基于概念的病变感知转换器,用于可解释的视网膜疾病诊断

Chi Wen, Mang Ye, He Li, Ting Chen, Xuan Xiao
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摘要

现有的深度学习方法在诊断视网膜疾病方面取得了显著成果,展示了先进人工智能在眼科领域的潜力。然而,这些方法的黑箱性质掩盖了决策过程,影响了其可信度和可接受性。受基于概念的方法的启发,并认识到视网膜病变与疾病之间的内在关联性,我们将视网膜病变视为概念,并提出了一个内在可解释的框架,旨在提高诊断模型的性能和可解释性。我们的模型利用以善于捕捉长距离依赖关系而著称的变换器架构,可以有效地识别病变特征。在视网膜基础模型的指导下,通过与图像级注释的整合,它实现了病变概念与人类认知的一致性。此外,为了在不丢失病变特定信息的情况下实现可解释性,我们的方法采用了一种建立在疾病诊断和解释的交叉注意机制上的分类器,其中解释是基于人类可理解的病变概念及其视觉定位的贡献。值得注意的是,由于我们模型的结构和内在可解释性,临床医生只需调整错误的病变预测,就能实施概念级干预,纠正诊断错误。在四个眼底图像数据集上进行的实验表明,与最先进的方法相比,我们的方法取得了良好的性能,同时提供了忠实的解释并实现了概念级干预。我们的代码可在 https://github.com/Sorades/CLAT 公开获取。
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Concept-based Lesion Aware Transformer for Interpretable Retinal Disease Diagnosis.

Existing deep learning methods have achieved remarkable results in diagnosing retinal diseases, showcasing the potential of advanced AI in ophthalmology. However, the black-box nature of these methods obscures the decision-making process, compromising their trustworthiness and acceptability. Inspired by the concept-based approaches and recognizing the intrinsic correlation between retinal lesions and diseases, we regard retinal lesions as concepts and propose an inherently interpretable framework designed to enhance both the performance and explainability of diagnostic models. Leveraging the transformer architecture, known for its proficiency in capturing long-range dependencies, our model can effectively identify lesion features. By integrating with image-level annotations, it achieves the alignment of lesion concepts with human cognition under the guidance of a retinal foundation model. Furthermore, to attain interpretability without losing lesion-specific information, our method employs a classifier built on a cross-attention mechanism for disease diagnosis and explanation, where explanations are grounded in the contributions of human-understandable lesion concepts and their visual localization. Notably, due to the structure and inherent interpretability of our model, clinicians can implement concept-level interventions to correct the diagnostic errors by simply adjusting erroneous lesion predictions. Experiments conducted on four fundus image datasets demonstrate that our method achieves favorable performance against state-of-the-art methods while providing faithful explanations and enabling conceptlevel interventions. Our code is publicly available at https://github.com/Sorades/CLAT.

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