Scientific Reports (Feb 2021)

Real-time acoustic sensing and artificial intelligence for error prevention in orthopedic surgery

  • Matthias Seibold,
  • Steven Maurer,
  • Armando Hoch,
  • Patrick Zingg,
  • Mazda Farshad,
  • Nassir Navab,
  • Philipp Fürnstahl

DOI
https://doi.org/10.1038/s41598-021-83506-4
Journal volume & issue
Vol. 11, no. 1
pp. 1 – 11

Abstract

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Abstract In this work, we developed and validated a computer method capable of robustly detecting drill breakthrough events and show the potential of deep learning-based acoustic sensing for surgical error prevention. Bone drilling is an essential part of orthopedic surgery and has a high risk of injuring vital structures when over-drilling into adjacent soft tissue. We acquired a dataset consisting of structure-borne audio recordings of drill breakthrough sequences with custom piezo contact microphones in an experimental setup using six human cadaveric hip specimens. In the following step, we developed a deep learning-based method for the automated detection of drill breakthrough events in a fast and accurate fashion. We evaluated the proposed network regarding breakthrough detection sensitivity and latency. The best performing variant yields a sensitivity of $$93.64 \pm 2.42$$ 93.64 ± 2.42 % for drill breakthrough detection in a total execution time of 139.29 $${\hbox { ms}}$$ ms . The validation and performance evaluation of our solution demonstrates promising results for surgical error prevention by automated acoustic-based drill breakthrough detection in a realistic experiment while being multiple times faster than a surgeon’s reaction time. Furthermore, our proposed method represents an important step for the translation of acoustic-based breakthrough detection towards surgical use.