Salamy A, Eldredge L, Sweetow R
Department of Psychiatry, University of California, San Francisco, USA.
Ear Hear. 1996 Feb;17(1):42-8. doi: 10.1097/00003446-199602000-00005.
To assess the feasibility of obtaining transient-evoked otoacoustic emissions (TEOAEs) directly in the nursery, to examine the nature of failures in this population, and to determine the time requirements for this test relative to the auditory brain stem response (ABR).
TEOAEs and ABRs were recorded from 149 ears, at bedside, in the recovery or intensive care nursery. Subjects were selected according to the risk criteria developed by the Joint Committee on Infant Hearing (1991). Parametric and nonparametric statistical procedures were conducted to describe demographics and test results, to evaluate TEOAE measures by subgroups, and to compare infants by pass/fail outcome. Multivariate techniques were applied to the data to test implicit hypotheses regarding the source of TEOAE failures. In addition, the time required to carry out each test was evaluated in an analysis of variance design.
63.5% of the ears studied passed both procedures, 5% failed both, and 31.5% passed the ABR but failed the TEOAE. Although infants who failed the TEOAE had lower birthweights, shorter gestational periods, and were younger at the time of testing, no statistical differences were found for nursery (intensive care nursery/recovery), bed type (isolette/open crib), ear (left/right), or gender. Infants < 38 wk postconceptional age had smaller TEOAE responses and lower noise levels than did those > 37 wk. There were no differences in environmental noise levels (at the microphone) for passed or failed ears or whether infants were in isolettes or open cribs. Statistically prolonged ABR wave I latencies (Z-scores) at 60 and 30 dB among infants who passed the ABR but failed the TEOAE indicated some obstruction to the acoustic stimulus, whereas TEOAE noise measures neither distinguished these groups nor identified this condition. Three summary times involved in the performance of these tests were obtained: (a) actual test time, measured from start to completion of data collection with a stopwatch; (b) total test time, defined by the actual test time plus the respective preparation, setup, and cleanup (ABR) time; and (c) time reported by the computer system during intrinsic sampling. There were no significant differences in actual or total test times, but these values were distinguished from the machine time, which represented an underestimate of the time required to effectively conduct each test.
These findings show that TEOAEs can be acquired in the nursery, but the high false-positive rate suggests that alternative or additional screening methods, for example, the ABR, must also be available. It must be recognized that TEOAE failures increase test time, thereby negating any savings relative to ABR screening alone.
评估在新生儿重症监护室直接获取瞬态诱发耳声发射(TEOAEs)的可行性,研究该群体中检测失败的原因,并确定此测试相对于听性脑干反应(ABR)所需的时间。
对新生儿重症监护室或恢复室的149只耳朵在床边进行TEOAEs和ABRs检测。根据婴儿听力联合委员会(1991年)制定的风险标准选择受试者。采用参数和非参数统计方法描述人口统计学特征和测试结果,按亚组评估TEOAE测量值,并根据通过/未通过结果比较婴儿。应用多变量技术对数据进行分析,以检验关于TEOAE检测失败原因的隐含假设。此外,在方差分析设计中评估进行每项测试所需的时间。
63.5%的受试耳朵两项检测均通过,5%两项均未通过,31.5%通过ABR但未通过TEOAE。虽然未通过TEOAE的婴儿出生体重较低、孕周较短且测试时年龄较小,但在新生儿重症监护室(重症监护室/恢复室)、床型(保温箱/开放式婴儿床)、耳朵(左/右)或性别方面未发现统计学差异。孕龄小于38周的婴儿TEOAE反应较小,噪声水平较低,而孕龄大于37周的婴儿则相反。通过或未通过检测的耳朵的环境噪声水平(在麦克风处)以及婴儿是在保温箱还是开放式婴儿床中并无差异。在通过ABR但未通过TEOAE的婴儿中,60 dB和30 dB时ABR波I潜伏期(Z分数)在统计学上延长,表明声刺激存在一定阻碍,而TEOAE噪声测量既无法区分这些组,也无法识别这种情况。获得了进行这些测试涉及的三个总结时间:(a)实际测试时间,用秒表从数据收集开始到结束测量;(b)总测试时间,定义为实际测试时间加上各自的准备、设置和清理(ABR)时间;(c)计算机系统在内部采样期间报告的时间。实际测试时间或总测试时间没有显著差异,但这些值与机器时间不同,机器时间低估了有效进行每项测试所需的时间。
这些结果表明,在新生儿重症监护室可以获取TEOAEs,但高假阳性率表明还必须有其他或额外的筛查方法,例如ABR。必须认识到,TEOAE检测失败会增加测试时间,从而抵消相对于单独进行ABR筛查所节省的时间。
