Stronks Hendrik Christiaan, Arendsen Timothy Samuel, Veenstra Mirte, Boermans Peter-Paul Bernard Marie, Briaire Jeroen Johannes, Frijns Johan Hubertus Maria
Department of Otorhinolaryngology and Head & Neck surgery, Leiden University Medical Center, Leiden, the Netherlands.
Leiden Institute for Brain and Cognition, Leiden University, Leiden, the Netherlands.
Ear Hear. 2025 May 29. doi: 10.1097/AUD.0000000000001690.
The substantial variability in speech perception outcomes after cochlear implantation complicates efforts to develop valid predictive models of these outcomes. Existing predictive regression models are too unreliable for clinical application, possibly because speech intelligibility (SI) after cochlear implant (CI) rehabilitation is often based on a limited number of assessments. The development of SI after CI has rarely been detailed, although knowing the shape of the learning curve can potentially improve predictive modeling. Knowing the learning curve after CI could also aid in setting expectations about SI immediately after implantation, and the duration of rehabilitation. The current objectives were to construct learning curves to estimate baseline SI at 1 week ( B ), maximal SI after rehabilitation ( M ), and rehabilitation time (time to reach 80% of the learning effect; t [ M - B ] 80% ), and to subsequently deploy these outcomes for multiple-regression modeling to predict CI outcomes.
To assess rehabilitation after cochlear implantation, we retrospectively fitted learning curves using clinically available SI assessments from 533 postlingually deaf, unilaterally implanted adults. SI was assessed with consonant-vowel-consonant words (CVC) in quiet, with phoneme score as the outcome measure. Participants were followed for up to 4 years, with SI measurements collected at fixed intervals. SI was commonly assessed 1, 2, 4, and 8 weeks after device activation. B , M , and t ( M - B ) 80% were determined from the fitted learning curves. Predictive multiple-regression analyses were performed on these three outcome measures based on eight previously identified preoperative demographic and audiometric predictor variables: age at implantation, duration of severe-to-profound hearing loss, best-aided CVC phoneme score (in the free field), unaided ipsilateral and contralateral residual hearing and CVC phoneme scores (measured with headphones), and education type (regular or special education).
At 1 week after CI activation, raw phoneme scores had increased from 40% preoperatively (best-aided condition) to 51%, with further improvement to approximately 78% at 4 years. SI increased significantly until 1 year after activation and then plateaued. Fitted learning curves supported better estimates of these parameters, showing that average baseline SI at 1 week after CI activation was 51%, increasing to 85% after rehabilitation. The asymptotic score exceeded the raw average after 4 years because many cases had not yet plateaued. The median t ( M - B ) 80% was 1.5 months. Predictive modeling identified duration of hearing loss, age at implantation, best-aided CVC phoneme score, and education type as the most robust predictors for postoperative SI. Despite the statistically significant correlations, however, the combined predictive value was ~19% for B , 10% for M , and 2% for t ( M - B ) 80% .
This study is among the few to generate detailed learning curves after cochlear implantation. By including clinical SI measures in the earliest rehabilitation period, we report a median rehabilitation time with CI of 1.5 months. This implied rapid learning effect emphasizes the value of monitoring SI in the first few weeks after rehabilitation. According to multiple-regression analyses, the most commonly used preoperative variables correlated significantly with postoperative outcomes, but with limited predictive value for the clinic. By fitting learning curves through data reported in the literature, we show that the increase in SI during rehabilitation is an important predictor for t ( M - B ) 80% .
人工耳蜗植入术后言语感知结果存在显著差异,这使得开发有效的这些结果预测模型变得复杂。现有的预测回归模型在临床应用中可靠性太差,可能是因为人工耳蜗(CI)康复后的言语清晰度(SI)通常基于有限的评估次数。尽管了解学习曲线的形状可能会改善预测模型,但CI后SI的发展情况很少有详细描述。了解CI后的学习曲线也有助于在植入后立即设定对SI的预期以及康复持续时间。当前的目标是构建学习曲线,以估计术后1周的基线SI(B)、康复后的最大SI(M)以及康复时间(达到学习效果80%的时间;t[M - B]80%),并随后将这些结果用于多元回归建模以预测CI结果。
为了评估人工耳蜗植入后的康复情况,我们回顾性地使用来自533名单侧植入人工耳蜗的语后聋成年患者的临床可用SI评估数据拟合学习曲线。在安静环境下用辅音 - 元音 - 辅音单词(CVC)评估SI,以音素得分作为结果指标。对参与者进行长达4年的随访,以固定间隔收集SI测量值。通常在设备激活后1、2、4和8周评估SI。从拟合的学习曲线中确定B、M和t(M - B)80%。基于八个先前确定的术前人口统计学和听力测定预测变量,对这三个结果指标进行预测性多元回归分析:植入时年龄、重度至极重度听力损失持续时间、最佳助听CVC音素得分(在自由声场中)、未助听的同侧和对侧残余听力以及CVC音素得分(用耳机测量),以及教育类型(普通教育或特殊教育)。
在CI激活后1周,原始音素得分从术前(最佳助听条件下)的40%提高到51%,在4年时进一步提高到约78%。SI在激活后1年内显著增加,然后趋于平稳。拟合的学习曲线支持对这些参数的更好估计,表明CI激活后1周的平均基线SI为51%,康复后增加到85%。4年后的渐近得分超过了原始平均值,因为许多病例尚未达到平稳状态。t(M - B)80%的中位数为1.5个月。预测建模确定听力损失持续时间、植入时年龄、最佳助听CVC音素得分和教育类型是术后SI最可靠的预测因素。然而,尽管存在统计学上的显著相关性,但综合预测值对于B约为19%,对于M约为10%,对于t(M - B)80%约为2%。
本研究是少数生成人工耳蜗植入后详细学习曲线的研究之一。通过在最早的康复期纳入临床SI测量,我们报告了CI康复的中位时间为1.5个月。这种快速的学习效果强调了在康复后头几周监测SI的价值。根据多元回归分析,最常用的术前变量与术后结果显著相关,但对临床的预测价值有限。通过根据文献报道的数据拟合学习曲线,我们表明康复期间SI的增加是t(M - B)80%的重要预测因素。
