Movement-Specific Analysis for FIM Score Classification Using Spatio-Temporal Deep Learning
This reduces the burden of manual FIM assessments for rehabilitation patients and healthcare professionals, though it is incremental as it builds on existing deep learning techniques.
The paper tackled automating the assessment of patients' physical independence (FIM scores) by using a deep learning model on simple exercises, achieving balanced accuracies of 70.09-78.79% in distinguishing independent patients from those needing assistance.
The functional independence measure (FIM) is widely used to evaluate patients' physical independence in activities of daily living. However, traditional FIM assessment imposes a significant burden on both patients and healthcare professionals. To address this challenge, we propose an automated FIM score estimation method that utilizes simple exercises different from the designated FIM assessment actions. Our approach employs a deep neural network architecture integrating a spatial-temporal graph convolutional network (ST-GCN), bidirectional long short-term memory (BiLSTM), and an attention mechanism to estimate FIM motor item scores. The model effectively captures long-term temporal dependencies and identifies key body-joint contributions through learned attention weights. We evaluated our method in a study of 277 rehabilitation patients, focusing on FIM transfer and locomotion items. Our approach successfully distinguishes between completely independent patients and those requiring assistance, achieving balanced accuracies of 70.09-78.79 % across different FIM items. Additionally, our analysis reveals specific movement patterns that serve as reliable predictors for particular FIM evaluation items.