丝绸之路上的听觉神经元——用来连接神经电极间隙的蜘蛛丝

Q4 Engineering
Jana Schwieger, Verena Scheper, Thomas Lenarz, Peter M. Vogt, Sarah Strauß
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引用次数: 1

摘要

人工耳蜗(CI)通过刺激螺旋神经节神经元(SGN)恢复重度至重度感音神经性听力损失患者的听力。由于内耳的解剖结构,在SGN和电极阵列之间仍然存在充满液体的间隙。这个间隙阻碍了集中增产,从而优化了CI的性能。再生的神经突可以为直接的神经电极连接桥接这个充满液体的间隙,但需要支持基质。蜘蛛丝可能是这种支持的合适人选。因此,我们测试了蚕丝纤维与内耳神经元组织的生物相容性、作为神经突生长基质的适用性以及对ci电极阵列的适用性。从雌性Trichonephila蜘蛛身上提取的拖丝被编织在一个框架上,然后被高压灭菌。制备幼龄大鼠螺旋神经节,切开后滴入培养液于平行丝纤维上预培养以支持粘附,再加入剩余培养液。培养5d后,固定细胞并进行免疫细胞染色。对于CIapplication,丝绸被包裹在硅胶假人和单侧垫片上。与隔离剂相对,海藻酸盐水凝胶用于固丝和屏蔽。胶凝后,从中间切断丝环,形成突出的线。细胞沿丝纤维高度迁移和神经突再生,在某些情况下,脱落的神经突直接接触丝。有可能将丝绸固定在假人身上,使其成为突出的纤维。测试的蜘蛛丝与培养的内耳组织兼容,支持细胞生长,似乎是神经突接触的有吸引力的材料。作为突出纤维应用于CI是可能的,使其成为一种有希望的结构支持候选者,以桥接神经电极间隙。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Auditory Neurons on the Silk Road – spider silk for bridging the nerve-electrode-gap
Abstract The cochlear implant (CI) restores hearing to patients with severe to profound sensorineural hearing loss by stimulating the spiral ganglion neurons (SGN). Due to the inner ear anatomy, a fluid-filled gap remains between the SGN and the electrode array. This gap impedes focused stimulation and thus optimized performance with the CI. Regenerating neurites may bridge this fluid-filled gap for a direct nerveelectrode- link but require a supportive matrix. Spider silk might be a suitable candidate for this support. Therefore, silk fibers were tested for biocompatibility with inner ear neuronal tissue, suitability as neurite outgrowth matrix and applicability to the CI-electrode array. Dragline silk from female Trichonephila spiders was woven around a frame and autoclaved. Spiral ganglia of young rats were prepared, cut and placed in a drop of medium on the parallel silk fibers for pre-cultivation to support adherence before remaining medium was added. After 5d of cultivation, cells were fixed and immunocytologically stained. For CIapplication, silk was wrapped around a silicone dummy and a one-sided spacer. Opposite the spacer, alginate-hydrogel was applied for silk-fixation and -shielding. After gelation, silk loops were cut in the middle to form protruding threads. Cells showed a high degree of migration and neurite regeneration along the silk fibers and in some cases the outgrown neurites directly contacted the silk. It was possible to fix the silk to the dummy as protruding fibers. The tested spider silk is compatible with the inner ear tissue in culture, supports cell growth and seems to be an attractive material for neurite contacting. Application to the CI as protruding fibers is possible, making it a promising candidate for structural support to bridge the nerve-electrode-gap.
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来源期刊
Current Directions in Biomedical Engineering
Current Directions in Biomedical Engineering Engineering-Biomedical Engineering
CiteScore
0.90
自引率
0.00%
发文量
239
审稿时长
14 weeks
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