Philip Chikontwe, Meejeong Kim, Jaehoon Jeong, Hyun Jung Sung, Heounjeong Go, Soo Jeong Nam, Sang Hyun Park
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引用次数: 0
Abstract
In digital pathology, whole slide images (WSI) are crucial for cancer prognostication and treatment planning. WSI classification is generally addressed using multiple instance learning (MIL), alleviating the challenge of processing billions of pixels and curating rich annotations. Though recent MIL approaches leverage variants of the attention mechanism to learn better representations, they scarcely study the properties of the data distribution itself i.e., different staining and acquisition protocols resulting in intra-patch and inter-slide variations. In this work, we first introduce a distribution re-calibration strategy to shift the feature distribution of a WSI bag (instances) using the statistics of the max-instance (critical) feature. Second, we enforce class (bag) separation via a metric loss assuming that positive bags exhibit larger magnitudes than negatives. We also introduce a generative process leveraging Vector Quantization (VQ) for improved instance discrimination i.e., VQ helps model bag latent factors for improved classification. To model spatial and context information, a position encoding module (PEM) is employed with transformer-based pooling by multi-head self-attention (PMSA). Evaluation of popular WSI benchmark datasets reveals our approach improves over state-of-the-art MIL methods. Further, we validate the general applicability of our method on classic MIL benchmark tasks and for point cloud classification with limited points https://github.com/PhilipChicco/FRMIL.
在数字病理学中,整张切片图像(WSI)对于癌症预后和治疗规划至关重要。WSI 分类通常采用多实例学习(MIL)方法,以减轻处理数十亿像素和整理丰富注释所带来的挑战。虽然最近的 MIL 方法利用注意力机制的变体来学习更好的表征,但它们几乎没有研究数据分布本身的属性,即不同染色和采集方案导致的斑块内和切片间的差异。在这项工作中,我们首先引入了一种分布重新校准策略,利用最大实例(临界)特征的统计数据来改变 WSI 包(实例)的特征分布。其次,我们通过度量损失来执行类(袋)分离,假设正向袋比负向袋表现出更大的量级。此外,我们还引入了一种利用矢量量化(VQ)的生成过程,以提高实例分辨能力,即 VQ 可帮助对袋的潜在因素进行建模,从而提高分类能力。为了对空间和上下文信息进行建模,我们采用了位置编码模块(PEM),并通过多头自注意(PMSA)进行基于变压器的汇集。对流行的 WSI 基准数据集进行评估后发现,我们的方法比最先进的 MIL 方法更胜一筹。此外,我们还验证了我们的方法在经典 MIL 基准任务和有限点 https://github.com/PhilipChicco/FRMIL 的点云分类中的普遍适用性。