Detection of Unilateral Arm Paresis after Stroke by Wearable Accelerometers and Machine Learning.
Johan WasseliusEric Lyckegård FinnEmma PerssonPetter EricsonChristina B BrogårdhArne G LindgrenTeresa UllbergKalle ÅströmPublished in: Sensors (Basel, Switzerland) (2021)
Recent advances in stroke treatment have provided effective tools to successfully treat ischemic stroke, but still a majority of patients are not treated due to late arrival to hospital. With modern stroke treatment, earlier arrival would greatly improve the overall treatment results. This prospective study was performed to asses the capability of bilateral accelerometers worn in bracelets 24/7 to detect unilateral arm paralysis, a hallmark symptom of stroke, early enough to receive treatment. Classical machine learning algorithms as well as state-of-the-art deep neural networks were evaluated on detection times between 15 min and 120 min. Motion data were collected using triaxial accelerometer bracelets worn on both arms for 24 h. Eighty-four stroke patients with unilateral arm motor impairment and 101 healthy subjects participated in the study. Accelerometer data were divided into data windows of different lengths and analyzed using multiple machine learning algorithms. The results show that all algorithms performed well in separating the two groups early enough to be clinically relevant, based on wrist-worn accelerometers. The two evaluated deep learning models, fully convolutional network and InceptionTime, performed better than the classical machine learning models with an AUC score between 0.947-0.957 on 15 min data windows and up to 0.993-0.994 on 120 min data windows. Window lengths longer than 90 min only marginally improved performance. The difference in performance between the deep learning models and the classical models was statistically significant according to a non-parametric Friedman test followed by a post-hoc Nemenyi test. Introduction of wearable stroke detection devices may dramatically increase the portion of stroke patients eligible for revascularization and shorten the time to treatment. Since the treatment effect is highly time-dependent, early stroke detection may dramatically improve stroke outcomes.
Keyphrases
- machine learning
- deep learning
- atrial fibrillation
- big data
- healthcare
- type diabetes
- physical activity
- newly diagnosed
- emergency department
- skeletal muscle
- chronic kidney disease
- end stage renal disease
- percutaneous coronary intervention
- neural network
- coronary artery disease
- combination therapy
- mass spectrometry
- blood pressure
- insulin resistance
- data analysis
- case report
- peritoneal dialysis
- smoking cessation