Christian Füllgrabe1,2, Brian C J Moore3. 1. 1 Medical Research Council Institute of Hearing Research, School of Medicine, University of Nottingham, UK. 2. 2 Hearing Sciences, Division of Clinical Neurosciences, School of Medicine, University of Nottingham, UK. 3. 3 Department of Psychology, University of Cambridge, UK.
Abstract
The ability to process binaural temporal fine structure (TFS) information, which influences the perception of speech in spatially distributed soundscapes, declines with increasing hearing loss and age. Because of the relatively small sample sizes used in previous studies, and the population-unrepresentative distribution of hearing loss and ages within study samples, it has been difficult to determine the relative and combined contributions of hearing loss and age. The aim of this study was to survey published and unpublished studies that assessed binaural TFS sensitivity using the TFS-low frequency (LF) test. Results from 19 studies were collated, yielding sample sizes of 147 to 648, depending on the test frequency. At least for the test frequency of 500 Hz, there were at least 67 listeners in each of four adult age groups and the distribution of audiometric thresholds at the test frequency within each group was similar to that for the population as a whole. Binaural TFS sensitivity declined with increasing age across the adult lifespan and with increasing hearing loss in old adulthood. For all test frequencies, both audiometric threshold and age were significantly negatively correlated with TFS-LF sensitivity ( r ranging from -0.19 to -0.64) but the correlation was always significantly higher for age than for audiometric threshold. Regression analyses showed that the standardized regression coefficient was greater for age than for audiometric threshold, and that there was a significant interaction; the effect of increasing age among older listeners was greater when the hearing loss was ≥30 dB than when it was < 30 dB.
The ability to process binaural temporal fine structure (TFS) information, which influences the perception of speech in spatially distributed soundscapes, declines with increasing hearing loss and age. Because of the relatively small sample sizes used in previous studies, and the population-unrepresentative distribution of hearing loss and ages within study samples, it has been difficult to determine the relative and combined contributions of hearing loss and age. The aim of this study was to survey published and unpublished studies that assessed binaural TFS sensitivity using the TFS-low frequency (LF) test. Results from 19 studies were collated, yielding sample sizes of 147 to 648, depending on the test frequency. At least for the test frequency of 500 Hz, there were at least 67 listeners in each of four adult age groups and the distribution of audiometric thresholds at the test frequency within each group was similar to that for the population as a whole. Binaural TFS sensitivity declined with increasing age across the adult lifespan and with increasing hearing loss in old adulthood. For all test frequencies, both audiometric threshold and age were significantly negatively correlated with TFS-LF sensitivity ( r ranging from -0.19 to -0.64) but the correlation was always significantly higher for age than for audiometric threshold. Regression analyses showed that the standardized regression coefficient was greater for age than for audiometric threshold, and that there was a significant interaction; the effect of increasing age among older listeners was greater when the hearing loss was ≥30 dB than when it was < 30 dB.
Changes in the temporal fine structure (TFS) of sounds at each ear and across the two
ears are used for the perceptual analysis of complex auditory scenes and for sound
localization (Moore,
2014). One example is speech perception in the presence of interfering
background sounds, which has been shown to be associated with sensitivity to TFS
(e.g., Füllgrabe, Moore, &
Stone, 2015; Lopez-Poveda et al., 2017; Neher, Lunner, Hopkins, & Moore, 2012;
Oberfeld &
Klöckner-Nowotny, 2016; Strelcyk & Dau, 2009), although it is
difficult to prove that the relationship is causal. There is increasing
psychoacoustical evidence that TFS sensitivity tends to decline with increasing
hearing loss (e.g., Füllgrabe
& Moore, 2017; Gallun et al., 2014; Hopkins & Moore, 2011; King, Hopkins, & Plack, 2014; Pichora-Fuller & Schneider,
1992) and with increasing age (e.g., Füllgrabe, 2013; Füllgrabe et al., 2015; Füllgrabe, Sęk,
& Moore, 2018; Grose &
Mamo, 2010; Hopkins
& Moore, 2011; King et al., 2014; Moore, Glasberg, Stoev, Füllgrabe, & Hopkins, 2012; Moore, Vickers, & Mehta,
2012; Ross, Fujioka,
Tremblay, & Picton, 2007), even when the effect of the other variable
is statistically or experimentally controlled. However, the relative influence of
hearing loss and age on binaural sensitivity to TFS remains unclear. Hopkins and Moore (2011)
found a significant group difference in binaural TFS sensitivity between young
normal-hearing and older normal-hearing listeners but the difference between the
latter group and older hearing-impaired listeners was not significant. Also,
binaural TFS sensitivity has been found to be more highly correlated with age than
with the audiometric threshold at the test frequency for listeners with normal or
near-normal hearing (Füllgrabe,
2013; Füllgrabe
et al., 2015; Füllgrabe et al., 2018; Moore, Glasberg, et al., 2012). Despite the
fact that no statistical comparison of the correlation coefficients was conducted in
those studies, it has been speculated that aging might have a stronger deleterious
effect than hearing loss on binaural TFS sensitivity (Füllgrabe & Moore, 2017; Moore, 2016).The results of King et al.
(2014) do not support this speculation. They tested 46 listeners with a
wide range of ages (20 to 83 years) and hearing thresholds (∼2 to 69 dB hearing
level [HL]) and reported significant moderate correlations of similar size between
thresholds for discriminating an interaural phase difference (IPD) and audiometric
thresholds at the test frequency of 500 Hz (r = 0.42) and between
IPD thresholds and age (r = 0.45). However, their sample of
listeners was characterized by a similar incidence of hearing impairment
(audiometric thresholds exceeding 20 dB HL) for the young (< 40 years; incidence:
37%) and older (> 60 years; incidence: 44%) listeners, and a weak nonsignificant
correlation (r = 0.08) between age and the absolute threshold at
low frequencies. These sample characteristics resulted from an explicit effort to
recruit young listeners with sensorineural hearing loss (A. King, personal
communication, February 15, 2018). While this allowed the authors to provide
experimental evidence that both hearing loss and age affect binaural TFS
sensitivity, it made it impossible to study the relative effects and interaction of
hearing loss and age that would be expected across the adult lifespan in the general
population. Indeed, low-frequency hearing loss is rather rare in the younger general
population. For example, in the United Kingdom (UK), 90% of people aged 18 to 30
years have low-frequency audiometric thresholds (averaged over 250, 500, and
1000 Hz) better (i.e., lower) than 20 dB HL (Davis, 1995).Clearly, the relative effects of hearing loss and age on TFS sensitivity measured in
a given study will depend on the ranges of audiometric thresholds and ages in the
study sample. In turn, these ranges might not be representative of the population as
a whole. Only a study of TFS sensitivity for a large sample of the general
population, in which hearing loss and age covary in a representative manner, can
establish the independent and combined contribution of these variables throughout
the lifespan. As such information is currently not available, and large-scale
studies are costly and time-consuming, the aim of this study was to collate existing
data from studies using listener samples with various audiometric and age
distributions, in order to obtain a picture of the changes in binaural TFS
sensitivity across the lifespan that is more representative than that which can be
gleaned from individual published studies.Binaural TFS sensitivity has been studied using a variety of behavioral tasks, such
as the binaural masking level difference (BMLD; e.g., Neher, 2017; Pichora-Fuller & Schneider, 1991; Santurette & Dau, 2012;
Strelcyk & Dau,
2009), interaural time difference (ITD) discrimination (e.g., Füllgrabe & Moore, 2014;
Strouse, Ashmead, Ohde,
& Grantham, 1998), and IPD discrimination (e.g., Füllgrabe, Harland, Sęk, &
Moore, 2017; Ross
et al., 2007; Strelcyk & Dau, 2009). One test that has been used in several recent
studies is the TFS-LF test developed by Hopkins and Moore (2010) and implemented by
Sęk and Moore (2012).
Unlike some tests that have been described in the literature, such as BMLDs (Hafter & Carrier, 1970)
or ITD discrimination tasks that require the listener to indicate whether a sound
moved to the left or the right (Wright & Fitzgerald, 2001), practice effects for the TFS-LF test are
small or absent (Hopkins &
Moore, 2010), so there is no need for a protracted familiarization period
prior to data collection. This might explain why this test has been frequently used
since its publication, including in two large-scale studies (with
N > 100; Füllgrabe, 2013; Rönnberg et al., 2016). Based on the frequency of its use and the
existence of large data sets, it was deemed appropriate to focus on the TFS-LF test
for the meta-analysis described here.
Method
Description of the TFS-LF Test
The TFS-LF test measures thresholds for detecting a change in IPD of bursts of
low-frequency pure tones, presented via headphones. The envelopes of the tones
are synchronous across the two ears, so there is an interaural disparity in the
TFS only. We describe here the “standard” version of the TFS-LF test. Variants
used in some of the studies included in the meta-analysis are described
later.The tones in each ear are presented at 30 dB sensation level (SL). A
two-interval, two-alternative forced-choice task is used, with four successive
tones in each interval (with the tone duration and the interstimulus interval
being at least 400 and 200 ms, respectively). In one interval, selected
randomly, the four tones all have the same IPD of 0°. In the other interval, the
IPD alternates between 0° and ϕ in successive tones. Listeners with normal
hearing and normal sensitivity to binaural TFS perceive pure tones with IPD = 0°
as being close to the center of the head, while tones with a sufficiently large
IPD are perceived as being lateralized toward one ear or the other, or as being
more diffuse. Hence, the listeners are asked to indicate the interval in which
the tones appear to change in some way, for example to move within the head.
Correct-answer feedback is provided after each trial. The initial value of ϕ is
usually set to the maximum value of 180° and ϕ is adaptively varied, using a
two-down, one-up rule to converge at an estimate of the “threshold”
corresponding to 71% correct. The threshold is computed as the geometric mean
value of ϕ at the last six turnpoints.If the adaptive procedure calls for the maximum value of ϕ (180°) twice before
the second turnpoint or at all after the second turnpoint, the adaptive
procedure is terminated and 40 further trials are presented with ϕ set to 180°;
the number of correct responses is recorded to yield a percent-correct
score.
Derivation of a Performance Measure
The adaptive procedure of the TFS-LF test results in a threshold estimate in
degrees, while the constant-stimulus procedure with ϕ set to 180° gives a
percent-correct score. In this study, to compare results from the two
procedures, the percent-correct scores from the constant-stimulus procedure were
converted into values of the detectability index d ′, using the
conversion table of Hacker
and Ratcliff (1979). Thresholds from the adaptive procedure were
converted into values of d ′ that would be obtained for
ϕ = 180°, using the equation: where 0.78 is the d ′ value corresponding to
the 71%-correct point on the psychometric function, the threshold tracked by the
adaptive procedure (for further details, see Hopkins & Moore, 2010). Equation
1 is based on the finding that d ′ is proportional
to ϕ, at least for d ′ values up to about 2 (Hafter & Carrier,
1972). Equation 1 can lead to very
large values of d ′ when the TFS-LF threshold is small. These
high values should not be taken literally; in practice, values of
d ′ greater than about 3 are very hard to measure. The
major advantage of using Equation 1 is that it allows a
meaningful comparison of performance across the adaptive and constant-stimulus
procedures; the larger the value of d ′, the better is
performance.
Selection of Studies for Inclusion
A search of published research papers, based on our knowledge of the literature,
yielded 19 studies that used a version of the TFS-LF test to assess binaural TFS
sensitivity. It was not possible to obtain data for three of these studies.
Informal discussions with colleagues yielded an additional three (as yet)
unpublished data sets (Barry, unpublished; Bramsløw, Eneroth, Lunner, & Schulte,
2012; Rost, Ellermeier, Kattner, & Oberfeld, 2018). Thus, a total
of 19 studies were entered into the meta-analysis and are referenced in Table 1 in
alphabetical order. For studies using distinct samples of listeners (e.g., young
vs. older), each sample is described separately. The age range, the test
frequencies, the range of audiometric thresholds at each test frequency, and the
size of each sample are indicated. In some cases, the latter does not match the
number of listeners in the original data set, as results from listeners with an
interaural difference in audiometric threshold exceeding 15 dB at the test
frequency were not included in the meta-analysis. This was done to follow the
audiometric inclusion criterion of symmetric hearing sensitivity used in most
(but not all) previous studies investigating binaural TFS sensitivity. Neher (2017) reported
that there were no differences in binaural TFS sensitivity between listeners
with symmetric and asymmetric hearing losses at low frequencies. However, his
study assessed BMLDs (and not IPD discrimination) and hence it was deemed
prudent to exclude the few asymmetric cases observed in some data sets from the
meta-analysis.
Table 1.
Listener-Sample Details (Age Range, Audiometric Range, and Number of
Listeners, N) and Test-Tone Frequencies From
Studies Included in the Meta-Analysis.
Study
Age range (years)
Audiometric range (dB HL)
N
Test frequency (Hz)
Barry (unpublished)
6 to 12
−3 to 20
38
500
20 to 38
−5 to 18
25
500
Bramsløw et al. (2012)
24 to 83
25 to 73
22
250
500
750
Füllgrabe (2013)
19 to 90
−8 to 20
112
500
850
Füllgrabe et al. (2015)
18 to 27
−1 to 10
8
500
750
60 to 79
−10 to 11
21
500
750
Füllgrabe and Moore (2017)
63 to 83
3 to 20
12
250
Füllgrabe et al. (2017)
19 to 25
−5 to 8
9
250
500
750
47 to 84
3 to 18
23
750
Hopkins and Moore (2011)
20 to 35
−9 to 8
10
250
500
750
62 to 69
−3 to 11
6
250
500
750
25 to 82
−4 to 55
24
250
500
750
Lőcsei et al. (2016)
20 to 29
−5 to 15
10
250
55 to 84
5 to 28
19
250
Moore, Glasberg, et al. (2012)
61 to 83
1 to 44
39
500
750
Moore et al. (2012)
22 to 61
1 to 23
35
500
850
Moore and Sęk (2016)
56 to 87
13 to 58
22
500
Neher et al. (2012)
28 to 75
22 to 55
17
250
500
750
Oberfeld and Klöckner-Nowotney (2016)a
18 to 30
−4 to 9
50
500
Perez et al. (2014)
54 to 85
13 to 53
51
500
Rönnberg et al. (2016)
27 to 80
0 to 65
196
250
Rost et al. (2018)a
17 to 37
0 to 15
67
500
Sharma et al. (2014)b
11 to 15
5 to 14
15
500
Whitmer and Akeroyd (2013)
23 to 75
−3 to 108
44
500
Whitmer et al. (2014)
26 to 79
−5 to 68
33
500
Audiometric thresholds were assessed using Bekesy tracking and
1/3-octave noise bands.
This study tested normal-hearing children with and without
listening difficulties. Only data from the children with no
listening difficulties were included here. Audiometric
thresholds for individual frequencies were not available, so the
pure-tone average across 500, 1000, and 2000 Hz was used.
Listener-Sample Details (Age Range, Audiometric Range, and Number of
Listeners, N) and Test-Tone Frequencies From
Studies Included in the Meta-Analysis.Audiometric thresholds were assessed using Bekesy tracking and
1/3-octave noise bands.This study tested normal-hearing children with and without
listening difficulties. Only data from the children with no
listening difficulties were included here. Audiometric
thresholds for individual frequencies were not available, so the
pure-tone average across 500, 1000, and 2000 Hz was used.
Characteristics of the Study Samples
Most of the data were for adult listeners, aged between 18 and 90 years; only two
studies investigated children (aged 6 to 15 years; N = 53). For
all samples combined, the audiometric threshold at the test frequency varied
from “normal” to “profoundly impaired” (from −10 to 108 dB HL; British Society of Audiology,
2011). Four tone frequencies were used: 250, 500, 750, and 850 Hz.
The largest data set was for 500-Hz tones (N = 648), followed
by 250-Hz tones (N = 325), 750-Hz tones
(N = 178), and 850-Hz tones (N = 147).To illustrate how the listeners were distributed across ages and audiometric
thresholds, the left-most column of Figure 1 shows the proportion and number
of listeners in each of five age groups (“children”, “young adults”,
“middle-aged adults”, “young-old adults”, and “old-old adults”) for each of the
four test frequencies; the remaining columns show the proportion of listeners in
each of eight audiometric categories (“−10 to 0”, “1 to 10”,…, “> 60”) for
each of the five age groups for the given test frequency. The colored thick
lines indicate proportions of listeners in terms of broader clinically used
hearing-loss categories (“normal hearing”, “mild hearing loss”, and “moderate
hearing loss”), here based on the audiometric ranges specified by the British Society of Audiology
(2011).
Figure 1.
Distribution in terms of proportions (bars) and numbers (colored
numbers) of listeners entered into the meta-analysis. First
column: Based on their age, listeners were categorized
into five age groups: “children” (< 18 years), “young adults” (18
to 39 years), “middle-aged adults” (40 to 59 years), “young-old
adults” (60 to 75 years), and “old-old adults” (> 75 years).
Columns 2 to 6: Based on their audiometric
thresholds at the test frequencies, listeners for each age group
were categorized into eight bins between −10 and > 60 dB HL (see
colored bars) or into the three lowest hearing-loss categories (see
colored horizontal lines), as defined by the British Society of Audiology
(2011): “normal hearing” (−10 to 20 dB HL), “mild hearing
loss” (21 to 40 dB HL), and “moderate hearing loss” (41 to 70 dB
HL). As there were only three cases of hearing losses greater than
70 dB HL, these listeners were included in the “moderate” category.
For comparison, distributions of audiometric thresholds for the
general population are indicated by the thin black horizontal lines
(Davis,
1995). Each row shows results for one of the test
frequencies.
Distribution in terms of proportions (bars) and numbers (colored
numbers) of listeners entered into the meta-analysis. First
column: Based on their age, listeners were categorized
into five age groups: “children” (< 18 years), “young adults” (18
to 39 years), “middle-aged adults” (40 to 59 years), “young-old
adults” (60 to 75 years), and “old-old adults” (> 75 years).
Columns 2 to 6: Based on their audiometric
thresholds at the test frequencies, listeners for each age group
were categorized into eight bins between −10 and > 60 dB HL (see
colored bars) or into the three lowest hearing-loss categories (see
colored horizontal lines), as defined by the British Society of Audiology
(2011): “normal hearing” (−10 to 20 dB HL), “mild hearing
loss” (21 to 40 dB HL), and “moderate hearing loss” (41 to 70 dB
HL). As there were only three cases of hearing losses greater than
70 dB HL, these listeners were included in the “moderate” category.
For comparison, distributions of audiometric thresholds for the
general population are indicated by the thin black horizontal lines
(Davis,
1995). Each row shows results for one of the test
frequencies.Despite our pooling of data across multiple studies from different research
groups, resulting in fairly large data sets, the different age groups were not
uniformly represented, with either the young or the young-old adults always
representing the largest listener group, and these two groups combined
constituting at least 65% of the listeners tested at any given tone frequency.
In a few cases, the sample size was relatively small, below 20 (see middle-aged
listeners at 750 Hz and old-old listeners at 850 Hz). This bias in the age
distribution probably reflects the consequences of the goal of many of the
studies included in the meta-analysis, which was to study age-group differences
in the absence of hearing loss. The bias may also reflect the availability of
research participants (generally sampled from among the student population and
early retirees).For children and young adults, most audiometric thresholds at all test
frequencies fell within the normal range, while, for older adults, they tended
to be more evenly distributed across the three broad hearing-loss categories. An
exception is the distribution of audiometric thresholds at 850 Hz; here, almost
all listeners, independent of age group, had normal hearing. To indicate how
well the distributions of audiometric thresholds are representative of those
found in the general population, data from the population-representative
“National Study of Hearing” (Davis, 1995), based on age groups and audiometric categories roughly
equivalent to those used in here, are plotted in Figure 1 as thick black horizontal lines
for the 250-Hz and 500-Hz test frequencies (no reference data were available for
the two other frequencies). The distributions of audiometric thresholds in our
meta-analysis are not markedly different from those for the UK population,
especially at 500 Hz. However, for the middle-aged group at 250 Hz, the current
data sets have greater proportions of mild and moderate losses than for the
population data.
Methods Used in the Study Sample
Most of the studies included in the meta-analysis conformed to the standard
experimental procedure (such as the use of a two-down, one-up stepping rule,
tracking the 71% correct point) and stimulus parameters (such as the duration of
the stimuli and interstimulus intervals), as described in the original article
describing the TFS-LF test (Hopkins & Moore, 2010), but there were a few exceptions. Perez, McCormack, and Edmonds
(2014) and Rönnberg et al. (2016) used, respectively, a lower (10 dB SL) and
higher (40 dB SL) presentation level than the 30 dB SL recommended by Hopkins and Moore
(2010), who showed that similar results are obtained for SLs between
30 and 50 dB but performance worsens for a lower SL of 20 dB. Hence, the
performance reported by Perez et al. might be worse than that observed in other
studies for listeners with comparable ages and degrees of hearing loss. All
relevant analyses were computed with and without this data set
(N = 51), representing 8% of the data for the 500-Hz test
tones. As the two sets of results were always very similar, only the results for
all data are reported here.Four studies (Oberfeld &
Klöckner-Nowotny, 2016; Rost et al., 2018; Whitmer & Akeroyd, 2013; Whitmer, Seeber, &
Akeroyd, 2014) used a three-down, one-up rule, thereby tracking a
higher performance level (i.e., 79% correct) than for the other studies. As
described in the Derivation of a Performance Measure section,
the raw data produced by the TFS-LF test (thresholds expressed in degrees or
percent-correct scores for the constant-stimulus procedure) were transformed
into values of d ′. The higher d ′ value of
1.14 corresponding to 79% correct was used for the four studies that used the
three-down, one-up rule, thus allowing comparison across data sets obtained
using different stepping rules. For listeners who did not score above chance in
the constant-stimulus procedure, d ′ was set to 0 (this
happened only in 13 cases; Whitmer & Akeroyd, 2013; Whitmer et al., 2014).
Data Analysis
To analyze the data, separate bivariate and partial correlational analyses were
conducted for each test frequency to assess the relationship between
d ′ scores and audiometric thresholds on the one hand and
between d ′ scores and age on the other. As we were testing the
hypotheses that d ′ scores would worsen with increasing hearing
loss and increasing age, one-tailed tests were used to assess the significance
of the correlations. The significance of the differences between pairs of
correlation values was assessed using two-tailed tests. Subsequently,
multiple-regression analyses were run for the different test frequencies to
study the relative contributions of audiometric threshold and age, as well as
their interaction, to binaural TFS sensitivity. Given the limited availability
of TFS-LF data for children and the possibility of developmental changes in
basic auditory processing during childhood (Moore, Cowan, Riley, Edmondson-Jones, &
Ferguson, 2011), it was decided to limit the correlation and
regression analyses to results from adults (≥18 years).
Results
An overview of the results is given in Figure 2. For the single tone frequency for
which data for children were available, all children were able to perform the TFS-LF
test. On average, TFS-LF sensitivity for children (mean d ′
score = 7.5) was lower (worse) than that for young adults (mean d ′
score = 10.2) but on a par with that for middle-aged adults (mean
d ′ score = 7.5). It is noteworthy that the two studies
investigating adjacent age ranges for young listeners gave clearly different
results: while performance for the younger children (N = 38; 6 to
12 years) spanned a wide range (d ′ scores ranged from 1.6 to 28.5,
similar to the range for young adults), d ′ scores for the
relatively small group of older children (N = 15; 11 to 15 years)
consistently fell below 8. It is not clear whether this discrepancy was because of
age differences, a sampling bias, or study differences. For the entire group of
children aged below 18 years, TFS-LF sensitivity was not significantly correlated
with audiometric thresholds (r = −0.04, p = 0.45)
or with age (r = −0.32, p = 0.12).
Figure 2.
Binaural TFS sensitivity measured by the TFS-LF test and expressed as the
sensitivity index d′. Individual data from several
studies (see different symbols in the key at the right) using different
low-frequency pure tones (see rows) are plotted as a function of the
listeners’ audiometric thresholds (left column) and ages (right column).
Vertical dotted lines in the left column show the boundaries of the
hearing-loss catergories proposed by the British Society of Audiology
(2011), while those in the right column show the boundaries
of the five age-group categories. Light-gray and black symbols denote
data from children and adults, respectively. Data points from adult
listeners that fell outside the range of audiometric thresholds
(N = 2) or the range of d′ scores
(N = 5) used in the panels are denoted by symbols
with arrows. The dark-gray-shaded areas and white thick horizontal lines
represent the IQR and median, respectively, for each of the three
audiometric groups and the five age groups. The large open circles,
plotted at the center of the audiometric or age group, represent the
mean. In each panel, the thick colored line is a regression line fitted
to the individual data. The corresponding regression equation and
R2 value are indicated. For the 500-Hz
condition (second row from the top), the thick black line shows the
running average, computed, in the left panel, as the arithmetic mean
over an 11-dB-wide symmetric rectangular window centered on audiometric
thresholds between −5 and 65 dB HL (in 1-dB steps), and, in the right
panel, as the running average over an 11-year-wide symmetric rectangular
window centered on ages between 23 and 85 years (in 1-year steps).
Binaural TFS sensitivity measured by the TFS-LF test and expressed as the
sensitivity index d′. Individual data from several
studies (see different symbols in the key at the right) using different
low-frequency pure tones (see rows) are plotted as a function of the
listeners’ audiometric thresholds (left column) and ages (right column).
Vertical dotted lines in the left column show the boundaries of the
hearing-loss catergories proposed by the British Society of Audiology
(2011), while those in the right column show the boundaries
of the five age-group categories. Light-gray and black symbols denote
data from children and adults, respectively. Data points from adult
listeners that fell outside the range of audiometric thresholds
(N = 2) or the range of d′ scores
(N = 5) used in the panels are denoted by symbols
with arrows. The dark-gray-shaded areas and white thick horizontal lines
represent the IQR and median, respectively, for each of the three
audiometric groups and the five age groups. The large open circles,
plotted at the center of the audiometric or age group, represent the
mean. In each panel, the thick colored line is a regression line fitted
to the individual data. The corresponding regression equation and
R2 value are indicated. For the 500-Hz
condition (second row from the top), the thick black line shows the
running average, computed, in the left panel, as the arithmetic mean
over an 11-dB-wide symmetric rectangular window centered on audiometric
thresholds between −5 and 65 dB HL (in 1-dB steps), and, in the right
panel, as the running average over an 11-year-wide symmetric rectangular
window centered on ages between 23 and 85 years (in 1-year steps).Consistent with previous investigations assessing TFS-LF thresholds for different
tone frequencies using small-sized samples of adult listeners (Füllgrabe et al., 2015; Hopkins & Moore, 2010,
2011), the highest
and average TFS-LF sensitivity declined with increasing tone frequency (compare
across rows).
Relationship of d′ Values With Audiometric Threshold
For the three highest test frequencies (see the three lower panels of the left
column of Figure 2), the
scatter plots relating d ′ scores to audiometric threshold were
roughly triangular in shape. For normal-hearing listeners (with audiometric
thresholds ≤ 20 dB HL), d ′ scores spanned the range from the
highest values observed in the meta-analysis to near or at 0. The highest and
average d ′ scores declined with increasing audiometric
threshold, while d ′ scores near 0 occurred across the whole
range of audiometric thresholds, from moderately impaired to normal hearing. At
250 Hz, the scatter plot had a round shape and fewer listeners were unable to
perform the test.Linear regression lines were fitted to the individual d ′ scores
as a function of audiometric threshold at the test frequency and are shown as
the thick blue lines in the left column of Figure 2. The equation for the regression
line and the percent variance explained are shown in each panel. Also, a running
average of the data at 500 Hz (which had the highest N) was
computed using an 11-year rectangular time window (see thick black line on the
left of Figure 2), to
assess whether there were deviations from linearity. This window duration was
chosen as it resulted in at least seven data points within each window, hence
smoothing the effect of individual variations in performance. The running
average closely followed the regression line for that frequency. The strength of
the association between d ′ scores and audiometric thresholds
for each of the four test frequencies is shown as Pearson correlations in column
2 of Table 2. For
the test frequencies for which the listeners’ audiometric thresholds covered a
wide range (i.e., 250, 500, and 750 Hz), the bivariate correlation coefficients
were −0.19, −0.40, and −0.27, respectively (all p < 0.001).
At 850 Hz, audiometric thresholds only varied over the normal hearing range
(i.e., between −10 and 20 dB HL), but the correlation of −0.34 was significant
(p < 0.001). Thus, depending on the test frequency,
between 4% and 16% of the variance in d ′ scores was accounted
for by audiometric thresholds. The correlations between d ′
scores and audiometric threshold with the effect of age partialled out are shown
in column 3 of Table
2. All partial correlations were significant (all
p ≤ 0.007) except for the partial correlation at 750 Hz which
just failed to reach significance (p = 0.052). All partial
correlations were consistently lower than the bivariate correlations (by a
factor of 1.4 to 2.2), suggesting that part of the effect of audiometric
threshold could be explained by the association between audiometric threshold
and age. The partial correlations accounted only for 2% to 5% of the variance in
the d ′ scores.
Table 2.
Bivariate and Partial Pearson Correlations (With Associated
One-Tailed Significance Levels Within Parentheses) Between TFS-LF
Thresholds (Expressed as d′ Scores) on the One Hand
and Audiometric Threshold (in Hz; Rows 2 and 3) and Age (in Years;
Rows 4 and 5) on the Other, for Each of the Four Test
Frequencies.
Test frequency
Audiometric threshold
Age
Bivariate
Partial
Bivariate
Partial
250 Hz
−.191 (<.001)
−.135 (.007)
−.262 (<.001)
−.226 (<.001)
500 Hz
−.400 (<.001)
−.192 (<.001)
−.502 (<.001)
−.377 (<.001)
750 Hz
−.266 (<.001)
−.123 (.052)
−.642 (<.001)
−.614 (<.001)
850 Hz
−.336 (<.001)
−.220 (.004)
−.509 (<.001)
−.453 (<.001)
Note. For the partial correlations, the effect
of the other variable (age in the case of audiometric threshold,
and vice versa) was partialled out. No correction for multiple
comparisons was applied.
Bivariate and Partial Pearson Correlations (With Associated
One-Tailed Significance Levels Within Parentheses) Between TFS-LF
Thresholds (Expressed as d′ Scores) on the One Hand
and Audiometric Threshold (in Hz; Rows 2 and 3) and Age (in Years;
Rows 4 and 5) on the Other, for Each of the Four Test
Frequencies.Note. For the partial correlations, the effect
of the other variable (age in the case of audiometric threshold,
and vice versa) was partialled out. No correction for multiple
comparisons was applied.While the absolute amount of variability of d ′ scores (in terms
of their range or interquartile range, IQR) generally decreased with increasing
audiometric loss, the coefficient of variation ([SD/mean] × 100), a measure of
relative variability, actually increased across the three audiometric groups
(“normal hearing”, “mild hearing loss”, and “moderate hearing loss”, as defined
by the British Society of
Audiology, 2011), being 71%, 78%, and 99% at 250 Hz, 71%, 91%, and
156% at 500 Hz, and 98%, 91%, and 145% at 750 Hz, respectively. Comparing the
coefficients of variation across audiometric groups, using Levene’s
F test, indicated a significant effect at 250 Hz
[F(2,322) = 5.73, p = 0.004]
and at 500 Hz [F(2,591) = 22.51,
p < 0.001], but not at 750 Hz
[F(2,175) = 2.54, p = 0.082].
Subsequent uncorrected one-tailed t tests on the data for the
two lower test frequencies revealed that there were significant differences
between all groups (all p < 0.05).
Relationship of d′ Values With Age
Performance on the TFS-LF test, in terms of highest individual and mean scores,
worsened with increasing age (right column of Figure 2). Linear regression lines were
fitted to the individual d ′ scores as a function of age, and
are shown as the thick red lines. The equation for the regression line and
percent variance explained are shown in each panel. A running average was
computed for the 500-Hz test frequency using an 11-year rectangular time window
(thick black line on the right of Figure 2), resulting in at least 24 data
points within each window. This closely followed the regression line, except
between the ages of 30 and 45 years: average scores remained roughly constant up
to about 40 years before declining more rapidly than the regression line between
40 and 45 years. The bivariate correlation coefficients (see column 4 of Table 2) were −0.26,
−0.50, −0.64, and −0.51 for the four test-tone frequencies in increasing order,
respectively (all p < 0.001), indicating that age explained
between 7% and 41% of the variance in d ′ scores. The
correlations between d ′ scores and age with the effect of
audiometric threshold partialled out are shown in column 5 of Table 2. The partial
correlations were only slightly lower than the bivariate correlations (by a
factor of 1.0 to 1.3), and all partial correlations were highly significant (all
p < 0.001), suggesting that most of the effect of age on
d ′ scores cannot be attributed to the correlation between
age and absolute threshold. The partial correlations explained 5% to 23% of the
variance in the d ′ scores.The range and IQR of the d ′ scores generally decreased with
increasing age, while the coefficient of variation increased across the four age
groups, being 41%, 71%, 91%, and 81% at 250 Hz, 60%, 71%, 81%, and 114% at
500 Hz, 47%, 93%, 106%, and 109% at 750 Hz, and 54%, 81%, 77%, and 128% at
850 Hz. Based on Levene’s F test, the coefficients of variation
across age groups differed significantly across age groups at 250 Hz
[F(3,321) = 4.09, p = 0.007] at
500 Hz[F(2,590) = 7.55,
p < 0.001], and at 850 Hz
[F(3,143) = 5.75, p = 0.001],
but not at 750 Hz [F(3,174) = 1.89,
p = 0.133]. Subsequent uncorrected one-tailed
t tests on the data for the three frequencies for which a
significant age-group effect was observed revealed that the variability for the
young adults differed significantly (all p < 0.05) from that
for all other age groups at 250 Hz, from that for the young-old and old-old
adults at 500 Hz, and from that for the middle-aged and old-old adults at
850 Hz.
Comparing Relationships
Although changes in TFS-LF sensitivity followed the same general trends with
increasing audiometric threshold and increasing age, there was one noticeable
difference. While very low d ′ scores occurred across the whole
range of audiometric thresholds, d ′ scores for listeners up to
midlife (∼40 to 45 years), almost all of whom had audiometric thresholds within
the normal range at the test frequency (see column 3 in Figure 1), only very exceptionally
approached 0 and generally remained above 5, 3, 3, and 1 for the test
frequencies 250, 500, 750, and 850 Hz, respectively. Thus, younger listeners
were usually able to perform the TFS-LF task. However, it appears that a
substantial or complete loss of sensitivity to binaural TFS can occur with
increasing age above 45 years even when the audiometric threshold at the test
frequency remains within the normal range.The correlation between d ′ score and age was always higher than
the correlation between d ′ score and audiometric threshold
(compare columns 2 and 4 in Table 2). Based on the test described by Lee and Preacher (2013), which assesses
the significance of the difference between two correlations with one variable in
common (d ′ score in this case; Steiger, 1980) using Fisher’s
r-to-z transform, the differences were
significant at 500 Hz (p = 0.0034), 750 Hz
(p < 0.0001), and 850 Hz (p = 0.041), but
not at 250 Hz (p = 0.28). Columns 3 and 5 of Table 2 show the
partial correlations for each variable (audiometric threshold or age) with the
effect of the second variable partialled out. At each test frequency, the
partial correlation between d ′ score and age was higher than
that between d ′ score and audiometric threshold. Using
Fisher’s r-to-z transform, the differences in
partial correlations (two-tailed test) were significant at 500 Hz
(p = 0.007), 750 Hz (p < 0.001), and
850 Hz (p = 0.024), but not at 250 Hz
(p = 0.234). Overall, these results suggest that, within the
population sampled, d ′ scores were more related to age than to
audiometric thresholds.To predict performance on the TFS-LF test, separate multiple linear regression
analyses were conducted, one for each of the four test frequencies, using the
“enter” method, in which both predictors (age and audiometric threshold) are
simultaneously entered. For all test frequencies, the two-predictor model was
significant (all p < 0.001). Details of the regression
analyses are shown in Table
3. When combined, age and audiometric thresholds accounted for
between 8% and 42% of the variation in d ′ scores. Regression
coefficients for both predictors were significantly different from 0 (all
p ≤ 0.015), except for audiometric threshold at 750 Hz
(p = 0.10). In all analyses, the standardized regression
coefficient for age was larger than that for audiometric threshold.
Table 3.
Results of the Two-Predictor (Age and Audiometric Threshold) Multiple
Linear Regression Model for Each Test Frequency.
Test frequency
R
Adjusted R2
β (p value)
Standardized β
250 Hz
.293
.080
−.086 (<.001)
−.229
−.050 (.015)
−.135
500 Hz
.528
.277
−.104 (<.001)
−.402
−.067 (<.001)
−.193
750 Hz
.649
.415
−.105 (<.001)
−.615
−.016 (.104)
−.098
850 Hz
.543
.286
−.052 (<.001)
−.449
−.085 (.008)
−.199
Note. R = Multiple correlation coefficient;
adjusted R2 = adjusted variance
explained; β (p
value) = regression coefficients for age and audiometric
threshold (top and bottom entries for each frequency) with
associated significance levels within parentheses; standardized
β = standardized regression
coefficients.
Results of the Two-Predictor (Age and Audiometric Threshold) Multiple
Linear Regression Model for Each Test Frequency.Note. R = Multiple correlation coefficient;
adjusted R2 = adjusted variance
explained; β (p
value) = regression coefficients for age and audiometric
threshold (top and bottom entries for each frequency) with
associated significance levels within parentheses; standardized
β = standardized regression
coefficients.As the sample size was largest for the test frequency of 500 Hz, all adult age
groups were reasonably well represented for that frequency, and the distribution
of audiometric thresholds for each age group followed that of the general
population (see the second row in Figure 1), this data set was further
analyzed. Figure 3 shows
a three-dimensional representation of mean d ′ scores as a
function of audiometric threshold and age group. Binaural TFS sensitivity
worsened from young to old-old adulthood, while it was additionally affected by
audiometric threshold in old adulthood.
Figure 3.
Changes in binaural TFS sensitivity at 500 Hz as a function of
hearing loss and age. Performance on the TFS-LF test in terms of
mean d′ scores (z axis) is plotted
for 10-year-wide age groups (x axis) and roughly
10-dB-wide audiometric-threshold groups (y axis).
Results are only shown for audiometric-threshold group × age group
combinations for which at least five d′ scores were
available. To smooth the data, the “true” value for each point was
replaced by the mean of the value for that point and the values for
the immediately adjacent points (higher and lower ages and greater
and smaller audiometric losses).
Changes in binaural TFS sensitivity at 500 Hz as a function of
hearing loss and age. Performance on the TFS-LF test in terms of
mean d′ scores (z axis) is plotted
for 10-year-wide age groups (x axis) and roughly
10-dB-wide audiometric-threshold groups (y axis).
Results are only shown for audiometric-threshold group × age group
combinations for which at least five d′ scores were
available. To smooth the data, the “true” value for each point was
replaced by the mean of the value for that point and the values for
the immediately adjacent points (higher and lower ages and greater
and smaller audiometric losses).To test for an interaction between age and audiometric threshold, two additional
multiple linear regression analyses were performed, using age, audiometric
threshold, and their interaction term (age × audiometric threshold) as
predictors. For better interpretability of the regression coefficients, both
predictors were centered (by subtracting a constant value from each datum point
of a given predictor) prior to running the regression analysis (Dalal & Zickar,
2012; Jaccard, Wan,
& Turrisi, 1990). Centering does not affect the multiple
correlation coefficient, the significance level of the model, or the regression
coefficient of the interaction term. However, a desirable consequence of this
transformation is that the regression coefficient for the second predictor
reflects its influence on the dependent variable at the chosen value of the
first predictor, and not when the latter equals zero (which in the case of the
second predictor audiometric threshold would correspond to a meaningless “age
zero” for the first predictor). Using more than one centering allows estimation
of the change in d ′ scores as a function of one predictor
(e.g., audiometric threshold) for different values of the other predictor (e.g.,
the effect of audiometric threshold on d ′ scores in young and
old adulthood). Such a transformation was not necessary for the previous
additive regression models, which tested only the main effects of age and
audiometric threshold, as in those cases, the regression coefficient for one
predictor reflects the influence of that predictor on the dependent variable
across the values of the other predictor.The first analysis used the age and audiometric-threshold means (25 years and
5.3 dB HL, respectively) for the adult listeners aged below 40 years, for whom
audiometric variability in the normal range did not seem to affect binaural TFS
sensitivity, to center the predictors. Incorporating the interaction between age
and audiometric threshold yielded a significant three-predictor model that
explained a similar amount of variation in d ′ scores (adjusted
R2 = 0.281; p < 0.001) to
that for the two-predictor model (adjusted
R2 = 0.277). The regression coefficients for age
(β = −0.098; p < 0.001) and for the
age × audiometric threshold interaction (β = −0.002;
p = 0.042) were both significant, but the regression
coefficient for audiometric threshold was not (β = −0.009,
p = 0.785). The corresponding standardized regression
coefficients were −0.378, −0.025, and −0.196, for age, audiometric threshold,
and their interaction, respectively. The second analysis used the age and
audiometric-threshold means for the adult listeners aged 60 years and above
(70.7 years and 22.4 dB HL, respectively) to center the predictors. This time,
all three regression coefficients were significant (for age:
β = −0.125; p < 0.001; for audiometric
threshold: β = −0.081; p < 0.001; for
age × audiometric threshold: β = −0.002;
p < 0.042). The corresponding standardized regression
coefficients were −0.483, −0.235, and −0.129, for age, audiometric threshold,
and their interaction, respectively. The interaction probably reflects the
observation that, among listeners aged 58 years and above, the effect of
increasing age is greater when the hearing loss is greater than 30 dB than when
it is less than 30 dB (see Figure 3).Taken together, the regression model incorporating an interaction term only
marginally improved the amount of variability in d ′ scores
explained, but it did reveal a significant interaction component. The
significance of the regression coefficients and the size of the standardized
regression coefficients depended on the group means used to center the data.
Discussion
Most previous studies of the effects of audiometric threshold and/or age on binaural
TFS sensitivity have used relatively small numbers of listeners, which would have
limited the ability to detect weak associations. The median number of listeners in
the studies used in our meta-analysis was 34; the average was higher at 48 because
of the two larger-scale studies of Füllgrabe (2013) and Rönnberg et al. (2016). With such a small
median sample size, the correlation between d ′ scores and
audiometric threshold or age has to be at least 0.34 to yield a 95% confidence
interval that does not include 0. The main motivation for the present study was to
assess the effects of audiometric threshold and age on binaural sensitivity to TFS,
using a large sample of listeners, who were audiometrically representative of the
general population, and with a reasonably large number of listeners within each age
group. While listeners aged 18 to 39 years and 60 to 75 years were somewhat
overrepresented relative to the other age groups, there were substantial numbers of
listeners in each adult age group, at least for the 500-Hz test frequency (for which
the minimum number of listeners in any given adult age group was 67). Also, for this
frequency, the distribution of audiometric thresholds in our sample followed that of
the general population fairly closely (see the second row in Figure 1). Therefore, the results presented
here probably are reasonably representative of those that would be found for the
general population.The results of our meta-analysis confirm previous reports that both audiometric
threshold and age are correlated with the ability of adult listeners to process
binaural TFS information. Our results showed that binaural TFS sensitivity was more
strongly associated with age than with the audiometric threshold at the test
frequency. At first sight, this appears to contradict the findings of King et al. (2014), who
reported similar correlations of IPD thresholds with audiometric threshold
(r = 0.42) and with age (r = 0.45). However,
as described in the Introduction section, their sample of listeners
was characterized by a similar incidence of hearing impairment for the young and
older listeners, and the correlation between age and the absolute threshold at low
frequencies was not significant. Their young listeners with hearing loss might have
had a form of hearing pathology that is not common in the general population and
that adversely affects binaural sensitivity to TFS.In the present study, the percentage of variance accounted for by the combination of
audiometric threshold and age was relatively small (being largest at 42% for the
750-Hz test frequency). Thus, there is substantial individual variability in
binaural TFS sensitivity that is not accounted for by audiometric threshold and age.
This may partly reflect the fact that performance of the TFS-LF test (and other
tests) is influenced by factors other than binaural TFS sensitivity per se. For
example, some cognitive abilities may play a role, such as maintaining attention,
using limited sensory information, and remembering “what to listen for” (e.g., Füllgrabe et al., 2015;
Wallaert, Moore, &
Lorenzi, 2016; Whiteford, Kreft, & Oxenham, 2017), while others, such as nonverbal
fluid reasoning, do not seem to affect binaural TFS processing (Füllgrabe et al.,
2018).The absolute variability in d ′ scores decreased with increasing
hearing loss and increasing age. However, this may be largely a consequence of the
fact that the “best” performance for a given hearing loss and age tended to decrease
with increasing hearing loss and age, while the worst performance could not drop
below d ′ = 0. The relative variability, expressed as the
coefficient of variation, actually increased with increasing audiometric threshold
and increasing age. The limitation of the TFS-LF test that some listeners cannot
perform the task at all can be largely overcome by use of the TFS-AF test (where AF
stands for adaptive frequency), which gives an estimate of the highest frequency at
which an IPD of ϕ (usually 180°) can be distinguished from an IPD of 0° (Füllgrabe et al., 2017;
Füllgrabe & Moore,
2017). The great majority of listeners are able to perform the TFS-AF
task to some extent, giving a graded measure of performance. Results for the TFS-AF
test show that both absolute and relative variability across listeners tend to
increase with increasing age (Füllgrabe et al., 2018).The results for the test frequency of 500 Hz, for which the number of listeners was
largest, suggested that d ′ scores did not change markedly with age
up to about 40 years, but declined progressively thereafter. This pattern of results
is similar to that inferred from a study using the TFS-AF test (Füllgrabe et al., 2018),
although that study did not include middle-aged listeners. The deviation of the
running average (thick black line in the right column of Figure 2) from the linear regression line
fitted to the individual data over the whole range of ages may be a result of random
variability or a sampling bias. However, over the age range 30 to 40 years, the
running average was always based on a relatively large number of data points (at
least 42), and the mean audiometric threshold of 7 dB HL for this age range was not
better than that observed for younger adults (5 dB HL). Therefore, binaural TFS
sensitivity might actually remain roughly constant with increasing age from 18 to 40
years, but declines with increasing age above 40 years.
Conclusions
A meta-analysis was performed of data from 19 studies using the TFS-LF test to assess
binaural sensitivity to TFS. The studies were conducted using listeners with a wide
range of ages and audiometric thresholds at the test frequency (250, 500, 750, and
850 Hz). At least for the test frequency of 500 Hz, the distribution of audiometric
thresholds within each age group was similar to that for the general population.
Within this population-representative context of restricted audiometric variability
in young and middle-aged adulthood and larger audiometric variability in older
adulthood, binaural TFS sensitivity declined with increasing age across the adult
lifespan and with increasing hearing loss beyond midlife. For all test frequencies,
both audiometric threshold and age were significantly negatively correlated with
TFS-LF sensitivity (with r varying from −0.19 to −0.64), but the
correlation was always significantly higher for age than for audiometric threshold.
Regression analyses showed that the standardized regression coefficient was greater
for age than for audiometric threshold, and that there was a significant
interaction. However, in combination, audiometric threshold and age only accounted
for up to 42% of the variance in binaural TFS sensitivity, leaving a substantial
amount of variance to be explained by other factors, such as cognitive
abilities.
Authors: Lucas S Baltzell; Jayaganesh Swaminathan; Adrian Y Cho; Mathieu Lavandier; Virginia Best Journal: J Acoust Soc Am Date: 2020-03 Impact factor: 1.840
Authors: Olaf Strelcyk; Pavel Zahorik; James Shehorn; Chhayakanta Patro; Ralph Peter Derleth Journal: Trends Hear Date: 2019 Jan-Dec Impact factor: 3.293
Figure 1.
Figure 2.
Figure 3.