Saarthak Kapse, Pushpak Pati, Srijan Das, Jingwei Zhang, Chao Chen, Maria Vakalopoulou, Joel Saltz, Dimitris Samaras, Rajarsi R Gupta, Prateek Prasanna
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引用次数: 0
Abstract
Introducing interpretability and reasoning into Multiple Instance Learning (MIL) methods for Whole Slide Image (WSI) analysis is challenging, given the complexity of gigapixel slides. Traditionally, MIL interpretability is limited to identifying salient regions deemed pertinent for downstream tasks, offering little insight to the end-user (pathologist) regarding the rationale behind these selections. To address this, we propose Self-Interpretable MIL (SI-MIL), a method intrinsically designed for interpretability from the very outset. SI-MIL employs a deep MIL framework to guide an interpretable branch grounded on handcrafted pathological features, facilitating linear predictions. Beyond identifying salient regions, SI-MIL uniquely provides feature-level interpretations rooted in pathological insights for WSIs. Notably, SI-MIL, with its linear prediction constraints, challenges the prevalent myth of an inevitable trade-off between model interpretability and performance, demonstrating competitive results compared to state-of-the-art methods on WSI-level prediction tasks across three cancer types. In addition, we thoroughly benchmark the local-and global-interpretability of SI-MIL in terms of statistical analysis, a domain expert study, and desiderata of interpretability, namely, user-friendliness and faithfulness.
鉴于千兆像素切片的复杂性,在用于全切片图像(WSI)分析的多实例学习(MIL)方法中引入可解释性和推理具有挑战性。传统上,MIL 的可解释性仅限于识别被认为与下游任务相关的突出区域,对于最终用户(病理学家)来说,几乎无法深入了解这些选择背后的原理。为了解决这个问题,我们提出了自解释 MIL(SI-MIL),这是一种从一开始就为可解释性而设计的方法。SI-MIL 采用深度 MIL 框架,以手工制作的病理特征为基础,引导可解释的分支,促进线性预测。除了识别突出区域外,SI-MIL 还能为 WSI 提供植根于病理学见解的独特的特征级解释。值得注意的是,SI-MIL 凭借其线性预测约束条件,挑战了模型可解释性与性能之间不可避免的权衡这一流行神话,在三种癌症类型的 WSI 级预测任务中,与最先进的方法相比,SI-MIL 取得了极具竞争力的结果。此外,我们还通过统计分析、领域专家研究以及可解释性的必要条件(即用户友好性和忠实性),对 SI-MIL 的局部和全局可解释性进行了全面的基准测试。
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