Deep Learning in Spinal Endoscopy: U-Net Models for Neural Tissue Detection

Biportal endoscopic spine surgery (BESS) is minimally invasive and therefore benefits both surgeons and patients. However, concerning complications include dural tears and neural tissue injuries. In this study, we aimed to develop a deep learning model for neural tissue segmentation to enhance the s...

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Vydané v:	Bioengineering (Basel) Ročník 11; číslo 11; s. 1082
Hlavní autori:	Lee, Hyung Rae, Rhee, Wounsuk, Chang, Sam Yeol, Chang, Bong-Soon, Kim, Hyoungmin
Médium:	Journal Article
Jazyk:	English
Vydavateľské údaje:	Switzerland MDPI AG 01.11.2024 MDPI
Predmet:	Back surgery Bone surgery computer vision Datasets Deep learning Effectiveness endoscopic spine surgery Endoscopy Equipment and supplies Frames (data processing) Frames per second Image enhancement Image processing Image segmentation Injuries Learning curves Medical imaging Neural networks neural tissue Patients Performance evaluation Recall Segmentation Spine Surgeons Surgery Training deep learning endoscopic spine surgery image segmentation computer vision neural tissue
ISSN:	2306-5354, 2306-5354
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Shrnutí:	Biportal endoscopic spine surgery (BESS) is minimally invasive and therefore benefits both surgeons and patients. However, concerning complications include dural tears and neural tissue injuries. In this study, we aimed to develop a deep learning model for neural tissue segmentation to enhance the safety and efficacy of endoscopic spinal surgery. We used frames extracted from videos of 28 endoscopic spine surgeries, comprising 2307 images for training and 635 images for validation. A U-Net-like architecture is employed for neural tissue segmentation. Quantitative assessments include the Dice-Sorensen coefficient, Jaccard index, precision, recall, average precision, and image-processing time. Our findings revealed that the best-performing model achieved a Dice-Sorensen coefficient of 0.824 and a Jaccard index of 0.701. The precision and recall values were 0.810 and 0.839, respectively, with an average precision of 0.890. The model processed images at 43 ms per frame, equating to 23.3 frames per second. Qualitative evaluations indicated the effective identification of neural tissue features. Our U-Net-based model robustly performed neural tissue segmentation, indicating its potential to support spine surgeons, especially those with less experience, and improve surgical outcomes in endoscopic procedures. Therefore, further advancements may enhance the clinical applicability of this technique.
Bibliografia:	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 14 content type line 23
ISSN:	2306-5354 2306-5354
DOI:	10.3390/bioengineering11111082