Application of a machine learning algorithms in a wrist-wearable sensor for patient health monitoring during autonomous hospital bed transport
Smart sensors, coupled with artificial intelligence (AI)-enabled remote automated monitoring (RAMs), can free a nurse from the task of in-person patient monitoring during the transportation process of patients between different wards in hospital settings. Automation of hospital beds using advanced r...
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sg-ntu-dr.10356-1539292022-06-06T02:46:48Z Application of a machine learning algorithms in a wrist-wearable sensor for patient health monitoring during autonomous hospital bed transport Tan, Yan Hao Liao, Yuwen Tan, Zhijie Li, Holden King Ho School of Mechanical and Aerospace Engineering Engineering::Mechanical engineering Machine Learning Polynomial Regression Smart sensors, coupled with artificial intelligence (AI)-enabled remote automated monitoring (RAMs), can free a nurse from the task of in-person patient monitoring during the transportation process of patients between different wards in hospital settings. Automation of hospital beds using advanced robotics and sensors has been a growing trend exacerbated by the COVID crisis. In this exploratory study, a polynomial regression (PR) machine learning (ML) RAM algorithm based on a Dreyfusian descriptor for immediate wellbeing monitoring was proposed for the autonomous hospital bed transport (AHBT) application. This method was preferred over several other AI algorithm for its simplicity and quick computation. The algorithm quantified historical data using supervised photoplethysmography (PPG) data for 5 min just before the start of the autonomous journey, referred as pre-journey (PJ) dataset. During the transport process, the algorithm continued to quantify immediate measurements using non-overlapping sets of 30 PPG waveforms, referred as in-journey (IJ) dataset. In combination, this algorithm provided a binary decision condition that determined if AHBT should continue its journey to destination by checking the degree of polynomial (DoP) between PJ and IJ. Wrist PPG was used as algorithm's monitoring parameter. PPG data was collected simultaneously from both wrists of 35 subjects, aged 21 and above in postures mimicking that in AHBT and were given full freedom of upper limb and wrist movement. It was observed that the top goodness-of-fit which indicated potentials for high data accountability had 0.2 to 0.6 cross validation score mean (CVSM) occurring at 8th to 10th DoP for PJ datasets and 0.967 to 0.994 CVSM at 9th to 10th DoP for IJ datasets. CVSM was a reliable metric to pick out the best PJ and IJ DoPs. Central tendency analysis showed that coinciding DoP distributions between PJ and IJ datasets, peaking at 8th DoP, was the precursor to high algorithm stability. Mean algorithm efficacy was 0.20 as our proposed algorithm was able to pick out all signals from a conscious subject having full freedom of movement. This efficacy was acceptable as a first ML proof of concept for AHBT. There was no observable difference between subjects' left and right wrists. Ministry of Education (MOE) Published version This research was funded by Ministry of Education (MOE) Tier 1 Award 020212-00001. 2022-06-06T02:46:48Z 2022-06-06T02:46:48Z 2021 Journal Article Tan, Y. H., Liao, Y., Tan, Z. & Li, H. K. H. (2021). Application of a machine learning algorithms in a wrist-wearable sensor for patient health monitoring during autonomous hospital bed transport. Sensors, 21(17), 5711-. https://dx.doi.org/10.3390/s21175711 1424-8220 https://hdl.handle.net/10356/153929 10.3390/s21175711 34502601 2-s2.0-85113292562 17 21 5711 en MOE 020212-00001 Sensors © 2021 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/). application/pdf |
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Engineering::Mechanical engineering Machine Learning Polynomial Regression Tan, Yan Hao Liao, Yuwen Tan, Zhijie Li, Holden King Ho Application of a machine learning algorithms in a wrist-wearable sensor for patient health monitoring during autonomous hospital bed transport |
| description |
Smart sensors, coupled with artificial intelligence (AI)-enabled remote automated monitoring (RAMs), can free a nurse from the task of in-person patient monitoring during the transportation process of patients between different wards in hospital settings. Automation of hospital beds using advanced robotics and sensors has been a growing trend exacerbated by the COVID crisis. In this exploratory study, a polynomial regression (PR) machine learning (ML) RAM algorithm based on a Dreyfusian descriptor for immediate wellbeing monitoring was proposed for the autonomous hospital bed transport (AHBT) application. This method was preferred over several other AI algorithm for its simplicity and quick computation. The algorithm quantified historical data using supervised photoplethysmography (PPG) data for 5 min just before the start of the autonomous journey, referred as pre-journey (PJ) dataset. During the transport process, the algorithm continued to quantify immediate measurements using non-overlapping sets of 30 PPG waveforms, referred as in-journey (IJ) dataset. In combination, this algorithm provided a binary decision condition that determined if AHBT should continue its journey to destination by checking the degree of polynomial (DoP) between PJ and IJ. Wrist PPG was used as algorithm's monitoring parameter. PPG data was collected simultaneously from both wrists of 35 subjects, aged 21 and above in postures mimicking that in AHBT and were given full freedom of upper limb and wrist movement. It was observed that the top goodness-of-fit which indicated potentials for high data accountability had 0.2 to 0.6 cross validation score mean (CVSM) occurring at 8th to 10th DoP for PJ datasets and 0.967 to 0.994 CVSM at 9th to 10th DoP for IJ datasets. CVSM was a reliable metric to pick out the best PJ and IJ DoPs. Central tendency analysis showed that coinciding DoP distributions between PJ and IJ datasets, peaking at 8th DoP, was the precursor to high algorithm stability. Mean algorithm efficacy was 0.20 as our proposed algorithm was able to pick out all signals from a conscious subject having full freedom of movement. This efficacy was acceptable as a first ML proof of concept for AHBT. There was no observable difference between subjects' left and right wrists. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Tan, Yan Hao Liao, Yuwen Tan, Zhijie Li, Holden King Ho |
| format |
Article |
| author |
Tan, Yan Hao Liao, Yuwen Tan, Zhijie Li, Holden King Ho |
| author_sort |
Tan, Yan Hao |
| title |
Application of a machine learning algorithms in a wrist-wearable sensor for patient health monitoring during autonomous hospital bed transport |
| title_short |
Application of a machine learning algorithms in a wrist-wearable sensor for patient health monitoring during autonomous hospital bed transport |
| title_full |
Application of a machine learning algorithms in a wrist-wearable sensor for patient health monitoring during autonomous hospital bed transport |
| title_fullStr |
Application of a machine learning algorithms in a wrist-wearable sensor for patient health monitoring during autonomous hospital bed transport |
| title_full_unstemmed |
Application of a machine learning algorithms in a wrist-wearable sensor for patient health monitoring during autonomous hospital bed transport |
| title_sort |
application of a machine learning algorithms in a wrist-wearable sensor for patient health monitoring during autonomous hospital bed transport |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/153929 |
| _version_ |
1735491217330798592 |