TY - JOUR
T1 - Automated mood disorder symptoms monitoring from multivariate time-series sensory data
T2 - getting the full picture beyond a single number
AU - Corponi, Filippo
AU - Li, Bryan M
AU - Anmella, Gerard
AU - Mas, Ariadna
AU - Pacchiarotti, Isabella
AU - Valentí, Marc
AU - Grande, Iria
AU - Benabarre, Antoni
AU - Garriga, Marina
AU - Vieta, Eduard
AU - Lawrie, Stephen M
AU - Whalley, Heather C
AU - Hidalgo-Mazzei, Diego
AU - Vergari, Antonio
N1 - © 2024. The Author(s).
PY - 2024/3/26
Y1 - 2024/3/26
N2 - Mood disorders (MDs) are among the leading causes of disease burden worldwide. Limited specialized care availability remains a major bottleneck thus hindering pre-emptive interventions. MDs manifest with changes in mood, sleep, and motor activity, observable in ecological physiological recordings thanks to recent advances in wearable technology. Therefore, near-continuous and passive collection of physiological data from wearables in daily life, analyzable with machine learning (ML), could mitigate this problem, bringing MDs monitoring outside the clinician's office. Previous works predict a single label, either the disease state or a psychometric scale total score. However, clinical practice suggests that the same label may underlie different symptom profiles, requiring specific treatments. Here we bridge this gap by proposing a new task: inferring all items in HDRS and YMRS, the two most widely used standardized scales for assessing MDs symptoms, using physiological data from wearables. To that end, we develop a deep learning pipeline to score the symptoms of a large cohort of MD patients and show that agreement between predictions and assessments by an expert clinician is clinically significant (quadratic Cohen's κ and macro-average F1 score both of 0.609). While doing so, we investigate several solutions to the ML challenges associated with this task, including multi-task learning, class imbalance, ordinal target variables, and subject-invariant representations. Lastly, we illustrate the importance of testing on out-of-distribution samples.
AB - Mood disorders (MDs) are among the leading causes of disease burden worldwide. Limited specialized care availability remains a major bottleneck thus hindering pre-emptive interventions. MDs manifest with changes in mood, sleep, and motor activity, observable in ecological physiological recordings thanks to recent advances in wearable technology. Therefore, near-continuous and passive collection of physiological data from wearables in daily life, analyzable with machine learning (ML), could mitigate this problem, bringing MDs monitoring outside the clinician's office. Previous works predict a single label, either the disease state or a psychometric scale total score. However, clinical practice suggests that the same label may underlie different symptom profiles, requiring specific treatments. Here we bridge this gap by proposing a new task: inferring all items in HDRS and YMRS, the two most widely used standardized scales for assessing MDs symptoms, using physiological data from wearables. To that end, we develop a deep learning pipeline to score the symptoms of a large cohort of MD patients and show that agreement between predictions and assessments by an expert clinician is clinically significant (quadratic Cohen's κ and macro-average F1 score both of 0.609). While doing so, we investigate several solutions to the ML challenges associated with this task, including multi-task learning, class imbalance, ordinal target variables, and subject-invariant representations. Lastly, we illustrate the importance of testing on out-of-distribution samples.
KW - Humans
KW - Mood Disorders/diagnosis
KW - Affect
KW - Machine Learning
KW - Sleep
U2 - 10.1038/s41398-024-02876-1
DO - 10.1038/s41398-024-02876-1
M3 - Article
C2 - 38531865
SN - 2158-3188
VL - 14
SP - 161
JO - Translational Psychiatry
JF - Translational Psychiatry
IS - 1
ER -