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ENGLISH for ENGINEERS This is an example of a clinical proposal written by an MSc student. The student was given the following scenario: You are based in an Audiology department that carries out standard hearing tests including pure tone audiometry, speech audiometry in quiet and speech audiometry in noise. The department has standard audiometric equipment, including audiometers with CD players for speech audiometry. Your head of department has heard that measurement of frequency resolution may be a useful additional test and has asked you to research the issue and make a proposal to the department for a test that must be completed in a maximum of 30 minutes for both ears. Executive summary 1. Frequency resolution ability is the capability of the ear to discriminate a tone at one frequency from a tone, or sound, at a different frequency. It is important for speech discrimination in noise. 2. Frequency resolution ability can be derived from the psychophysical tuning curve (PTC). 3. This proposal describes a clinical test which uses a masking method, based on Lutman and Wood (1985), for measuring one PTC in both ears within 30 minutes. Characteristic parameters of the PTC are identified. However, there is no reference data available to relate these parameters directly to a subjects’ frequency resolution ability. This data has to (and can) be derived before the test can be employed reliably in the clinic. 4. The test can be performed with the existing audiometric equipment in the department. 5. The test should be used for subjects with hearing aids, or subjects with normal hearing, who complain about problems with speech discrimination in noise. 6. Knowledge about a subjects’ frequency resolution might be useful in the clinic for counselling but there is no consensus about its usefulness in fitting hearing aids. 7. Taking into account the previous point and the absence of reference data, it is advisable to start with a pilot study in order to get a better feeling if PTCs, and consequently a clinical test for frequency resolution, is useful. 1. Introduction 1.1 Frequency resolution and the auditory filter Frequency resolution ability can be interpreted as the filtering capability of the auditory system and is important for speech recognition. For example a reduction in this (spectral) ability makes it difficult to distinguish speech elements like formants in vowels. It can be studied by the shape of the underlying filter – called the auditory filter – that is centred at the frequency component of interest. Different methods can be used to estimate the shape of this filter. In general these methods use a pure tone signal (mostly just above hearing threshold) and they are based on the assumption that a subject can detect the tone if the signal-to-noise ratio (SNR) within the auditory filter, exceeds a critical threshold. The reduction of the SNR is the reason that problems arise in a noisy environment. Noise can be interpreted as all sounds different from the signal pure tone. Most methods use the principle of changing the level and/or frequency content of the noise in order to obtain the shape of the filter. The noise added on purpose in the method is called ‘the masker’ and the differences between methods are mainly related to the maskers applied. The auditory filter is nonlinear and its shape depends on the method and signal level used, e.g. the filter broadens with increasing signal level (Moore, 2012; p. 78). A psychophysical (or psychoacoustical) tuning curve (PTC) is closely related to the auditory filter1 and it shows the frequency sensitivity of the ear as a function of frequency for a pure tone of a chosen frequency, see Figure 1. Two characteristics of the PTC are very important for frequency resolution: 1. The location of the dip of the V-shaped curve on the frequency axis. This is the most sensitive frequency and it will be called the characteristic frequency (CF). This frequency should correspond to the signal frequency SF. If this is not the case the subject has no access to the auditory filter tuned to the signal frequency and he uses the auditory filter tuned to CF. This phenomenon is called ‘off-frequency listing’ and it is an indication for a cochlear dead region (e.g. Dillon, 2012; p. 298). Frequency resolution around the signal frequency will be poor because the subject cannot distinguish between the frequencies SF and CF. The difference DF = SF – CF is an appropriate parameter to describe the correctness of the peak location. Its value should be low for good frequency resolution. 2. The sharpness of the curve. This can be expressed with the so-called Q10dB factor (Q for quality; Moore, 2012, p. 28) which corresponds to a relative bandwidth and is calculated as the bandwidth 10 dB above the threshold at the tip, divided by the frequency at the tip (CF). A sharp curve (high Q10dB) indicates a good frequency resolution because the system can distinguish between a tone at SF and a tone with a slightly different frequency. A broad PTC will give a low Q10dB and it indicates poor frequency resolution. 1.2 Importance of measuring frequency resolution in the clinic Knowledge about frequency resolution of a subject might be useful in clinic for: 1. A better understanding of speech recognition difficulties of the subject in noise, which is important for counselling. For example subjects with an early sensorineural (noiseinduced) hearing loss might complain but their PTA shows no, or only a small, increase in pure tone thresholds (for references see Larsby and Arlinger, 1998). 2. Detection of the presence of a cochlear dead region (side effect). Although other tests (such as TEN-HL, see Moore et al., 2004) are faster and specially developed for this 1 A PTC shows a level in dB SPL (so a reference level) and not a gain in dB as is usual for a filter. purpose, they are not routinely done in the clinic. The proposed test can show the necessity to investigate (the extent of) the cochlear dead region with different tests. There is no consensus in the literature about its usefulness in fitting hearing aids (Dillon, 2012; p. 301, Summers, 2004). A subject with serious loss of frequency resolution (broad PTC), will still have difficulties with frequency resolution because the aid cannot change the shape of the PTC (without introducing distortion for other auditory filters). 2. Method 2.1 Motivation of the method proposed The filter shape, and in particular its bandwidth, is studied in several methods (Moore, 2012; chapter 3). Most methods need some special equipment or do not give a complete PTC which is needed to calculate DF and Q10dB. For example in methods based on broadband noise with a spectral notch at SF (e.g. see Larsby and Arlinger, 1998) the width of the notch is varied. Another disadvantage of using broadband noise is the need for high masker levels for hearing impaired subject which can be uncomfortable. Fast methods (5-7 minutes) for obtaining a PTC have been brought under attention again (e.g. Malika et al. 2009). They use an automatically sweeping masker across the frequency axis and a Békésky threshold tracking scheme. However, this appealing method needs a PC with sound card and special software. An improved method to measure frequency resolution is proposed that is an extension of the method of Lutman and Wood (1985), and does not need investment in new equipment. It consists of measuring the relevant part of a PTC with a (standard) masking narrowband noise centred at different frequencies. Lutman and Wood (1985) calculated a measure for sharpness of the PTC at the signal frequency by considering three points on the PTC (one at the signal frequency, one at higher frequency FMAX and one at lower frequency FMIN). However, with three points the frequency shift DF cannot be calculated and Q10dB seems to be a more general measure than their measure for defining the sharpness of a filter. For these reasons we propose to measure more points on the PTC such that DF and Q10dB can be calculated. Only one PTC for each ear at SF = 2000 Hz (i.e. centre of speech relevant frequencies) is calculated in order to limit the time of testing. 2.2 Stimuli The signal tone used in the test is a pulsed pure tone of 2000 Hz at 10 dB SL (duration 170 ms, rise/fall 50 ms). Pulsation is used to make the task less difficult for the subject, see Lutman and Wood (1985). The maskers used in the test are narrowband noise centred at seven different frequencies ranging from FMIN = 1250 Hz to FMAX = 2500 Hz, including the signal frequency SF = 2000 Hz. The other frequencies are logarithmically equally spaced between these frequencies, see Figure 1. The design of the narrowband noise masker and the extreme frequencies (FMIN and FMAX) are taken from Lutman and Wood (1985) such that the masker level would not be undesirable loud. 2.3 Procedure The test consists of two stages: (1) measuring a PTC in each ear and (2) processing the results in the computer to calculate the parameters DF and Q10dB2. The procedure and instructions to measure the PTC (in each ear) are similar to these for measuring thresholds with PTA (see British Society of Audiology, 2011). The main points are: 1. The audiometric data (PTA) is assumed to be available, including the 2000 Hz AC. 2. The threshold for the pulsed signal tone (no noise masker) is measured using the standard protocol (5 dB steps up/10 dB steps down): starting at the level found in (1). 3. The modulated signal is set at 10 dB above the level found in (2), which equals 10 dB SL. 4. The order of the 7 frequencies (1250 Hz,... , 2500 Hz ) is chosen at random. 5. The level of masking required to just mask the signal tone (both channels to the same ear!) is measured for each frequencies in (4) with an inverse protocol (10 dB steps up/5 dB steps down) because the masker level, and not the signal level, is changed during the procedure (Lutman and Wood, 1985); start level as (2). The patient should be instructed to “ignore the noise and listen for the tone, and always indicate if the noise is too loud”. The time needed for the test is 30 minutes: 25 minutes for the (2 + 2x7 = 16) measurements3 5 minutes for putting the results in the computer and the interpretation. 2.4 Equipment The test proposed can be performed with the existing audiometric equipment in the department. Insert earphones are used to minimize the risk of cross-hearing. The test uses: 1. The audiometer with CD-player. Signal tone on channel 1 (derived from main oscillator within audiometer, see Lutman and Wood, 1985) and the CD containing the masker signals to channel 2. The CD has to be purchased or it can be produced in the clinic4. 2 The definition of both parameters is given in Section 1.1. The script to fit a curve to the data points from which the parameters can be calculated automatically is beyond the scope of this proposal. 3 Lutman and Wood (1985) made 2 + 2x3 = 8 measurements in 10-15 minutes. 2. The laptop/PC in the clinic to calculate the parameters (with e.g. an Excel-script). Calibration and daily checks conform an audiometer, see British Society of Audiology (2011). 2.1 Subjects The test is appropriate for two groups of subjects who complain about problems with speech discrimination in noise5: (1) subject without a hearing loss (see example in Section 1.2 for explanation), and (2) subjects with a hearing aid, when using their hearing aid. 3. Results 3.1 Reference data The author has not found reference data concerning the proposed measures (DF and Q10dB) in the literature. Lutman and Wood (1985) have derived a nominal value for the sharpness of the PTC for normal hearing people but their measure is different from Q10dB. Reference data has to be collected before the test can be used in the clinic. The reference data consists of the minimal and maximal values of the parameters DF and Q10dB for people without speech recognition problems in noise. These values vary probably with hearing loss because the PTC will be broader with signal level (see Section 1.1). Consequently PTCs have to be measured for each degree of hearing loss, for example with 6 groups; normal hearing to severe hearing loss according to the standard categories (British Society of Audiology, 2011). This has to be done for subjects with and without speech recognition problems in noise. If each subgroup consists of 10 subjects, this means a total of 2 x 6 x 10 = 120 subjects. 3.2 Action to be taken with results obtained from the test All parameters as measured for the subject are compared with the reference values (thresholds) for their degree of hearing loss, see Figure 2. This has to be done for both ears. Note: the results of the test are only valid for the best ear if there is a risk of cross-hearing (this can be deduced from the subjects’ PTA)6. This should be mentioned in the test results. 4 It would be interesting to know if the test can be done with the default maskers on the audiometer. 5 It would be desirable to use a measure to describe the extent of the problem. This could be coming from a general questionnaire or a speech recognition test. 6 An additional audiometer might be used to mask the non-test ear (as in PTA). 4. Discussion and conclusion This proposal is about testing the subjects’ frequency selectivity ability by using PTCs. The test proposed is easy to implement because it does not need investment in additional equipment and the procedure is similar to PTA such that no training is required. However, the proposed test lacks reference (or normative) data and a serious amount of time is needed to get this data. Consequently, a test for measuring frequency resolution ability is at the moment more in a research stage than in a clinical applicable stage. However, it would be worth the effort to start a small pilot study in order to get a better insight if PTCs are useful in the clinic (Section 1.2) and if the proposed parameters to describe the PTC (Section 1.1) correlated with the speech recognition problem in a noisy environment, as experienced by the subjects. 5. References British Society of Audiology (2011) Recommended Procedure. Pure-tone air-conduction and bone-conduction threshold audiometry with and without masking. BSA, Reading. Dillon, H. (2012) Hearing Aids.2nd edition, Thieme, Stuttgart. Larsby, B. and Arlinger, S. (1998) A method for evaluating temporal, spectral and combined temporal-spectral resolution of hearing. Scandinavian Audiology, 27, 3-27. Lutman, M.E. and Wood, E.J. (1985) A simple clinical measure of frequency resolution. British Journal of Audiology, 19, 1-8. Malika, A.N., Munro, K.J. and Baker, R.J. (2009) Fast method for psychophysical tuning curve measurement in school-age children. Int. Journal of Audiology, 48, 546-553. Moore, B.J.C. (2012) An Introduction to the Psychiology of Hearing. 6th edition, Emarald, Bingley. Moore, B.C.J., Glasberg, B.R. and Stone, M.A. (2004) New version of the TEN test with calibrations in dB HL. Ear & Hearing, 25, 478-487. Summers, V. (2004) Do tests for cochlear dead regions provide important information for fitting hearing aids? (L) Journal of the Acoustical Society of America, 115, 1420-1423. Figure 1. Examples of PTCs measured with a narrowband noise masker centred at 7 different frequencies (circles) for a pure tone signal of SF = 2000 Hz at 10 dB SL (red star). (A) Typical PTC for a normal hearing subject. Red arrow illustrates the measure of sharpness Q10dB. (B) Typical PTC for a subject using ‘off-frequency listening’. Red arrow illustrates the measure of frequency shift DF. Figure 2. Flow chart for each ear with the test results (parameters DF and Q10dB). Values for threshold1,2,3 depend on hearing loss and have to be deduced from reference data (to be determined).