Determining Physical Activity Characteristics from Wristband Data for Use in Automated Insulin Delivery Systems

Overview

Journal IEEE Sens J

Date 2020 Oct 26

PMID 33100923

Citations 17

Authors

Mert Sevil

Mudassir Rashid

Zacharie Maloney

Iman Hajizadeh

Sediqeh Samadi

Mohammad Reza Askari

Nicole Hobbs

Rachel Brandt

Minsun Park

Laurie Quinn

Ali Cinar

Affiliations

Soon will be listed here.

Abstract

Algorithms that can determine the type of physical activity (PA) and quantify the intensity can allow precision medicine approaches, such as automated insulin delivery systems that modulate insulin administration in response to PA. In this work, data from a multi-sensor wristband is used to design classifiers to distinguish among five different physical states (PS) (resting, activities of daily living, running, biking, and resistance training), and to develop models to estimate the energy expenditure (EE) of the PA for diabetes therapy. The data collected are filtered, features are extracted from the reconciled signals, and the extracted features are used by machine learning algorithms, including deep-learning techniques, to obtain accurate PS classification and EE estimation. The various machine learning techniques have different success rates ranging from 75.7% to 94.8% in classifying the five different PS. The deep neural network model with long short-term memory has 94.8% classification accuracy. We achieved 0.5 MET (Metabolic Equivalent of Task) root-mean-square error for EE estimation accuracy, relative to indirect calorimetry with randomly selected testing data (10% of collected data). We also demonstrate a 5% improvement in PS classification accuracy and a 0.34 MET decrease in the mean absolute error when using multi-sensor approach relative to using only accelerometer data.

Citing Articles

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