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Frequency-specific analysis of hearing outcomes after surgery for chronic ear diseases

Published online by Cambridge University Press:  08 May 2024

Liangxuan Cai ,
TaiQin Wang ,
Huanhuan Sun ,
Jinqing Qiu  and
Jianzhi Liu Open the ORCID record for Jianzhi Liu [Opens in a new window]
Liangxuan Cai
Affiliation:
Department of Otolaryngology, Datian County General Hospital, Fujian, Sanming 365300, China
TaiQin Wang
Affiliation:
Department of Otolaryngology, Fujian Medical University Union Hospital, Fujian, Fuzhou 350001, China
Huanhuan Sun
Affiliation:
Department of Otolaryngology, Chinese Medicine Hospitals, Changji Hui Autonomous Prefecture, Xinjiang, Changji
Jinqing Qiu
Affiliation:
Department of Otolaryngology, The Second Hospital of LongYan, Fujian, Longyan 364000, China
Jianzhi Liu*
Affiliation:
Department of Otolaryngology, Fujian Medical University Union Hospital, Fujian, Fuzhou 350001, China
*
Corresponding author: Jianzhi Liu; Email: [email protected]
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Abstract

Objective

To examine the relationship between different surgical factors and frequency-specific hearing results following surgery for chronic ear disorders.

Methods

We reviewed retrospectively data of 246 patients with chronic ear diseases who had surgery between January 2019 and December 2020. Seventy-three patients did not fulfil the criteria and were excluded. Air-conduction threshold, bone-conduction threshold and air–bone gap were tested at 250–4000 Hz, respectively. Frequency-specific results were investigated in relation to various surgical factors.

Results

The radical mastoidectomy group and tympanoplasty group significantly improved in air-conduction threshold changes at every frequency. In the tympanoplasty group, air–bone gap at all frequencies except 4000 significantly improved. Air-conduction threshold improved at low and middle frequencies when ossicular reconstruction was conducted. In all groups, bone-conduction threshold data revealed significant improvements at 500, 1000, and 2000 Hz.

Conclusions

Hearing improved significantly post-operatively in air-conduction threshold and air-bone gap test, mainly at low and middle frequencies. Bone-conduction threshold improved significantly at 500–2000 Hz.

Keywords

frequencyconductive hearing losssurgerychronic ear diseases
Type
Main Article
Information
The Journal of Laryngology & Otology , First View , pp. 1 - 5
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of J.L.O. (1984) LIMITED

Introduction

The main purposes of chronic otitis media surgery are to re-establish the protective barrier of the middle ear and improve hearing.Reference Jackson, Glasscock, Schwaber, Nissen, Christiansen and Smith1 However, as variations in surgical method, lesion severity, and other factors can alter the comparability of surgical results, the study results that have been reported do not show good agreement.Reference Kim2 Pure tone audiometry is routinely used to assess pre-and post-operative hearing. Most clinical research, on the other hand, has only assessed average pure tone threshold, rather than frequency-specific hearing results. Frequency-specific hearing studies are important since the same average pure tone threshold does not always lead to the same patterns of hearing perception.Reference Choi, Lee, Chang, Yeo, Yoon and Jun3 Therefore, we conducted a retrospective study in which we assessed frequency-specific hearing results based on potential influencing factors to give evidence for frequency-specific post-operative hearing rehabilitation.

Materials and methods

We reviewed retrospectively data of 246 consecutive patients with chronic otitis media who had surgery at our hospital between January 2019 and December 2020. We included 173 patients with pre- and post-operative pure tone audiometry data in the analysis. Patients with adhesive otitis media, revision surgery and failed surgical procedures were excluded. The surgical procedures were performed by one otology surgeon. The selection of surgical approach was determined by the range of lesion as well as the pre-operative status of hearing and facial nerve function. Canal wall down tympanoplasty refers to canal wall mastoidectomy plus tympanoplasty.

Pure tone audiometry was conducted in a double-chamber anechoic room using standard procedures. All patients had pre-operative pure tone audiometry within one week of surgery. Air-conduction threshold, bone-conduction threshold, and air–bone gap (ABG) were tested at 250, 500, 1000, 2000 and 4000 Hz. Post-operative pure tone audiometry was examined using the same techniques one year after surgery. At these frequencies, changes in air-conduction threshold, bone-conduction threshold, and ABG were calculated between pre- and post-operative examinations. Statistical analysis was performed for each frequency by comparing pre- and post-operative mean values. A positive value indicates improvement, and a negative value indicates deterioration.

According to the different surgical procedures, patients were divided into two subgroups: tympanoplasty versus canal wall down tympanoplasty. The patients also were divided into subgroups according to the type of ossicular replacement: partial ossicular replacement prosthesis (PORP) versus total ossicular replacement prosthesis (TORP) versus none (Table 1).

Table 1. Distribution of cases in different groups; TORP = total ossicular replacement prosthesis, PORP = partial ossicular replacement prosthesis

Statistical analyses were performed using SPSS version 21.0 software (IBM, Armonk, NY, USA). The metering data were expressed as mean ± standard deviation (SD) and the significance analysis was conducted using a t-test. The categorical variables were compared using the chi-square test or Fisher's exact test; p < 0.05 indicates that the difference is statistically significant.

Results

Among the 173 chronic otitis media patients (173 ears), ages 10–74 years (median = 45 years), there were 66 males and 107 females, with a male:female ratio of 1:1.62, of which 91 (52.6 per cent) were left ears. Of the total cohort, hearing in all frequencies improved significantly post-operatively in air-conduction threshold (Figure 1a) and ABG (Figure 1c) test. Bone-conduction threshold (Figure 1b) significantly improved at 500, 1000 and 2000 Hz.

Figure 1. Pre-operative and Post-operative frequency-specific hearing results in air-conduction threshold (AC), bone-conduction threshold (BC), and air–bone gap (ABG). a, Pre-operative and post-operative levels in AC. b, Pre-operative and post-operative levels in BC. c, Pre-operative and post-operative levels in ABG.

Hearing results and surgical method

The canal wall down tympanoplasty group and tympanoplasty group significantly improved in air-conduction threshold changes at every frequency. Air–bone gap results in the tympanoplasty group showed improvement at every frequency. In the canal wall down tympanoplasty group, ABG at all frequencies except 4000 Hz (p = 0.069) significantly improved. Bone-conduction threshold changes in the canal wall down tympanoplasty group and tympanoplasty group were significantly improved at 500, 1000 and 2000 Hz (Figure 2).

Figure 2. Analysis by surgical methods (tympanoplasty versus canal wall- down tympanoplasty); AC = air-conduction threshold; BC = bone-conduction threshold; ABG = air–bone gap; p values represent significance of hearing change from pre-operative to post-operative follow up.

Ossicular replacement comparison

Air-conduction threshold and bone-conduction threshold results significantly improved in the ‘None’ group at 250, 500, 1000 and 2000 Hz. Air–bone gap changes were significantly improved at 250, 500 and 1000 Hz. Using the TORP replacement, air-conduction threshold and bone-conduction threshold showed significant differences at 250, 500, 1000 and 2000 Hz, and at 1000, 2000 and 4000 Hz, respectively. Air–bone gap change statistically improved only at 500 and 1000 Hz. In the PORP group, air-conduction threshold and ABG significantly improved at every frequency. Bone-conduction threshold data revealed significant improvements at 500, 1000 and 2000 Hz (Figure 3).

Figure 3. Analysis of the types of ossicular replacement (None versus TORP versus PORP); TORP = total ossicular replacement prosthesis; PORP = partial ossicular replacement prosthesis; p values represent significance of hearing change from pre-operative to post-operative follow-up.

Discussion

This study compared pre- and post-operative frequency-specific hearing outcomes in patients with chronic otitis media. As anticipated, all frequencies of the group showed significant post-operative improvement in hearing in the air-conduction threshold and ABG tests. The gain is most prominent at low and middle frequencies. This is consistent with previous studies.Reference Şevik Eliçora, Erdem, Dinç, Damar and Bişkin4 The normal middle-ear pressure gain (a result of ossicular coupling) is frequency-dependent.Reference Merchant, Ravicz, Puria, Voss, Whittemore, Peake and Rosowski5 Choi et al. noted that the mean gain decreases 6 dB or less per octave for frequencies above 1000 Hz.Reference Choi, Lee, Chang, Yeo, Yoon and Jun3 The low- and middle-frequency improvements may represent a normalisation of the ossicular coupling effect following reconstructive surgery. In addition to air-conduction threshold elevation, some patients with chronic otitis media also have bone-conduction threshold elevation.

An elevation in bone-conduction threshold can result from tympanosclerosis, stapes fixation, round window membrane alteration, tympanic membrane perforation, and ossicular chain disruption or fixation.Reference Yoshida, Miyamoto and Takahashi6 The current study found that, with the exception of 250 and 4000 Hz, bone-conduction threshold significantly improved in the whole cohort. The ossicular chain has a large resonance effect at 500–2000 Hz. Weakness or disappearance of resonance caused by destruction of the ossicular chain can lead to bone-conduction threshold changes at 500–2000 Hz, and bone-conduction threshold can be improved when the continuity and resonance of the ossicular chain are restored through reconstructive surgery.Reference Merchant, Ravicz, Puria, Voss, Whittemore, Peake and Rosowski5Reference Tüz, Doğru, Uygur and Gedikli7

At all frequencies except 2000 Hz, the hearing improvement of patients who underwent tympanoplasty was better than that of patients who underwent canal wall down tympanoplasty in this study. The difference in efficacy between tympanoplasty and canal wall down tympanoplasty typically has been ascribed to poor Eustachian tube function and greater disease severity in patients requiring canal wall down tympanoplasty.Reference Lee, Hong, Hong, Cho and Chung8 Furthermore, Quaranta et al. claimed that an intact posterior canal wall was considered a predictor of the better hearing result in ossiculoplasty.Reference Goldenberg and Emmet9

Hearing improvement at 2000 Hz was significantly better in the canal wall down tympanoplasty group than in the tympanoplasty group in our investigation. This was consistent with results in research by Şevik Eliçora et al.Reference Şevik Eliçora, Erdem, Dinç, Damar and Bişkin4 It is perhaps relevant that the intact ossicular chain has the greatest effect on hearing at 2000 Hz.Reference Quaranta, Taliente, Coppola and Salonna10 The bone-conduction threshold change results were superior in the canal wall down tympanoplasty group compared with the tympanoplasty group at 250–2000 Hz. The canal wall down tympanoplasty group had poorer post-operative bone-conduction threshold outcomes compared to the tympanoplasty group at 4000 Hz. Excessive ossicular chain movement, vibration or noise from drilling, or other inner-ear disruption are all associated with high-frequency sensorineural hearing loss (i.e. strong suction or thermal damage).Reference Dinç, Damar, Erdem, Eliçora, Akyıldız and Kumbul11Reference Gerber, Mason and Lambert13 Canal wall down tympanoplasty generally has more drilling time in the middle ear near the stapes and oval window, and the bone-conduction threshold seems to be more susceptible to its adverse effect at 4000 Hz.

Surprisingly, the TORP group had the best hearing improvement, followed by the PORP group and the None group at all frequencies except 1000 Hz. The None group was closer to normal hearing to begin with and had less room for improvement. Most studies assumed that PORP was associated with superior post-operative hearing outcomes when compared with TORP.Reference Choi, Lee, Chang, Yeo, Yoon and Jun3 They suggested that the stapes suprastructure plays an important role in hearing,Reference Badr-El-Dine, James, Panetti, Marchioni, Presutti and Nogueira14 and the stability between TORP and stapes floor is inadequate and prone to displacement, resulting in the interruption of TORP and stapes footplate connection. But in their studies, post-operative audiometry tests were generally conducted about three months after surgeryReference Choi, Lee, Chang, Yeo, Yoon and Jun3.

It is our opinion that the residual stapes in subsequent recovery may continue to be disrupted and experience adhesion with the surrounding tissue. Furthermore, ossicular coupling of TORP may be superior to that of PORP.Reference House and Teufert15 Cadaveric temporal bone studies support this viewpoint and considered that TORP placement to a stapes footplate offers acoustic advantages over other ossiculoplasty techniques. The reduced middle-ear pressure can be restored after ossiculoplasty. Therefore, the results suggest that air-conduction threshold changes occurred principally at lower and middle frequencies, with no substantial changes at higher frequencies. Tonndorf et al. thought that the influence of ossicular chain mechanics on bone-conduction threshold is expressed at most as improvement for the frequency of 2000 Hz, which is caused by the reduction or elimination of resonance within the ossicular chain.Reference Baker, O'Connell, Nguyen and Lambert16 Similarly, we found that three groups all showed significant improvement at 1000–2000 Hz.

This study is limited by its retrospective nature and small sample size. Other confounding factors, such as infection degree, operator experience and surgery duration, could influence study results. In addition, hearing data at 6000 Hz were lacking in this study. Although 6000 Hz has little effect on the verbal communication, the relevant changes still need to be studied further.

  • Most studies only assessed average pure tone threshold after middle-ear surgery, rather than frequency-specific hearing results

  • This audit showed that the hearing improved significantly post-operatively in air-conduction threshold and air–bone gap tests, mainly at low and middle frequencies

  • Post-operative frequency-specific hearing results were affected by variances in surgical method and ossicular replacement

  • This study provides a basis for post-operative frequency-specific hearing rehabilitation

Conclusion

We systematically evaluated the effect of hearing reconstruction at different frequencies after surgery. Hearing improved significantly post-operatively in air-conduction threshold and the ABG test, mainly at low and middle frequencies. Bone-conduction threshold improved significantly at 500–2000 Hz. Post-operative preparation for high-frequency hearing rehabilitation may be needed.

Conflicts of interest

The authors declare that they have no conflicts of interest.

Financial disclosure

The authors declare that they have no financial disclosures.

Authorship

Concept, LXC; design, HHS; supervision, JQQ; resources, LXC; materials, HHS; data collection and processing, JQQ; analysis and interpretation, LXC; literature search, HHS; Writing, JZL; critical review, JZL.

Acknowledgements

This work was financially supported by the Joint Funds for the Innovation of Science and Technology of Fujian Province (2023Y9158).

Footnotes

*

Contributed equally to this work.

#

Jinqing Qiu and Jianzhi Liu are the co-corresponding authors of this work.

Jianzhi Liu takes responsibility for the integrity of the content of the paper

References

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Figure 0

Table 1. Distribution of cases in different groups; TORP = total ossicular replacement prosthesis, PORP = partial ossicular replacement prosthesis

Figure 1

Figure 1. Pre-operative and Post-operative frequency-specific hearing results in air-conduction threshold (AC), bone-conduction threshold (BC), and air–bone gap (ABG). a, Pre-operative and post-operative levels in AC. b, Pre-operative and post-operative levels in BC. c, Pre-operative and post-operative levels in ABG.

Figure 2

Figure 2. Analysis by surgical methods (tympanoplasty versus canal wall- down tympanoplasty); AC = air-conduction threshold; BC = bone-conduction threshold; ABG = air–bone gap; p values represent significance of hearing change from pre-operative to post-operative follow up.

Figure 3

Figure 3. Analysis of the types of ossicular replacement (None versus TORP versus PORP); TORP = total ossicular replacement prosthesis; PORP = partial ossicular replacement prosthesis; p values represent significance of hearing change from pre-operative to post-operative follow-up.