Abstract
Purpose
To investigate 2-year post-operative hearing performance, safety, and patient-reported outcomes of hearing-impaired adults treated with the Osia® 2 System, an active osseointegrated bone-conduction hearing implant that uses piezoelectric technology.
Methods
A prospective, multicenter, open-label, single-arm, within-subject clinical study conducted at three tertiary referral clinical centers located in Melbourne, Sydney and Hong Kong. Twenty adult recipients of the Osia 2 System were enrolled and followed up between 12 and 24 months post-implantation: 17 with mixed or conductive hearing loss and 3 with single-sided sensorineural deafness. Safety data, audiological thresholds, speech recognition thresholds in noise, and patient-reported outcomes were collected and evaluated. In addition, pre-and 6-month post-implantation data were collected retrospectively for this recipient cohort enrolled into the earlier study (ClinicalTrials.gov NCT04041700).
Results
Between 6- and 24-month follow-up, there was no statistically significant change in free-field hearing thresholds or speech reception thresholds in noise (p = > 0.05), indicating that aided improvements were maintained up to 24 months of follow-up. Furthermore, improvements in health-related quality of life and daily hearing ability, as well as clinical and subjective measures of hearing benefit remained stable over the 24-month period. No serious adverse events were reported during extended follow-up.
Conclusions
These study results provide further evidence to support the longer term clinical safety, hearing performance, and patient-related benefits of the Osia 2 System in patients with either a conductive hearing loss, mixed hearing loss, or single-sided sensorineural deafness.
Trial Registration
ClinicalTrials.gov Identifier: NCT04754477. First posted: February 15, 2021.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
The Osia® System is an active bone-conduction hearing implant indicated for patients with conductive hearing loss (CHL), mixed hearing loss (MHL), and single-sided deafness (SSD). The osseointegrated implant stimulates the skull bone directly using an implanted piezoelectric transducer and is controlled and powered by an external sound processor that captures external sounds via the microphones. A key advantage of the Osia System compared to passive devices is the gain provided at higher frequencies compared to passive bone conduction [1].
The system has a fitting range of up to 55 dB HL. An overview of the current system design and function and short-term clinical outcomes for a cohort of 29 subjects have been published previously [1]. The safety and efficacy of the Osia System has also been reported in several additional clinical studies [2,3,4,5]. However, no study has presented longer term (> 12 month) follow-up data with the current system to date. Therefore, the aim of this study was to evaluate the longer term safety and efficacy of the Osia 2 System through the collection of safety, audiological, and quality of life data up to 24 months post-implantation. As the device is expected to be implanted for many years, it is important to characterize the long-term safety profile and clinical benefits of the system.
Methods
Study information
This study collected 12- and 24-month follow-up data from the enrolled group of Osia System recipients, who had existing data from a previous study, at pre-implantation and 6 months post-implantation [1]. The current study was approved by respective local ethics committees as per local regulations, conducted in accordance with the Declaration of Helsinki [6] and ISO14155:2011[7] and was registered on ClinicalTrials.gov with identifier NCT04754477.
Investigational device
The investigational device was the Cochlear™ Osia 2 System (Cochlear Ltd., Sydney, Australia) consisting of an external sound processor (SP) (Osia 2 SP) magnetically retained on the skin over the site of an internal implant (OSI200 Implant), which is fixed to the temporal bone with an osseointegrating implant (BI300 screw fixture, 3 or 4 mm). Surgical technique has been published previously [1] and the SP was individually fitted to each subject's hearing loss using Osia Fitting Software 2.0.
Study schedule and assessments
The objective of the clinical study was to compare safety parameters, patient-reported outcomes (PRO), and change in free-field hearing thresholds and speech reception threshold (SRT) in noise (dB SNR) with the Osia 2 System at 6 months and 12 and 24 months post-implantation. As part of the current study, visits were carried out at 12 and 24 months after implantation with the Osia 2 System for efficacy and safety evaluation. Data collected between baseline (pre-implantation) and 6-month follow-up post-implantation with the Osia 2 System were retrospectively collected from the previous clinical study sponsored by Cochlear (ClinicalTrials.gov NCT04041700). Safety parameters were recorded throughout the current clinical study and retrospectively collected for enrolled patients in the previous clinical study between implantation with the Osia 2 System and 6-month follow-up.
Hearing thresholds
The tests were performed in a sound-insulated audiometric booth using calibrated equipment with the non-test ear blocked using both a foam plug and earmuffs in case of normal or near-normal hearing or a large asymmetry between ears. During testing, SPs were set to fixed directionality mode. Threshold audiometry was performed using warble tones presented via a loudspeaker located 1 m in front of the subjects at 0-degree azimuth, with 1 m of free space surrounding the test subject. PTA4 hearing thresholds were calculated by taking an average of hearing thresholds measured at 0.5, 1, 2, and 4 kHz. Changes in audiometric thresholds of > 10 dB at a single frequency are considered as clinically relevant as outside of the test–retest variability [8].
Speech recognition in noise
For speech in noise testing, both speech and noise were presented in free field at 0-degree azimuth (front). In Melbourne and Sydney, the AuSTIN test was administered and sentences were presented at a constant level of 65 dB SPL throughout the test, and babble noise was adapted stepwise according to the software used to establish the signal-to-noise ratio (SNR) providing a 50% level of correctly repeated morphemes. In Hong Kong, the CHINT methodology was used, where noise was maintained at a constant 65 dB SPL, and sentence speech stimuli were presented adaptatively, with stepwise adjustments to the speech level made by the software to establish the SNR where the test subject repeated 50% of the material correctly. Improvements of greater than 3 dB SNR are considered to be clinically relevant [9].
Patient-reported outcomes
Patient-reported outcome measures were collected using validated questionnaires: the Health Utilities Index (HUI-3) [10, 11], the Abbreviated Profile of Hearing Aid Benefit (APHAB) [12, 13], and the Speech, Spatial and Qualities of Hearing Scale 12 (SSQ12) [14, 15]. HUI-3 evaluates eight health-related quality of life (QoL) dimensions (vision, hearing, speech, walking/mobility, dexterity, self-care, emotion, and cognition) and a comprehensive health state attribute. A change in global HUI-3 score of 0.03 or higher is considered clinically relevant [16]. APHAB is a hearing-related PRO instrument, which includes four subscales (ease of communication, reverberation, and background noise, aversiveness) and a global score. A change in score of higher than 10 for global score is generally regarded as clinically relevant [17]. SSQ12 is a short (12-item) version of the original 49-item SSQ questionnaire [18] that measures the self-reported auditory disability in everyday life across three subdomains (speech, spatial, and qualities of hearing). Changes of 1.0 unit or greater on SSQ subscales indicate a clinically relevant change [18]. Data between baseline and 6 months post-implantation were retrospectively collected from the previous clinical study. PRO at 12 and 24 months post-implantation were prospectively collected as part of the current study.
Patient-reported daily usage, wearing comfort, and retention were collected at all study visits after activation. Daily use communicated by the patient was reported as the average hours of daily SP use during the period preceding the visit. Comfort and retention were assessed subjectively by indicating on a visual analog scale consisting of a straight line running from 0 to 100 mm (0 mm indicated no comfort at all/insufficient retention, and 100 mm indicated the most comfortable situation imaginable/excellent retention).
Statistical analysis
Analyses were performed on all subjects enrolled in the current study. All statistical analyses were paired and nonparametric and the Friedman’s test was used to test for paired observations. All significance tests were two-tailed and performed at the 0.05 significance level. All significance values were adjusted by the Bonferroni correction for multiple tests. Statistical analysis was performed in SAS version 9.4 (SAS Institute Inc.) and IBM SPSS Statistics, version 28 (Armonk, NY: IBM Corp.). Demographics, baseline characteristics, daily use, comfort, adverse events, and device deficiencies are presented descriptively.
Results
The data of 20 subjects attending the 6-month follow-up visit in the previous study [1] who consented to participate in this extended follow-up study and attended the 12- or 24-month visit were combined and analyzed. Subject demographics can be seen in Table 1. As the study did not control for type of hearing loss, the majority had CHL or MHL (N = 17) and three with SSD. Data are presented as means and p values, where p values are presented for the sample as a whole.
Safety evaluation
Between 6- and 24-month follow-up, there were nine adverse events in six subjects that were either possibly, probably or definitely related to the device or procedure. Three of these events (pain behind implant, skin irritation, and prominence of the posterior inferior edge of system) were related to both device and procedure and six were related to the device only (discomfort from SP heating up, increased tinnitus, two reports of frustration, and two reports of non-use). The two reports of non-use were classified as moderate in severity and the remaining events were all classified as mild in severity. Figure 1 presents the cumulative adverse event rate for all related adverse events from implantation to 24-month follow-up. The majority of related adverse events occurred within the first 3 months post-implantation and the rate decreased between 3 and 24 months. All but three adverse events (two reports of non-use and one report of frustration) related to device or procedure reported in two subjects were resolved by study end.
Hearing performance
Mean change in pure-tone audiometry four frequency average (PTA4) from 6-months to 24-months follow-up was − 3.7 dB HL (SD: 5.2 dB HL, range − 5.0 to 13.8. dB HL), while the mean change in PTA4 from 6-months to the 12-month follow-up period was − 2.2 dB HL (SD: 5.1 dB HL, range − 6.3 to 13.8. dB HL). There were no statistically significant differences in paired comparisons between the 6-month follow-up and 24-month follow-up (all p values > 0.05), indicating stable improvements up to 24-month follow-up with the investigational device for subjects with MHL/CHL and those with SSD (Fig. 2). There were also statistically significant (all p-values < 0.001) improvements in PTA4 hearing thresholds between pre-implantation and all subsequent aided follow-up measurements. At the 12-month follow-up, the mean improvement in PTA4 from the unaided situation was 26.7 dB HL (SD: 7.0 dB HL, range − 43.8 to − 13.8 dB HL). At the 24-month follow-up, the mean improvement in PTA4 from the unaided situation was 25.5 dB HL (SD: 6.5 dB HL, range − 37.5 to − 12.5 dB HL).
For the adaptive speech recognition in noise test, there was no statistically significant difference when comparing the investigational device at the 12- and 24-month follow-up to the aided situation at the last performed assessment 6 months after surgery in the previous clinical study (all p values > 0.05). Mean change in SRT in noise from 6 months to the 24-month follow-up visit was -0.244 dB SNR (SD: 0.913 dB SNR, range − 1.7 to 1.4 dB SNR). While the mean change in SNR from 6-months to the 12-month follow-up period was − 0.106 dB SNR (SD: 2.726 dB SNR, range − 3.8 to 9.2 dB SNR). These results indicate stable improvements for speech recognition up to 24-month follow-up for subjects with MHL/CHL and SSD (Fig. 3). Compared to the unaided situation, the SRT in noise improved by 8.7 dB SNR (SD 7.2 dB, range − 22.5 to 0.0 dB) when aided with the Osia System at the 12-month follow-up. At the 24-month follow-up, the average improvement with the Osia System was 8.7 dB (SD: 7.2 dB, range − 21.3 to − 1.7 dB) compared to the unaided situation at baseline.
Patient-reported outcomes
Health Utilities Index-Mark 3
When comparing the investigational device at the 12- and 24-month follow-up to the aided situation at the last performed assessment 6-month post-surgery in the previous study (Table 2), no statistically significant changes were seen for any of the single-attribute utility scores or for the multi-attribute utility score (all p values > 0.05), indicating stable outcomes between 6 and 24 months. There was also no statistically significant difference when comparing single-attribute scores or multi-attribute utility score with the investigational device between fitting and 24-month follow-up (all p-values > 0.05), indicating stable improvements in HUI-3 scores up to 24-months.
Compared to the unaided listening situation before implantation, the HUI-3 multi-attribute utility score improved by 0.080 (SD 0.179, range − 0.192 to 0.329, p = 0.067) at the 12-month follow-up and by 0.028 (SD: 0.237, range − 0.41 to 0.426, p = 0.610) at the 24-month follow-up visit. HUI-3 hearing attribute score improved by 0.159 (SD 0.309, range − 0.290 to 0.710, p = 0.040) at the 12-month follow-up with the investigational device compared to the unaided situation before implantation. At the 24-month follow-up, the mean improvement in the hearing attribute score was 0.126 (SD: 0.355, range − 0.680 to 0.710, p = . 150) compared to the unaided condition prior to Osia system implantation.
Abbreviated profile of hearing aid benefit
When comparing the investigational device at the 12- and 24-month follow-up to the aided situation at the last performed assessment at the 6-month follow-up in the previous study, no statistically significant changes were seen for any of the APHAB subscale scores (all p values > 0.05) (Table 2). There was also no statistically significant difference when comparing individual subdomain scores or global APHAB score with the investigational device between sound processor fitting and 24-month follow-up (all p values > 0.05) (Table 2). This indicated stable hearing status in all APHAB subscales up to 24-month follow-up with the investigational device.
The speech, spatial and qualities of hearing scale
When comparing the investigational device at the 12- and 24-month follow-up to the aided situation at the last performed assessment at 6 months in the previous study, no statistically significant mean changes were seen for any of the SSQ scores (all p values > 0.05) (Table 2), indicating stable improvements in SSQ scores up to 24-month follow-up with the investigational device for the study cohort. SSQ global score improved by 3.14 (SD 1.74, range − 0.11 to 6.26, p = < 0.001) at the 12-month follow-up with the investigational device compared to the unaided situation, pre-implantation. At the 24-month follow-up, the mean improvement in global SSQ score was 2.53 compared to unaided listening before Osia system implantation (SD: 2.19, range − 1.13 to 6.78, p = < 0.001).
Satisfaction, battery lifetime, and device usage
At 12 months post-implant, all subjects who completed the questionnaire (N = 19) reported that they were satisfied with the implanted device. At 24 months, 18/19 subjects were either satisfied or very satisfied with the investigational device overall. One subject with MHL/CHL who was not satisfied reported that they were unsatisfied with the sound quality of the system and had stopped wearing their device. The non-user with SSD reported that they were satisfied with their device.
Battery lifetime remained stable between the 6-month and the 24-month follow-up visits. Mean battery lifetime was 24.7 h (SD: 12.9 h) at the 6-month follow-up and 23.3 h (SD: 9.2 h) at the 24-month follow-up visit.
Daily device usage was consistent from 8.2 h (SD: 4.6 h) to 8.5 h (SD: 5.2) at the 6-month and 24-month follow-up visits, respectively. Retention ratings also remained stable between 6- and 24-month follow-up (75.7/100 at 6 months and 82.8/100 at 24 months). The device comfort rating also remained stable between 6- and 24-month follow-up (86.7/100 at 6 months and 87.8/100 at 24 months).
Discussion
This cohort of adults implanted with the Osia 2 System was followed up over a 24-month period. Audiological outcomes, PROs and safety data collected throughout this extended follow-up study demonstrated that the implant system remains safe and that it continues to provide clinically important longer term aural habilitation/rehabilitation for subjects with MHL/CHL or SSD.
Safety outcomes
The acceptable low rate of adverse events reported in this study is also in line with a recent evidence synthesis of adverse event rates for active bone-conduction hearing implant systems, including the Osia System [19]. Events reported during the 24-month follow-up (N = 19) were classified as mild or moderate. It was apparent that the rate of adverse events decreased markedly after the initial 3–6-month follow-up period post-implantation and that this continued to decrease with time. Rates of adverse events in studies with limited follow-up (i.e., ≤ 6 months) may therefore not be useful to model complication rates over the longer term and may lead to an overestimation of complication rates. These data can be used to inform counseling and future cost-effectiveness modeling with active bone-conduction hearing implants. Regarding the two subjects who had stopped using their device regularly, one retired subject with SSD did not feel the need for the Osia device due to social isolation during COVID-19 restrictions. Non-compliance rates with bone-conduction hearing implants are typically higher in subjects with SSD compared to those with MHL/CHL [20]. The other non-user with CHL/MHL was unhappy with the sound quality of the device after fitting and remained a non-user, highlighting the importance of patient-centered counseling, rehabilitation, and managing post-operative expectations.
Audiometric and quality of life benefits
The extended follow-up data confirmed that most patients continue using their Osia System and remain satisfied with the device. Importantly, the clinically relevant improvements in audiometric thresholds (including at higher frequencies), speech reception thresholds in noise, and health-related QoL reported in the previous study [1] remained stable during this 24-month follow-up study. These findings are echoed in an additional study in which Osia System recipients were followed for at least 12 months [21]. Results of the SSQ and HUI questionnaires in this study improved with longer Osia System experience and aided hearing thresholds and speech recognition in quiet were also significantly improved in comparison to the unaided situation [21]. The clinical benefits experienced with the Osia System soon after fitting are therefore expected to remain over the longer term.
Strengths and limitations
The strength of this study is that it overcomes a previous limitation regarding the paucity of longer term follow-up data with the Osia System. The study was also focused on patient safety and had rigorous safety follow-up, ensuring that all adverse events were captured. Regarding limitations, the study cohort is relatively small, and the number of subjects with SSD prevented a sub-analysis being performed for this subgroup. However, there are published data available demonstrating the safety and efficacy of the Osia System in this population [2]. As seen for subjects with MHL/CHL, we would also expect the benefits observed after short-term observation to remain stable for those with SSD, as observed for a small cohort of subjects with SSD and extended follow-up [21]. Studies are now emerging that compare outcomes for hearing-impaired subjects implanted with active and passive bone-conduction systems [22]. Additional studies with larger patient numbers are required to truly capture the benefits of the system in comparison with other bone-conduction hearing implant systems.
Conclusion
Extended follow-up data collected as part of this clinical study demonstrate that the Osia 2 System remains a safe and effective treatment for individuals with CHL/MHL or SSD over time. Hearing and patient-reported outcomes remained stable from fitting of the SP to 24 months post-implantation. Importantly, the majority of recipients continued to use and benefit from the daily use of the Osia System.
Data availability
Aggregated, anonymized study data will be made available upon reasonable request by contacting the corresponding author.
References
Briggs R et al (2022) Clinical performance, safety, and patient-reported outcomes of an active osseointegrated steady-state implant system. Otol Neurotol 43(7):827–834
Willenborg K et al (2022) A new active osseointegrated implant system in patients with single-sided deafness. Audiol Neurootol 27(1):83–92
Goycoolea M, et al (2020) Clinical performance of the Osia™ system, a new active osseointegrated implant system. Results from a prospective clinical investigation. Acta Otolaryngol 140(3): 212–219
Florentine MM, Virbalas J, Chan DK (2022) Early surgical and audiologic outcomes of active, transcutaneous, osseointegrated bone-conduction hearing device (Osia 2® system) placement. Int J Pediatr Otorhinolaryngol 156:111114
Lau K et al (2020) First United Kingdom experience of the novel Osia active transcutaneous piezoelectric bone conduction implant. Eur Arch Otorhinolaryngol 277(11):2995–3002
World Medical Association Declaration of Helsinki (2013) ethical principles for medical research involving human subjects. JAMA 310(20):2191–2194
Singh K (2022) ISO 14155: clinical investigation of medical devices for human subjects. Medical device guidelines and regulations handbook. Springer, pp 1–18
Stuart A et al (1991) Test–retest variability in audiometric threshold with supraaural and insert earphones among children and adults. Audiology 30(2):82–90
McShefferty D, Whitmer WM, Akeroyd MA (2015) The just-noticeable difference in speech-to-noise ratio. Trends Hear 19.
Feeny D et al (2002) Multiattribute and single-attribute utility functions for the health utilities index mark 3 system. Med Care 40(2):113–128
Mok WKY et al (2014) Validation and application of health utilities index in Chinese subjects with down syndrome. Health Qual Life Outcomes 12(1):144
Cox RM, Alexander GC (1995) The abbreviated profile of hearing aid benefit. Ear Hear 16(2):176–186
Kam AC, Tong MC, van Hasselt A (2011) Cross-cultural adaptation and validation of the Chinese abbreviated profile of hearing aid benefit. Int J Audiol 50(5):334–339
Noble W et al (2013) A short form of the Speech, Spatial and Qualities of Hearing scale suitable for clinical use: the SSQ12. Int J Audiol 52(6):409–412
Ou H et al (2016) Validation of the chinese translation of the spatial hearing questionnaire and its short form. Am J Audiol 25(1):25–33
Horsman J et al (2003) The Health Utilities Index (HUI): concepts, measurement properties and applications. Health Qual Life Outcomes 1:54
Cox RM (1997) Administration and application of the APHAB. Hearing J 50(4): 32, 35–36, 38, 40–41, 44–45, 48
Gatehouse S, Noble W (2004) The speech, spatial and qualities of hearing scale (SSQ). Int J Audiol 43(2):85–99
Ray J, et al (2023) Evaluating the effectiveness of bone conduction hearing implants in rehabilitation of hearing loss. Eur Arch Otorhinolaryngol:1–10.
Han JJ et al (2020) A comparison study of audiological outcome and compliance of bone conduction implantable hearing implants. Eur Arch Otorhinolaryngol 277(11):3003–3012
Rauch A-K et al (2022) Long-term data of the new transcutaneous partially implantable bone conduction hearing system Osia®. Eur Arch Otorhinolaryngol 279(9):4279–4288
Szabo L, et al (2022) Baha Attract-to-Osia conversion patients: comparison of the two systems and long term outcomes. J Laryngol Otol:1–22.
Acknowledgements
The authors would like to thank Rachelle Hassarati, Nick Baulderstone, Ashni Perera, and WaiKong Lai for their contributions to the work conducted at NextSense (formerly SCIC/RIDBC) Sydney; and Dr. Jeanmarc Gerard, Dr Claire Iseli, Alex Rousset, Sylvia Tari, and Evelyn Do for their contributions to the work conducted at The Royal Victorian Eye and Ear Hospital Melbourne; and Adrienne Paterson at HEARnet Melbourne. The authors would also like to thank statistician Mattias Molin and team at Statistiska Konsultgruppen for their support with statistical analysis, and the patients and additional clinicians for their participation in the study.
Funding
Open Access funding enabled and organized by CAUL and its Member Institutions
Author information
Authors and Affiliations
Contributions
All study authors critically reviewed the manuscript for important intellectual content and approved the final work for publication. Individual author contributions: RB; study design and data acquisition. ATL; study design and manuscript preparation, CH; study design. MCFT; study design and data acquisition. RC, study design and data acquisition. IHYN; data acquisition. CSB; study design and data acquisition.
Corresponding author
Ethics declarations
Declarations
This clinical study was sponsored by Cochlear Limited, a manufacturer and supplier of implantable hearing devices. ATL and CH are employees of Cochlear Limited, a manufacturer and supplier of implantable hearing devices.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Cowan, R., Lewis, A.T., Hallberg, C. et al. Clinical performance, safety, and patient-reported outcomes of an active osseointegrated bone-conduction hearing implant system at 24-month follow-up. Eur Arch Otorhinolaryngol 281, 683–691 (2024). https://doi.org/10.1007/s00405-023-08133-3
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00405-023-08133-3