风险评估
可穿戴计算机
光容积图
推论
风险分析(工程)
人工智能
事件(粒子物理)
计算机科学
远程病人监护
机器学习
延迟(音频)
嵌入式系统
特征(语言学)
实时计算
可穿戴技术
特征提取
系统体系结构
即插即用
作者
Chao Ma,Yue Feng,Songhua Luan,Zixi Zhao,Yuqi Bai,Lu Sun,Hongliang Liu,Jian Bo
标识
DOI:10.1109/tce.2026.3655427
摘要
Prediction of risks and constant monitoring is essential in treatment of Myeloproliferative Neoplasms (MPNs). The design of this paper aims at providing an Explainable Artificial Intelligence-based framework, integrated with consumer-level wearable devices can enable accurate, low-latency, and clinically trusted real-time detection of thrombotic risk and treatment optimization. The system uses multimodal signal acquisition that includes the photoplethysmography (PPG), heart rate variability (HRV), accelerations, and clinical biomarkers. A hybrid CNN-Transformer backbone is employed for temporal and contextual feature fusion, with Grad-CAM and SHAP used to generate visual and feature-level explanations supporting clinical interpretability. The mathematical model formalizes the preprocessing, fusion, interpretability, and multi-objective optimization of the accuracy, latency, safety, and clinician trust. Training and validation were done using synthetic and clinical wearable datasets. Experimental evaluation demonstrates a risk prediction accuracy of 92.8%, an event detection AUC of 0.94, an inference latency of 1.8 s, and clinician trust alignment of 89%, outperforming conventional LSTM- and Transformer-based baselines. The hybrid architecture of edges and clouds proposed provides guarantee of low-latency inference, secure synchronization, and regulatory compliance. All in all, the research establishes interpretable, efficient, and clinically dependable wearable AI system to manage the risk of MPN and personalized treatment support.
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