Scientific Reports (Jun 2024)

A multi-institutional machine learning algorithm for prognosticating facial nerve injury following microsurgical resection of vestibular schwannoma

  • Sabrina M. Heman-Ackah,
  • Rachel Blue,
  • Alexandra E. Quimby,
  • Hussein Abdallah,
  • Elizabeth M. Sweeney,
  • Daksh Chauhan,
  • Tiffany Hwa,
  • Jason Brant,
  • Michael J. Ruckenstein,
  • Douglas C. Bigelow,
  • Christina Jackson,
  • Georgios Zenonos,
  • Paul Gardner,
  • Selena E. Briggs,
  • Yale Cohen,
  • John Y. K. Lee

DOI
https://doi.org/10.1038/s41598-024-63161-1
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 9

Abstract

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Abstract Vestibular schwannomas (VS) are the most common tumor of the skull base with available treatment options that carry a risk of iatrogenic injury to the facial nerve, which can significantly impact patients’ quality of life. As facial nerve outcomes remain challenging to prognosticate, we endeavored to utilize machine learning to decipher predictive factors relevant to facial nerve outcomes following microsurgical resection of VS. A database of patient-, tumor- and surgery-specific features was constructed via retrospective chart review of 242 consecutive patients who underwent microsurgical resection of VS over a 7-year study period. This database was then used to train non-linear supervised machine learning classifiers to predict facial nerve preservation, defined as House-Brackmann (HB) I vs. facial nerve injury, defined as HB II–VI, as determined at 6-month outpatient follow-up. A random forest algorithm demonstrated 90.5% accuracy, 90% sensitivity and 90% specificity in facial nerve injury prognostication. A random variable (rv) was generated by randomly sampling a Gaussian distribution and used as a benchmark to compare the predictiveness of other features. This analysis revealed age, body mass index (BMI), case length and the tumor dimension representing tumor growth towards the brainstem as prognosticators of facial nerve injury. When validated via prospective assessment of facial nerve injury risk, this model demonstrated 84% accuracy. Here, we describe the development of a machine learning algorithm to predict the likelihood of facial nerve injury following microsurgical resection of VS. In addition to serving as a clinically applicable tool, this highlights the potential of machine learning to reveal non-linear relationships between variables which may have clinical value in prognostication of outcomes for high-risk surgical procedures.