About the Author(s)


Lucretia Petersen Email symbol
Division of Communication Sciences and Disorders, Department of Health and Rehabilitation Sciences, Faculty of Health Sciences, University of Cape Town, South Africa

Wayne J. Wilson symbol
School of Health and Rehabilitation Sciences, Faculty of Health and Behavioural Sciences, University of Queensland, Australia

Harsha Kathard
Division of Communication Sciences and Disorders, Department of Health and Rehabilitation Sciences, Faculty of Health Sciences, University of Cape Town, South Africa

Citation


Petersen, L., Wilson, W.J., & Kathard, H. (2018). Towards the preferred stimulus parameters for distortion product otoacoustic emissions in adults: A preliminary study. South African Journal of Communication Disorders, 65(1), a585. https://doi.org/10.4102/sajcd.v65i1.585

Original Research

Towards the preferred stimulus parameters for distortion product otoacoustic emissions in adults: A preliminary study

Lucretia Petersen, Wayne J. Wilson, Harsha Kathard

Received: 31 Oct. 2017; Accepted: 31 Mar. 2018; Published: 16 July 2018

Copyright: © 2018. The Author(s). Licensee: AOSIS.
This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Background: Although distortion product otoacoustic emissions (DPOAEs) are useful in evaluating cochlear outer hair cell function, determining the optimal stimulus parameters could result in a more reliable, sensitive and specific diagnostic tool across the range of DPOAE applications.

Objectives: To identify which stimulus parameters warrant further investigation for eliciting the largest and most reliable DPOAEs in adult humans.

Method: A single group, repeated measures design involving a convenience sample of 20 normal-hearing participants between 19 and 24 years of age.

Results: Descriptive statistics and mixed model analyses suggested L1/L2 intensity levels of 65/65 dB sound pressure level (SPL) and 65/55 dB SPL, and f2/f1 ratios of 1.18, 1.20 and 1.22 elicited larger and more reliable DPOAEs in both ears.

Conclusion: Further investigation of the 65/65 dB SPL and 65/55 dB SPL intensity levels and the 1.18, 1.20 and 1.22 f2/f1 ratios is warranted to determine the stimulus parameters for eliciting the largest and most reliable DPOAEs in adult humans across the range of DPOAE applications.

Introduction

Distortion product otoacoustic emissions (DPOAEs) are sounds emitted from the cochlea in response to two simultaneously presented tonal stimuli. These stimuli have levels designated as L1 and L2 and frequencies designated as f1 and f2. The sensitivity of DPOAEs to outer hair cell dysfunction in the cochlea has seen them successfully used in a variety of clinical and research applications, such as newborn hearing screening, diagnostic audiological assessment, ototoxicity monitoring and the study of cochlear mechanics (Dhar & Hall, 2012; Hood & Berlin, 2002).

The successful use of DPOAEs in a range of applications suggests that their optimal stimulus parameters have been determined. This is not the case (Petersen, Wilson, & Kathard, 2017). Instead, the DPOAE level has been found to depend on varying combinations of stimulus parameters, including f1 and f2 frequencies, f2/f1 ratio, L1 and L2 intensity levels and L1/L2 level separation (Prieve & Fitzgerald, 2015). Furthermore, DPOAEs have been elicited using a wide range of stimulus parameters, including f2/f1 ratios from 1.03 to 1.79 and L1/L2 combinations ranging from 30/30 dB sound pressure level (SPL) to 85/85 dB SPL (Petersen et al., 2017). Dreisbach and Siegel (2001) added to this complexity by reporting that the optimal f2/f1 ratio varies as a function of f2 frequency, with lower f2/f1 values eliciting higher DPOAE levels at higher f2 frequencies and vice versa.

Recommended stimulus parameters have also varied depending on the application. For diagnostic purposes and/or ototoxicity monitoring, f2/f1 ratios have ranged from 1.20 to 1.22 and L1/L2 combinations from 45/35 dB to 65/55 dB SPL (Dhar & Hall, 2012; Hall, 2000). Hall (2000) also reported that for cochlear lesions, decreasing the stimulus levels improved DPOAE sensitivity, whereas increasing the stimulus levels improved DPOAE specificity. For screening applications, an f2/f1 ratio of 1.20 has often been recommended with L1/L2 combinations of either 65/55 dB SPL or 65/65 dB SPL (Dhar & Hall, 2012; Hall, 2000). Other recommendations have included an L1/L2 combination of 65/55 dB SPL for its reported twofold advantage of producing a higher DPOAE level with an improved sensitivity to cochlear dysfunction, whereas the use of L1/L2 combinations above 70/70 dB SPL has been discouraged to avoid possible response artifact that can be mistaken for DPOAEs and confusion over the source of the resulting DPOAEs (Dhar & Hall, 2012).

The variation in stimulus parameters used to elicit DPOAEs highlights the continuing need to determine the optimal DPOAE stimulus parameters across all its applications. This search needs to be driven by sound research based on a continuum of evidence that considers two factors: the cyclical nature of knowledge creation and the quality of existing evidence informing clinical practice. The cyclical nature of knowledge creation, especially in the case of clinical practice, refers to the cycle of developing theories that are then tested by research to develop new knowledge. This new knowledge is then applied to clinical settings where it is used to refine existing theories or propose new ones (Schmidt & Brown, 2015). Patient care is improved through the repeating nature of this cycle and its ability to generate ever-changing scientific knowledge. In the case of DPOAEs, the quality of existing evidence informing clinical practice refers to the following questions: ‘how rigorous is the research investigating DPOAE stimulus parameters?’ and ‘how strong is the evidence for the stimulus parameters currently used in the clinical setting?’ Asking such questions seeks to strengthen clinical practice and expand current evidence bases (Puddy & Wilkins, 2011).

In response to the above call, the authors of this study recently began to search for the optimal stimulus parameters for eliciting DPOAEs from human adults for clinical applications, especially to assist with early identification of cochlear damage in individuals receiving ototoxic treatment for multi-drug-resistant tuberculosis. This search began with a systematic review (Petersen et al., 2017) that first asked: ‘what is an “optimal” DPOAE?’ Factors such as the clinical value of DPOAE level, signal-to-noise ratio (SNR), reliability, sensitivity and specificity to cochlear dysfunction were considered, as well as confounds such as the high number of DPOAE parameters open to manipulation, the small effect sizes of changing some parameters, the physiological processes represented by DPOAEs and the high intersubject variability seen in DPOAEs. The review then examined 47 DPOAE studies that had met the inclusion criteria for the systematic review. Of these, 33 studies met the inclusion criteria to examine the influence of intensity and/or frequency ratio on the DPOAE level. Most of the studies were found to have small sample sizes (often fewer than 10 participants) and/or to have manipulated only one set of stimulus parameters (18 having manipulated L1/L2 levels at a fixed f2/f1 ratio, or vice versa). Of the remaining 15 studies that manipulated both intensity and frequency ratio parameters, 8 studies used 15 participants or fewer. Ten of the 15 studies had only used descriptive statistics when reporting their results, leaving open the possibility that any observed differences had occurred by chance alone (interestingly, this limitation was seen in two seminal and highly cited papers on DPOAE stimulus parameters by Gaskill and Brown [1990] and Harris, Lonsbury-Martin, Stagner, Coats and Martin [1989]). Petersen et al. (2017) concluded that although some parameters are commonly used to elicit DPOAEs, only their effects on DPOAE level have been considered in limited detail (with their effect of DPOAE SNR, reliability and sensitivity and specificity to cochlear dysfunction being largely ignored), and the optimal parameters for eliciting DPOAEs in adult humans in clinical applications have yet to be determined (Petersen et al., 2017).

This study sought to expand on the findings of Petersen et al. (2017) towards a final determination of the optimal stimulus parameters for eliciting DPOAEs from human adults for clinical diagnostic applications. It considered a wide range of commonly used stimulus parameters from those reported by Petersen et al. (2017) but expanded their investigation by systematically manipulating both f2/f1 ratios and L1/L2 levels simultaneously. This study was limited to measuring the effect of stimulus parameters on DPOAE level and reliability (and not SNR or sensitivity and specificity to cochlear dysfunction) in adult humans with normal hearing, to manage the total number of variables under examination.

Method

Research design

A single group, repeated measures design was used for this study. This design was deemed appropriate to examine the influence of intensity and frequency ratio stimulus parameters on DPOAE levels.

Participants

Twenty normal-hearing adult participants (15 female, 5 male, aged 19 to 24 years) were conveniently sampled from the staff and student population of the University of Cape Town, South Africa. These participants had no obvious outer ear or tympanic membrane abnormalities on otoscopy, had hearing thresholds ≤ 15 dB HL at octave frequencies from 0.25 to 8 kHz on pure tone audiometry (Clark, 1981), had middle ear pressure and compliance within normal limits -(Grason-Stadler, 2001) on tympanometry, had no self-reported history of ear events that could affect DPOAE recordings and had passed a DPOAE screening assessment.

Protocol

Participants were initially screened for inclusion in the study using a live voice interview and a commercially available otoscope, audiometer, tympanometer and DPOAE device (GSI Audera 2.7, Version C). To pass the DPOAE screening, the participants had to show 2f1-f2 DPOAEs at least 3 dB above the noise floor at f2 frequencies 2, 4 and 8 kHz to tonal stimuli with an f2/f1 ratio of 1.2 and an L1/L2 setting of 65/55 dB SPL. All initial testing was conducted in a sound-treated booth meeting South African National Standards (2006).

Distortion product otoacoustic emissions testing was conducted in a quiet room with background noise levels < 55 dB A as measured using a Brüel & Kjær 2238 class 1 handheld sound level meter. The 2f1-f2 DPOAE measurements were obtained from each ear of each participant using the following stimulus parameters: f2/f1 ratios – 1.18, 1.20, 1.22, 1.24, 1.26 and 1.28; L1/L2 settings – 65/65 dB SPL, 65/55 dB SPL, 60/45 dB SPL, 60/53 dB SPL and 55/40 dB SPL; and f2 frequencies: 2003 Hz, 2519 Hz, 3178 Hz, 3996 Hz, 5000 Hz, 6996 Hz and 8003 Hz. To mitigate potential order effects, a single sequence of stimulus parameters was set, and each participant was started at a different point in this sequence. The order of ear testing was reversed for each sequential participant. The 2f1-f2 DPOAEs were sampled until at least one of the two stopping rules was met: (1) the noise floor at the distortion product frequency was less than -10 dB SPL or (2) until 32 s of artifact-free sampling had been averaged (Dille et al., 2010). Participants were seated in a comfortable chair and were instructed to remain still and quiet during the DPOAE test procedure with breaks provided as required. The DPOAE test time per participant was approximately 90 min per test occasion. Each participant underwent DPOAE testing on two occasions 24 h – 48 h apart.

Data collection

The following DPOAE data were recorded from each participant for each set of stimulus parameters at each f2 frequency on each test occasion: absolute level of DPOAE, absolute level of the noise floor and the DPOAE SNR, calculated as the absolute level of the DPOAE minus the level of the noise floor.

Data analysis

All DPOAE data were found to meet parametric assumptions following examination of the histograms of these data, box-and-whisker plots and Q–Q plots (data not shown). Descriptive statistics were calculated for all DPOAE measures, and correlation analyses were conducted to determine if the DPOAE results for the left and right ears were related. As these analyses showed significant correlations in DPOAE results between the ears, all further analyses of the DPOAE data were conducted for each ear separately.

Two sets of linear mixed model analysis were conducted at the 5% significance level on the DPOAE data for each f2 value separately. Each set of analyses considered DPOAE amplitudes as dependent variables, the stimulus level combinations and frequency ratios as fixed effect independent variables and the participants as a random effect independent variable. The first set of analyses sought to identify the presence of any main effects of level settings (L1/L2 in dB SPL) for all f2/f1 settings combined, and any main effects of frequency ratio settings (f2/f1) for all L1/L2 settings combined. The second set of analyses sought to identify the presence of any main effects of the combined level (L1/L2 in dB SPL) and frequency ratio (f2/f1) settings.

Finally, two-way mixed model intraclass correlation coefficient (ICC) analyses for absolute agreement were conducted at the 5% significance level on the DPOAE data for each f2 value separately to determine the level of agreement (reliability) of the absolute levels of the DPOAE recordings from the first to the second assessment occasions for each combined level (L1/L2 in dB SPL) and frequency ratio (f2/f1) setting separately.

All statistical analyses were conducted using IBM SPSS Statistics versions 23 and 24 (64-bit edition).

Ethical consideration

Unconditional ethical clearance was granted to conduct the study by the Faculty of Health Sciences Human Research Ethics Committee (HREC/REF: 512/2013).

Results

Figure 1 shows the DPOAE mean absolute levels for all combinations of f2/f1 and L1/L2 at each f2 frequency for the participants at the first assessment occasion. This figure also presents the numbers of ears showing DPOAEs at each of these stimulus combinations. These results showed this study’s participants were more likely to show DPOAEs of higher intensity at lower f2 frequencies.

FIGURE 1: Mean distortion product otoacoustic emission absolute levels per intensity and frequency ratio combinations for each frequency (f2): (a) right ear at 2003 Hz, (b) left ear at 2003 Hz, (c) right ear at 2519 Hz, (d) left ear at 2519 Hz, (e) right ear at 3175 Hz, (f) left ear at 3175 Hz, (g) right ear at 3996 Hz, (h) left ear at 3996 Hz, (i) right ear 5000 Hz, (j) left ear at 5000 Hz, (k) right ear at 6996 Hz, (l) left ear at 6996 Hz, (m) right ear at 8003Hz and (n) left ear at 8003Hz. Hz, hertz.

FIGURE 1 (Continues…): Mean distortion product otoacoustic emission absolute levels per intensity and frequency ratio combinations for each frequency (f2): (a) right ear at 2003 Hz, (b) left ear at 2003 Hz, (c) right ear at 2519 Hz, (d) left ear at 2519 Hz, (e) right ear at 3175 Hz, (f) left ear at 3175 Hz, (g) right ear at 3996 Hz, (h) left ear at 3996 Hz, (i) right ear 5000 Hz, (j) left ear at 5000 Hz, (k) right ear at 6996 Hz, (l) left ear at 6996 Hz, (m) right ear at 8003Hz and (n) left ear at 8003Hz. Hz, hertz.

FIGURE 1 (Continues…): Mean distortion product otoacoustic emission absolute levels per intensity and frequency ratio combinations for each frequency (f2): (a) right ear at 2003 Hz, (b) left ear at 2003 Hz, (c) right ear at 2519 Hz, (d) left ear at 2519 Hz, (e) right ear at 3175 Hz, (f) left ear at 3175 Hz, (g) right ear at 3996 Hz, (h) left ear at 3996 Hz, (i) right ear 5000 Hz, (j) left ear at 5000 Hz, (k) right ear at 6996 Hz, (l) left ear at 6996 Hz, (m) right ear at 8003Hz and (n) left ear at 8003Hz. Hz, hertz.

FIGURE 1 (Continues…): Mean distortion product otoacoustic emission absolute levels per intensity and frequency ratio combinations for each frequency (f2): (a) right ear at 2003 Hz, (b) left ear at 2003 Hz, (c) right ear at 2519 Hz, (d) left ear at 2519 Hz, (e) right ear at 3175 Hz, (f) left ear at 3175 Hz, (g) right ear at 3996 Hz, (h) left ear at 3996 Hz, (i) right ear 5000 Hz, (j) left ear at 5000 Hz, (k) right ear at 6996 Hz, (l) left ear at 6996 Hz, (m) right ear at 8003Hz and (n) left ear at 8003Hz. Hz, hertz.

Table 1 shows the results of the linear mixed model analyses for main effects of level (L1/L2 in dB SPL) and frequency (f2/f1) settings. For all f2 values and in both ears, these analyses showed that the 65/55 and 65/65 level settings consistently resulted in higher DPOAE levels across all f2/f1 settings, and the 1.18, 1.20 and 1.22 f2/f1 settings regularly resulted in higher DPOAE levels across all L1/L2 settings.

TABLE 1: Results of the mixed model analyses for main effects (p < 0.05) of level (L1/L2 in dB SPL) and frequency (f2/f1) settings.

Table 2 shows the results of the mixed model analyses of all level and frequency settings combined. For all f2 values and in both ears, these analyses showed that the level (dB SPL) and frequency ratio settings of 65/65 and 1.20, 65/55 and 1.22, 65/55 and 1.20, and 65/55 and 1.18 regularly resulted in higher DPOAE levels compared to other level and frequency ratio combinations.

TABLE 2: Results of the mixed model analyses of all level and frequency settings combined.

The results of the ICC analysis of DPOAE results obtained for each f2 value, for right and left ears, and for every L1/L2 (dB SPL) and f2/f1 stimulus combination are not shown in this article (because of the very high number of these analyses conducted). Instead, Table 3 shows for each f2 value, for right and left ears, the lowest and highest ICC absolute agreement (single) coefficients with their 95% confidence intervals from all L1/L2 and f2/f1 stimulus combinations returning significant (p < 0.05) ICC values. Table 3 also shows for each f2 value, for right and left ears, the L1/L2 (dB SPL) and f2/f1 stimulus combinations that returned insignificant ICC values. No obvious patterns emerged regarding L1/L2 (dB SPL) and f2/f1 stimulus combinations that were more or less likely to return better or worse ICC results for each f2. It was noted, however, that more L1/L2 (dB SPL) and f2/f1 stimulus combinations returned insignificant ICC values for f2 = 8003 Hz, meaning that results at this frequency were more likely to be unreliable, regardless of the L1/L2 (dB SPL) and f2/f1 stimulus combinations used.

TABLE 3: Results of the intraclass correlation coefficient absolute agreement (single) analyses of distortion product otoacoustic emissions results obtained at each f2 value for each stimulus level (L1/L2 in dB SPL) and frequency (f2/f1) setting.

Discussion

Overall, the L1/L2 combinations and f2/f1 ratios used in this study elicited DPOAEs of varying amplitude and reliability. An L1/L2 combination of 65/55 dB SPL appeared to elicit the largest DPOAEs at most f2 values, followed by an L1/L2 combination of 65/65. This finding supports similar findings regarding the L1/L2 combinations more likely to elicit larger DPOAEs from human adults (Beattie & Jones, 1998; Vento, Durrant, Sabo, & Boston, 2004). Direct comparisons between this study’s findings and similar studies in the literature were difficult, however, with many studies in the literature having used higher L1/L2 levels than this study (Beattie, Kenworthy, & Neal-Johnson, 2004; Hauser & Probst, 1991; Meinke et al., 2013; Whitehead, McCoy, Lonsbury-Martin, & Martin, 1995). These higher L1/L2 levels were avoided in this study because of their higher likelihood of eliciting false-negative results and artefacts (Dhar & Hall, 2012).

The f2/f1 ratios of 1.18, 1.20 and 1.22 appeared to elicit the largest DPOAEs at most f2 values. This finding supports similar findings regarding the f2/f1 ratios that are more likely to elicit larger DPOAEs from human adults (Abdala, 1996; Dreisbach & Siegel, 2001; Gaskill & Brown, 1990) as well as supporting previous reports that the best f2/f1 ratio appears to decrease as f2 increases and vice versa (Abdala, 1996; Dreisbach & Siegel, 2001).

Stimulus parameters using an L1/L2 of 65/65 with an f2/f1 ratio of 1.20 or an L1/L2 of 65/55 with f2/f1 ratios of 1.18, 1.20 or 1.22 appeared to elicit the largest DPOAEs at most f2 values. This result supports similar findings regarding the L1/L2 and f2/f1 ratio parameter settings that are more likely to elicit larger DPOAEs from human adults (Beattie & Jones, 1998; Vento et al., 2004).

This study’s results do not explain why the largest DPOAEs were elicited using stimulus parameters using L1/L2 combinations of 65/65 dB SPL or 65/55 dB SPL and f2/f1 ratios of 1.18, 1.20 or 1.22. Regarding L1/L2 combinations, the larger DPOAEs elicited by stimuli with primaries of 65 (i.e. the 65/65 dB SPL and 65/55 dB SPL level stimuli) could be related to the function of the cochlear amplifier (Harris et al., 1989) as stimuli, with lower level primaries (L1/L2 levels of 60/53 dB SPL, 60/45 dB SPL and 55/40 dB SPL) yielding lower level DPOAEs. Such a possibility would be generally consistent with Brown and Gaskill (1990) who reported DPOAE amplitude to depend more on the level of L1 than L2. Regarding f2/f1 ratios, the larger DPOAEs elicited by f2/f1 ratios of 1.18, 1.20 or 1.22 could reflect the cochlea’s frequency selectivity and bandpass filter function or properties (Allen & Fahey, 1993). Such a possibility would be generally consistent with Gaskill and Brown (1990) and Harris et al. (1989) who found that DPOAE levels peaked at f2/f1 ratios of 1.22 and 1.25, respectively, with a decline with higher or lower f2/f1 ratios. Stover, Neely, and Gorga (1999) suggested that these declines at higher f2/f1 ratios could result from greater separation of the primaries that lessen the interaction of their travelling waves on the basilar membrane, whereas the declines at lower f2/f1 ratios could result from less separation of the primaries and greater cancellation of their travelling waves on the basilar membrane.

Although some L1/L2 combinations and f2/f1 ratios clearly elicited larger DPOAEs, no L1/L2 combinations and f2/f1 ratios clearly elicited more reliable DPOAEs. This was consistent with previous reports that commonly used sets of stimulus parameters to elicit DPOAEs of similarly varying reliability (Stuart, Passmore, Culbertson, & Jones, 2009; Wagner, Heppelmann, Vonthein, & Zenner, 2008) but inconsistent with reports finding higher L1/L2 combinations to elicit more reliable DPOAEs (Franklin, McCoy, Martin, & Lonsbury-Martin, 1992; Keppler et al., 2010; Roede, Harris, Probst, & Xu, 1993). It must be noted that DPOAEs for f2 = 8003 Hz in this study were most likely to be unreliable. This finding could indicate that any DPOAE recorded at such high f2 frequencies is likely to be unreliable; however, such a conclusion should be interpreted with caution as varying the location of the probe microphone has been shown to affect the calibration of the sound source at these frequencies (Siegel, 2002).

Conclusion

The study concluded that further, targeted investigation of the 65/65 dB SPL, 65/55 dB SPL and 60/53 dB SPL intensity levels and the 1.18, 1.20, 1.22 f2/f1 ratios is warranted to determine the best stimulus parameters for eliciting the largest and most reliable DPOAEs in adult humans. In addition, these stimulus parameters should be investigated in individuals with hearing loss of cochlear origin to select the parameters most sensitive to cochlear damage.

Acknowledgements

This research was funded in part by the National Research Foundation Thuthuka grant TTK14052267763.

Competing interests

The authors declare that they have no financial or personal relationships that may have inappropriately influenced them in writing this article.

Authors’ contributions

L.P. was the project leader, conducted the research, analysed the data and wrote the manuscript. W.J.W. assisted with conceptualising and writing the manuscript, as well as data analysis. H. K. assisted with conceptualising and writing the manuscript.

References

Abdala, C. (1996). Distortion product otoacoustic emission (2f1–2f2) amplitude as a function of f2/f1 frequency ratio and primary tone level separation in human adults and neonates. The Journal of the Acoustical Society of America, 100(6), 3726–3740. https://doi.org/10.1121/1.417234

Allen, J., & Fahey, P. (1993). A second cochlear-frequency map that correlates distortion product and neural tuning measurements. The Journal of the Acoustical Society of America, 94(2), 809–816. https://doi.org/10.1121/1.408182

Beattie, R. C., & Jones, R. L. (1998). Effects of relative levels of the primary tones on distortion product otoacoustic emissions in normal-hearing subjects. Audiology, 37(4), 187–197. https://doi.org/10.3109/00206099809072973

Beattie, R. C., Kenworthy, O., & Neal-Johnson, C. M. (2004). Distortion product otoacoustic emissions: Input-output functions for primary-tone pairs at 1000, 2000 and 4000 Hz in normal-hearing females. The Australian and New Zealand Journal of Audiology, 26(2), 116. https://doi.org/10.1375/audi.26.2.116.58273

Brown, A. M., & Gaskill, S. A. (1990). Measurement of acoustic distortion reveals underlying similarities between human and rodent mechanical responses. The Journal of the Acoustical Society of America, 88(2), 840–849. https://doi.org/10.1121/1.399733

Clark, J. G. (1981). Uses and abuses of hearing loss classification. Asha, 23(7), 493–500.

Dhar, S., & Hall, J. W. (2012). Otoacoustic emissions: Principles, procedures and protocols. San Diego, CA: Plural Publishing.

Dille, M. F., McMillan, G. P., Reavis, K. M., Jacobs, P., Fausti, S. A., & Konrad-Martin, D. (2010). Ototoxicity risk assessment combining distortion product otoacoustic emissions with a cisplatin dose model. The Journal of the Acoustical Society of America, 128(3), 1163–1174. https://doi.org/10.1121/1.3473693

Dreisbach, L. E., & Siegel, J. H. (2001). Distortion-product otoacoustic emissions measured at high frequencies in humans. The Journal of the Acoustical Society of America, 110(5), 2456–2469. https://doi.org/10.1121/1.1406497

Franklin, D. J., McCoy, M. J., Martin, G. K., & Lonsbury-Martin, B. L. (1992). Test/retest reliability of distortion-product and transiently evoked otoacoustic emissions. Ear and hearing, 13(6), 417–429. https://doi.org/10.1097/00003446-199212000-00008

Gaskill, S. A., & Brown, A. M. (1990). The behavior of the acoustic distortion product, 2f1-f2, from the human ear and its relation to auditory sensitivity. Journal of the Acoustical Society of America, 88(2), 821–839. https://doi.org/10.1121/1.399732

Grason-Stadler, G. (2001). TympStar Version 2 Middle-Ear Analyzer Reference Instruction Manual 2000–0120. Eden Prairie, MN: In: Ver.

Hall, J. W. (2000). Handbook of otoacoustic emissions. San Diego, CA: Cengage Learning.

Harris, F. P., Lonsbury-Martin, B. L., Stagner, B. B., Coats, A. C., & Martin, G. K. (1989). Acoustic distortion products in humans: Systematic changes in amplitude as a function of f2/f1 ratio. Journal of the Acoustical Society of America, 85(1), 220–229. https://doi.org/10.1121/1.397728

Hauser, R., & Probst, R. (1991). The influence of systematic primary-tone level variation L 2− L 1 on the acoustic distortion product emission 2 f 1− f 2 in normal human ears. The Journal of the Acoustical Society of America, 89(1), 280–286. https://doi.org/10.1121/1.400511

Hood, L. J., & Berlin, C. I. (2002). Clinical applications of otoacoustic emissions. In C. I. Berlin, L. J. Hood, & A. Ricci (Eds.), Hair cell micromechanics and otoacoustic emissions (pp. 121–137). New York, NY: Thomson Delmar Learning.

Keppler, H., Dhooge, I., Maes, L., D’Haenens, W., Bockstael, A., Philips, B., … Vinck, B. (2010). Transient-evoked and distortion product otoacoustic emissions: A short-term test-retest reliability study. International Journal of Audiology, 49(2), 99–109. https://doi.org/10.3109/14992020903300431

Meinke, D. K., Clavier, O. H., Norris, J., Kline-Schoder, R., Allen, L., & Buckey, J. C. (2013). Distortion product otoacoustic emission level maps from normal and noise-damaged cochleae. Noise and Health, 15(66), 315. https://doi.org/10.4103/1463-1741.116575

Petersen, L., Wilson, W. J., & Kathard, H. (2017). A systematic review of stimulus parameters for eliciting distortion product otoacoustic emissions from adult humans. International Journal of Audiology, 56(6), 1–10. https://doi.org/10.1080/14992027.2017.1290282

Prieve, B., & Fitzgerald, T. (2015). Otoacoustic emissions. In J. Katz, M. Chasin, K. English, L. J. Hood, & K. Tillery (Eds.), Handbook of clinical audiology (7th edn., pp. 357–379). Philadelphia, PA: Wolters Kluwer Health.

Puddy, R. W., & Wilkins, N. (2011). Understanding Evidence Part 1: Best Available Research Evidence. A guide to the continuum of evidence of effectiveness, Atlanta, GA. Retrieved from.

Roede, J., Harris, F. P., Probst, R., & Xu, L. (1993). Repeatability of distortion product otoacoustic emissions in humans. Audiology, 32, 273–281. https://doi.org/10.3109/00206099309072943

SANS. (2006). The measurement and assessment of acoustic environments for audiometric tests. In (Vol. 10182:2006 Edition 2.2). Pretoria: SABS.

Schmidt, N., & Brown, J. (2015). Evidence-Based practice for nurses: Appraisal and application of research (3rd edn.). Burlington: Jones & Bartlett Learning.

Siegel, J. H. (2002). Calibrating otoacoustic emission probes. In M. S. Robinette & T. J. Glattke (Eds.), Otoacoustic emissions: Clinical applications (2nd edn., pp. 416–441). New York: Thieme.

Stover, L. J., Neely, S. T., & Gorga, M. P. (1999). Cochlear generation of intermodulation distortion revealed by DPOAE frequency functions in normal and impaired ears. The Journal of Acoustical Society of America, 106(5), 2669–2678. https://doi.org/10.1121/1.428097

Stuart, A., Passmore, A. L., Culbertson, D. S., & Jones, S. M. (2009). Test-retest reliability of low-level evoked distortion product otoacoustic emissions. Journal of Speech, Language, and Hearing Research: JSLHR, 52(3), 671–681. https://doi.org/10.1044/1092-4388(2008/08-0118)

Vento, B. A., Durrant, J. D., Sabo, D. L., & Boston, J. R. (2004). Development of f2/f1 ratio functions in humans. The Journal of the Acoustical Society of America, 115(5 Pt 1), 2138–2147. https://doi.org/10.1121/1.1675819

Wagner, W., Heppelmann, G., Vonthein, R., & Zenner, H. P. (2008). Test-retest repeatability of distortion product otoacoustic emissions. Ear and Hearing, 29(3), 378–391. https://doi.org/10.1097/AUD.0b013e31816906e7

Whitehead, M., McCoy, M., Lonsbury-Martin, B., & Martin, G. (1995). Dependence of distortion-product otoacoustic emissions on primary levels in normal and impaired ears. I. Effects of decreasing L 2 below L 1. The Journal of the Acoustical Society of America, 97(4), 2346–2358. https://doi.org/10.1121/1.411959