Predicting Acoustic Hearing Preservation Following Cochlear Implant Surgery Using Machine Learning

Daniel M Zeitler; Quinlan D Buchlak; Savindi Ramasundara; Farrokh Farrokhi; Nazanin Esmaili

doi:10.1002/lary.30894

Predicting Acoustic Hearing Preservation Following Cochlear Implant Surgery Using Machine Learning

Laryngoscope. 2024 Feb;134(2):926-936. doi: 10.1002/lary.30894. Epub 2023 Jul 14.

Authors

Daniel M Zeitler^{1

2}, Quinlan D Buchlak^{3

4}, Savindi Ramasundara³, Farrokh Farrokhi^{1

5}, Nazanin Esmaili^{3

6}

Affiliations

¹ Neuroscience Institute, Virginia Mason Franciscan Health, Seattle, Washington, USA.
² Department of Otolaryngology-Head Neck Surgery, Section of Otology/Neurotology, Virginia Mason Franciscan Health, Seattle, Washington, USA.
³ School of Medicine, University of Notre Dame Australia, Sydney, New South Wales, Australia.
⁴ Department of Neurosurgery, Monash Health, Melbourne, Victoria, Australia.
⁵ Department of Neurosurgery, Virginia Mason Franciscan Health, Seattle, Washington, USA.
⁶ Faculty of Engineering and Information Technology, University of Technology Sydney, Sydney, New South Wales, Australia.

PMID: 37449725
DOI: 10.1002/lary.30894

Abstract

Objectives: The aim of the study was to train and test supervised machine-learning classifiers to predict acoustic hearing preservation after CI using preoperative clinical data.

Study design: Retrospective predictive modeling study of prospectively collected single-institution CI dataset.

Methods: One hundred and seventy-five patients from a REDCap database including 761 patients >18 years who underwent CI and had audiometric testing preoperatively and one month after surgery were included. The primary outcome variable was the lowest quartile change in acoustic hearing at one month after CI using various formulae (standard pure tone average, SPTA; low-frequency PTA, LFPTA). Analysis involved applying multivariate logistic regression to detect statistical associations and training and testing supervised learning classifiers. Classifier performance was assessed with numerous metrics including area under the receiver operating characteristic curve (AUC) and Matthews correlation coefficient (MCC).

Results: Lowest quartile change (indicating hearing preservation) in SPTA was positively associated with a history of meningitis, preoperative LFPTA, and preoperative SPTA. Lowest quartile change in SPTA was negatively associated with sudden hearing loss, noise exposure, aural fullness, and abnormal anatomy. Lowest quartile change in LFPTA was positively associated with preoperative LFPTA. Lowest quartile change in LFPTA was negatively associated with tobacco use. Random forest demonstrated the highest mean classification performance on the validation dataset when predicting each of the outcome variables.

Conclusions: Machine learning demonstrated utility for predicting preservation of residual acoustic hearing in patients undergoing CI surgery, and the detected associations facilitated the interpretation of our machine-learning models. The models and statistical associations together may be used to facilitate improvements in shared clinical decision-making and patient outcomes.

Level of evidence: 3 Laryngoscope, 134:926-936, 2024.

Keywords: artificial intelligence; cochlear implant; machine learning; predictive value of tests; sensorineural hearing loss.

MeSH terms

Acoustics
Audiometry, Pure-Tone
Cochlear Implantation*
Cochlear Implants*
Hearing
Humans
Machine Learning
Retrospective Studies
Treatment Outcome