Raghunandhan S, Ravikumar A, Kameswaran Mohan, Mandke Kalyani, Ranjith R
Cochlear Implants Int. 2014 May;15(3):145-60. doi: 10.1179/1754762814Y.0000000064. Epub 2014 Mar 7.
Indications for cochlear implantation have expanded today to include very young children and those with syndromes/multiple handicaps. Programming the implant based on behavioural responses may be tedious for audiologists in such cases, wherein matching an effective Measurable Auditory Percept (MAP) and appropriate MAP becomes the key issue in the habilitation program. In 'Difficult to MAP' scenarios, objective measures become paramount to predict optimal current levels to be set in the MAP. We aimed to (a) study the trends in multi-modal electrophysiological tests and behavioural responses sequentially over the first year of implant use; (b) generate normative data from the above; (c) correlate the multi-modal electrophysiological thresholds levels with behavioural comfort levels; and (d) create predictive formulae for deriving optimal comfort levels (if unknown), using linear and multiple regression analysis.
This prospective study included 10 profoundly hearing impaired children aged between 2 and 7 years with normal inner ear anatomy and no additional handicaps. They received the Advanced Bionics HiRes 90 K Implant with Harmony Speech processor and used HiRes-P with Fidelity 120 strategy. They underwent, impedance telemetry, neural response imaging, electrically evoked stapedial response telemetry (ESRT), and electrically evoked auditory brainstem response (EABR) tests at 1, 4, 8, and 12 months of implant use, in conjunction with behavioural mapping. Trends in electrophysiological and behavioural responses were analyzed using paired t-test. By Karl Pearson's correlation method, electrode-wise correlations were derived for neural response imaging (NRI) thresholds versus most comfortable level (M-levels) and offset based (apical, mid-array, and basal array) correlations for EABR and ESRT thresholds versus M-levels were calculated over time. These were used to derive predictive formulae by linear and multiple regression analysis. Such statistically predicted M-levels were compared with the behaviourally recorded M-levels among the cohort, using Cronbach's alpha reliability test method for confirming the efficacy of this method.
NRI, ESRT, and EABR thresholds showed statistically significant positive correlations with behavioural M-levels, which improved with implant use over time. These correlations were used to derive predicted M-levels using regression analysis. On an average, predicted M-levels were found to be statistically reliable and they were a fair match to the actual behavioural M-levels. When applied in clinical practice, the predicted values were found to be useful for programming members of the study group. However, individuals showed considerable deviations in behavioural M-levels, above and below the electrophysiologically predicted values, due to various factors. While the current method appears helpful as a reference to predict initial maps in 'difficult to Map' subjects, it is recommended that behavioural measures are mandatory to further optimize the maps for these individuals.
The study explores the trends, correlations and individual variabilities that occur between electrophysiological tests and behavioural responses, recorded over time among a cohort of cochlear implantees. The statistical method shown may be used as a guideline to predict optimal behavioural levels in difficult situations among future implantees, bearing in mind that optimal M-levels for individuals can vary from predicted values. In 'Difficult to MAP' scenarios, following a protocol of sequential behavioural programming, in conjunction with electrophysiological correlates will provide the best outcomes.
如今,人工耳蜗植入的适应症已扩大到包括非常年幼的儿童以及患有综合征/多重残疾的人群。在这种情况下,基于行为反应对植入设备进行编程,对于听力学家而言可能很繁琐,在此类康复计划中,匹配有效的可测量听觉感知(MAP)以及合适的MAP成为关键问题。在“难以进行MAP编程”的情况下,客观测量对于预测MAP中要设置的最佳电流水平至关重要。我们旨在:(a)研究人工耳蜗使用第一年中多模态电生理测试和行为反应的连续趋势;(b)从上述研究中生成规范数据;(c)将多模态电生理阈值水平与行为舒适水平相关联;以及(d)使用线性和多元回归分析创建用于推导最佳舒适水平(如果未知)的预测公式。
这项前瞻性研究纳入了10名年龄在2至7岁之间、内耳解剖结构正常且无其他残疾的重度听力障碍儿童。他们接受了Advanced Bionics HiRes 90 K植入设备及Harmony言语处理器,并采用了具有保真度120策略的HiRes - P。在植入使用后的1、4、8和12个月,他们接受了阻抗遥测、神经反应成像、电诱发镫骨肌反射遥测(ESRT)和电诱发听觉脑干反应(EABR)测试,并结合行为图谱分析。使用配对t检验分析电生理和行为反应的趋势。通过卡尔·皮尔逊相关方法,得出神经反应成像(NRI)阈值与最舒适水平(M水平)的电极相关性,并计算EABR和ESRT阈值与M水平随时间的基于偏移(顶端、阵列中部和基底阵列)的相关性。这些用于通过线性和多元回归分析推导预测公式。使用克朗巴赫α可靠性检验方法,将此类统计预测的M水平与队列中行为记录的M水平进行比较,以确认该方法的有效性。
NRI、ESRT和EABR阈值与行为M水平呈现出统计学上显著的正相关,且随着植入使用时间的推移而改善。这些相关性用于通过回归分析推导预测的M水平。平均而言,预测的M水平在统计学上是可靠的,并且与实际行为M水平相当匹配。当应用于临床实践时,发现预测值对研究组的编程很有用。然而,由于各种因素,个体的行为M水平在电生理预测值之上和之下均表现出相当大的偏差。虽然当前方法作为预测“难以进行MAP编程”受试者初始图谱的参考似乎很有帮助,但建议必须采用行为测量来进一步优化这些个体的图谱。
本研究探讨了在一组人工耳蜗植入者中随时间记录的电生理测试和行为反应之间出现的趋势、相关性和个体变异性。所示的统计方法可作为指导方针,用于预测未来植入者在困难情况下的最佳行为水平,同时要记住个体的最佳M水平可能与预测值不同。在“难以进行MAP编程”的情况下,遵循顺序行为编程方案并结合电生理相关性将提供最佳结果。
