A Waist-Worn Inertial Measurement Unit for Long-Term Monitoring of Parkinson's Disease Patients

Overview

Journal Sensors (Basel)

Publisher MDPI

Specialty Biotechnology

Date 2017 Apr 12

PMID 28398265

Citations 18

Authors

Daniel Rodriguez-Martin

Carlos Perez-Lopez

Albert Sama

Andreu Catala

Joan Manuel Moreno Arostegui

Joan Cabestany

Berta Mestre

Sheila Alcaine

Anna Prats

Maria de la Cruz Crespo

Angels Bayes

Affiliations

Soon will be listed here.

Abstract

Inertial measurement units (IMUs) are devices used, among other fields, in health applications, since they are light, small and effective. More concretely, IMUs have been demonstrated to be useful in the monitoring of motor symptoms of Parkinson's disease (PD). In this sense, most of previous works have attempted to assess PD symptoms in controlled environments or short tests. This paper presents the design of an IMU, called 9 × 3, that aims to assess PD symptoms, enabling the possibility to perform a map of patients' symptoms at their homes during long periods. The device is able to acquire and store raw inertial data for artificial intelligence algorithmic training purposes. Furthermore, the presented IMU enables the real-time execution of the developed and embedded learning models. Results show the great flexibility of the 9 × 3, storing inertial information and algorithm outputs, sending messages to external devices and being able to detect freezing of gait and bradykinetic gait. Results obtained in 12 patients exhibit a sensitivity and specificity over 80%. Additionally, the system enables working 23 days (at waking hours) with a 1200 mAh battery and a sampling rate of 50 Hz, opening up the possibility to be used for other applications like wellbeing and sports.

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