HMF:动态预测术中低血压的混合多因素框架

Mingyue Cheng, Jintao Zhang, Zhiding Liu, Chunli Liu, Yanhu Xie
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引用次数: 0

摘要

利用平均动脉压(MAP)预测术中低血压(IOH)是一个重要的研究领域,对手术期间患者的预后有重大影响。然而,现有方法主要采用静态建模范式,忽略了生理信号的动态特性。在本文中,我们介绍了一种新颖的混合多因素(HMF)框架,它将 IOH 预测重新表述为血压预测任务。我们的框架利用 Transformer 编码器,该编码器专门设计用于通过基于补丁的输入表示有效捕捉 MAP 序列的时间演化,从而将输入的生理序列分割成信息补丁,以便进行精确分析。为了应对生理序列分布偏移的挑战,我们的方法采用了两项关键创新:(1)对称归一化和去归一化过程有助于缓解统计属性的分布偏移,从而确保模型在不同条件下的鲁棒性;(2)序列分解,将输入序列分解为趋势和季节成分,从而可以更精确地模拟固有的序列依赖性。在两个真实世界数据集上进行的广泛实验证明,与竞争基线相比,我们的方法具有更优越的性能,尤其是在捕捉输入序列的细微变化方面,而这对于准确预测 IOH 至关重要。
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HMF: A Hybrid Multi-Factor Framework for Dynamic Intraoperative Hypotension Prediction
Intraoperative hypotension (IOH) prediction using Mean Arterial Pressure (MAP) is a critical research area with significant implications for patient outcomes during surgery. However, existing approaches predominantly employ static modeling paradigms that overlook the dynamic nature of physiological signals. In this paper, we introduce a novel Hybrid Multi-Factor (HMF) framework that reformulates IOH prediction as a blood pressure forecasting task. Our framework leverages a Transformer encoder, specifically designed to effectively capture the temporal evolution of MAP series through a patch-based input representation, which segments the input physiological series into informative patches for accurate analysis. To address the challenges of distribution shift in physiological series, our approach incorporates two key innovations: (1) Symmetric normalization and de-normalization processes help mitigate distributional drift in statistical properties, thereby ensuring the model's robustness across varying conditions, and (2) Sequence decomposition, which disaggregates the input series into trend and seasonal components, allowing for a more precise modeling of inherent sequence dependencies. Extensive experiments conducted on two real-world datasets demonstrate the superior performance of our approach compared to competitive baselines, particularly in capturing the nuanced variations in input series that are crucial for accurate IOH prediction.
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