Hostname: page-component-586b7cd67f-dsjbd Total loading time: 0 Render date: 2024-11-23T22:16:42.688Z Has data issue: false hasContentIssue false

Complications of cochlear implants: a MAUDE database study

Published online by Cambridge University Press:  06 June 2023

S Jinka
Affiliation:
Northeast Ohio Medical University, Rootstown, Ohio, USA
S Wase
Affiliation:
Northeast Ohio Medical University, Rootstown, Ohio, USA
A Jeyakumar*
Affiliation:
Northeast Ohio Medical University, Rootstown, Ohio, USA Department of Otolaryngology, Mercy Bon Secours, Youngstown, Ohio, USA
*
Corresponding author: Dr A Jeyakumar; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective

A retrospective cross-sectional analysis was conducted of the US Food and Drug Administration's MAUDE (Manufacturer and User Facility Device Experience) database, to evaluate the complication profile of cochlear implantation according to manufacturer.

Methods

A review of the MAUDE database was conducted from 1 January 2010 to 31 December 2020. Complications, including infection, extrusion, facial nerve stimulation, meningitis and cerebrospinal fluid leak, were identified using key word searches. The categorised data were analysed using a chi-square test to determine a difference in global complication incidence between three major cochlear implant manufacturers: manufacturer A (Cochlear Limited), manufacturer B (Med-El) and manufacturer C (Advanced Bionics).

Results

A total of 31 857 adverse events were analysed. Implants of manufacturer C were associated with a statistically higher rate of infection (0.97 per cent), cerebrospinal fluid leak (0.07 per cent), extrusion (0.44 per cent) and facial nerve stimulation (0.11 per cent). Implants of manufacturer B were associated with a statistically higher rate of meningitis (0.07 per cent).

Conclusion

Consideration of patient risk factors along with cochlear implant manufacturers can heighten awareness of cochlear implant complications pre-operatively, intra-operatively and post-operatively.

Type
Main Article
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of J.L.O. (1984) LIMITED

Introduction

The World Health Organization reports a rise in the rate of hearing loss, with 466 million people living with disabling hearing loss worldwide.1 The cochlear implant is a cornerstone option of hearing loss management in patients whose management needs are greater than can be met by traditional hearing aids.Reference Ferguson, Kitterick, Chong, Edmondson-Jones, Barker and Hoare2,Reference McRackan, Bauschard, Hatch, Franko-Tobin, Droghini and Nguyen3 With over 500 000 recipients of cochlear implant devices to date, an analysis of the complications will further quantify the risks of cochlear implant surgery. Understanding the potential risks of cochlear implants is important for patient informed consent and for surgeons to appropriately educate patients about post-operative complications.Reference Mulsow, Feeley and Tierney4

The US Food and Drug Administration's MAUDE (Manufacturer and User Facility Device Experience) database mandates the reporting of complications that lead to ‘death and serious injury’ by manufacturers, importers and device user facilities.5 Recent analyses of the MAUDE database, conducted in 2005 and 2013, revealed trends of cochlear implant complications. The 2005 study revealed spontaneous device failure as the largest contributor to device failure.Reference Tambyraja, Gutman and Megerian6 The 2013 study reported a statistically significant increase in ‘idiopathic performance decrement’ and ‘idiopathic loss of lock’ from 2000 to 2010. This article categorised cochlear implant complications into device malfunction (software or hardware) and patient injury (infection, meningitis, cerebrospinal fluid (CSF) leaks or facial nerve stimulation).Reference Causon, Verschuur and Newman7

Our study aimed to analyse the hardware-related complications of cochlear implants in the past decade. We will do this by reporting the rate of infection, extrusion, facial nerve stimulation, meningitis and CSF leak, from 2010 to 2020, as conveyed to the MAUDE database. We will also investigate the three main manufacturers of cochlear implants and determine any variations between the companies.

Materials and methods

An institutional review board exempt status for the study was obtained from Mercy Health (Youngstown, Ohio, USA).

MAUDE database compilation

We accessed adverse event reports from the MAUDE database for all devices manufactured by manufacturer A (Cochlear Limited, Sydney, Australia), manufacturer B (Med-El, Innsbruck, Austria) and manufacturer C (Advanced Bionics, Valencia, California, USA), with report dates between 1 January 2010 and 30 December 2020. From these records, we included cochlear implant reports and excluded those related to bone conduction implants.

Key word search

Records were filtered by key words to search for the presence of certain variables. Specific key word searches were: ‘extru’ for extrusions, ‘meningitis’ for meningitis, ‘infection’ for infection, ‘facial nerve stimul’ for facial nerve stimulation and ‘CSF leak’ for CSF leaks. Key word searches were controlled for false negatives and false positives, such as ‘nerve stimulation not reported’ or ‘no infection present’. We randomly evaluated 10 per cent of reports following the key word search to reaffirm event classifications, and calculated an acceptable error rate of less than 0.1 per cent in our search process.

Total device sample size determination

The Cochlear Limited Annual Report from 2020 was used to determine the total number of cochlear devices implanted by manufacturer A from 2010 to 2020. This number (312 011) was compared with publicly available global market share data from multiple sources in order to extrapolate estimates of the total number of devices implanted between 2010 and 2020.8,9 Specifically, the global market share of manufacturer A, B, and C was estimated to be 55, 20 and 20 per cent, respectively. The total number of implanted devices was accordingly extrapolated to be 312 011, 113 459 and 113 459 for manufacturers A, B and C, respectively. The number of complications from the key word search (described above) was divided by each respective data point to determine the estimated global rate of each complication per manufacturer.

Statistical methods

Records were evaluated with chi-square tests to determine whether a difference in complication rate for each variable existed between the three manufacturers. A chi-square test was also run comparing the rate of meningitis to the rate of CSF leak, regardless of manufacturer. For all analyses, a Bonferroni corrected p-value of less than 0.008 was used to determine significance.

Results

General findings

A total of 32 785 adverse event reports were obtained for analysis. After selecting only cochlear implant related reports, 31 857 reports were available for analysis. Of these reports, 15 953 (50.0 per cent) concerned manufacturer A devices, 8266 (25.9 per cent) related to manufacturer B devices and 7683 (24.1 per cent) involved manufacturer C devices. In our 10-year study period, a total of 538 929 cochlear implants have been sold globally based on market share extrapolation. Further, 312 011 manufacturer A devices were estimated to have been implanted in the same period as 113 459 devices for manufacturers B and C each. The total complication rate for cochlear implantation in the past 10 years is 5.91 per cent. Overall, 3836 cochlear implant recipients (0.71 per cent) experienced infection, 1819 (0.34 per cent) extrusion, 421 (0.08 per cent) facial nerve stimulation, 248 (0.05 per cent) meningitis and 169 (0.03 per cent) experienced CSF leak (Table 1). There was no demographic information (e.g. age, sex, race) provided by the database for analysis.

Table 1. Classification of adverse events

CSF = cerebrospinal fluid

Infection by manufacturer

Manufacturer C had the statistically highest rate of reported infections (p < 0.008) of 0.97 per cent (n = 1097), followed by manufacturer A with 0.79 per cent (n = 2472) and manufacturer B with 0.24 per cent (n = 267) (Fig. 1).

Figure 1. Incidence of complications by manufacturer. CSF = cerebrospinal fluid

Extrusion by manufacturer

Manufacturer C had the statistically highest rate of device or electrode extrusion (p < 0.008) of 0.44 per cent (n = 500), followed by manufacturer A with 0.37 per cent (n = 1165) and manufacturer B with 0.13 per cent (n = 152) (Fig. 1).

Facial nerve stimulation by manufacturer

Manufacturer C had the statistically highest rate of facial nerve stimulation (p < 0.008) of 0.11 per cent (n = 123), followed by manufacturer A with 0.07 per cent (n = 230) and manufacturer B with 0.06 per cent (n = 69) (Fig. 1).

Meningitis by manufacturer

Manufacturer B had the statistically highest rate of reported meningitis (p < 0.008) of 0.07 per cent (n = 83), followed by manufacturer A with 0.04 per cent (n = 120) and manufacturer C with 0.04 per cent (n = 45) (Fig. 1).

Cerebrospinal fluid leak by manufacturer

Manufacturer C had the statistically highest rate of reported CSF leaks (p < 0.008) of 0.07 per cent (n = 84), followed by manufacturer A with 0.02 per cent (n = 61) and manufacturer B with 0.02 per cent (n = 24) (Fig. 1).

Cerebrospinal fluid leak versus meningitis

It was shown that those patients with a CSF leak were significantly (p < 0.008) more likely to have meningitis than those without a CSF leak, with 35.50 per cent (n = 60) of patients with CSF leaks having meningitis (Fig. 2a) versus 0.59 per cent (n = 188) of patients without CSF leak having meningitis (Fig. 2b).

Figure 2. Patients with (a) and without (b) cerebrospinal fluid leaks.

Discussion

Our data demonstrated that infection (0.71 per cent) and extrusion (0.34 per cent) were the two most reported complications, in comparison to facial nerve stimulation (0.08 per cent), meningitis (0.05 per cent) and CSF leak (0.03 per cent). Our results also revealed the distribution of complications between manufacturers. Manufacturer C had a statistically greater rate of infection, extrusion, facial nerve stimulation and CSF leaks, and manufacturer B had a statistically greater rate of meningitis. These findings may indicate over-reporting of complications of manufacturer C's cochlear implants, but, nonetheless, the data are clinically relevant for determining complications associated with the products of each device manufacturer.

Infection is a commonly reported complication of cochlear implants. The infection rate in cochlear implant recipients ranges from 1.4 per cent to 8.2 per cent, based on the most recent literature.Reference Vila, Ghogomu, Odom-John, Hullar and Hirose10,Reference Ciorba, Bovo, Trevisi, Rosignoli, Aimoni and Castiglione11 Common infections in cochlear implant recipients include skin infections, labyrinthitis, acute otitis media and mastoiditis.Reference Farinetti, Gharbia, Mancini, Roman, Nicollas and Triglia12 Biofilm formation is a predisposing factor for antibiotic-resistant infection in cochlear implant recipients.Reference Costerton, Montanaro and Arciola13Reference Macassey and Dawes15 Some risk factors for post-operative infection include a history of chronic ear infectionsReference Cunningham, Slattery and Luxford16 and younger age.Reference Rubin and Papsin17,Reference Kempf, Stöver and Lenarz18 Manufacturer C had the statistically highest rate of infection based on our data. If cochlear implantation is undertaken, Vijendren et al. (2019) suggest the use of intra-operative prophylactic antibiotics, to prevent infections.Reference Vijendren, Borsetto, Barker, Manjaly, Tysome and Axon19 However, there is no uniform protocol for preventing infection. The infection rate in our study is lower than previously reported infection rates.

Implant extrusion is one of the most common complications of cochlear implants.Reference Geraghty, Fagan and Moisidis20 The rate of extrusion may be under-recognised.Reference Vaid, Roland and Vaid21 There are multiple predisposing factors, including cochlear ossification,Reference Connell, Balkany, Hodges, Telischi, Angeli and Eshraghi22 adhesions, trauma, infection,Reference Vaid, Roland and Vaid21 and growth of head circumference in children.Reference Brown, Connell, Balkany, Eshraghi, Telischi and Angeli23 In the MAUDE database, extrusion can be secondary to electrode migration or cutaneous extrusion of the stimulator or receiver (these were not differentiated). Gatto et al. (2021) postulated that cochlear implant extrusion can be prevented by a surgical technique to fix the receiver/stimulator.Reference Gatto, Tofanelli, Piccinato, Antonio, Zucchini and Achilli24 Vaid et al. (2011) published data suggesting that perimodiolar electrodes have a lower rate of extrusion.Reference Vaid, Roland and Vaid21 Further study of the cochlear implants could explain a relationship between electrode type and extrusion rate.

Aberrant facial nerve stimulation is a known complication of cochlear implants. A retrospective chart review reported that 14 per cent of patients experienced facial nerve stimulation following cochlear implantation of devices from manufacturers A, B and C.Reference Bigelow, Kay, Rafter, Montes, Knox and Yousem25 The most stimulated segment of the facial nerve is the labyrinthine segment.Reference Bigelow, Kay, Rafter, Montes, Knox and Yousem25 Some risk factors for facial nerve stimulation cited in the literature include otosclerosis, and lateral wall electrodes as opposed to perimodiolar electrodes.Reference Bigelow, Kay, Rafter, Montes, Knox and Yousem25,Reference Van Horn, Hayden and Mahairas26 Our study demonstrated an overall rate of reported facial nerve stimulation of 0.08 per cent, considerably lower than previously reported in the literature.

Cerebrospinal fluid leaks and meningitis are less commonly reported complications of cochlear implants. However, they lead to elevated levels of morbidity and mortality.Reference Wei, Shepherd, Robins-Browne, Clark and O'Leary27 A retrospective chart review of 523 cochlear implant recipients found that 2.87 per cent of patients had a CSF leak, 80 per cent of whom had inner-ear malformations.Reference Eftekharian and Amizadeh28 Other retrospective chart reviews have cited inner-ear malformations as a risk factor for CSF leaks in paediatric and adult populations.Reference Melo, Martins, Silva, Quadros and Paiva29,Reference Aldhafeeri and Alsanosi30 Other anatomical variations, such as stapes footplate defectsReference Vartanyan, Hill, Orimoto and O'Leary31 and air–bone gapsReference Attias, Ulanovski, Shemesh, Kornreich, Nageris and Preis32 predisposed cochlear implant recipients to CSF leaks. ObesityReference Nelson, Hansen, Gantz and Hansen33 and X-linked deafnessReference Saeed, Powell and Saeed34 have also been cited as risk factors for CSF leaks. Although meningitis is a rare complication, there is a greater rate of meningitis in cochlear implant recipients compared to their age-matched cohort of the general population.Reference Wei, Shepherd, Robins-Browne, Clark and O'Leary27 Certain factors increase the risk of meningitis. Stapes footplate defectsReference Vartanyan, Hill, Orimoto and O'Leary31 and CSF leaksReference Ter Horst, Brouwer, van der Ende and van de Beek35 are risk factors in the development of meningitis in cochlear implant recipients. Our study results suggest that CSF leaks present with meningitis with greater frequency than meningitis without CSF leaks. Our study also demonstrated low rates for both meningitis, at 0.05 per cent, and CSF leaks, at 0.03 per cent. The meningitis risk can be reduced with a non-traumatic design, an adequate fibrous seal around the cochleostomy site, and proper surgical technique.Reference Wei, Shepherd, Robins-Browne, Clark and O'Leary27,Reference Mancini, D'Elia, Bosco, De Seta, Panebianco and Vergari36

  • Cochlear implantation is an option for hearing loss management; over 500 000 devices were implanted over the past 10 years

  • There have been no MAUDE database studies after 2013 examining cochlear implant complications; this study analysed complications in the past decade

  • The study reported rates of infection, extrusion, facial nerve stimulation, meningitis and cerebrospinal fluid (CSF) leaks for 2010–2020, as reported in the MAUDE database

  • It investigated the three main cochlear implant manufacturers and any variations in reported complication rates

  • Manufacturer C had higher rates of infection, CSF leak, extrusion and facial nerve stimulation; manufacturer B had a higher rate of meningitis

  • Consideration of patient risk factors and cochlear implant manufacturers can heighten awareness of cochlear implant complications

Limitations

Our study used global market share data to extrapolate the total number of implanted devices sold by each manufacturer. However, variation between manufacturer reporting limited reliability. Furthermore, we did not consider implants manufactured by smaller companies including Neurelec (Vallauris, France) and Oticon (Copenhagen, Denmark).

Another limitation is that MAUDE database reports are overwhelmingly US-based, suggesting our manufacturer-specific complication rates are not an accurate global representation. Our attempts to reach out to manufacturers for data were met with resistance. We hope that this study will encourage manufacturers to share more market data in the future in order to encourage transparent post-market surveillance.

Finally, some details are missing from the MAUDE database, including vaccination status, surgical technique, patient demographic information, duration of implantation, and the presence of any underlying anatomical abnormalities. Additionally, the MAUDE database relies on a combination of mandatory and voluntary reporters, such as healthcare professionals, patients and consumers, which can confound reliability. Nonetheless, the MAUDE database remains one of the only databases for the analysis of device-related complications, and has been employed for previous analyses within and outside the field of otolaryngology.Reference Gurtcheff3742

Conclusion

Our study compared cochlear implant complications between the three major manufacturers over a 10-year period utilising the MAUDE database. Our research does not show a clearly superior manufacturer in cochlear implantation. Further research with more co-operation from manufacturers is needed to investigate the mechanisms behind, and true global incidence of, these complications. We encourage manufacturers of cochlear implants to work more willingly with researchers in the future in order to conduct this type of analysis. Taken together, alongside careful analysis of patient history and anatomy, this study can aid providers in anticipating complications of cochlear implants, while laying the groundwork for future post-market cochlear implant studies.

Competing interests

None declared.

Footnotes

Dr A Jeyakumar takes responsibility for the integrity of the content of the paper

Some of the data were presented at the American Academy of Otolaryngology–Head and Neck Surgery Foundation Annual Meeting, 3–6 October 2021, Los Angeles, California, USA.

References

Estimates – World Health Organization. In: https://www.who.int/health-topics/hearing-loss#tab=tab_1 [16 July 2018]Google Scholar
Ferguson, M, Kitterick, P, Chong, L, Edmondson-Jones, M, Barker, F, Hoare, D. Hearing aids for mild to moderate hearing loss in adults. Cochrane Database Syst Rev 2017;2017:CD012023Google Scholar
McRackan, T, Bauschard, M, Hatch, J, Franko-Tobin, E, Droghini, H, Nguyen, S et al. Meta-analysis of quality-of-life improvement after cochlear implantation and associations with speech recognition abilities. Laryngoscope. 2018;128(suppl 4):982–90CrossRefGoogle ScholarPubMed
Mulsow, J, Feeley, T, Tierney, S. Beyond consent-improving understanding in surgical patients. Am J Surg 2012;203:112–20CrossRefGoogle ScholarPubMed
MAUDE – Manufacturer and User Facility Device Experience. In: https://www.accessdata.fda.gov/scripts/cdrh/cfdocs/cfmaude/search.cfm [28 June 2023]Google Scholar
Tambyraja, R, Gutman, M, Megerian, C. Cochlear implant complications: utility of federal database in systematic analysis. Arch Otolaryngol Head Neck Surg 2005;131:245–50CrossRefGoogle ScholarPubMed
Causon, A, Verschuur, C, Newman, T. Trends in cochlear implant complications: implications for improving long-term outcomes. Otol Neurotol 2013;34:259–65CrossRefGoogle ScholarPubMed
Vila, P, Ghogomu, N, Odom-John, A, Hullar, T, Hirose, K. Infectious complications in pediatric cochlear implants. Laryngoscope 2007;117:1825–9Google Scholar
Ciorba, A, Bovo, R, Trevisi, P, Rosignoli, M, Aimoni, C, Castiglione, A et al. Postoperative complications in cochlear implants: a retrospective analysis of 438 consecutive cases. Eur Arch Otorhinolaryngol 2012;269:1599–603CrossRefGoogle ScholarPubMed
Farinetti, A, Gharbia, B, Mancini, J, Roman, S, Nicollas, R, Triglia, J. Cochlear implant complications in 403 patients: comparative study of adults and children and review of the literature. Eur Ann Otorhinolaryngol Head Neck Dis 2014;131:177–82CrossRefGoogle ScholarPubMed
Costerton, J, Montanaro, L, Arciola, C. Biofilm in implant infections: its production and regulation. Int J Artif Organs 2005;28:1062–8CrossRefGoogle ScholarPubMed
Vaid, N, Vaid, S, Manikoth, M. Case report – biofilm infection of a cochlear implant. Cochlear Implants Int 2013;14:117–20CrossRefGoogle ScholarPubMed
Macassey, E, Dawes, P. Biofilms and their role in otorhinolaryngological disease. J Laryngol Otol 2008;122:1273–8CrossRefGoogle ScholarPubMed
Cunningham, CD, Slattery, WH, Luxford, WM. Postoperative infection in cochlear implant patients. Otolaryngol Head Neck Surg 2004;131:109–14CrossRefGoogle ScholarPubMed
Rubin, LG, Papsin, B; Committee on Infectious Diseases and Section on Otolaryngology-Head and Neck Surgery. Cochlear implants in children: surgical site infections and prevention and treatment of acute otitis media and meningitis. Pediatrics 2010;126:381–91CrossRefGoogle ScholarPubMed
Kempf, HG, Stöver, T, Lenarz, T. Mastoiditis and acute otitis media in children with cochlear implants: recommendations for medical management. Ann Otol Rhinol Laryngol Suppl 2000;185:25–7CrossRefGoogle ScholarPubMed
Vijendren, A, Borsetto, D, Barker, E, Manjaly, J, Tysome, J, Axon, P et al. A systematic review on prevention and management of wound infections from cochlear implantation. Clin Otolaryngol 2019;44:1059–70CrossRefGoogle ScholarPubMed
Geraghty, M, Fagan, P, Moisidis, E. Management of cochlear implant device extrusion: case series and literature review. J Laryngol Otol 2014;128(suppl 2):S55–8CrossRefGoogle ScholarPubMed
Vaid, N, Roland, J, Vaid, S. Extracochlear electrode extrusion. Cochlear Implants Int 2011;12:177–80CrossRefGoogle ScholarPubMed
Connell, S, Balkany, T, Hodges, A, Telischi, F, Angeli, S, Eshraghi, A. Electrode migration after cochlear implantation. Otol Neurotol 2008;29:156–9CrossRefGoogle ScholarPubMed
Brown, K, Connell, S, Balkany, T, Eshraghi, A, Telischi, F, Angeli, S. Incidence and indications for revision cochlear implant surgery in adults and children. Laryngoscope 2009;119:152–7CrossRefGoogle ScholarPubMed
Gatto, A, Tofanelli, M, Piccinato, A, Antonio, J, Zucchini, S, Achilli, V et al. Cochlear implant surgery: how to fix receiver/stimulator avoiding extrusion. Ear Nose Throat J 2021;100(3 suppl):212–14SCrossRefGoogle ScholarPubMed
Bigelow, D, Kay, D, Rafter, K, Montes, M, Knox, G, Yousem, D. Facial nerve stimulation from cochlear implants. Am J Otol 1998;19:163–9Google ScholarPubMed
Van Horn, A, Hayden, C, Mahairas, A. Factors influencing aberrant facial nerve stimulation following cochlear implantation: a systematic review and meta-analysis. Otol Neurotol 2020;41:1050–9CrossRefGoogle ScholarPubMed
Wei, B, Shepherd, R, Robins-Browne, R, Clark, G, O'Leary, S. Pneumococcal meningitis post-cochlear implantation: preventative measures. Otolaryngol Head Neck Surg 2010;143(5 suppl 3):S914CrossRefGoogle ScholarPubMed
Eftekharian, A, Amizadeh, M. Cerebrospinal fluid gusher in cochlear implantation. Cochlear Implants Int 2014;15:179–84CrossRefGoogle ScholarPubMed
Melo, A, Martins, J, Silva, J, Quadros, J, Paiva, A. Cochlear implantation in children with anomalous cochleovestibular anatomy. Auris Nasus Larynx 2017;44:509–16CrossRefGoogle ScholarPubMed
Aldhafeeri, A, Alsanosi, A. Management of surgical difficulties during cochlear implant with inner ear anomalies. Int J Pediatr Otorhinolaryngol 2017;92:45–9CrossRefGoogle ScholarPubMed
Vartanyan, M, Hill, F, Orimoto, K, O'Leary, S. Stapes footplate defect as a source of CSF leak and otogenic meningitis in a patient with a cochlear implant. Ear Nose Throat J 2018;97:E31–2CrossRefGoogle Scholar
Attias, J, Ulanovski, D, Shemesh, R, Kornreich, L, Nageris, B, Preis, M et al. Air-bone gap component of inner-ear origin in audiograms of cochlear implant candidates. Otol Neurotol 2012;33:512–17CrossRefGoogle ScholarPubMed
Nelson, R, Hansen, K, Gantz, B, Hansen, M. Calvarium thinning in patients with spontaneous cerebrospinal fluid leak. Otol Neurotol 2015;36:481–5CrossRefGoogle ScholarPubMed
Saeed, H, Powell, H, Saeed, S. Cochlear implantation in X-linked deafness – how to manage the surgical challenges. Cochlear Implants Int 2016;17:178–83CrossRefGoogle ScholarPubMed
Ter Horst, L, Brouwer, MC, van der Ende, A, van de Beek, D. Community-acquired bacterial meningitis in adults with cerebrospinal fluid leakage. Clin Infect Dis 2020;70:2256–61CrossRefGoogle ScholarPubMed
Mancini, P, D'Elia, C, Bosco, E, De Seta, E, Panebianco, V, Vergari, V et al. Follow-up of cochlear implant use in patients who developed bacterial meningitis following cochlear implantation. Laryngoscope 2008;118:1467–71CrossRefGoogle ScholarPubMed
Gurtcheff, S. Introduction to the MAUDE database. Clin Obstet Gynecol 2008;51:120–3CrossRefGoogle Scholar
Gurtcheff, S, Sharp, H. Complications associated with global endometrial ablation: the utility of the MAUDE database. Obstet Gynecol 2003;102:1278–82Google ScholarPubMed
Tremaine, A, Avram, M. FDA MAUDE data on complications with lasers, light sources, and energy-based devices. Lasers Surg Med 2015;47:133–40CrossRefGoogle ScholarPubMed
Abi-Rafeh, J, Safran, T, Al-Halabi, B, Dionisopolous, T. Death by implants: critical analysis of the FDA-MAUDE database on breast implant-related mortality. Plast Reconstr Surg Glob Open 2019;7:e2554CrossRefGoogle ScholarPubMed
Raz, Y. The utility of the MAUDE database in researching cochlear implantation complications. Arch Otolaryngol Head Neck Surg 2005;131:251CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Classification of adverse events

Figure 1

Figure 1. Incidence of complications by manufacturer. CSF = cerebrospinal fluid

Figure 2

Figure 2. Patients with (a) and without (b) cerebrospinal fluid leaks.