第一代人工耳蜗电极移位的颞骨组织病理学

Temporal Bone Histopathology of First-Generation Cochlear Implant Electrode Translocation.

机构信息

Department of Head and Neck Surgery.

Department of Neurology, David Geffen School of Medicine, University of California, Los Angeles, California.

出版信息

Otol Neurotol. 2019 Jul;40(6):e581-e591. doi: 10.1097/MAO.0000000000002247.

DOI:10.1097/MAO.0000000000002247

PMID:31058752

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6565463/

Abstract

OBJECTIVE

To evaluate the histopathology of human temporal bones (HTBs) with cochlear implants (CI).

BACKGROUND

Understanding CI translocation injuries is critical for improving outcomes.

MATERIAL AND METHODS

Thirteen HTBs from 12 CI patients were studied. Six HTBs exhibited translocation with localized injury (Group 1) and seven HTBs exhibited translocation with significant lateral wall injury (Group 2). There were no significant differences between Group 1 and Group 2 for age at death, age at implantation, and years with CI.

RESULTS

Four out of six of Group 1 had round window approach, while all seven of Group 2 had cochleostomy approach. Translocation injuries tended to occur near 180 degrees of angular insertion with a mean of 186.36 ± 51.62 degrees. Average CI insertion length for Group 2 was 21.86 ± 2.55 mm, significantly longer than Group 1 at 18.50 ± 3.33 mm (p = 0.031). Group 1 had an average of 17300 ± 9415 spiral ganglia neurons (SGNs) while Group 2 had significantly fewer SGNs 6714 ± 4269 (p = 0.015). Group 1 average auditory performance of 66.55 ± 27.20% was higher than that of Group 2 of 39.86 ± 15.36%. Group 2 had a high degree of osteoneogenesis and infiltration of cells generally localized to areas of translocation injury and cochleostomy.

CONCLUSION

Translocation injuries tend to occur at an insertion angle of 180 degrees, at 9 to 10 mm. Lateral wall injury and damage to the organ of Corti incites fibrosis, osteoneogenesis, and infiltration, lower SGN count and poorer auditory performance. Longer electrodes were more prone to translocation and higher chance of significant intracochlear injury.

摘要

目的

评估带人工耳蜗的人类颞骨（HTB）的组织病理学。

背景

了解人工耳蜗移位损伤对于改善结果至关重要。

材料和方法

研究了 12 例人工耳蜗患者的 13 例 HTB。6 例 HTB 显示有局部损伤的移位（第 1 组），7 例 HTB 显示有明显外侧壁损伤的移位（第 2 组）。第 1 组和第 2 组在死亡年龄、植入年龄和带人工耳蜗的年限方面没有显著差异。

结果

第 1 组有 4 例采用圆窗入路，而第 2 组全部采用镫骨切开术入路。移位损伤倾向于发生在 180 度角插入处附近，平均为 186.36±51.62 度。第 2 组的人工耳蜗插入长度平均为 21.86±2.55mm，明显长于第 1 组的 18.50±3.33mm（p=0.031）。第 1 组的平均螺旋神经节神经元（SGN）为 17300±9415 个，而第 2 组明显较少，为 6714±4269 个（p=0.015）。第 1 组的平均听力表现为 66.55±27.20%，高于第 2 组的 39.86±15.36%。第 2 组有高度的骨生成和细胞浸润，通常局限于移位损伤和镫骨切开术的区域。

结论

移位损伤倾向于在 180 度插入角发生，在 9 至 10mm 处。外侧壁损伤和耳蜗器损伤会引发纤维化、骨生成和浸润，导致 SGN 计数减少和听力表现变差。较长的电极更容易发生移位，并增加发生严重耳蜗内损伤的机会。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/58ab/6565463/aae82533a45f/nihms-1522298-f0001.jpg

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