Esmailie Fateme, Francoeur Mathieu, Ameel Tim
Department of Mechanical Engineering, University of Utah, Salt Lake City, Utah 84112, USA.
Int J Heat Mass Transf. 2020 Jun;154. doi: 10.1016/j.ijheatmasstransfer.2020.119683. Epub 2020 Apr 16.
Magnetic cochlear implant surgery requires removal of a magnet via a heating process after implant insertion, which may cause thermal trauma within the ear. Intra-cochlear heat transfer analysis is required to ensure that the magnet removal phase is thermally safe. The objective of this work is to determine the safe range of input power density to detach the magnet without causing thermal trauma in the ear, and to analyze the effectiveness of natural convection with respect to conduction for removing the excess heat. A finite element model of an uncoiled cochlea, which is verified and validated, is applied to determine the range of maximum safe input power density to detach a 1-mm-long, 0.5-mm-diameter cylindrical magnet from the cochlear implant electrode array tip. It is shown that heat dissipation in the cochlea is primarily mediated by conduction through the electrode array. The electrode array simultaneously reduces natural convection due to the no-slip boundary condition on its surface and increases axial conduction in the cochlea. It is concluded that natural convection heat transfer in a cochlea during robotic cochlear implant surgery can be neglected. It is found that thermal trauma is avoided by applying a power density from 2.265 × 10 W/m for 114 s to 6.6×10 W/m for 9 s resulting in a maximum temperature increase of 6°C on the magnet boundary.
磁性人工耳蜗植入手术需要在植入后通过加热过程移除磁铁,这可能会在耳内造成热损伤。需要进行耳蜗内热传递分析,以确保磁铁移除阶段在热方面是安全的。这项工作的目的是确定在不引起耳内热损伤的情况下分离磁铁的安全输入功率密度范围,并分析自然对流相对于传导在去除多余热量方面的有效性。应用经过验证和确认的未卷曲耳蜗有限元模型,来确定从人工耳蜗电极阵列尖端分离一个1毫米长、0.5毫米直径的圆柱形磁铁的最大安全输入功率密度范围。结果表明,耳蜗内的热耗散主要通过电极阵列的传导来介导。由于电极阵列表面的无滑移边界条件,电极阵列同时减少了自然对流,并增加了耳蜗内的轴向传导。得出的结论是,在机器人辅助人工耳蜗植入手术中,耳蜗内的自然对流热传递可以忽略不计。研究发现,通过施加功率密度从2.265×10 W/m持续114秒到6.6×10 W/m持续9秒,可避免热损伤,磁铁边界处的最高温度升高6°C。