基于嵌入式多模态学习的泛鳞状细胞癌改善生存结果

arXiv - QuanBio - Cell Behavior Pub Date : 2024-06-11 DOI:arxiv-2406.08521

Asim Waqas, Aakash Tripathi, Paul Stewart, Mia Naeini, Ghulam Rasool

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引用次数: 0

摘要

癌症诊所从基因到器官层面捕捉各种规模的疾病数据。目前的生物信息学方法很难处理这些数据的异质性，尤其是缺失的模式。我们提出的 PARADIGM 是一种图神经网络（GNN）框架，它可以从多模态、异构数据集中学习，从而改进临床结果预测。PARADIGM 利用基础模型从多分辨率数据中生成嵌入，将它们聚合成患者级别的表示，融合成统一的图，并提高生存分析等任务的性能。我们在泛鳞状细胞癌上训练 GNN，并在 Moffitt 癌症中心的肺 SCC 数据上验证了我们的方法。多模态 GNN 在患者生存预测方面的表现优于其他模型。我们的解决方案旨在全面了解患者的情况，提供关于异构数据整合的见解以及最大数据视图融合的益处。

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Embedding-based Multimodal Learning on Pan-Squamous Cell Carcinomas for Improved Survival Outcomes

Cancer clinics capture disease data at various scales, from genetic to organ level. Current bioinformatic methods struggle to handle the heterogeneous nature of this data, especially with missing modalities. We propose PARADIGM, a Graph Neural Network (GNN) framework that learns from multimodal, heterogeneous datasets to improve clinical outcome prediction. PARADIGM generates embeddings from multi-resolution data using foundation models, aggregates them into patient-level representations, fuses them into a unified graph, and enhances performance for tasks like survival analysis. We train GNNs on pan-Squamous Cell Carcinomas and validate our approach on Moffitt Cancer Center lung SCC data. Multimodal GNN outperforms other models in patient survival prediction. Converging individual data modalities across varying scales provides a more insightful disease view. Our solution aims to understand the patient's circumstances comprehensively, offering insights on heterogeneous data integration and the benefits of converging maximum data views.

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arXiv - QuanBio - Cell Behavior

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