Background
Tinnitus is the perceived sensation of sound in the absence of a corresponding external acoustic stimulus [1]. Tinnitus sensations are usually acoustic, such as a buzzing, hissing, or ringing sound [2]. Tinnitus can be unilateral or bilateral, sometimes described as emerging within the head. The perceived sensation can be intermittent or have a pulsatile character. In the “neurophysiological model” of tinnitus [3], tinnitus results from the abnormal processing of a signal generated in the auditory system. This abnormal processing occurs before the signal is perceived centrally. This may result in “feedback,” whereby the annoyance created by the tinnitus causes the individual to focus increasingly on the noise, exacerbating the annoyance, and so a “vicious cycle” develops.
Main text
Studies have shown that tinnitus can impair various central auditory processing abilities [4–15]. Central auditory processing is complex and difficult to comprehend in detail. Central auditory processing disorder [(C)APD] is the name given to difficulties in the perceptual processing of auditory information in the central nervous system [16]. (C)APD covers a range of disorders that affect auditory analysis, although, typically, patients have normal auditory threshold sensitivity but difficulty identifying speech in background noise [17]. The deficits can be measured in terms of sound source localization, level discrimination; temporal patterning; temporal aspects (such as temporal integration, temporal discrimination, such as gap detection, temporal ordering/sequencing of rapid events, and temporal masking); and skill in word recognition in the presence of competing acoustic signals (such as dichotic listening) or understanding degraded speech [16]. A detailed assessment of the various processes that may be affected in individuals with (C)APD requires a comprehensive case history along with an appropriate test battery.
The auditory processing is affected by both auditory factor and cognitive factors [18]. Tinnitus is an auditory factor that can affect auditory processing [19]. Studies have shown that tinnitus affects speech perception in noise (SPIN) [6–8, 10, 14], temporal processing [5, 8, 9, 11, 20, 21], localization [22], working memory [5, 8, 9, 11, 20, 21], and even in those with normal hearing. A higher level of central auditory processing is needed for SPIN, temporal processing, auditory discrimination, etc. [4]. Speech comprehension difficulties are among the most common causes of tinnitus-related handicaps in many patients [23].
The cerebral imagery techniques have indicated abnormal activation in cortical structures, abnormal cortical excitation, and evidence for functional reorganization in tinnitus patients with normal hearing sensitivity [24]. This might affect central auditory processing abilities. However, the outcome of the studies is mixed, wherein few studies have shown a negative impact of tinnitus on auditory processing [7, 20, 21, 23], and few studies have shown no impact of tinnitus on auditory processing [15, 25, 26]. Therefore, there is a need to systematically review the studies on tinnitus’s effect on central auditory processing, which can help the clinician to modify assessment protocol in tinnitus individuals. Thus, the present study aimed to review the studies on tinnitus’s potential impact and interference on central auditory processing skills.
Methods
The study followed the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines [27].
Eligibility criteria
The literature search was done for articles published after 2002. Experimental studies were chosen for systematic review, and the systematic reviews were excluded. The population of interest was individuals with tinnitus with normal hearing sensitivity. Articles that included populations with tinnitus existing with other audiological complaints were excluded. The experimental group should have at least 10 participants, with or without the control group. Articles published in any other language other than English language were not included in the review process.
Search strategy
The electronic databases, PubMed, Google Scholar, and the institutional repository of All India Institute of Speech and Hearing, were searched. The keyword used was as follows: 'tinnitus,' 'ringing in the ear,' 'buzzing in the ear,' 'humming in the ear,' 'auditory processing,' 'CAPD,' 'speech perception in noise, 'SPIN,' 'binaural interaction,' 'binaural integration,' 'dichotic listening,' 'temporal processing,' and 'auditory closure.' The keywords were combined with the Boolean search operators to search.
Study selection
After the database search, a three-step process was used to review all studies according to the eligibility criteria: title screening, reading the abstract, and reading the full text. The full text was retrieved for all potentially relevant records meeting the inclusion criteria or for insufficient information in the title and abstract to make a firm decision. Two review authors performed each key step independently for every record. A third author reviewed any discrepancies at each step, and a decision was made after discussion.
Quality assessment
Quality assessment of the included studies was done using the National Institute of Health Quality Assessment Tool for Case–Control Studies for Observational Cohort and Cross-Sectional Studies [28]. Each study was rated to assess the risk of bias. Each study was classified as good, fair, or poor based on the assessment score. Studies with good and fair scores were only included in the review process.
Results
The process of search is represented in Fig. 1. A total of 3087 articles were obtained from the database search. The articles were exported to the Rayyan software [32] to identify and remove the duplicated articles, and 396 duplicates were removed. Title and abstract screening were carried out, and the full texts were screened to select the articles based on eligibility. After the screening process, 18 articles were included in the systematic review. The included studies are cross-sectional studies, prospective controlled studies, and prospective non-randomized clinical studies.
Fig. 1 [Images not available. See PDF.]
PRISMA flowchart for the selection process of articles in the review
Furthermore, nine out of the eighteen selected studies provided tinnitus pitch and loudness match results on the individuals with tinnitus. Nine studies included participants with both unilateral and bilateral tinnitus, while the remaining had either bilateral or unilateral tinnitus group. All studies except Sanches et al. [4] included information on tinnitus duration. The duration of tinnitus among the selected studies ranged from 3 months to 4 years. Ten studies assessed tinnitus severity using the Tinnitus Handicap Inventory (THI). Of the eighteen studies selected, none of the studies had information regarding the previous or ongoing treatment for tinnitus. Table 1 shows the tinnitus characteristics of the patients included in the various studies.
Table 1. Tinnitus characteristics of the patients included in the various studies
Sl no | Author | Pitch match | Loudness match | Laterality of tinnitus | Duration of tinnitus | Severity | The scale used to measure tinnitus severity |
|---|---|---|---|---|---|---|---|
1 | Rossiter and Walker [13] | NM | NM | B/L: 14 U/L: 5 | > 3 months | Mild | THI |
2 | Huang et al. [7] | NM | 5.25 on 9-point scale | B/L: 15 U/L: 5 | > 2 months | Chronic | THI, TLS |
3 | Sanches et al. [4] | NM | NM | B/L | NM | NM | NM |
4 | Gabriela, Sanches, and Ganz [21] | High frequency | NM | B/L | > 1 year | NM | NM |
5 | An et al. [22] | 250 to 8 kHz | 20 to 60 dB SPL | B/L: 14 U/L: 25 | > 12 months | NM | NM |
6 | Ryu et al. [14] | 250 Hz to 8 kHz | 8.3 (SD = 6.8) dB SPL | U/L | > 12 months | 30.2 plus or minus 16.9 of 100 | THI |
7 | Gilani et al. [5] | NM | NM | U/L | > 12 months | NM | NM |
8 | Fournier and Hébert [20] | Ranged from 250 Hz to 16 kHz Maximum at 16 kHz | Ranged from 25 to 55 dB SPL | B/L | > 6 months | NM | NM |
9 | Jain and Sahoo [8] | NM | NM | B/L | > 3 months | Mild to moderate | THI |
10 | Shakarami et al. [29] | 2 klHz to 8 kHz | Slight to severely loud | B/L: 10 U/L: 6 | 6 to 36 months | Mild to severe | THI |
11 | Moon et al. [10] | NM | NM | B/L: 9 U/L: 9 | > 6 months | NM | NM |
12 | Gilles et al. [6] | NM | NM | U/L:19 | > 3 months | NM | NM |
13 | Jain and Dwarkanath [9] | NM | NM | B/L: 16 U/L: 22 | > 6 months | Mild to severe | THI |
14 | Tai & Husain [15] | Wide frequency range | 48.36 (25.71)/100 | B/L: 14 | > 3 years | Chronic tinnitus | THI |
15 | Ravirose, Thanikaiarasu, and Prabhu [12] | 250 Hz to 8 kHz | 20 to 40 dB HL | B/L:15 | 62–4 months | NM | NM |
16 | Kondli, Amruthavarshini, and Prashanth [30] | NM | NM | B/L:9 U/L: 6 | 6–24 months | Mild to severe | THI |
17 | Mohanapriya [31] | 250 Hz to 8 kHz | 20 to 40 dB HL | B/L or U/L: 20 | > 3 months | Mild to severe | THI |
18 | Raj et al. [11] | 0.125 to 12.5 kHz | 2 to 65 dB | B/L: 70%, U/L: 30% | 3.8 (SD = 2.5) years | Chronic | THI |
NM not mentioned, THI Tinnitus Handicap Inventory, TLS tinnitus loudness scale. B/L bilateral, U/L unilateral
Studies on assessing temporal perception in individuals with tinnitus have used gap in noise (GIN), gap startle paradigm, gap detection test (GDT), temporal modulation transfer function (TMTF), amplitude modulation depth discrimination (AMDD), and amplitude modulation rate discrimination (AMRD). Four studies carried out the GIN test to assess the temporal resolution, and all the studies showed that the tinnitus group required longer gaps than the control group to identify [4, 5, 9, 21]. Similarly, two studies reported differences between the experimental and control group using the GDT [8, 11]. Fournier and Hébert [20] used the gap startle paradigm to assess temporal resolution. Results showed that participants with tinnitus displayed a stronger startle response than controls without tinnitus, as the tinnitus participants could not perceive the gap embedded in the stimulus. Similarly, Mohanapriya [31] reported poor depth discrimination abilities of the tinnitus group in the presence of noise, while the without noise condition did not show any significant difference between the groups. In contrast, Moon et al. [10] reported no significant difference in spectral ripple discrimination (SRD), temporal modulation detection (TMD), and Schroeder-phase discrimination (SPD) tests among individuals in the tinnitus and no tinnitus groups. For the rate discrimination experiment, the control group performed better than the experimental group in with and without noise conditions at 10- and 100-Hz modulation rates, whereas at 40-Hz modulation rate, there was no significant difference between the groups in the without noise condition [33]. Furthermore, no significant difference was seen between the control and the tinnitus group for temporal sequencing task [5, 9, 11].
Speech perception abilities in tinnitus individuals were assessed using Mandarin speech in noise (MSPIN), Korean version of hearing in noise test (K-HINT), reception threshold for speech (RTS), QuickSIN, speech recognition threshold (SRT), and speech in noise testing Leuven Intelligibility Sentence Test (LIST). In a study where SPIN was assessed using MSPIN, it was noted that the control group had significantly higher scores than the experimental group in high and low predictability list scores [7]. Ryu et al. [14] assessed speech perception using K-HINT, RTS (quiet) and signal-to-noise ratio (SNR) RTS in a quiet environment, and SNR in various noise conditions. Results showed that the scores were significantly poorer in the tinnitus group than in the control group, regardless of whether the noise came from the front, right, or left. QuickSIN results revealed that tinnitus participants had significantly poorer speech-in-noise performance (5 dB SNR) in the left ear than in the right ear, and at 10–25 dB SNR conditions, there was no significant between-group difference [8, 15]. Speech-in-noise testing using LIST was done by Gilles et al. [6], where the tinnitus subjects had significantly worse SRT scores compared to non-tinnitus subjects for sentences embedded in steady-state noise and for sentences embedded in 15-Hz AM noise. Similar results were reported by Moon et al. [10], where the tinnitus-affected ears (TEs) showed poorer SRTs than the non-tinnitus ears (NTEs). Overall, all the studies showed that the tinnitus group either required high SNR or the speech perception was affected compared to the control group.
In this review, three studies tested auditory memory using the reading span test, digit forward span, digit backward span, ascending span test, and descending span test. Kondli, Amruthavarshini, and Prashanth [30] reported that individuals with tinnitus had poor backward span, ascending span, and descending span tasks but not the forward digit span. Furthermore, the reading span test revealed that the reading span of the tinnitus group was significantly shorter than that of the control group [13]. Scores on dichotic auditory verbal memory test (DAVMT), and randomized dichotic digit test (RDDT), showed no significant differences between the tinnitus and control group [29].
Ravirose, Thanikaiarasu, and Prabhu [12] assessed discrimination abilities through duration discrimination test (DDT), difference limen for intensity (DLI), and difference limen for frequency (DLF). Results showed a significant increase in DDT, DLI, and DLF thresholds at the tinnitus frequency compared to half an octave above and below the matched frequency in individuals with tinnitus.
An et al. [22] studied localization through sound localization test (SLT) at 30-degree resolution for a total of 180° on the horizontal plane in front of the listener at a distance of 1 m. The results showed that the mean total error score (TES) was significantly greater in the tinnitus group than in the control group. Regarding stimulus frequency, no significant difference was seen for the tinnitus group. In the control group, mean TES values were significantly higher for 4 and 8 kHz than for 0.25 and 1 kHz. There was no significant difference in the scores between the right tinnitus group, the left tinnitus group, and the bilateral tinnitus group. Also, TES was higher for stimulus presented from the side of the tinnitus than the opposite side. There was no correlation between tinnitus pitch and TES and between tinnitus loudness and TES. A summary table of the selected articles is given in Table 2.
Table 2. Summary of eighteen articles on the effect of tinnitus on CAP
Author and year | Objectives of the study | Population type | Tests used | Results |
|---|---|---|---|---|
Rossiter and Walker [13] | To investigate the relationship between tinnitus and cognition | Clinical group: 19 adult patients with tinnitus, with 34 to 3 years old (mean = 48.9 years, SD = 8.2) Control group: 19 normal hearing adults without tinnitus, with 34 to 63 years old (mean = 48.8 years, SD = 8.8) | Reading span test | Reading span affected in tinnitus group |
Huang et al. [7] | To investigate the following: • The effect of tinnitus on speech perception | Clinical group: 20 adults (13 M and 7 F) with tinnitus, mean age — 40.75 years old (range 22–62 years) Control group: 20 healthy adults (12 M and 8 F) without tinnitus, mean age — 38.35 years old (range — 29–56 years) | MSPIN, tinnitus loudness scale, THI | • MSPIN-tinnitus group had less scores in high and low predictability list scores |
Sanches et al. [4] | • To compare the results of the GIN test in normal listeners with and without tinnitus | Clinical group: 18 tinnitus patients with normal hearing (3 M, 15 F) aged between 21 and 45 years, mean age — 31.3 years Control group: 23 normal hearing participants (8 M, 15 F) aged between 21 and 45 years, mean age — 29.7 years | GIN test | GIN is affected in tinnitus group |
Gabriela, Sanches, and Ganz [21] | To analyze auditory temporal resolution in tinnitus patients using GIN | Clinical group: 20 adults with tinnitus, mean age: 33.5 years Control group: 28 participants with no tinnitus Mean age: 28.8 years | GIN | GIN is affected in tinnitus group |
An et al. [22] | Effect of tinnitus on localization | Clinical group: 40 adults (15 M and 25 F) with tinnitus Mean age — 36.7 years (range — 14–63 years) Control group: 40 adults (14 males and 26 females) Mean age — 39.3 years (range = 16–62 years) | SLT at 30-degree resolution for a total of 180° on the horizontal plane in front of the listener Distance 1 m | • Mean TES significantly greater in the tinnitus group than in the control group |
Ryu et al. [14] | To evaluate the effects of masking noise on speech perception ability in patients with normal hearing but unilateral chronic tinnitus | Clinical group: 20 adult patients with unilateral tinnitus, with 20 to 35 years old tinnitus Control group: 20 normally hearing adults without tinnitus, with 20 to 35 years old | K-HINT RTS (quiet) SNR | Tinnitus group had reduced values than the control group |
Gilani et al. [5] | To assess temporal processing in individuals with tinnitus | Clinical group: 20 individuals with tinnitus Mean age: 30.31 ± 9.35 years Control group: 20 individuals without tinnitus, mean age: 27.80 ± 7.74 years | GIN, DPT | GIN is affected in tinnitus group |
Fournier and Hébert [20] | To investigate the gap paradigm in high-frequency tinnitus | Clinical group: 15 adult patients, 19 to 61 years old (mean age = 28.5 years, SD = 6), with tinnitus Control group: 17 normally hearing adults without tinnitus; mean age = 23 years (SD = 3) | Gap startle paradigm | Impaired perception of gap in tinnitus group |
Jain and Sahoo [8] | To investigate the effect of tinnitus on the temporal perception, frequency, and intensity discrimination and speech perception ability in noise in persons with normal hearing sensitivity | Clinical group: 20 normal hearing individuals with tinnitus Age range: 18–55 years (mean age: 38.1 years) The clinical group was further subdivided into mild tinnitus group (10 subjects; 6 M, 4 F) and moderate tinnitus group (10 subjects; 6 M,4 F) Control group: 20 normal hearing participants without tinnitus Age range: 18–55 years (mean age: 38.1 years) | GDT, MDT, DLF, DLI, Kannada QuickSIN | GDT, MDT, DLF, and Kannada QuickSIN were affected in tinnitus group, and no difference was seen in DLI |
Shakarami et al. [29] | To compare the verbal auditory memory between individuals with normal hearing with and without tinnitus | Clinical group: 16 adults (6 males and 10 females) with tinnitus Mean age — 36.44 years (range — 23–53 years) Control group: 20 adults (3 males and 17 females) without tinnitus Mean age — 33.65 years (range — 21–49 years) | DAVMT, RDDT | • No significant differences seen |
Moon et al. [10] | To investigate the pathophysiology of tinnitus using psychoacoustic assessments of auditory spectral and temporal resolution and speech perception in noise | Clinical group: 9 unilateral tinnitus subjects with normal hearing thresholds (group 1 mean age — 28.22 + − 9.22 years), 12 unilateral tinnitus subjects with hearing loss (group 2 mean age — 56.08 + − 12.92 years), 9 bilateral tinnitus subjects with symmetrical hearing loss (group 3 mean age — 60.67 + − 10.98 years) Control group: 15 normally hearing adults without tinnitus, with less than 30 years old (mean age − 44.93 + − 9 years) | SRD, TMD SPD, and SRT | • No significant differences in SRD, TMD, and SPD • The TEs showed poorer SRTs than the NTEs |
Gilles et al. [6] | To assess differences in audiological characteristics between noise-exposed adolescents with and without NIT | Clinical group: 19 adult patients with unilateral tinnitus, participants age was less than 30 years old Control group: 68 normally hearing adults without tinnitus, with less than 30 years old | Speech-in-noise testing list | Scores were affected in tinnitus group |
Jain and Dwarkanath [9] | To assess psychoacoustic abilities in individuals with tinnitus | Control group: 38 participants (19 M & 19 F) Mean age — 33.7 years UTG — 22 participants (9 M and 13 F) Mean age — 34.7 years BTG — 16 participants (8 M and 8 F) Mean age — 38.3 years All participants were in the age range of 24–50 years | GIN, TMTF, DDT, backward masking, DPT | DPT — no difference was observed GIN, TMTF, DDT, and backward masking affected in tinnitus |
Tai & Husain [15] | To investigate how tinnitus interferes with speech recognition ability in noise, and to examine the impact of tinnitus (severity or loudness) on speech recognition | Clinical group: 14 adults with chronic bilateral tinnitus, mean age — 43.86 years Control group: 14 adults with no history of tinnitus, mean age — 44 years | QuickSIN | Tinnitus group required more SNR than the control group • At 10–25-dB SNR conditions, there was no significant between-group difference • No significant correlation |
Ravirose, Thanikaiarasu, and Prabhu [12] | To determine the DDT, DLI, and DLF thresholds in patients with tinnitus | Fifteen participants with tinnitus in the age range of 18 to 40 years (mean age = 29.47 and SD = 7.20) with their hearing thresholds at normal limits | DDT, DLI, and DLF | DDT, DLI, and DLF are affected in tinnitus |
Kondli, Amruthavarshini, and Prashanth [30] | • To evaluate the performance of auditory working memory tasks in adults with tinnitus | Clinical group: 15 individuals with tinnitus Mean age: 32.7 years (SD = 6.25) Control group: 15 individuals without tinnitus Mean age: 33.4 years (SD = 9.7) | Digit forward span, backward span, ascending span, and descending span tasks | • Poor backward span, ascending span, and descending span tasks but not the forward digit span |
Mohanapriya [31] | To evaluate the amplitude modulation discrimination function in terms of depth and rate discrimination in individuals with normal hearing sensitivity having tinnitus | Clinical group: 20 individuals with normal hearing sensitivity with tinnitus Age rage — 18–45 years Control group: 20 individuals with normal hearing sensitivity without tinnitus | PTA, immittance audiometry, tinnitus evaluation, AMDD, AMRD | Depth discrimination was comparable, but the rate discrimination was affected in tinnitus group |
Raj et al. [11] | To compare the auditory processing abilities of two groups: those with normal hearing and tinnitus and a similar group who did not have tinnitus | Clinical group: 54 adult patients, 19 to 61 years old (mean age 37.1 years, SD = 10.7) Tinnitus for 3.8 (SD = 2.5) years Control group: 43 normally hearing adults without tinnitus. The mean age was 35.5 years (SD = 11.1) | FPT, DPT, GDT, and DLT | GDT and DLT were affected in tinnitus group, and no difference was seen in FPT and DPT. And right ear advantage was absent |
GIN Gap in noise, PTA Pure-tone audiometry, M Males, F Females, GDT Gap detection test, MDT Modulation detection test, DLF Difference limen for frequency, DLI Difference limen for intensity, SPIN Speech perception in noise, THI Tinnitus Handicap Inventory, SD Standard deviation, DPT Duration pattern test, MSPIN Mandarin speech in noise, TLS Tinnitus loudness scale, UTG Unilateral tinnitus group, BTG Bilateral tinnitus group, TMTF Temporal modulation transfer function, DDT Duration discrimination test, FPT Frequency pattern test, DLT Dichotic listening test, REA Right ear advantage, DPOAE Distortion product otoacoustic emissions, DAVMT Dichotic auditory verbal memory test, RDDT Randomized dichotic digit test, SLT Sound localization test, TES Total error score, ES Error score, K-HINT Korean version of hearing in noise test, RTS Reception threshold for speech, SNR Signal-to-noise ratio, SRD Spectral ripple discrimination test, TMD Temporal modulation detection test, SPD Schroeder-phase discrimination test, SRT Speech recognition threshold, TE Tinnitus-affected ears, NTE Non-tinnitus ears, NIT Noise-induced tinnitus, LIST Leuven intelligibility sentence test, AMRD Amplitude modulation rate discrimination, AMDD Amplitude modulation depth discrimination
Discussion
The present review aims to study tinnitus’ effect on central auditory processing abilities. Eighteen articles were shortlisted after extensive review. The majority of the articles showed that individuals with tinnitus had affected central auditory processing, which was seen in terms of poor temporal processing [4, 5, 8, 9, 11, 20], poor auditory memory [13, 30], and reduced SPIN [7, 8, 10, 14]. The anatomical and physiological defects in the central auditory nervous system’s neural structures result in tinnitus perception and impair central auditory processing abilities.
Studies reported that temporal resolution was affected in individuals with tinnitus, assessed using the GIN test and TMTF [4, 5, 8, 9, 11, 20]. Boyen et al. [34] postulated that the reason for poor gap detection could be that ongoing tinnitus masks the gap, resulting in impaired gap detection and modulation function. Also, physiologically, detecting silence gaps in noise requires precise processing of the temporal structure of the sound stimulus [33]. The difference in the GIN test performance between patients with and without tinnitus shows dysfunction in the central auditory system in patients with tinnitus [35].
It has also been reported that there is hyperactivity in cortical and thalamic structures in tinnitus patients [36]. This can lead to neural changes at the higher auditory structures, reorganizing the tonotopic map. These neural changes are thought to alter the temporal processing abilities of individuals with tinnitus. Good performance in auditory temporal resolution requires precise neuronal firing, which can be impaired in individuals with tinnitus [5, 9]. However, studies on temporal sequencing using duration pattern test (DPT) and frequency pattern test (FPT) found no difference between the clinical and control groups [9]. This could be attributed to the insensitivity of the tests used to assess temporal ordering (sequencing) to the abnormalities of structures below the auditory cortex [1].
Studies also report tinnitus interferes with SPIN [7, 8, 10, 14]. Studies have shown that tinnitus patients had aberrant links between the limbic and auditory systems, suggesting that tinnitus might originate in the central auditory system rather than the cochlea. Changes in cortical plasticity might account for tinnitus and associated symptoms which affect speech perception [24, 37]. Studies have also reported that tinnitus may affect the central auditory system as “a central masker” that interrupts speech perception [10].
The present systematic review also showed that auditory memory was affected in individuals with tinnitus [13, 30]. Attention resources may be disrupted or depleted due to negative thoughts due to tinnitus, continual orienting to tinnitus [13], and increased self-focused and somatic attention [38], which can cause poor auditory memory. Individuals with tinnitus, for whom annoyance is generally linked with tinnitus, have been shown to perform poorly compared to others for whom tinnitus is not annoying. Hence, the attention toward the auditory stimulus would be reduced [39]. Few studies reported no difference between the mild tinnitus and the control groups in individuals with normal hearing in the divided auditory attention and verbal auditory memory [29]. This indicates that the severity of tinnitus has a differential effect on auditory memory.
Studies on the effect of tinnitus on dichotic listening are sparse [11]. These studies have shown no difference in dichotic listening among tinnitus and no tinnitus groups. However, Cuny et al. [40] reported that tinnitus modifies the normal left-hemisphere specialization in the dichotic listening test. The reason could be that tinnitus modifies the organization of cerebral function. Tinnitus has also been shown to interfere with sound localization ability [22]. The interference is worse when the sound originates from the same side as the tinnitus because the tinnitus reduces interaural level difference [22].
Furthermore, it was noted that THI was used predominantly to measure tinnitus severity across studies. In addition, most studies have not reported tinnitus characteristics such as pitch and loudness (n = 9). It is felt that standardization of assessment protocols and reporting of results could overcome these problems. The details of the tinnitus rehabilitation are missing, as these would have affected the auditory processing test results; hence, a detailed pre- and post-assessment report are needed. The sample size of the individual studies included in the review ranged from 9 to 40 participants per group.
Furthermore, most of the studies did not perform a power analysis. With a low sample size, the generalizability of the individual study results to the tinnitus population becomes debatable. Hence, the results of this review could stand as preliminary evidence for an auditory processing deficit in individuals with tinnitus. Thus, the present systematic review concludes that temporal resolution, speech perception in noise, and working memory are the most affected skills in individuals with tinnitus and normal hearing.
Conclusion
Central auditory processing is affected in individuals with tinnitus in terms of difficulty in understanding speech in noise, temporal processing, localization, and auditory memory. The assessment of central auditory processing abilities should be routinely included for individuals with tinnitus. Further studies are needed with large sample size and various degrees of tinnitus severity to assess various central auditory processing abilities.
Acknowledgements
Not applicable.
Authors’ contributions
SS was involved in concept development, study selection, analysis of the results, interpretation, and writing the manuscript; VV was involved in concept development, study selection, analysis of the results, interpretation, and writing the manuscript; CJ was involved in concept development, study selection, analysis of the results, interpretation, and writing the manuscript; and all authors read and approved the final manuscript.
Funding
No funding was received to assist with the preparation of this manuscript.
Availability of data and materials
Not applicable.
Declarations
Ethics approval and consent to participate
Not applicable.
Consent for publication
Not applicable.
Competing interests
The authors declare that they have no competing interests.
Abbreviations
Central auditory processing disorder
Preferred Reporting Items for Systematic Reviews and Meta-Analyses
Gap in noise
Pure-tone audiometry
Males
Females
Gap detection test
Modulation detection test
Difference limen for frequency
Difference limen for intensity
Speech perception in noise
Tinnitus Handicap Inventory
Standard deviation
Duration pattern test
Mandarin speech in noise
Tinnitus loudness scale
Unilateral tinnitus group
Bilateral tinnitus group
Temporal modulation transfer function
Duration discrimination test
Frequency pattern test
Dichotic listening test
Right ear advantage
Distortion product otoacoustic emissions
Dichotic auditory verbal memory test
Randomized dichotic digit test
Sound localization test
Total error score
Error score
Korean version of hearing in noise test
Reception threshold for speech
Signal-to-noise ratio
Spectral ripple discrimination test
Temporal modulation detection test
Schroeder-phase discrimination test
Speech recognition threshold
Tinnitus-affected ears
Non-tinnitus ears
Noise-induced tinnitus
Leuven intelligibility sentence test
Amplitude modulation rate discrimination
Amplitude modulation depth discrimination
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Abstract
Background
Tinnitus is the perception of sound when there is no external sound stimulus. Individuals with tinnitus may have altered neurological system corresponding to the auditory pathway. Therefore, central auditory processing abilities, which rely on the central auditory pathway, may be affected. This study reviewed the published studies regarding the impact of tinnitus on central auditory processing abilities.
Main text
A total of 3087 studies were identified, of which 18 fulfilled the eligibility criteria and were included in the review. The included studies scored good or fair in the quality assessment checklist. The review showed that individuals who had tinnitus with normal hearing sensitivity performed poorly on temporal resolution tests, speech perception in noise, localization, and auditory memory. However, temporal patterning and dichotic tests were not shown to be affected by tinnitus.
Conclusion
The audiologists involved in tinnitus assessment are recommended to include central auditory processing tests in routine evaluation for the early diagnosis and intervention for subjects with tinnitus.
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Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer
Details
; Vinod, Vibha 1 ; Jain, Chandni 1 1 All India Institute of Speech and Hearing, Department of Audiology, Mysore, India (GRID:grid.413039.c) (ISNI:0000 0001 0805 7368)