Anomaly detection using intraoperative iKnife data: a comparative analysis in breast cancer surgery.

IF 2.3 3区医学 Q3 ENGINEERING, BIOMEDICAL

International Journal of Computer Assisted Radiology and Surgery Pub Date : 2025-09-01 Epub Date: 2025-07-29 DOI:10.1007/s11548-025-03476-0

Olivia Radcliffe, Laura Connolly, Amoon Jamzad, Martin Kaufmann, Shaila Merchant, Jay Engel, Ross Walker, Sonal Varma, Gabor Fichtinger, John Rudan, Parvin Mousavi

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引用次数: 0

Abstract

Purpose: Intraoperative margin assessment is crucial to ensure complete tumor removal and minimize the risk of cancer recurrence during breast-conserving surgery. The Intelligent Knife (iKnife), a mass spectrometry device that analyzes surgical smoke, shows promise in near-real-time margin evaluation. However, current AI models depend on labeled ex-vivo datasets, which are costly and time-consuming to produce. This research explores the potential of machine learning anomaly detection models to reduce reliance on labeled ex-vivo datasets by utilizing unlabeled intraoperative spectra.

Methods: iKnife spectra were collected intraoperatively from 15 breast cancer surgeries. Ex-vivo samples were recorded from the resected specimen by a pathologist. Healthy samples were from the margin, and tumor samples were from the cross-section. We trained four anomaly detection methods, Isolation Forest (iForest), One Class Principal Component Analysis (OCPCA), Generalized One Class Discriminative Subspaces (GODS), and its Kernelized extension (KGODS), under two strategies: (i) intraoperative data only and (ii) intraoperative data plus healthy ex-vivo data. Performance was evaluated via four-fold cross-validation on labeled ex-vivo samples, with an additional ensemble approach on a held-out set. We compared the models to benchmark supervised classifiers and explored intraoperative feasibility with a retrospective case.

Results: Using intraoperative data alone, the average balanced accuracies were 70% (iForest), 81% (OC-PCA), 77% (GODS), and 81% (KGODS) during four-fold cross-validation. Adding healthy ex-vivo data improved performance across all models; however, OC-PCA remained competitive without ex-vivo labels. On the held-out set, OC-PCA trained only on intraoperative data achieved 81% balanced accuracy, 90% sensitivity, and 72% specificity. OC-PCA was selected for intraoperative feasibility and correctly detected the tumor breach with one false positive.

Conclusion: Anomaly detection models, particularly OC-PCA, can identify positive breast cancer margins with no labeled ex-vivo data. Though slightly lower in performance than supervised classifiers, they offer a promising low-resource alternative for intraoperative label generation and semi-supervised training, which can enhance clinical deployment.

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术中iKnife数据异常检测在乳腺癌手术中的比较分析。

目的：术中切缘评估是保乳手术中确保肿瘤完全切除和降低肿瘤复发风险的关键。智能刀（iKnife）是一种分析手术烟雾的质谱设备，在近实时的边缘评估中表现出了希望。然而，目前的人工智能模型依赖于标记的离体数据集，这是昂贵和耗时的生产。本研究探索了机器学习异常检测模型的潜力，通过利用未标记的术中光谱来减少对标记的离体数据集的依赖。方法：收集15例乳腺癌患者术中iKnife光谱。病理学家从切除的标本中记录离体样本。健康样本来自边缘，肿瘤样本来自横切面。我们在两种策略下训练了四种异常检测方法：隔离森林（ifforest）、一类主成分分析（OCPCA）、广义一类判别子空间（GODS）及其核化扩展（KGODS）： (i)仅术中数据和（ii）术中数据加健康离体数据。通过标记的离体样品的四倍交叉验证来评估性能，并在保留集上使用额外的集成方法。我们将模型与基准监督分类器进行比较，并通过回顾性病例探讨术中可行性。结果：仅使用术中数据，四重交叉验证的平均平衡准确率分别为70% （ifforest）、81% （OC-PCA）、77% （GODS）和81% （KGODS）。添加健康的离体数据提高了所有模型的性能；然而，在没有离体标签的情况下，OC-PCA仍然具有竞争力。在保留集上，仅根据术中数据训练的OC-PCA达到81%的平衡准确度，90%的灵敏度和72%的特异性。术中选择OC-PCA可行，正确检出肿瘤破口1例假阳性。结论：异常检测模型，特别是OC-PCA，可以在没有标记离体数据的情况下识别出阳性乳腺癌边缘。虽然性能略低于监督分类器，但它们为术中标签生成和半监督训练提供了一个有前途的低资源替代方案，可以增强临床部署。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Computer Assisted Radiology and Surgery ENGINEERING, BIOMEDICAL-RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

CiteScore

5.90

自引率

6.70%

发文量

243

审稿时长

6-12 weeks

期刊介绍： The International Journal for Computer Assisted Radiology and Surgery (IJCARS) is a peer-reviewed journal that provides a platform for closing the gap between medical and technical disciplines, and encourages interdisciplinary research and development activities in an international environment.