Smart Health-Enhanced Early Mobilisation in Intensive Care Units
Abstract
:1. Introduction
1.1. Barriers to Early Mobilisation
- Patient-level barriers: related to patient safety and efficacy of EM (e.g., medical instability, endotrach intubation, obesity, cognitive impairment).
- Institutional-level barriers: such as a lack of equipment or unclear guidelines.
- Provider-level barriers: such as limited staff (issues typically reported by physical therapists), problems in communication and protocol continuity over shift changes.
1.2. The Evolution of Healthcare Paradigms
1.3. Contribution and Plan of the Article
- Q1: Does the relevant literature on EM practice consider the use of technology?
- Q2: Does the literature on ICT include applications to EM?
- Q3: How can technology (e.g., e-health, sensors, robotics, etc.) help overcome barriers to EM practice?
2. Methodology
2.1. Definition of the Review Scope
2.2. Conceptualisation
2.3. Literature Selection
- Set 1. The most recent reviews and surveys on EM that consider/mention technology in their analyses or discussions. The articles in this set will be used to address Q1.
- Set 2. The most-cited contributions on EM that mention the use of technology. The articles in this set will also be used to address Q1.
- Set 3. Original research articles on the application of technology to EM. The articles in this set will be used to address Q2.
= ( = {“early mobili*ation” OR “early rehabilitation”}) AND (={“review” OR “survey”}).
= ( = {“early mobili*ation” OR “early rehabilitation”})
S3 = ( = {(“early mobili*ation” OR “early rehabilitation”) AND (“HAR” OR “human activity recognition” OR “sensors” OR “robotics” OR “software” OR “artificial intelligence”)})
= ( = {“early mobili*ation” OR “early rehabilitation”})
3. Results
3.1. Technology and Early Mobilisation
3.1.1. Neuromuscular Electrical Stimulation
3.1.2. Robotics and Mechatronics
3.1.3. Sensors to Monitor EM Routines
4. Discussion
4.1. Limitations of the Analysed Proposals
4.2. Smart Healthcare-Enhanced Early Mobilisation
4.3. Integrating Proposals from the Rehabilitation Area
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Set | Title | Year | Citations | NES | Robotics | Sensors |
---|---|---|---|---|---|---|
Set 1. Surveys on EM mentioning technology | Early mobilization and physical exercise in patients with COVID-19: A narrative literature review [27] | 2021 | 0 | • | • | |
Rehabilitation to enable recovery from COVID-19: a rapid systematic review [28] | 2021 | 0 | • | |||
Review: How Can Intelligent Robots and Smart Mechatronic Modules Facilitate Remote Assessment, Assistance, and Rehabilitation for Isolated Adults With Neuro-Musculoskeletal Conditions? [29] | 2021 | 0 | • | |||
Three-Fourths of ICU Physical Therapists Report the Use of Assistive Equipment and Technology in Practice: Results of an International Survey [25] | 2021 | 0 | ||||
The effects of neuromuscular electrical stimulation in critically ill patients: A systematic review and meta-analysis of randomised controlled trials [30] | 2020 | 6 | • | |||
Gait rehabilitation after stroke: review of the evidence of predictors, clinical outcomes and timing for interventions [31] | 2020 | 3 | • | |||
Actigraphy to Measure Physical Activity in the Intensive Care Unit: A Systematic Review [32] | 2019 | 8 | • | |||
Physiotherapy in the neurotrauma intensive care unit: A scoping review [33] | 2018 | 4 | • | |||
Set 2. The most-cited contributions on EM that mention the use of technology. | An early rehabilitation intervention to enhance recovery during hospital admission for an exacerbation of chronic respiratory disease: Randomised controlled trial [34] | 2014 | 144 | • | ||
Technology to enhance physical rehabilitation of critically ill patients [26] | 2009 | 127 | ||||
Set 3. Original research articles on the application of technology to EM | The Effect of Multi-Frequency Whole-Body Vibration on Muscle Activation, Metabolic Cost and Regional Tissue Oxygenation [35] | 2020 | 0 | • | ||
Joint Distribution and Transitions of Pain and Activity in Critically Ill Patients [36] | 2020 | 0 | • | |||
e-PEMICU: an e-Health Platform to Support Early Mobilisation in Intensive Care Units [37] | 2019 | 1 | • | |||
Postoperative healing patterns in elbow using electromyography: Towards the development of a wearable mechatronic elbow brace [38] | 2017 | 1 | • | |||
Real-Time Closed-Loop Control of Human Heart Rate and Blood Pressure [39] | 2015 | 11 | • | |||
Novel tilt table with integrated robotic stepping mechanism: design principles and clinical application [40] | 2005 | 14 | • | |||
Visualization of transfer motion based on accelerometry data in the hemiplegic patients [41] | 2002 | 0 | • | |||
Evaluation of bed rest using a bed temperature monitor after acute myocardial infarction [42] | 1995 | 1 | • |
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Ferre, M.; Batista, E.; Solanas, A.; Martínez-Ballesté, A. Smart Health-Enhanced Early Mobilisation in Intensive Care Units. Sensors 2021, 21, 5408. https://doi.org/10.3390/s21165408
Ferre M, Batista E, Solanas A, Martínez-Ballesté A. Smart Health-Enhanced Early Mobilisation in Intensive Care Units. Sensors. 2021; 21(16):5408. https://doi.org/10.3390/s21165408
Chicago/Turabian StyleFerre, Maria, Edgar Batista, Agusti Solanas, and Antoni Martínez-Ballesté. 2021. "Smart Health-Enhanced Early Mobilisation in Intensive Care Units" Sensors 21, no. 16: 5408. https://doi.org/10.3390/s21165408
APA StyleFerre, M., Batista, E., Solanas, A., & Martínez-Ballesté, A. (2021). Smart Health-Enhanced Early Mobilisation in Intensive Care Units. Sensors, 21(16), 5408. https://doi.org/10.3390/s21165408