PURPOSE: Minimally invasive surgery is often built upon a time-consuming preoperative step consisting of segmentation and trajectory planning. At the temporal bone, a complete automation of these two tasks might lead to faster interventions and more reproducible results, benefiting clinical workflow and patient health. METHODS: We propose an automatic segmentation and trajectory planning pipeline for image-guided interventions at the temporal bone. For segmentation, we use a shape regularized deep learning approach that is capable of automatically detecting even the cluttered tiny structures specific for this anatomy. We then perform trajectory planning for both linear and nonlinear interventions on these automatically segmented risk structures. RESULTS: We evaluate the usability of segmentation algorithms for planning access canals to the cochlea and the internal auditory canal on 24 CT data sets of real patients. Our new approach achieves similar results to the existing semiautomatic method in terms of Dice but provides more accurate organ shapes for the subsequent trajectory planning step. The source code of the algorithms is publicly available. CONCLUSION: Automatic segmentation and trajectory planning for various clinical procedures at the temporal bone are feasible. The proposed automatic pipeline leads to an efficient and unbiased workflow for preoperative planning.
PURPOSE: Minimally invasive surgery is often built upon a time-consuming preoperative step consisting of segmentation and trajectory planning. At the temporal bone, a complete automation of these two tasks might lead to faster interventions and more reproducible results, benefiting clinical workflow and patient health. METHODS: We propose an automatic segmentation and trajectory planning pipeline for image-guided interventions at the temporal bone. For segmentation, we use a shape regularized deep learning approach that is capable of automatically detecting even the cluttered tiny structures specific for this anatomy. We then perform trajectory planning for both linear and nonlinear interventions on these automatically segmented risk structures. RESULTS: We evaluate the usability of segmentation algorithms for planning access canals to the cochlea and the internal auditory canal on 24 CT data sets of real patients. Our new approach achieves similar results to the existing semiautomatic method in terms of Dice but provides more accurate organ shapes for the subsequent trajectory planning step. The source code of the algorithms is publicly available. CONCLUSION: Automatic segmentation and trajectory planning for various clinical procedures at the temporal bone are feasible. The proposed automatic pipeline leads to an efficient and unbiased workflow for preoperative planning.
Authors: A E Rajesh; J T Rubinstein; M Ferreira; A P Patel; R A Bly; G D Kohlberg Journal: Int J Comput Assist Radiol Surg Date: 2022-01-28 Impact factor: 2.924
Authors: Johannes Fauser; Simon Bohlender; Igor Stenin; Julia Kristin; Thomas Klenzner; Jörg Schipper; Anirban Mukhopadhyay Journal: Int J Comput Assist Radiol Surg Date: 2020-10-11 Impact factor: 2.924
Authors: Raymond van de Berg; Philippe Lambin; Akshayaa Vaidyanathan; Marly F J A van der Lubbe; Ralph T H Leijenaar; Marc van Hoof; Fadila Zerka; Benjamin Miraglio; Sergey Primakov; Alida A Postma; Tjasse D Bruintjes; Monique A L Bilderbeek; Hammer Sebastiaan; Patrick F M Dammeijer; Vincent van Rompaey; Henry C Woodruff; Wim Vos; Seán Walsh Journal: Sci Rep Date: 2021-02-03 Impact factor: 4.379