳鼻咽喉头颈外科 北京 100700
钟旻璇 在读硕士;研究方向:临床听力学、助听器效果评估、人工耳蜗术前筛查及术后疗效评估
刘军,E-mail:liujunent@126.com
收稿:2024-11-24,
纸质出版:2025-01-15
移动端阅览
钟旻璇,杨崇灵,唐菲等.听皮层功能的神经电生理学评估方法研究进展[J].中国听力语言康复科学杂志,2025,23(01):104-108.
ZHONG Min-xuan,YANG Chong-ling,TANG Fei,et al.Research Progress on Neuroelectrophysiological Evaluation Methods of Auditory Cortex Function[J].Chinese Scientific Journal of Hearing and Speech Rehabilitation,2025,23(01):104-108.
钟旻璇,杨崇灵,唐菲等.听皮层功能的神经电生理学评估方法研究进展[J].中国听力语言康复科学杂志,2025,23(01):104-108. DOI: 10.3969/j.issn.1672-4933.2025.01.025.
ZHONG Min-xuan,YANG Chong-ling,TANG Fei,et al.Research Progress on Neuroelectrophysiological Evaluation Methods of Auditory Cortex Function[J].Chinese Scientific Journal of Hearing and Speech Rehabilitation,2025,23(01):104-108. DOI: 10.3969/j.issn.1672-4933.2025.01.025.
植入年龄和听觉剥夺时间是影响先天性聋患者人工耳蜗植入(CI)后听觉和言语康复效果的重要因素,这可能与不同年龄听皮层功能水平有关,听皮层功能评估在CI术前筛查、术后疗效评估,以及神经、精神和心理学相关疾病研究中具有重要意义。听皮层功能评估方法包括神经电生理学、形态学、功能影像学、分子生物学等方面,其中神经电生理学方法操作简单且无创,主要包括基于脑电图(electroencephalography,EEG)的皮层听觉诱发电位(cortical auditory evoked potential,CAEP),如P1-N1-P2波和失匹配负波(mismatch negative,MMN)等,以及基于脑磁图(magnetoencephalography,MEG)的听觉诱发磁场(auditory evoked field,AEF),但AEF检测设备昂贵、操作复杂、环境要求高,应用较少。本文将对听皮层功能的神经电生理学评估方法及其研究进展进行综述。
Auditory deprivation time and implantation age are important factors affecting the auditory and speech rehabilitation outcomes of cochlear implantation (CI) in patients with congenital deafness possibly associated with the functional level of the auditory cortex at different developmental stages. In terms of predicting preoperative efficacy
evaluating postoperative efficacy of CI
and conducting research on neurological
psychiatric
and psychological related diseases
the functional evaluation of the auditory cortex is essential. Methods for evaluating auditory cortex function encompass neuroelectrophysiology
morphology
functional imaging
and molecular biology. The neuroelectrophysiological methods have characteristics such as simplicity in operation and non-invasiveness
mainly including cortical auditory evoked potential (CAEP) based on electroencephalography (EEG)
such as P1-N1-P2 waves and mismatch negative (MMN)
and auditory evoked field (AEF) based on magnetoencephalography (MEG). However
AEF is less applied due to its costly detection equipment
complex operation
and stringent environmental requirements. This article will review neuroelectrophysiological evaluation methods and the research progress in auditory cortex function.
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