Location via proxy:   [ UP ]  
[Report a bug]   [Manage cookies]                
Next Article in Journal
Transverse Growth of the Maxillo-Mandibular Complex in Untreated Children: A Longitudinal Cone Beam Computed Tomography Study
Next Article in Special Issue
A Brake-Based Overground Gait Rehabilitation Device for Altering Propulsion Impulse Symmetry
Previous Article in Journal
Mechanosensory Hairs and Hair-like Structures in the Animal Kingdom: Specializations and Shared Functions Serve to Inspire Technology Applications
Previous Article in Special Issue
A System for Neuromotor Based Rehabilitation on a Passive Robotic Aid
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Sensors
Volume 21
Issue 19
10.3390/s21196377
sensors-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Evidence for the Effectiveness of Feedback from Wearable Inertial Sensors during Work-Related Activities: A Scoping Review

by
Roger Lee
1,2,*,
Carole James
1,3,
Suzi Edwards
4,
Geoff Skinner
5,
Jodi L. Young
6 and
Suzanne J. Snodgrass
1,2
1
School of Health Sciences, The University of Newcastle, Newcastle 2308, Australia
2
Centre for Brain and Mental Health Research, The University of Newcastle, Newcastle 2308, Australia
3
Centre for Resources Health and Safety, The University of Newcastle, Newcastle 2308, Australia
4
School of Health Sciences, The University of Sydney, Sydney 2006, Australia
5
School of Information and Physical Sciences, The University of Newcastle, Newcastle 2308, Australia
6
Department of Physical Therapy, Bellin College, Green Bay, WI 54311, USA
*
Author to whom correspondence should be addressed.
Sensors 2021, 21(19), 6377; https://doi.org/10.3390/s21196377
Submission received: 22 July 2021 / Revised: 16 September 2021 / Accepted: 18 September 2021 / Published: 24 September 2021
(This article belongs to the Special Issue Feedback-Based Balance, Gait Assistive and Rehabilitation Aids)
Browse Figures
Versions Notes

Abstract

:
Background: Wearable inertial sensor technology (WIST) systems provide feedback, aiming to modify aberrant postures and movements. The literature on the effects of feedback from WIST during work or work-related activities has not been previously summarised. This review examines the effectiveness of feedback on upper body kinematics during work or work-related activities, along with the wearability and a quantification of the kinematics of the related device. Methods: The Cinahl, Cochrane, Embase, Medline, Scopus, Sportdiscus and Google Scholar databases were searched, including reports from January 2005 to July 2021. The included studies were summarised descriptively and the evidence was assessed. Results: Fourteen included studies demonstrated a ‘limited’ level of evidence supporting posture and/or movement behaviour improvements using WIST feedback, with no improvements in pain. One study assessed wearability and another two investigated comfort. Studies used tri-axial accelerometers or IMU integration (n = 5 studies). Visual and/or vibrotactile feedback was mostly used. Most studies had a risk of bias, lacked detail for methodological reproducibility and displayed inconsistent reporting of sensor technology, with validation provided only in one study. Thus, we have proposed a minimum ‘Technology and Design Checklist’ for reporting. Conclusions: Our findings suggest that WIST may improve posture, though not pain; however, the quality of the studies limits the strength of this conclusion. Wearability evaluations are needed for the translation of WIST outcomes. Minimum reporting standards for WIST should be followed to ensure methodological reproducibility.

1. Introduction

Work-related musculoskeletal disorders (WMSDs) can result from non-traumatic inflammatory or degenerative conditions during work or work-related activities [1]. Dysfunction of muscles, ligaments, tendons, joints and/or cartilage may decrease the overall physiological efficiency within the human body [2]. The most common WMSDs are neck and back pain, which together represent the leading cause of years lived with disability globally [3] and are a debilitating ongoing health concern for many individuals [4,5,6]. Other consequences from WMSDs are economic factors, which may result in lower job satisfaction and psychological wellbeing [7], worker absenteeism, reduced productivity, and increasing business/health-care costs [6,8,9]. Therefore, practical solutions to mitigate and/or manage upper body WMSDs are required.
Poor posture and movement behaviour are likely to contribute to neck, shoulder and/or lower back pain complaints among workers [10,11]. Individuals that engage in awkward upper body postures (non-neutral joint positions) [12,13] and/or poor movement behaviour (e.g., sedentary behaviour) [14,15,16] are likely to sustain a WMSD. Alongside sedentary tasks, manual handling (pushing, pulling, carrying, lifting, holding, moving or restraining an object) [17] and physical exposure [13] represent a large proportion of work-related MSD, as postures are mostly determined by the spatial relationship between the worker and the task. Furthermore, MSDs are multifactorial, for example, increased work stressors, demands and durations of working hours are highly correlated with an increased risk of WRMDs [18], in addition to psychological and behavioural well-being [19,20]. Thus, there is a need to design appropriate workplace interventions to mitigate WMSD risks [21,22] that consider all of these factors.
Designing evidence-based workplace interventions requires a well-designed and rigorous evaluation process [23]. However, results from studies investigating the link between posture and MSD vary [23], with a lack of consensus for current MSD intervention(s) that are likely to be attributed to low patient compliance [24]. Greater rigor in measurement and higher-quality studies are required in order to identify the underlying mechanisms responsible for WMSDs and/or pain development [20,23,25], to improve and further develop current workplace interventions.
Rigorous kinematic evaluation can assist in WMSD management and prevention strategies by improving knowledge of the underlying mechanical, physiological and anatomical factors involved in human motion [26]. Evaluation of the kinematics of workplace activities can be broadly classified into three categories: observational studies, self-reported studies and direct measurements [27]. Although observational assessments and self-reports are widely used [28], their reliance on an observer’s interpretation or an individual’s perception of events may lack objectivity. Direct measurements such as the three-dimensional motion capture system (MOCAP) are the gold standard in kinematic analysis, providing in-depth objective measurements. However, MOCAP systems are expensive, complex and require specialised software [26,29] and are therefore mostly laboratory-based [30], making it difficult to determine functional postures within a real-world working environment [31]. Kinematics measured within an individual’s naturalistic or usual environment is more likely to identify their ‘usual’ or true postures, in comparison to laboratory settings, which typically lack any workplace stressors and/or demands [32].
A recent advancement in wearable technology, incorporating several inertial sensors (an accelerometer, gyroscope and/or a magnetometer) [33], which is able to measure kinematics outside the laboratory, is the inertial measurement unit (IMU). The IMU can detect motion, orientation and heading within a 3D space by performing calculations in terms of acceleration (accelerometer), angular velocity (gyroscope) and rotation (magnetometer), respectively, and can send data wirelessly via Bluetooth or Wi-Fi [34]. An IMU can objectively measure an individual’s body positioning in real-time and within their own environment or workspace [33,35]. Further advancements in customisable software and algorithms provide individualised real-time feedback on posture or movement behaviour [30,36]. Synchronizing multiple IMU devices can operate as a wireless body area network (WBAN) to support detailed biomechanical model development and capture more complex kinematic movement data compared to a single IMU. An IMU has a large range of applications, for example, distinguishing postural differences between individuals [37], or home-based monitoring during rehabilitation to enhance patient compliance and therefore improve functional recovery [38] An inertial sensor is mostly reliable and valid for measuring posture [37,39,40,41]. However, the validity of an inertial sensor is largely dependent on the environment and task performed. Therefore, wherever practical, the inertial sensor(s) should be validated using a gold standard (e.g., a mocap system) prior to their specific usage and environment [30,42]. Validation is paramount for the translation of sensor technology into clinical and rehabilitation settings [42,43,44].
Wearability is described as the interaction between the individual and the sensing equipment [45]. An individual’s task performance may be affected by poor wearability [43]. The consideration of wearability is essential to evaluating the effectiveness of sensor technology, and includes aspects such as sensors’ comfort, mass, appropriate attachment (the prevention of aberrant sensor movement) and obtrusiveness, which may interfere with achieving the user acceptability of the wearable technology [45,46]. Wearability is important for achieving adherence to, and subsequently effectiveness with, workplace interventions using wearable technology [25] and in implementing wearable technology in real-world settings [43].
Wearable inertial sensor technology (WIST) can provide real-time feedback to the wearer. The aim of real-time feedback from WIST is to provide the individual with greater self-awareness of posture and/or movement behaviour during a task and to facilitate changes in order to mitigate or manage musculoskeletal injury. Real-time feedback is a form of extrinsic prompting to assist individuals when intrinsic (internal) feedback mechanisms are weak or compromised, e.g., in cases of stroke or cerebral palsy [43]. Several rehabilitation and clinical studies have reported on the effectiveness of real-time feedback from WIST, for example, in relation to increased range of movement (ROM) [47,48], the retention of motivation during rehabilitation [49] and reduction of lower back pain [48]. Feedback increases self-awareness during functional tasks through goal-directed practice and the repetition of prompts to improve task retention [50], e.g., self-correction of posture through repeated personalised extrinsic prompts. Extrinsic feedback mechanisms are particularly beneficial for patients with stroke, where intrinsic feedback mechanisms are often impaired [49]. Feedback has been reported to improve functional movements and the retention of learning [51,52,53,54]. Given the flexibility of WIST, in terms of its ability to personalise feedback and capture motion in real-time, WIST is becoming more commonly used in movement analysis and neurological rehabilitation settings [43].
Several reviews have researched the use of WIST systems for rehabilitation and motion analysis. A review by Valero, Sivanathan [55] focussing on wearable technology and WMSD within the construction industry reviewed methods to evaluate posture and movement and proposed a new form of WIST to track posture in construction workers. A review by Wang, Markopoulos [43] investigated wearable systems for upper body rehabilitation and found that most were used in studies of patients with stroke. Another review evaluated commercially available WIST devices and evaluated their benefits and limitations [56]. However, no review has summarised the effectiveness of the use of WIST feedback during work or work-related activities to change upper body posture and movement behaviour. Therefore, this scoping review aims to provide a synthesis for the effectiveness of WIST feedback on upper body kinematics during work or work-related activities, as well as the related topics of device wearability and the use of WIST to quantify kinematics. These findings will assist researchers and clinicians by providing knowledge to facilitate the translation of WIST into practice, specifically for upper body work-related activities.

2. Materials and Methods

Preliminary literature searches identified limited studies on the effectiveness of WIST feedback; therefore, a scoping review to support a broader set of aims was considered more appropriate than a systematic review, which applies a narrower focus. This review is based upon the modified framework of Daudt, van Mossel [57] for scoping reviews developed by Arksey and O’Malley [58] to assist with the continuum in methodological standards. These authors [57] defined a scoping review as a review mapping literature on a particular topic or research area and reporting upon key aspects, such as research gaps, sources and types of evidence to inform practice. Adhering to the recommendations of these authors [57], this review employed a multidisciplinary team (physiotherapists, occupational therapists, software engineer and biomechanist) to ensure that a diverse range of knowledge and expertise was utilised.

2.1. Search Strategies and Search Terms

Six databases were searched from 1 January 2005 to 15 July 2021: Cinahl, Cochrane, Embase, Medline, Scopus, and Sportdiscus, with additional records identified through other sources e.g., Google Scholar (Table 1). Medical subject headings (MESHs) or title/abstract spelling terms and synonym variations were modified to suit each database. For the Scopus database, we performed separate title then abstract searches and used the capitalised ‘OR’ operand. Main headings used in Google Scholar, google searches and the University of Newcastle library.

2.2. Study Selection Process

The selection process was reported in accordance with the PRISMA guidelines [59] (Figure 1).
Eligible studies were required to meet all four inclusion criteria: (1) the use of a WIST system to monitor or track upper body posture and/or movement behaviour using an on-body accelerometer or gyroscope or magnetometer, used in combination or individually, using real-time monitoring and the provision of feedback during work in a workplace setting or during work-related activities; (2) studies that report on feedback from WIST devices in individuals 18–65 years of age of any gender with or without an upper body musculoskeletal disorder (MSD); (3) peer-reviewed journal articles (or full engineering conference proceeding articles) that met criteria 1 and 2, irrespective of study quality; (4) articles in English with inclusion dates ranging from January 2005 (due to WIST being a relatively new technology) to July 2021. Data pertaining to device wearability and the use of WIST to quantify kinematics were extracted from studies that met these four inclusion criteria. Studies were not eligible that included movement theory, model-based movement or animal investigations. Studies of activities other than those at work or that were workplace-related (e.g., the activities of daily living or in-patient settings) were not eligible. Studies including neurological disorders (e.g., stroke or stroke rehabilitation) or conditions other than musculoskeletal disorders were excluded. Lower limb or standing balance studies using feedback from WIST were excluded to allow discussion of specific aspects related to neck and back MSD. Furthermore, studies that reported on validity, reliability or biomechanical evaluations were not eligible. Following the completion of computerised database searches, the removal of duplicates was completed by one investigator (RL) using the Endnote X8 citation manager [60] with any remaining duplicates detected and removed automatically using Covidence systematic review software [61]. Two investigators (RL and JY) independently screened articles. Disagreements following each screening round were resolved by consensus, or if consensus was not achieved consultation with a third investigator (SS). The level of inter-rater agreement between investigators for title/abstract and full text screening was assessed using Cohen’s kappa [62].

2.3. Data Extraction

One investigator (RL) independently organised and extracted data from the included studies, with accuracy checked by a second investigator (JY). The extracted data included the study characteristics: year, setting, study population and condition, study design, objective and comparison groups; the effect of WIST feedback; the technical characteristics of feedback: monitoring duration, type of feedback, feedback trigger, feedback source, origin of set-point and anatomical monitoring; and WIST system characteristics: model/manufacture, frequency, sensor type, sensor quantity, connection and attachment method, sampling rate, filter type, cut-off frequency, algorithm origin, sensor validation, anatomical location and device limitations.

2.4. Methodological Quality

The methodological quality of the included studies was assessed using the National Institutes of Health (NIH) risk-of-bias tools for ‘Observational Cohort and Cross-Sectional Studies’ (for cross-sectional studies), the tool for ‘Before-After (pre-post) Studies With No Control Group’ (for pre-post studies) and Controlled Intervention Studies (for randomised controlled trials) [63]. Two investigators (RL and JY) independently assessed the risk of bias; if a consensus was not met, resolution was achieved through consultation with a third investigator (SS). Cohen’s kappa was used to assess the level of agreement between reviewers. To control for rater bias, individuals were from different disciplines and detailed inclusion and exclusion criteria were used.

2.5. Quality of Evidence for the Effectiveness of Feedback

A synthesis to evaluate the levels of evidence was performed since the included studies were heterogenous in terms of the equipment detailed and study design. The synthesis rates the level of evidence for the reported outcomes from studies based on the following hierarchical criteria, as previously described [64,65,66]:
Strong evidence—consistent findings among three or more studies, including a minimum of two high-quality studies.
Moderate evidence—consistent findings among two or more studies, including at least one high-quality study.
Limited evidence—findings from at least one high-quality study or two low- or moderate-quality studies.
Very limited evidence—findings from one low- or moderate-quality study.
Inconsistent evidence—inconsistent findings among multiple studies (e.g., one or multiple studies reported a significant result, whereas one or multiple studies reported no significant result).
Conflicting evidence—we defined conflicting as contradictory results between studies (e.g., one or multiple studies reported a significant result in one direction, whereas one or multiple studies reported a significant result in the other direction).
No evidence—results were insignificant and derived from multiple studies regardless of the quality.

3. Results

A total of 4351 articles were identified from the databases and additional record searches (Figure 1). Duplications (1249) were removed. Title and abstract screening of 3102 studies excluded 3035 studies, with most exclusions based on no feedback and/or evaluation, reliability and validity studies, abstracts, or a lack of relevance to upper body posture or work activities. Following the full-text screening of 67 studies, a further 53 studies were excluded (reasons provided in Figure 1 and Section 3.1). Fourteen studies met the inclusion criteria of this review. The characteristics of the included studies are summarised in Table 2.

3.1. Excluded Studies

A total of 53 studies were excluded in full-text screening as follows: WIST studies without feedback (n = 14) [55,81,82,83,84,85,86,87,88,89,90,91,92,93]; feedback without an inertial sensor (s) [94]; sensors integrated into equipment (n = 5), e.g., seat sensors and robotic devices rather than those worn by an individual [95,96,97,98,99]; standing balance and/or lower body sway (n = 5) [100,101,102,103,104]; abstracts (n = 7) [105,106,107,108,109,110,111]; stroke/other neurological rehabilitation studies (n = 4) [112,113,114,115]; a non-work setting (n = 3) [116,117,118]; no evaluation of WIST feedback effectiveness (n = 6) [119,120,121,122,123,124]; research proposal (n = 1) [125]; and validity and reliability studies without a field assessment of WIST feedback (n = 7) [40,42,126,127,128,129,130].

3.2. Effectiveness of Feedback

The majority of studies reported improvements in primary outcomes using feedback compared to no feedback with no negative health effects (Table 3). No included study reported post-intervention monitoring to assess the retention of improvements following WIST feedback. Four types of feedback prompts were identified throughout the included studies: auditory [68,71,73,74,75,80]; vibrotactile (haptic) [69,72,74,76,77,78,79]; visual [67,70,71,72,74,75,78] and summary feedback (visual) [74]. The most common multimodal feedback interaction was auditory and visual [71,74,75]. Most studies applied concurrent bandwidth feedback [67,69,73,75,76,77,79,80] (i.e., a feedback prompt when a movement variable exceeds a pre-determined set-point (feedback trigger) during the activity/task [131,132]; and in conjunction with a pre-determined time period [68,71,72,74,78] (Table 4); the remaining studies used terminal bandwidth feedback (feedback post-activity) [70] and summary feedback in addition to visual, auditory and vibrotactile feedback [74].
Improved trunk posture occurred using various types of WIST feedback for different tasks, for example, auditory during lifting [73], moving patients from bed to chair [80] and office tasks [68], vibratory/auditory during nursing tasks [74], visual/vibrotactile during several simulated workplace tasks [78] vibrotactile during a computer task [76] and vibrotactile [69] and visual [70] during dental procedures (Table 3). However, using vibratory feedback alone during sedentary tasks resulted in no trunk posture improvements [77]. Improved neck posture was observed using WIST feedback: vibrotactile/visual [72,78] and visual/auditory [75] and vibratory during computer tasks [76], and visual during a dental procedure [70]. Visual/auditory feedback reduced the exposure to WMSD during an industrial task [71]. A slight risk increase (RULA/LUBA) was observed for arms during tasks 2–4 using visual/vibrotactile feedback [78] (though the results were confounded by participants reaching for the chair during these tasks). However, [79] identified less accumulated time and angles for arms during the simulated mail sorting tasks. Visual feedback increased step counts during office tasks [67]. Two studies reported changes in pain symptoms from WIST feedback: increased neck pain during a computer task [76], and no significant reduction in lower back pain during sedentary work [77] (Table 3).
Table
Table 3. Effect of wearable inertial sensor technology (WIST) feedback on participant outcomes in each of the included studies.
Table 3. Effect of wearable inertial sensor technology (WIST) feedback on participant outcomes in each of the included studies.
StudyReported Effect from Feedback
Brakenridge, Fjeldsoe [67]Improved between-group differences in movement behaviour at 12 months in overall hours/16 h using feedback compared to no feedback:
  • Increased stepping time: +20.6 min (95% CI, 3.1, 38.1), p = 0.021
  • Increased step count +846.5 steps (67.8, 1625.2), p = 0.003
Improved within-group differences from baseline to 12 months during work hours/10 h using feedback compared to no feedback:
  • Increased stepping: +9.1 min (0.2, 17.9), p = 0.045
Ribeiro, Sole [68]Reduced rate within-groups of exceeding lumbar (lower back) postural threshold using constant feedback compared to intermittent and no feedback (4-week follow-up minus baseline):
  • Constant feedback: frequency/h −0.9 (95% CI, −1.9, −0.1), d = 51 p = 0.03
Large effect between-group postural patterns favoured constant feedback (4-week follow-up minus baseline):
  • Constant feedback: frequency/h −0.49 (−1.62, 0.64), d = 0.60, p = 0.91
Thanathornwong and Suebnukarn [69]Decreased upper trunk flexion and lateral trunk flexion using feedback compared to no feedback:
  • flexion 3.6° to 8.5° (95% CI, NR) p = 0.05
  • lateral flexion 6.1° to 8.9° (95% CI, NR) p = 0.05
Thanathornwong, Suebnukarn [70]Decreased flexion using feedback compared to no feedback: Mean (SD)
  • Neck: pre-test: 16.7° (8.88); post-test 10.5° (7.29) p < 0.05
  • Upper trunk: pre-test: 22.0° (6.1); post-test 12.8° (6.58), p < 0.05
Vignais, Miezal [71]Reduced risk of WMSD between-group for lower global RULA † scores using feedback: Mean (SD):
  • Feedback 3.95 (.83); no feedback 4.35 (.54), p < 0.05
Decreased time spend in each RULA range using feedback: % (SD)
  • Range 3–4 feedback 76.4% (17.7); no feedback 56.9% (13.6), p < 0.05
  • Range 5–6 feedback 16.8% (13.2); no feedback 30.5% (6.9), p < 0.05
  • Range 7 feedback 3.4% (5.5); no feedback 10.4% (12.2), p = 0.07
Decreased neck exposure to hazardous posture: % (SD)
  • Feedback 12.24% (15.89); no feedback 34.03% (10.8), p < 0.05
Overall time in task: Mean (SD) seconds
  • Feedback 227.9 s (33.7); no feedback 157.0 s (28.9), p < 0.005
Ailneni, Syamala [72]Reduced cranio-cervical and neck flexion angle during sitting computer condition favouring feedback: Mean, (SD)
  • Neck angle: Feedback 57.52° (1.25); no feedback 63.16° (1.83), p = 0.02
  • Cranio-cervical angle: Feedback 157.14 (1.89); no feedback 160.90 (2.00), p = 0.01
  • No significant difference between head flexion
Reduced cranio-cervical and neck flexion angle during standing computer condition favouring feedback: mean, (SD)
  • Neck angle: feedback 58.49° (1.11); no feedback 63.21° (1.38), p < 0.01
  • Head angle: feedback 81.32 (2.01); no feedback 84.35 (1.69), p = 0.04
  • No significant difference between Cranio-cervical angle
Boocock, Naudé [73]Decreased lumbar (lumbosacral) flexion at 20th minute:
  • Feedback 182.6° (95% CI, 182.6–190.4); no feedback 188.2° (182.7, 193.8), p < 0.001
Decreased trunk flexion at 20th minute:
  • Feedback 27.4° (23.7–31.1); no feedback 48.3° (43.5, 53.2), p < 0.001
Time to perform lift (s) at 20th minute: feedback 1.07 s (0.99, 1.14); no feedback 1.31 s (1.17, 1.45), p = 0.01
Bootsman, Markopoulos [74]Improved lumbar posture occurrences reduced using feedback compared to no feedback: mean, (SD)
  • Feedback (vibration and audible) M = 22.1, (10.8) and feedback (vibration, audible and smartphone) M = 19.1, (12.2); no feedback (baseline) M = 25.5 (12.5); no feedback (withdrawal condition) M = 24.9, (12.8).
No significant between feedback conditions
Breen, Nisar [75]Reduced time spent in poor neck (flexion/extension) posture using feedback during a 5-h period:
  • Feedback 6.5% (SD, 9.6); no feedback 35.7% (15.26), p < 0.05
Kuo, Wang [76]Between-group difference favouring feedback compared to no feedback
  • Reduced neck flexion 3.3° (95% CI, 1.8°, 4.7°), p < 0.001
  • Reduced upper cervical angle 3.3° (1.7°, 5.0°), p < 0.001
  • Reduced lower thoracic (lumbar) angle 1.6° (0.4°, 2.7°), p = 0.001
  • Increased NRS score between-group difference:
  • ↑ time ↑ neck pain: 1.6 (0.9, 2.4), p < 0.001
  • ↑ time ↑ shoulder pain: 1.8 (1.0, 2.7), p < 0.001
  • Decreased cervical erector spinae activity:
  • Right 24.9% (8.4, 41.5), p = 0.005; left 24.6% (7.7, 41.5), p = 0.007
Park, Hetzler [77]No between-group difference in Cornell musculoskeletal discomfort questionnaire scores (CMDQ):
  • Lower back pain (LBP) experience: (F (1,29) = 0.58, p = 0.45
  • LBP discomfort (F (1,18) = 0.14, p = 0.71
  • LBP interference (F (1,18) = 0.93, p = 0.35
No relationship between number of good posture hours and CMDQ score changes:
  • LBP experience r2 (0.17), p = 0.28
  • LBP discomfort r2 (0.03), p = 0.87
  • LBP interference r2 (0.28), p = 0.20)
Cerqueira, Da Silva [78]Reduced HR (high risk) level for neck using feedback compared to no feedback:
  • task 2: 36.6%, task 3: 43.6%, task 4: 45%, and task 5: 26%
Reduced HR (high risk) level for trunk using feedback compared to no feedback:
  • tasks 1–5 respectively 1.8%, 22.4%, 39.8%, 28.6% and 4.6%
No HR (high risk) level for arms using feedback compared to no feedback during all 5 tasksLonger task duration using feedback (M = 343.98 ± 47.27 s) without feedback (M = 263.98 ± 46.47 s)
Lind, Diaz-Olivares [79]Less accumulated time (difference %) and angle (difference %) in upper-arm elevations using feedback compared to baseline (no feedback)
Feedback 1 (accumulative time):
  • ≥30° (↓38%) p = <0.001
  • ≥45° (↓36%) p = <0.001
  • ≥60° (↓49%) p = 0.001
Feedback 2 (accumulative time):
  • ≥30° (↓29.7%) p = <0.001
  • ≥45° (↓14%) p = <0.001
  • ≥60° (↓4.5%) p = <0.001
Feedback 1 (elevation angles):
  • 50th (↓32%) p = <0.001
  • (↓16%) p = <0.001
  • (↓10%) p = 0.002
  • (↓13%) p = 0.001
Feedback 2 (elevation angles):
  • 50th (↓33%) p = <0.001
  • (↓21%) p = 0.001
  • (↓19%) p = 0.001
  • (↓16%) p = <0.001
Doss, Robathan [80]The bed-to-chair condition using feedback compared to no feedback reached significance *:
  • Decrease in mean time to complete each task 6.2° (4.4) second or 23.3% decrease p = 0.01, reduction in trunk flexion 7.6° p = 0.05
  • Reduction in peak trunk flexion/extension (flexion = 1548 (38)°/S2 (p = 0.01) representing a 46.9% decrease) (extension = 1020 (74)°/S2 (p = 0.03))
  • Peak lateral bending acceleration right reduced 1189 (39)°/S2 38.3% decrease (p = 0.01) and left reduced 1473 (187)°/S2 48.4% decrease (p = 0.0007)
  • Reductions in peak rotation acceleration left 1188 (143)°/S2 (p = 0.003), right 1398 (1.3)°/S2 (p = 0.001)
  • Reduction in time to complete task 6.2 (4.4) seconds (p = 0.01)
* Significance not reached for conditions using a sling under and/or patient adjustment
NR: not reported; † RULA: The Rapid Upper Limb Assessment [133].
Table
Table 4. Technical characteristics of wearable inertial sensor technology (WIST) feedback in each of the included studies.
Table 4. Technical characteristics of wearable inertial sensor technology (WIST) feedback in each of the included studies.
StudyMonitoring Duration (h/min)Type of FeedbackFeedback Trigger (Set-Point)Feedback
Source		Origin of Kinematic Set-PointAnatomical Monitoring/Direction
Brakenridge, Fjeldsoe [67]Self-directed use. >1 h = valid day. 12-month interventionVisual (concurrent)Device app compares initial daily calibration ¥Smart phoneManufacturerSagittal plane: Lumbopelvic (flexion/extension)
Ribeiro, Sole [68]4 weeks: working hours only. Mean h (SD): 5.9 (1.9)Auditory (concurrent with latency)Exceeding cumulative ROM threshold: Feedback triggered when workers exceed 45° pelvic flexion + max of 2° flexion/min +static posture (flexed pelvis) = 5 sSensor deviceLiterature-basedSagittal plane: Lumbopelvic: (flexion/extension)
Thanathornwong and Suebnukarn [69]NR.Vibrotactile (concurrent)Exceeding posture outside the norm of the hidden Markov models (HMMs)Sensor deviceHidden Markov models (HMMs)Sagittal and frontal plane: upper body (lateral flexion; flexion/extension)
Thanathornwong, Suebnukarn [70]NR.Visual (terminal)Exceeding posture outside the norm of the hidden Markov models (HMMs)NRHidden Markov models (HMMs)Sagittal and frontal plane: upper body and head (lateral flexion; flexion/extension)
Vignais, Miezal [71]4 minVisual (incorporated in to STHMD) and auditory (concurrent with latency)Auditory: RULA global score = 7, => 0.5 s; 5–6, =5 s
Visual: Local score: Shoulder and upper arm > 5; Elbow and lower arm >3; Wrist and hand >5; Neck and head > 4; Pelvis and trunk > 4. ¤		Within the head-mounted displayRapid Upper Limb Assessment (RULA)Sagittal, frontal and transverse plane: upper body (lateral flexion; flexion/extension and rotation)
Ailneni, Syamala [72]2 hVibrotactile and visual (concurrent with latency)Neck flexion angle greater than 15° and exceeding 30 s relative to neutral posture ¤Sensor deviceLiterature-basedSagittal plane: neck/head posture
(Flexion/extension)
Boocock, Naudé [73]20 minAuditory (concurrent; high pitched tone)80% of maximum lumbosacral range of motion was exceeded ¤Purpose-built softwareLiterature-basedSagittal plane: lumbosacral, trunk posture
(Flexion/extension)
Bootsman, Markopoulos [74]4-phase treatment: baseline 30 min; per phase A, B and C = 60 min each. Total duration 210 minAuditory, vibrotactile, visual and summary feedback (concurrent with latency)>20° from neutral posture during lower back flexion and exceeding 1.5 sGarment (auditory and vibrotactile)
Visual (smartphone)		Literature-basedSagittal plane: lumbar spine
(Flexion/extension)
Breen, Nisar [75]5 h without feedback, another 5 h with feedbackVisual and auditory (concurrent)Exceeding −5 to 10° thresholdVisual to user via a graphical interface (GUI) on a computerLiterature basedSagittal plane: neck cranial-vertebral: (flexion/extension).
Kuo, Wang [76]2 hVibrotactile (concurrent)Exceeding threshold ¥Sensor deviceManufacturerSagittal plane: trunk posture
(Flexion/extension)
Park, Hetzler [77]21 days during working day (8.5 h average per day)Vibrotactile (concurrent)Exceeding threshold ¥Sensor deviceManufacturerSagittal and frontal plane: Upper body posture
Cerqueira, Da Silva [78]Maximum duration 391 s (<6.5 min)Visual and vibrotactile (concurrent)Combination of RULA and LUBA thresholds
Trunk sagittal: (risk)
(high) < −10° ∆t > 1 s extension
(high) > 60° ∆t > 1 s flexion
(medium) <20° <60° ∆t > 10 s flexion
(low) −10° <20° desirable
Trunk coronal: (risk)
(medium-high) < −10° or >10° ∆t > 5 s bent left or right
(low) −10° <10° desirable
Neck sagittal:
(high) <−5° ∆t > 1 s extension
(high) >20° ∆t > 1 s flexion
(medium) 10° <20° ∆t > 10 s flexion
(low) −5° <10° desirable
Neck Coronal:
(medium-high) <−5° or >5° ∆t > 5 s bent to left or right
(low) −5° <5° desirable
Arm sagittal:
(high) >90° ∆t > 1 s
(medium-high) <−20° ∆t > 5 s shoulder adducted
(medium-high) 45° <90° ∆t > 5 s abducted
(medium) 20° <45° ∆t > 10 s
(low) −20° <20° desirable
Arm coronal:
(medium-high) −20° or >20° ∆t > 5 s shoulder flexed/extended
(low) −20° <20° desirable		Haptic motors × 4 and visual to user via a graphical interface (GUI) on a computerLiterature based on rapid upper-limb assessment (RULA) and loading on the upper body (LUBA)Sagittal and coronal plane of the trunk, neck and arm.
Lind, Diaz-Olivares [79]<15 minVibrotactile (concurrent)Exceeding ≥30° and ≥60° threshold for the dominate armOn-body two-frequency-level vibrotactile unitLiterature-basedSagittal plane: upper arm flexion
Doss, Robathan [80]NRAuditory
(concurrent)		>45° trunk flexionSmart phoneLiterature-basedSagittal plane: trunk posture (flexion)
NR: not reported. ¤ Researcher discretion; ¥ manufacturer discretion: all biomechanical set points/thresholds are pre-determined by the researchers or manufacturer. STHMD: see-through head-mounted display. Min: minutes.

3.3. WIST Device Wearability

The sensor attachment methods in the fourteen included studies were diverse: ‘on’ clothing (n = 6) [68,69,70,78,79,80]; within a smart sensing garment (n = 1) [74]; worn as a belt (n = 1) [67]; direct skin attachment using tape (n = 2) [73,76]; magnetic clasp to undershirt (n = 1) [77]; secured by bands on ears positioned posteriorly on neck [72]; and not reported (n = 2) [71,75] (Table 5). Ribeiro, Sole [68] evaluated workers’ perception of WIST usefulness using a Likert scale. Three studies (n = 3) [74,78,79] provided a comprehensive evaluation of their WIST device (garment) in terms of user comfort and acceptability, e.g., three validated questionnaires and a semi-structured interview [74], assessments of users experience via a semi-structed interview and discomfort/pain using the Borg CR10 [134] scale [79], and Cerqueira, Da Silva [78] applied the guidelines of the System Usability Scale (SUS) [135].

3.4. Use of WIST Systems to Quantify Kinematics

A tri-axial accelerometer was used in all included studies, with the tri-axial IMU used in five studies [71,73,74,78,79] (Table 5). On-body sensor quantities were diverse between studies, e.g., IMU studies (n = 5) [71,73,74,78,79] ranging from two IMUs to seven on-body sensors. Increasing the number of IMUs enabled greater complexity in movement data within a three-dimensional (3D) space. The remaining studies [67,68,69,70,72,75,76,77] (n = 8) applied one sensor. Three studies reported a rationale for sensor quantities [74,75,78]. Eight studies developed custom WIST systems and/or software [69,70,71,74,75,78,79,80] to address their specific research; the remaining studies [67,68,72,73,76,77] utilised commercial devices.
Sensor sampling frequency and data processing methods (filtering type and filtering cut-off frequency) were not reported in studies using a commercial device nor in some customised studies [67,68,69,70,72,73,74,76,77,80]. Three studies [71,75,78] reported the sensor sampling frequency; two studies reported the sampling frequency range [69,70]. The reported limitations of WIST were sensor drift [67,79]; a lack of time stamping during data recording [68]; inconsistencies in Bluetooth connection [77,79]; software issues [69]; a lack of degrees of freedom (DOF) [75]; loose fitting sensors [70]; magnetic material interference with the magnetometer signal [71]; garment may not suit individual anthropometric measurements [74]; and a potential reduction in sensitivity without direct validation [72,79] (Table 5).
Two of the included studies conducted a prior evaluation into WIST system reliability and validity [79,136]; another study validated the WIST system prior to use [78] (Table 5). No other studies reported on the reliability nor validity of their WIST system [69,70,71,72,74,75,80]; the remaining included studies reported or mentioned the validation results from the manufacturer [67,73,76,77]. A three-dimensional motion capture system was used simultaneously with the WIST sensor(s) in four studies [72,73,76,80].

3.5. Risk of Bias

Inter-rater agreement between investigators (RL and JY) was high: title and abstract screening (k = 0.75; 95% CI, 0.59, 0.90); full text screening (k = 0.90; 95% CI, 0.71, 0.99). Controlled intervention studies (n = 2; Table 6) scored well in terms of the study description, the sample size being sufficient to detect differences and randomisation. Bias was identified in several quality criteria, e.g., blinding, baseline characteristics, dropout rates, adherence protocols and outcomes being valid and reliable. Before–after studies (n = 2; Table 7) scored well in terms of their stated objectives, sample size, intervention description and statistical tests used in outcome measures, with bias identified in their participant eligibility criteria, validity and reliability in reported outcomes. Observational cohort and cross-sectional studies (n = 10; Table 8) scored poorly to fairly, as certain criteria were absent from several studies. The risk of bias assessment categorised five studies (n = 8) as ‘fair’ and the remaining six studies (n = 6) were categorised as ‘poor’ (Table 6, Table 7 and Table 8).

3.6. Quality of Evidence

The synthesis of the quality of evidence supporting WIST feedback (Table 9, Figure 2) identified a ‘limited’ level of evidence from eleven studies to support improvements in neck and upper and lower trunk posture; ‘limited’ evidence from two studies supporting improved neck and lower back pain/discomfort; ‘very limited’ evidence from one study supporting movement behaviour; and ‘limited’ evidence from two studies to support a reduction in upper-arm elevation angle or accumulative time. Many included studies were not forthcoming in details about WIST technology/equipment, study design, sensor validation or data collection procedures; hence, methodological reproducibility would not be achievable. Therefore, to improve the consistency and quality of the evidence of future WIST studies, in this review we propose a ‘Technology and Design Checklist’ (TDC) to improve on the minimum reporting criteria (Table 10). The TDC is a checklist for researchers of the essential technical and study design aspects to consider reporting when designing a study using WIST. The objective of the TDC is to support future research investigating the effects of WIST, to minimise reporting omissions.

4. Discussion

This review provides evidence for the effectiveness of feedback from WIST for work or work-related activities. The review summarises the effects of WIST feedback on upper body kinematics and movement behaviour, then discusses wearability and the use of WIST to quantify kinematics, as expressed in the fourteen included studies. Meaningful and clinically relevant improvements in posture and/or movement behaviour were observed using WIST feedback compared to not using feedback (Table 3), although no improvements in pain symptoms were identified. The duration of feedback was diverse, ranging from 4 min [71] to 12 months [67]. Longer interactions of feedback may improve the retention of learnt skills [48], but no included study investigated the effects of varying durations. Visual and/or vibrotactile (haptic) feedback were the most applied feedback strategies (Table 5). Only three included studies assessed wearability to indicate the level of device acceptability, and most of the included studies did not comprehensively report on WIST technical aspects or device validity (Table 5). Of the fourteen included studies, tri-axial accelerometers, followed by IMUs, were the most frequently used technologies (Table 5). This review identified lower levels of evidence in supporting any of the identified outcomes resulting from WIST usage, due to poor/fair study quality and between-study heterogeneity, preventing data pooling.

4.1. Effectiveness of Feedback Strategies

Overall, most of the reported outcomes from the use of WIST feedback assessed in the current review were positive, i.e., improved upper body posture or movement behaviour in users. WIST feedback can have practical merit in the workplace, where real-time feedback is a constant reminder of adverse posture and/or movement behaviour compared to previously learnt ergonomic instruction that tends to be forgotten, especially during cognitively demanding activities [138]. However, gauging the effectiveness of a particular feedback type was difficult due to the between-study heterogeneity of tasks evaluated and feedback strategies used (Table 3). The effectiveness of various feedback types has been previously debated in motor relearning interventions that reported varying success [139,140,141]. Visual and/or vibrotactile feedback were the most commonly preferred feedback strategies in this review. Visual feedback was rarely used individually (n = 2) and may be paired with auditory feedback (n = 2) or vibrotactile (n = 2) feedback. Only one included study applied three feedback strategies [74]. Combining visual and auditory feedback is more effective than using visual feedback alone to improve performance during a single task [142], which might explain their use (n = 3) among studies within this review.
Vibrotactile and/or auditory feedback strategies do not require visual attention, which may be preferred for some tasks that require constant visual attention. However, visual feedback can enhance users’ learning through visualising their movement with greater detail, and is commonly applied in upper body rehabilitation [43]. Audible feedback in a workplace environments may not be practical, and can incur potential confounding effects; for example, users may become self-conscious or embarrassed during audible feedback, which may adversely affect their task performance [74], or feedback may become dampened due to a noisy environment [78]. Hence, any type of WIST feedback should be suitable for that working environment and should not distract the user or others from their tasks.
Concurrent bandwidth feedback was the preferred method of feedback interaction in most included studies (n = 13/14 studies) (Table 4), and this is consistent with other postural and rehabilitation reviews [43,103,131,139]. The consensus suggests that feedback content should match the user’s proficiency to the specified task, for example, concurrent bandwidth feedback is most suited to non-proficient users for shorter feedback periods, whereas individuals with higher skill levels are suited to terminal feedback [43,131], as applied during a dental procedure in one included study [70], and/or for longer training periods [79]. A pre-determined latency period is often incorporated to prevent the excessive prompting of feedback during short-term aberrant movements [143]. Latency was applied in the feedback strategies of several of the included studies to assist with any unnecessary prompting (n = 6) [68,71,72,74,78,79]. These examples suggest that the selection of feedback types/schedules are dependent on the task and environmental constraints [144]. This review identified no study that applied feedback fading or self-controlled frequency schedules to reduce an individual’s dependence on feedback within a given task [131,141].

4.2. Effects of WIST Feedback on Posture, Movement Behaviour and/or Pain

Our review findings are consistent with other recent reviews that have identified that feedback from WIST can be effective. However, the majority of reviews focused on the use of WIST feedback in sporting applications, balance or stroke [44,145,146]. Wang, Markopoulos [43] reviewed 45 studies using WIST for rehabilitation and found only three studies that reported the clinical effects of WIST feedback, primarily in populations with stroke. One review that examined the effects of feedback from devices other than inertial sensors found moderate evidence that feedback from surface electromyography (sEMG) does not prevent WMSD [23]. Another found that feedback from a computer mouse caused workers to modify their postures, which resulted in the reduction of neck and/or shoulder WMSD in workers [147]. In the majority of reviews, the authors appeal for higher-quality studies investigating WIST feedback [44,146,148]. Thus, improving the quality of future studies may enable the greater utility of WIST in rehabilitation, clinical and workplace settings.
In the current review, all the included studies that reported feedback from WIST compared to no feedback demonstrated improved upper body postures (reductions in non-neutral positions) and/or movement behaviour (Table 3). In this review, ‘very limited’ evidence from one study was identified to support changes in movement behaviour from WIST feedback. Improvements in upper body posture and/or movement behaviour can be learnt rapidly using feedback from WIST [73,76]. However, retaining learnt behaviour post-feedback intervention is suggested to be more dependent on the duration of the feedback interaction than the content/type of feedback (visual, vibrotactile, audible or multimodal) [48]. For example, compared to baseline or 3-month follow up, the included study by Brakenridge, Fjeldsoe [67] identified significant improvements in movement behaviour using WIST feedback at the 12-month period. In contrast, the included study by Bootsman, Markopoulos [74] found that participants immediately reverted to baseline postures during no WIST feedback despite improved posture during the previous 60-min multimodal WIST feedback phase (Table 4), or if participants retained knowledge of improved lifting tasks post-feedback intervention [80]. This may suggest that feedback distributed across a greater time period is more effective at modifying behaviour and causing acceptance in learning than feedback delivered during a single point in time [149]. Nevertheless, only one study in this current review reported on the longevity of feedback [67]. In other sectors of health research, the retention of learned movement behaviour from WIST was shown for arm-hand movement in stroke rehabilitation [43,150] and lower limb running biomechanics [44]. Previous research on the retention of skills following feedback has indicated that a fading schedule of feedback is most effective for motor-relearning and for learned skills to be retained, suggesting that gradually reducing the dependence on external feedback improved the intrinsic feedback mechanisms and subsequent motor re-learning to occur [44,132,151]. Though, the retention of skills following feedback is seldom evaluated [146]; hence, further post-evaluation research is required.
This review identified ‘limited’ evidence from two work-related studies that WIST feedback does not improve neck and lower back pain/discomfort (Table 9). Despite improved posture as a result of WIST feedback, participants in two studies reported pain (increased neck pain [76] during a one-hour task, and no significant change in lower back pain [77] during a three week intervention) (Table 3). However, pain reduction may not be immediately evident using WIST feedback; for instance, previous research found that lower back pain symptoms subsided near the end of the six-week intervention [152]. Kent, Laird [48] identified that the WIST feedback group self-reported a slight peak in lower back pain at the 8-week mark, followed by a clinically relevant difference in pain reduction at the 3-month and 12-month follow-up compared to a control. This suggests that pain may worsen initially until an individual adapts to their new postural state. This circumstance may occur as individuals with neck or lower back pain are more likely to experience maladaptive neuromuscular control, which may require longer periods in rehabilitation [153,154,155], which may challenge postural changes in response to short-term feedback strategies. Analogous to improvements in posture or movement behaviour, the likelihood of retaining learnt behaviour to reduce pain appears to be dependent on longer periods of feedback interaction. However, extrinsic feedback dependency may arise from a longer duration of concurrent feedback dominance, causing the user to be less responsive their body’s own internal or intrinsic feedback mechanisms [132]. Hence, WIST feedback latency during rehabilitation studies must be considered.
This review identified ‘limited’ evidence from eleven studies that WIST feedback improves neck, upper and lower back posture (Table 9). The included studies investigating lower back kinematics reported results indicating that feedback from WIST improved lumbar posture during sitting (1.6°) [76], reduced trunk flexion during patient bed-to-chair transfers (7.6°) [80] and resulted in clinically relevant changes in lumbar tilt during a lifting task (15.2°) [73]. These findings are consistent with a previous study on the activities of daily living showing a reduction in lumbar flexion (~23°) from WIST feedback [36]. However, variations in joint angle magnitude can be due to differences in inter-segmental angle definition, participant demographics or activity requirements. Feedback triggers (kinematic set points) were heterogenous between studies (Table 4). Therefore, the determination of an average value for changed postures from the included studies was unachievable, e.g., triggers for postural change occurred when exceeding 45° lower back flexion for longer than five seconds [68], greater-than-45° trunk flexion without latency [80];,greater-than-20° lumbar flexion for 1.5 s [74] and exceeding 80% of the maximum lumbar range of motion [73]. Nevertheless, as neck and lower back pain are a leading cause of global disability [5,156], changes in posture from WIST feedback that may reduce the risk of WMSD are encouraging. Greater magnitude in neck flexion is associated with an increased risk of the development of neck pain [157], especially during prolonged computer use [158]. Additionally, individuals that adopt a forward head posture (large cranio-cervical angle in the sagittal plane) are more likely to experience neck pain [159] and pain-induced headaches [160]. Three included studies showed a significant reduction in neck flexion that ranged between 3° and 6° using WIST feedback compared to no feedback during computer use [72,76], and during a dental procedure [70]. In previous research, individuals with neck pain presented with 6.8°-greater neck flexion compared to asymptomatic individuals [161]. A reduction in the gravitational moment of the neck joint [162] may assist in pain reduction [157], muscular fatigue and lower MSD risk [163]. Another three studies in this review [71,75,78] showed significantly less time spent in ‘adverse neck postures’ using feedback from WIST, suggesting that ‘less hazardous’ postures were adopted during the task using WIST feedback compared to no feedback. Though industrial processes have automated some repetitious workplace activities, manual handling tasks are in most instances still a feasible and viable option for many businesses to adopt [164]. Hazardous postures may be dependent on the actual task undertaken, for example, the included study by Lind, Diaz-Olivares [79] identified a significant reduction in adverse (high-risk) upper arm positioning, although the participants in the study by Cerqueira, Da Silva [78] did not present any arm postures in the high-risk category, as determined by RULA or LUBA guidelines. Despite these included studies having promising outcomes, the level of evidence for improved upper body posture was limited; therefore, caution during interpretation is recommended.

4.3. Device Wearability

Wearability guidelines consider appropriate sensor placement to enhance user comfort, device usability [45] and device accuracy [165]. Therefore, a single sensor or wireless body area network (WBAN) design must consider conforming to the user’s body, weight, attachment method, connection (data transmission, wireless/cable), interaction with movement, unobtrusiveness, duration of use and thermal aspects (breathability between skin and the device) [46]. The placement/attachment of individual sensor(s) were only superficially described throughout most of the included studies. The included study by Bootsman, Markopoulos [74] used an e-textile garment integrated two tri-axial IMUs into the workplace uniform, providing greater comfort and practicality compared to other common methods of sensor placement (e.g., directly on skin) (Table 5). However, in the study by Bootsman, Markopoulos [74], accuracy was considered, though not assessed, suggesting that the garment may have introduced error if loosely fitted to the skin. Nonetheless, studies using e-textile garments have shown promising results in neurological rehabilitation [43,120,166], and thus further investigation of this approach during work-related activities is warranted.
To determine technology acceptance, wearability must also incorporate the user’s experience and perception of WIST feedback. The included study by Bootsman, Markopoulos [74] identified that wearability influenced device usability, with feelings of negative social influences being expressed by users when patients and/or colleagues overheard the audible feedback that emanated from the WIST garment during its use; which may potentially affect task performance [167]. Other areas of health and rehabilitation services have experienced similar issues when using audible feedback opposed to more subtle feedback strategies such as vibratory feedback [168,169]. Therefore, each sensor should not be salient or distract the user. Assessments in wearability (comfort, usability and safety [167,170]) are a benchmark for device improvements in future, especially for studies conducting prolonged monitoring [46]. However, in the current review, studies rarely addressed wearability, limiting the translation of WIST initiatives into practice.

4.4. Use of WIST Systems to Quantify Kinematics

The included studies indicated that the tri-axial accelerometer was used to track more simplistic body movements, whereas tri-axial IMUs tracked more complex kinematic movements, increasing the measured DOF during tasks (Table 4). Hence, sensor selection appears to be dependent on the complexity of the desired detection of movement during a specific task, which is consistent with other recent studies [30,36]. A known limitation is gyroscope drift [171], which occurs from accumulative measurement errors generated by fluctuating offset averages and measurement noise (despite appropriate calibration) [172] as reported in two included studies [68,79]. Additionally, magnetic disturbance can increase the divergence in yaw rotation accuracy (z-axis) in respect to time within the magnetometer signal [173,174]. These errors in orientation estimates can be mitigated through various filtration algorithms, e.g., the Kalman filter [175,176,177], and/or dedicated reference points, e.g., optical-based tracking systems integration [178]. Most included studies (n = 13) focused on less complex and dynamic movement rotations in flexion/extension (x-axis) and lateral flexion (y-axis) rather than head or body rotation (z-axis); therefore, orientation estimates were not affected by drift. To track complex movements, the included study by Vignais, Miezal [71] used multiple IMUs (9 DOF) to monitor rotations (z-axis) of the head, arm and upper trunk, and improved the level of certainty within the orientation estimates and the overall sensor accuracy by way of a Kalman filter [34,177]. However, the Kalman filter is not a fundamental requirement for all applications [174]. Nevertheless, differences in joint angles >10 degrees in magnitude with and without this filter during kinematic testing have been reported [172,179]. Understanding these limitations will help to improve reporting accuracies in future studies that track complex movements.
Many included studies did not disclose sampling frequency nor filtering cut-off frequency (Table 5). These are essential components to ensure WIST device accuracy, reliability and validity [180,181]. The Nyqusit sampling theorem may be violated if the sampling frequency is too low, as kinematic data may be lost in the sampling process [33,182]. Too low or high filtering cut-off frequencies will over-smooth the data or incur unwanted noise in the output data, respectively [33]. Although no reporting standards currently exist, failing to report these parameters reduces the overall level of confidence in the stated outcomes.
Importantly, WIST device validation against a gold standard such as a 3D motion capture system is paramount and is a requirement for successful translation into clinical practice [30,36,183]. Only the included study by Cerqueira, Da Silva [78] conducted a direct validation analysis to determine sensor accuracy, although Ribeiro, Sole [68] referred to their previous study, which assessed WIST device validity and reliability using a similar study design and setting (Table 5). As WIST device accuracy and reliability are task- and environment-dependent [30], achieving appropriate sensor validation for a specific task and location is a necessity. Thus, reported outcomes from the included studies without validation should be viewed with caution.

5. Study Limitations

This review is limited to the included studies that applied feedback from WIST for work-related tasks; therefore, examinations of device wearability and the use of WIST to quantify kinematics was summarised only from these 14 studies. We acknowledge that further studies on device wearability and the use of WIST to quantify kinematics exist; however, they were not the focus of this review. The included studies were heterogeneous in terms of workplace settings and activities, anatomical regions of interest, the level of WIST development and the reported outcomes. Hence, the pooling of data was not achievable. However, some studies have reported meaningful and clinically relevant differences using their specific WIST. No summary for wrist/hands nor for task duration comparing feedback to no feedback was conducted, as information in the included studies was scarce.

6. Future Research

A risk of bias and a lack of detail in reporting for methodological reproducibility was identified for most of the included studies. Therefore, in this review we propose a ‘Technology and Design Checklist’ for minimum reporting in studies evaluating outcomes using WIST or WIST interventions (Table 10). The checklist has four key research recommendations (data collection, WIST processing/analysis, feedback parameters and study design) to assist researchers in improving methodological quality in future studies. The reliability and validity of WIST should be reported to ensure dependability in reported outcomes. Future studies should investigate skill retention following WIST feedback. Additionally, greater collaboration between researchers and health professionals may assist in translating WIST more effectively into clinical practice.

7. Conclusions

This review identified 14 studies investigating feedback from WIST during work-related tasks. All studies used tri-axial accelerometers, with three studies using tri-axial IMUs to provide feedback on posture or movement behaviour during work-related tasks. Visual and/or vibrotactile feedback were the most common feedback strategies, with only three studies evaluating comfort and/or wearability. A low level of evidence from the 14 studies supported upper body posture and/or movement behaviour improvements using WIST feedback, but no improvements in pain. Few studies reported enough technological detail for methodological reproducibility. Thus, a minimum reporting Technology and Design Checklist for WIST studies has been proposed in this review. Moreover, higher-quality studies are needed to translate WIST systems into current ergonomic or rehabilitation practices for individuals with work-related posture or movement problems.

8. Key Findings

This review investigated wearable inertial sensor technology to measure upper body posture and movement behaviour and provide feedback during work or work-related activities.
Based on the low quality of studies, there was limited evidence to support the use of wearable inertial sensor feedback to change neck, upper and/or lower trunk posture, very limited evidence supporting changes in movement behaviour and limited evidence that WIST feedback improves neck and lower back pain/discomfort.
Despite the importance of user’s acceptance of technology for implementation in the workplace, wearability and/or comfort assessments were only conducted in three included studies.
Most studies lacked technological detail for methodological reproducibility; therefore, a ‘Technology and Design Checklist’ was proposed to recommend a minimum reporting standard for the technical and design methodologies of future wearable inertial sensor studies.

Author Contributions

R.L.: conceptualisation, methodology, writing—original draft, writing—review and editing, formal analysis. C.J.: supervision, writing—review and editing. S.E.: supervision, writing—review and editing. G.S.: supervision, writing—review and editing. J.L.Y.: writing—review and editing. S.J.S.: supervision, conceptualisation, methodology, writing—review and editing. All authors have read and agreed to the published version of the manuscript.

Funding

This research was supported by an Australian Government Research Training Program (RTP) Scholarship.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable. Database searches were conducted only for this scoping review.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Punnett, L.; Wegman, D.H. Work-related musculoskeletal disorders: The epidemiologic evidence and the debate. J. Electromyogr. Kinesiol. 2004, 14, 13–23. [Google Scholar] [CrossRef]
  2. Ezugwu, U.A.; Egba, E.N.; Igweagu, P.C.; Eneje, L.E.; Orji, S.; Ugwu, U.C. Awareness of Awkward Posture and Repetitive Motion as Ergonomic Factors Associated With Musculoskeletal Disorders by Health Promotion Professionals. Glob. J. Health Sci. 2020, 12, 128. [Google Scholar] [CrossRef]
  3. Hurwitz, E.L.; Randhawa, K.; Yu, H.; Côté, P.; Haldeman, S. The Global Spine Care Initiative: A summary of the global burden of low back and neck pain studies. Eur. Spine J. 2018, 27, 796–801. [Google Scholar] [CrossRef]
  4. Damgaard, P.; Bartels, E.M.; Ris, I.; Christensen, R.; Juul-Kristensen, B. Evidence of Physiotherapy Interventions for Patients with Chronic Neck Pain: A Systematic Review of Randomised Controlled Trials. ISRN Pain 2013, 2013, 567175. [Google Scholar] [CrossRef] [PubMed]
  5. Hoy, D.; March, L.; Woolf, A.; Blyth, F.; Brooks, P.; Smith, E.; Vos, T.; Barendregt, J.; Blore, J.; Murray, C.; et al. The global burden of neck pain: Estimates from the global burden of disease 2010 study. Ann. Rheum. Dis. 2014, 73, 1309–1315. [Google Scholar] [CrossRef] [PubMed]
  6. Sadosky, A.B.; DiBonaventura, M.; Cappelleri, J.C.; Ebata, N.; Fujii, K. The association between lower back pain and health status, work productivity, and health care resource use in Japan. J. Pain Res. 2015, 8, 119. [Google Scholar]
  7. Pereira, M.J.; Johnston, V.; Straker, L.M.; Sjøgaard, G.; Melloh, M.; O’Leary, S.P.; Comans, T.A. An investigation of self-reported health-related productivity loss in office workers and associations with individual and work-related factors using an employer’s perspective. J. Occup. Environ. Med. 2017, 59, e138–e144. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  8. Hoy, D.G.; Protani, M.; De, R.; Buchbinder, R. The epidemiology of neck pain. Best Pract. Res. Clin. Rheumatol. 2010, 24, 783–792. [Google Scholar] [CrossRef]
  9. Hansson, E.K.; Hansson, T.H. The costs for persons sick-listed more than one month because of low back or neck problems. A two-year prospective study of Swedish patients. Eur. Spine J. 2005, 14, 337–345. [Google Scholar] [CrossRef] [Green Version]
  10. Gerr, F.; Marcus, M.; Monteilh, C. Epidemiology of musculoskeletal disorders among computer users: Lesson learned from the role of posture and keyboard use. J. Electromyogr. Kinesiol. 2004, 14, 25–31. [Google Scholar] [CrossRef]
  11. James, C.; James, D.; Nie, V.; Schumacher, T.; Guest, M.; Tessier, J.; Marley, J.; Bohatko-Naismith, J.; Snodgrass, S. Musculoskeletal discomfort and use of computers in the university environment. Appl. Ergon. 2018, 69, 128–135. [Google Scholar] [CrossRef] [PubMed]
  12. Sarig Bahat, H.; Weiss, P.L.; Sprecher, E.; Krasovsky, A.; Laufer, Y. Do neck kinematics correlate with pain intensity, neck disability or with fear of motion? Man. Ther. 2014, 19, 252–258. [Google Scholar] [CrossRef] [PubMed]
  13. Gerr, F.; Fethke, N.B.; Merlino, L.; Anton, D.; Rosecrance, J.; Jones, M.P.; Marcus, M.; Meyers, A.R. A prospective study of musculoskeletal outcomes among manufacturing workers: I. Effects of physical risk factors. Hum. Factors 2014, 56, 112–130. [Google Scholar] [CrossRef] [PubMed]
  14. Ariens, G.A.; Van Mechelen, W.; Bongers, P.M.; Bouter, L.M.; Van Der Wal, G. Physical risk factors for neck pain. Scand. J. Work. Health 2000, 26, 7–19. [Google Scholar] [CrossRef] [Green Version]
  15. Da Costa, B.R.; Vieira, E.R. Risk factors for work—Related musculoskeletal disorders: A systematic review of recent longitudinal studies. Am. J. Ind. Med. 2010, 53, 285–323. [Google Scholar] [CrossRef]
  16. Torbeyns, T.; Bailey, S.; Bos, I.; Meeusen, R. Active workstations to fight sedentary behaviour. Sports Med. 2014, 44, 1261–1273. [Google Scholar] [CrossRef]
  17. Western Australia Commission for Occupational Safety and Health. Code of Practice: Manual Tasks 2010/Commission for Occupational Safety and Health. In Code of Practice; Commission for Occupational Safety and Health: West Perth, Australia, 2010. [Google Scholar]
  18. Hannan, L.M.; Monteilh, C.P.; Gerr, F.; Kleinbaum, D.G.; Marcus, M. Job strain and risk of musculoskeletal symptoms among a prospective cohort of occupational computer users. Scand. J. Work Health 2005, 31, 375–386. [Google Scholar] [CrossRef] [Green Version]
  19. Theorell, T.; Hammarström, A.; Aronsson, G.; Bendz, L.T.; Grape, T.; Hogstedt, C.; Marteinsdottir, I.; Skoog, I.; Hall, C. A systematic review including meta-analysis of work environment and depressive symptoms. BMC Public Health 2015, 15, 738. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  20. Pieper, C.; Schröer, S.; Eilerts, A.-L. Evidence of Workplace Interventions—A Systematic Review of Systematic Reviews. Int. J. Environ. Res. Public Health 2019, 16, 3553. [Google Scholar] [CrossRef] [Green Version]
  21. Jain, R.; Meena, M.; Dangayach, G. Ergonomic intervention for manual harvesting in agriculture: A review. In Ergonomics in Caring for People; Springer: Berlin/Heidelberg, Germany, 2018; pp. 183–191. [Google Scholar]
  22. Waters, T.R. Ergonomics in design: Interventions for youth working in the agricultural industry. Theor. Issues Ergon. Sci. 2012, 13, 270–285. [Google Scholar] [CrossRef]
  23. Van Eerd, D.; Munhall, C.; Irvin, E.; Rempel, D.; Brewer, S.; Van Der Beek, A.; Dennerlein, J.; Tullar, J.; Skivington, K.; Pinion, C. Effectiveness of workplace interventions in the prevention of upper extremity musculoskeletal disorders and symptoms: An update of the evidence. Occup. Environ. Med. 2016, 73, 62–70. [Google Scholar] [CrossRef]
  24. Gerr, F.; Marcus, M.; Monteilh, C.; Hannan, L.; Ortiz, D.; Kleinbaum, D. A randomised controlled trial of postural interventions for prevention of musculoskeletal symptoms among computer users. Occup. Environ. Med. 2005, 62, 478–487. [Google Scholar] [CrossRef] [Green Version]
  25. Agarwal, S.; Steinmaus, C.; Harris-Adamson, C. Sit-stand workstations and impact on low back discomfort: A systematic review and meta-analysis. Ergonomics 2018, 61, 538–552. [Google Scholar] [CrossRef] [PubMed]
  26. Wong, W.Y.; Wong, M.S.; Lo, K.H. Clinical applications of sensors for human posture and movement analysis: A review. Prosthet. Orthot. Int. 2007, 31, 62–75. [Google Scholar] [CrossRef]
  27. David, G.C. Ergonomic methods for assessing exposure to risk factors for work-related musculoskeletal disorders. Occup. Med. 2005, 55, 190–199. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  28. Tang, K.H.D. Abating Biomechanical Risks: A Comparative Review of Ergonomic Assessment Tools. J. Eng. Res. Rep. 2020, 17, 41–51. [Google Scholar] [CrossRef]
  29. Pearcy, M.; Gill, J.; Hindle, R.; Johnson, G. Measurement of human back movements in three dimensions by opto-electronic devices. Clin. Biomech. 1987, 2, 199–204. [Google Scholar] [CrossRef]
  30. Cuesta-Vargas, A.I.; Galán-Mercant, A.; Williams, J.M. The use of inertial sensors system for human motion analysis. Phys. Ther. Rev. 2010, 15, 462–473. [Google Scholar] [CrossRef] [Green Version]
  31. Picerno, P. 25 years of lower limb joint kinematics by using inertial and magnetic sensors: A review of methodological approaches. Gait Posture 2017, 51, 239–246. [Google Scholar] [CrossRef]
  32. Szeto, G.P.; Straker, L.; Raine, S. A field comparison of neck and shoulder postures in symptomatic and asymptomatic office workers. Appl. Ergon. 2002, 33, 75–84. [Google Scholar] [CrossRef]
  33. Macadam, P.; Cronin, J.; Neville, J.; Diewald, S. Quantification of the validity and reliability of sprint performance metrics computed using inertial sensors: A systematic review. Gait Posture 2019, 73, 26–38. [Google Scholar] [CrossRef]
  34. Ahmad, N.; Ghazilla, R.A.R.; Khairi, N.M.; Kasi, V. Reviews on various inertial measurement unit (IMU) sensor applications. Int. J. Signal Process. Syst. 2013, 1, 256–262. [Google Scholar] [CrossRef] [Green Version]
  35. Zhang, Y.; Chen, K.; Yi, J. Dynamic rider/bicycle pose estimation with force/IMU measurements. In Proceedings of the 2013 American Control Conference, Washington, DC, USA, 17–19 June 2013; pp. 2840–2845. [Google Scholar]
  36. Wong, W.Y.; Wong, M.S. Trunk posture monitoring with inertial sensors. Eur. Spine J. 2008, 17, 743–753. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  37. Jun, D.; Johnston, V.; McPhail, S.M.; O’Leary, S. Are measures of postural behavior using motion sensors in seated office workers reliable? Hum. Factors 2019, 61, 1141–1161. [Google Scholar] [CrossRef] [PubMed]
  38. Chen, Y.-P.; Lin, C.-Y.; Tsai, M.-J.; Chuang, T.-Y.; Lee, O.K.-S. Wearable motion sensor device to facilitate rehabilitation in patients with shoulder adhesive capsulitis: Pilot study to assess feasibility. J. Med. Internet Res. 2020, 22, e17032. [Google Scholar] [CrossRef] [PubMed]
  39. Aranda-Valera, I.C.; Garrido-Castro, J.L.; Martinez-Sanchez, I.; Gonzalez, C.; Gardiner, P.; Machado, P.M.; Collantes, E. Inertial motion sensors using the vimovec system is a valid method to assess spinal mobility in patients with axial spondyloarthritis. Ann. Rheum. Dis. 2018, 77, 642–643. [Google Scholar] [CrossRef] [Green Version]
  40. Bolink, S.A.; Naisas, H.; Senden, R.; Essers, H.; Heyligers, I.C.; Meijer, K.; Grimm, B. Validity of an inertial measurement unit to assess pelvic orientation angles during gait, sit-stand transfers and step-up transfers: Comparison with an optoelectronic motion capture system. Med. Eng. Phys. 2016, 38, 225–231. [Google Scholar] [CrossRef]
  41. Pérez-Fernández, T.; Armijo-Olivo, S.; Liébana, S.; de la Torre Ortíz, P.J.; Fernández-Carnero, J.; Raya, R.; Martín-Pintado-Zugasti, A. A novel use of inertial sensors to measure the craniocervical flexion range of motion associated to the craniocervical flexion test: An observational study. J. Neuroeng. Rehabil. 2020, 17, 1–10. [Google Scholar] [CrossRef] [PubMed]
  42. Beange, K.H.E.; Chan, A.D.C.; Beaudette, S.M.; Graham, R.B. Concurrent validity of a wearable IMU for objective assessments of functional movement quality and control of the lumbar spine. J. Biomech. 2019, 97, 109356. [Google Scholar] [CrossRef]
  43. Wang, Q.; Markopoulos, P.; Yu, B.; Chen, W.; Timmermans, A. Interactive wearable systems for upper body rehabilitation: A systematic review. J. Neuroeng. Rehabil. 2017, 14, 1–21. [Google Scholar] [CrossRef] [Green Version]
  44. Giraldo-Pedroza, A.; Lee, W.C.-C.; Lam, W.-K.; Coman, R.; Alici, G. Effects of Wearable Devices with Biofeedback on Biomechanical Performance of Running—A Systematic Review. Sensors 2020, 20, 6637. [Google Scholar] [CrossRef]
  45. Knight, J.F.; Baber, C. A tool to assess the comfort of wearable computers. Hum. Factors 2005, 47, 77–91. [Google Scholar] [CrossRef]
  46. Gemperle, F.; Kasabach, C.; Stivoric, J.; Bauer, M.; Martin, R. Design for wearability. In Proceedings of the Digest of Papers. Second International Symposium on Wearable Computers (cat. No. 98EX215), Pittsburgh, PA, USA, 19–20 October 1998; pp. 116–122. [Google Scholar]
  47. Bleser, G.; Steffen, D.; Weber, M.; Hendeby, G.; Stricker, D.; Fradet, L.; Marin, F.; Ville, N.; Carré, F. A personalized exercise trainer for the elderly. J. Ambient Intell. Smart Environ. 2013, 5, 547–562. [Google Scholar] [CrossRef] [Green Version]
  48. Kent, P.; Laird, R.; Haines, T. The effect of changing movement and posture using motion-sensor biofeedback, versus guidelines-based care, on the clinical outcomes of people with sub-acute or chronic low back pain-a multicentre, cluster-randomised, placebo-controlled, pilot trial. BMC Musculoskelet. Disord. 2015, 16, 131. [Google Scholar] [CrossRef] [Green Version]
  49. Van Vliet, P.M.; Wulf, G. Extrinsic feedback for motor learning after stroke: What is the evidence? Disabil. Rehabil. 2006, 28, 831–840. [Google Scholar] [CrossRef]
  50. Hubbard, I.J.; Parsons, M.W.; Neilson, C.; Carey, L.M. Task—specific training: Evidence for and translation to clinical practice. Occup. Ther. Int. 2009, 16, 175–189. [Google Scholar] [CrossRef] [PubMed]
  51. Richards, L.G.; Stewart, K.C.; Woodbury, M.L.; Senesac, C.; Cauraugh, J.H. Movement-dependent stroke recovery: A systematic review and meta-analysis of TMS and fMRI evidence. Neuropsychologia 2008, 46, 3–11. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  52. Snodgrass, S.J.; Heneghan, N.R.; Tsao, H.; Stanwell, P.T.; Rivett, D.A.; Van Vliet, P.M. Recognising neuroplasticity in musculoskeletal rehabilitation: A basis for greater collaboration between musculoskeletal and neurological physiotherapists. Man. Ther. 2014, 19, 614–617. [Google Scholar] [CrossRef] [PubMed]
  53. French, B.; Thomas, L.H.; Coupe, J.; McMahon, N.E.; Connell, L.; Harrison, J.; Sutton, C.J.; Tishkovskaya, S.; Watkins, C.L. Repetitive task training for improving functional ability after stroke. Cochrane Database Syst. Rev. 2016. [Google Scholar] [CrossRef] [Green Version]
  54. Sturmberg, C.; Marquez, J.; Heneghan, N.; Snodgrass, S.; van Vliet, P. Attentional focus of feedback and instructions in the treatment of musculoskeletal dysfunction: A systematic review. Man. Ther. 2013, 18, 458–467. [Google Scholar] [CrossRef] [PubMed]
  55. Valero, E.; Sivanathan, A.; Bosché, F.; Abdel-Wahab, M. Musculoskeletal disorders in construction: A review and a novel system for activity tracking with body area network. Appl. Ergon. 2016, 54, 120–130. [Google Scholar] [CrossRef]
  56. Yoong, N.K.M.; Perring, J.; Mobbs, R.J. Commercial Postural Devices: A Review. Sensors 2019, 19, 5128. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  57. Daudt, H.M.; van Mossel, C.; Scott, S.J. Enhancing the scoping study methodology: A large, inter-professional team’s experience with Arksey and O’Malley’s framework. BMC Med. Res. Methodol. 2013, 13, 48. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  58. Arksey, H.; O’Malley, L. Scoping studies: Towards a methodological framework. Int. J. Soc. Res. Methodol. 2005, 8, 19–32. [Google Scholar] [CrossRef] [Green Version]
  59. Moher, D.; Liberati, A.; Tetzlaff, J.; Altman, D.G. Preferred reporting items for systematic reviews and meta-analyses: The PRISMA statement. Ann. Intern. Med. 2009, 151, 264–269. [Google Scholar] [CrossRef] [Green Version]
  60. Rathvon, D. EndNote X8—Citation Manager—What’s New? UT Southwestern Medical Center: Dallas, TX, USA, 2017. [Google Scholar]
  61. Innovation, V. Covidence Systematic Review Software. Available online: https://www.covidence.org/ (accessed on 7 February 2021).
  62. Viera, A.J.; Garrett, J.M. Understanding interobserver agreement: The kappa statistic. Fam. Med. 2005, 37, 360–363. [Google Scholar]
  63. National Heart, Lung and Blood Institute. Study Quality Assessment Tools. Available online: https://www.nhlbi.nih.gov/health-topics/study-quality-assessment-tools (accessed on 5 February 2021).
  64. Van Tulder, M.; Furlan, A.; Bombardier, C.; Bouter, L.; Editorial Board of the Cochrane Collaboration Back Review Group. Updated method guidelines for systematic reviews in the cochrane collaboration back review group. Spine 2003, 28, 1290–1299. [Google Scholar] [CrossRef] [Green Version]
  65. Green, B.; Pizzari, T. Calf muscle strain injuries in sport: A systematic review of risk factors for injury. Br. J. Sports Med. 2017, 51, 1189–1194. [Google Scholar] [CrossRef]
  66. Schut, L.; Wangensteen, A.; Maaskant, J.; Tol, J.L.; Bahr, R.; Moen, M. Can clinical evaluation predict return to sport after acute hamstring injuries? A systematic review. Sports Med. 2017, 47, 1123–1144. [Google Scholar] [CrossRef] [PubMed]
  67. Brakenridge, C.L.; Fjeldsoe, B.S.; Young, D.C.; Winkler, E.A.; Dunstan, D.W.; Straker, L.M.; Healy, G.N. Evaluating the effectiveness of organisational-level strategies with or without an activity tracker to reduce office workers’ sitting time: A cluster-randomised trial. Int. J. Behav. Nutr. Phys. Act. 2016, 13, 115. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  68. Ribeiro, D.C.; Sole, G.; Abbott, J.H.; Milosavljevic, S. The effectiveness of a lumbopelvic monitor and feedback device to change postural behavior: A feasibility randomized controlled trial. J. Orthop. Sports Phys. Ther. 2014, 44, 702–711. [Google Scholar] [CrossRef]
  69. Thanathornwong, B.; Suebnukarn, S. The Improvement of Dental Posture Using Personalized Biofeedback. Stud. Health Technol. Inform. 2015, 216, 756–760. [Google Scholar]
  70. Thanathornwong, B.; Suebnukarn, S.; Ouivirach, K. A system for predicting musculoskeletal disorders among dental students. Int. J. Occup. Saf. Ergon. 2014, 20, 463–475. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  71. Vignais, N.; Miezal, M.; Bleser, G.; Mura, K.; Gorecky, D.; Marin, F. Innovative system for real-time ergonomic feedback in industrial manufacturing. Appl. Ergon. 2013, 44, 566–574. [Google Scholar] [CrossRef] [PubMed]
  72. Ailneni, R.C.; Syamala, K.R.; Kim, I.-S.; Hwang, J. Influence of the wearable posture correction sensor on head and neck posture: Sitting and standing workstations. Work 2019, 62, 27–35. [Google Scholar] [CrossRef]
  73. Boocock, M.; Naudé, Y.; Taylor, S.; Kilby, J.; Mawston, G. Influencing lumbar posture through real-time biofeedback and its effects on the kinematics and kinetics of a repetitive lifting task. Gait Posture 2019, 73, 93–100. [Google Scholar] [CrossRef] [PubMed]
  74. Bootsman, R.; Markopoulos, P.; Qi, Q.; Wang, Q.; Timmermans, A.A. Wearable technology for posture monitoring at the workplace. Int. J. Hum. Comput. Stud. 2019, 132, 99–111. [Google Scholar] [CrossRef]
  75. Breen, P.P.; Nisar, A.; ÓLaighin, G. Evaluation of a single accelerometer based biofeedback system for real-time correction of neck posture in computer users. In Proceedings of the 2009 Annual International Conference of the IEEE Engineering in Medicine and Biology Society, Minneapolis, MN, USA, 3–6 September 2009; pp. 7269–7272. [Google Scholar]
  76. Kuo, Y.-L.; Wang, P.-S.; Ko, P.-Y.; Huang, K.-Y.; Tsai, Y.-J. Immediate effects of real-time postural biofeedback on spinal posture, muscle activity, and perceived pain severity in adults with neck pain. Gait Posture 2019, 67, 187–193. [Google Scholar] [CrossRef]
  77. Park, S.; Hetzler, T.; Hammons, D.; Ward, G. Effects of biofeedback postural training on pre-existing low back pain in static-posture workers. J. Back Musculoskelet. Rehabil. 2018, 31, 849–857. [Google Scholar] [CrossRef]
  78. Cerqueira, S.M.; Da Silva, A.F.; Santos, C.P. Smart vest for real-time postural biofeedback and ergonomic risk assessment. IEEE Access 2020, 8, 107583–107592. [Google Scholar] [CrossRef]
  79. Lind, C.M.; Diaz-Olivares, J.A.; Lindecrantz, K.; Eklund, J. A wearable sensor system for physical ergonomics interventions using haptic feedback. Sensors 2020, 20, 6010. [Google Scholar] [CrossRef] [PubMed]
  80. Doss, R.; Robathan, J.; Abdel-Malek, D.; Holmes, M.W. Posture coaching and feedback during patient handling in a student nurse population. Iise Trans. Occup. Ergon. Hum. Factors 2018, 6, 116–127. [Google Scholar] [CrossRef]
  81. Felisberto, F.; Costa, N.; Fdez-Riverola, F.; Pereira, A. Unobstructive Body Area Networks (BAN) for efficient movement monitoring. Sensors 2012, 12, 12473–12488. [Google Scholar] [CrossRef] [Green Version]
  82. Hermens, H.; op den Akker, H.; Tabak, M.; Wijsman, J.; Vollenbroek, M. Personalized coaching systems to support healthy behavior in people with chronic conditions. J. Electromyogr. Kinesiol. 2014, 24, 815–826. [Google Scholar] [CrossRef] [PubMed]
  83. Wagenaar, R.C.; Sapir, I.; Zhang, Y.; Markovic, S.; Vaina, L.M.; Little, T.D. Continuous monitoring of functional activities using wearable, wireless gyroscope and accelerometer technology. In Proceedings of the 2011 Annual International Conference of the IEEE Engineering in Medicine and Biology Society, Boston, MA, USA, 30 August–3 September 2011; pp. 4844–4847. [Google Scholar]
  84. Stollenwerk, K.; Muller, J.; Hinkenjann, A.; Kruger, B. Analyzing Spinal Shape Changes During Posture Training Using a Wearable Device. Sensors 2019, 19, 3625. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  85. Muscillo, R.; Schmid, M.; Conforto, S.; D’Alessio, T. Early recognition of upper limb motor tasks through accelerometers: Real-time implementation of a DTW-based algorithm. Comput. Biol. Med. 2011, 41, 164–172. [Google Scholar] [CrossRef]
  86. Peppoloni, L.; Filippeschi, A.; Ruffaldi, E.; Avizzano, C.A. (WMSDs issue) A novel wearable system for the online assessment of risk for biomechanical load in repetitive efforts. Int. J. Ind. Ergon. 2014, 52, 1–11. [Google Scholar] [CrossRef]
  87. Oliva-Lozano, J.M.; Maraver, E.F.; Fortes, V.; Muyor, J.M. Kinematic Analysis of the Postural Demands in Professional Soccer Match Play Using Inertial Measurement Units. Sensors 2020, 20, 5971. [Google Scholar] [CrossRef]
  88. Ribeiro, P.; Soares, A.R.; Girão, R.; Neto, M.; Cardoso, S. Spine cop: Posture correction monitor and assistant. Sensors 2020, 20, 5376. [Google Scholar] [CrossRef] [PubMed]
  89. Thamsuwan, O.; Galvin, K.; Tchong-French, M.; Aulck, L.; Boyle, L.N.; Ching, R.P.; McQuade, K.J.; Johnson, P.W. Comparisons of physical exposure between workers harvesting apples on mobile orchard platforms and ladders, part 1: Back and upper arm postures. Appl. Ergon. 2020, 89, 103193. [Google Scholar] [CrossRef]
  90. Carbonaro, N.; Mascherini, G.; Bartolini, I.; Ringressi, M.N.; Taddei, A.; Tognetti, A.; Vanello, N. A Wearable Sensor-Based Platform for Surgeon Posture Monitoring: A Tool to Prevent Musculoskeletal Disorders. Int. J. Environ. Res. Public Health 2021, 18, 3734. [Google Scholar] [CrossRef]
  91. Hoglund, G.; Grip, H.; Ohberg, F. The importance of inertial measurement unit placement in assessing upper limb motion. Med. Eng. Phys. 2021, 92, 1–9. [Google Scholar] [CrossRef]
  92. Jeong, I.C.; Finkelstein, J. Computer-assisted upper extremity training using interactive biking exercise (iBikE) platform. In Proceedings of the 2012 Annual International Conference of the IEEE Engineering in Medicine and Biology Society, San Diego, CA, USA, 28 August–1 September 2012; pp. 6095–6099. [Google Scholar]
  93. Pollard, B.; Engelen, L.; Held, F.; de Dear, R. Movement at work: A comparison of real time location system, accelerometer and observational data from an office work environment. Appl. Ergon. 2021, 92, 103341. [Google Scholar] [CrossRef]
  94. Madeleine, P.; Vedsted, P.; Blangsted, A.K.; Sj⊘gaard, G.; S⊘gaard, K. Effects of electromyographic and mechanomyographic biofeedback on upper trapezius muscle activity during standardized computer work. Ergonomics 2006, 49, 921–933. [Google Scholar] [CrossRef]
  95. Cuesta-Vargas, A.I.; Williams, J. Inertial sensor real-time feedback enhances the learning of cervical spine manipulation: A prospective study. BMC Med. Educ. 2014, 14, 1–5. [Google Scholar] [CrossRef] [Green Version]
  96. Nct. Inertial Sensors Used to Learn Manipulation. 2013. Available online: https://clinicaltrials.gov/show/NCT01911338 (accessed on 3 March 2021).
  97. Cuesta-Vargas, A.I.; Gonzalez-Sanchez, M.; Lenfant, Y. Inertial sensors as real-time feedback improve learning posterior-anterior thoracic manipulation: A randomized controlled trial. J. Manip. Physiol. Ther. 2015, 38, 425–433. [Google Scholar] [CrossRef]
  98. Milosevic, M.; McConville, K.M.V. Audio-visual biofeedback system for postural control. Int. J. Disabil. Hum. Dev. 2011, 10, 321–324. [Google Scholar] [CrossRef] [Green Version]
  99. Coleman Wood, K.A.; Lathan, C.E.; Kaufman, K.R. Development of an interactive upper extremity gestural robotic feedback system: From bench to reality. In Proceedings of the 2009 Annual International Conference of the IEEE Engineering in Medicine and Biology Society, Minneapolis, MN, USA, 3–6 September 2009; pp. 5973–5976. [Google Scholar]
  100. Janssen, L.J.F.; Verhoeff, L.L.; Horlings, C.G.C.; Allum, J.H.J. Directional effects of biofeedback on trunk sway during gait tasks in healthy young subjects. Gait Posture 2009, 29, 575–581. [Google Scholar] [CrossRef] [PubMed]
  101. Giansanti, D.; Dozza, M.; Chiari, L.; Maccioni, G.; Cappello, A. Energetic assessment of trunk postural modifications induced by a wearable audio-biofeedback system. Med. Eng. Phys. 2009, 31, 48–54. [Google Scholar] [CrossRef] [PubMed]
  102. Verhoeff, L.L.; Horlings, C.G.; Janssen, L.J.; Bridenbaugh, S.A.; Allum, J.H. Effects of biofeedback on trunk sway during dual tasking in the healthy young and elderly. Gait Posture 2009, 30, 76–81. [Google Scholar] [CrossRef]
  103. Costantini, G.; Casali, D.; Paolizzo, F.; Alessandrini, M.; Micarelli, A.; Viziano, A.; Saggio, G. Towards the enhancement of body standing balance recovery by means of a wireless audio-biofeedback system. Med. Eng. Phys. 2018, 54, 74–81. [Google Scholar] [CrossRef]
  104. Tucker, M.G.; Kavanagh, J.J.; Barrett, R.S.; Morrison, S. Age-related differences in postural reaction time and coordination during voluntary sway movements. Hum. Mov. Sci. 2008, 27, 728–737. [Google Scholar] [CrossRef] [PubMed]
  105. Wu, C.C.; Chiu, C.C.; Yeh, C.Y. Development of wearable posture monitoring system for dynamic assessment of sitting posture. Australas. Phys. Eng. Sci. Med. 2019, 19, 19. [Google Scholar] [CrossRef] [PubMed]
  106. LeMoyne, R.; Mastroianni, T. Virtual Proprioception for eccentric training. In Proceedings of the Annual International Conference of the IEEE Engineering in Medicine & Biology Society, Jeju, Korea, 11–15 July 2017; Volume 2017, pp. 4557–4561. [Google Scholar] [CrossRef]
  107. Gonzalez-Sanchez, M.; Vaes, P.; Trinidad-Fernandez, M.; Roldan-Jimenez, C.; Cuesta-Vargas, A.I. Kinematic-real time feedback. A new methodology for teaching manual therapy: A randomized controlled trial. Man. Ther. 2016, 25, 162–169. [Google Scholar] [CrossRef]
  108. Williams, J. The learning of higher order manual therapy through real-time feedback. Int. J. Ther. Rehabil. 2015, 22, S2. [Google Scholar] [CrossRef]
  109. Alsubaie, A.M.; Jimenez-Grande, D.; De Nunzio, A.M. Trunk coordination in people with low back pain during goal-directed repetitive sagittal trunk movements. Physiotherapy 2020, 107 (Suppl. 1), e82–e83. [Google Scholar] [CrossRef]
  110. Luna, J.; Y Rosas, D.S.; Elias, D. A low-cost portable measurement system for a clinical test of balance. Annu. Int. Conf. IEEE Eng. Med. Biol. Soc. 2020, 2020, 4038–4041. [Google Scholar] [CrossRef] [PubMed]
  111. Owlia, M.; Ng, C.; Ledda, K.; Kamachi, M.; Longfield, A.; Dutta, T. Preventing back injury in caregivers using real-time posture-based feedback. In Proceedings of the 20th Congress of the International Ergonomics Association, 26–30 August 2018; pp. 750–758. [Google Scholar]
  112. Armstrong, K.; Audu, M.; Triolo, R. Automatic detection of destabilizing wheelchair conditions for modulating actions of neuroprostheses to maintain seated posture. J. Spinal Cord Med. 2017, 40, 581. [Google Scholar] [CrossRef]
  113. Urbin, M.A.; Bailey, R.R.; Lang, C.E. Validity of Body-Worn Sensor Acceleration Metrics to Index Upper Extremity Function in Hemiparetic Stroke. J. Neurol. Phys. Ther. 2015, 39, 111–118. [Google Scholar] [CrossRef] [Green Version]
  114. De Lucena, D.S.; Stoller, O.; Rowe, J.B.; Chan, V.; Reinkensmeyer, D.J. Wearable sensing for rehabilitation after stroke: Bimanual jerk asymmetry encodes unique information about the variability of upper extremity recovery. In Proceedings of the 2017 International Conference on Rehabilitation Robotics (ICORR), London, UK, 17–20 July 2017; pp. 1603–1608. [Google Scholar]
  115. Fanchamps, M.H.J.; Horemans, H.L.D.; Ribbers, G.M.; Stam, H.J.; Bussmann, J.B.J. The accuracy of the detection of body postures and movements using a physical activity monitor in people after a stroke. Sensors 2018, 18, 2167. [Google Scholar] [CrossRef] [Green Version]
  116. Verwey, R.; van der Weegen, S.; Spreeuwenberg, M.; Tange, H.; van der Weijden, T.; de Witte, L. Process evaluation of physical activity counselling with and without the use of mobile technology: A mixed methods study. Int. J. Nurs. Stud. 2016, 53, 3–16. [Google Scholar] [CrossRef]
  117. Wu, Z.; Zhang, J.; Chen, K.; Fu, C. Yoga Posture Recognition and Quantitative Evaluation with Wearable Sensors Based on Two-Stage Classifier and Prior Bayesian Network. Sensors 2019, 19, 5129. [Google Scholar] [CrossRef] [Green Version]
  118. Thanathornwong, B.; Jalayondeja, W. Vibrotactile -Feedback Device for Postural Balance among Malocclusion Patients. IEEE J. Transl. Eng. Health Med. 2020, 8, 1–6. [Google Scholar] [CrossRef] [PubMed]
  119. Spook, S.M.; Koolhaas, W.; Bultmann, U.; Brouwer, S. Implementing sensor technology applications for workplace health promotion: A needs assessment among workers with physically demanding work. BMC Public Health 2019, 19, 1100. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  120. Wang, Q.; Chen, W.; Timmermans, A.A.; Karachristos, C.; Martens, J.-B.; Markopoulos, P. Smart Rehabilitation Garment for posture monitoring. In Proceedings of the 2015 37th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC), Milan, Italy, 25–29 August 2015; pp. 5736–5739. [Google Scholar]
  121. Kos, A.; Tomažič, S.; Umek, A. Suitability of smartphone inertial sensors for real-time biofeedback applications. Sensors 2016, 16, 301. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  122. Cortell-Tormo, J.M.; Garcia-Jaen, M.; Ruiz-Fernandez, D.; Fuster-Lloret, V. Lumbatex: A Wearable Monitoring System Based on Inertial Sensors to Measure and Control the Lumbar Spine Motion. IEEE Trans. Neural Syst. Rehabil. Eng. 2019, 27, 1644–1653. [Google Scholar] [CrossRef] [PubMed]
  123. Yang, L.; Lu, K.; Diaz-Olivares, J.A.; Seoane, F.; Lindecrantz, K.; Forsman, M.; Abtahi, F.; Eklund, J.A. Towards smart work clothing for automatic risk assessment of physical workload. IEEE Access 2018, 6, 40059–40072. [Google Scholar] [CrossRef]
  124. Battini, D.; Persona, A.; Sgarbossa, F. Innovative real-time system to integrate ergonomic evaluations into warehouse design and management. Comput. Ind. Eng. 2014, 77, 1–10. [Google Scholar] [CrossRef]
  125. Tctr. The Physical Activity at Work (PAW) Study: A Cluster Randomised Trial of a Multi-Component Short-Break Intervention to Reduce Sitting Time and Increase Physical Activity among Office Workers in Thailand. 2020. Available online: http://www.who.int/trialsearch/Trial2.aspx?TrialID=TCTR20200604007 (accessed on 12 March 2021).
  126. Allison, M.A.; Kang, Y.S.; Bolte, J.H.T.; Maltese, M.R.; Arbogast, K.B. Validation of a helmet-based system to measure head impact biomechanics in ice hockey. Med. Sci. Sports Exerc. 2014, 46, 115–123. [Google Scholar] [CrossRef]
  127. Amasay, T.; Zodrow, K.; Kincl, L.; Hess, J.; Karduna, A. Validation of tri-axial accelerometer for the calculation of elevation angles. Int. J. Ind. Ergon. 2009, 39, 783–789. [Google Scholar] [CrossRef]
  128. Bauer, C.M.; Rast, F.M.; Ernst, M.J.; Kool, J.; Luomajoki, H.; Suni, J.; Kankaanpaa, M. Validity and reliability of inertial measurement units when measuring lumbar range of motion, movement control, repetetive movement and reposition error. Physiotherapy 2015, 1, eS914–eS915. [Google Scholar] [CrossRef] [Green Version]
  129. Bauer, C.M.; Rast, F.M.; Ernst, M.J.; Kool, J.; Oetiker, S.; Rissanen, S.M.; Suni, J.H.; Kankaanpaa, M. Concurrent validity and reliability of a novel wireless inertial measurement system to assess trunk movement. J. Electromyogr. Kinesiol. 2015, 25, 782–790. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  130. Dahlqvist, C.; Hansson, G.A.; Forsman, M. Validity of a small low-cost triaxial accelerometer with integrated logger for uncomplicated measurements of postures and movements of head, upper back and upper arms. Appl. Ergon. 2016, 55, 108–116. [Google Scholar] [CrossRef] [PubMed]
  131. Timmermans, A.A.; Seelen, H.A.; Willmann, R.D.; Kingma, H. Technology-assisted training of arm-hand skills in stroke: Concepts on reacquisition of motor control and therapist guidelines for rehabilitation technology design. J. Neuroeng. Rehabil. 2009, 6, 1. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  132. Ribeiro, D.C.; Sole, G.; Abbott, J.H.; Milosavljevic, S. Extrinsic feedback and management of low back pain: A critical review of the literature. Man. Ther. 2011, 16, 231–239. [Google Scholar] [CrossRef] [PubMed]
  133. McAtamney, L.; Corlett, E.N. RULA: A survey method for the investigation of work-related upper limb disorders. Appl. Ergon. 1993, 24, 91–99. [Google Scholar] [CrossRef]
  134. Borg, G. Borg’s Perceived Exertion and Pain Scales; Human Kinetics: Champaign, IL, USA, 1998. [Google Scholar]
  135. Bangor, A.; Kortum, P.; Miller, J. Determining what individual SUS scores mean: Adding an adjective rating scale. J. Usability Stud. 2009, 4, 114–123. [Google Scholar]
  136. Ribeiro, D.C.; Sole, G.; Abbott, J.H.; Milosavljevic, S. Validity and reliability of the Spineangel® lumbo-pelvic postural monitor. Ergonomics 2013, 56, 977–991. [Google Scholar] [CrossRef]
  137. Von Elm, E.; Altman, D.G.; Egger, M.; Pocock, S.J.; Gøtzsche, P.C.; Vandenbroucke, J.P.; Initiative, S. The Strengthening the Reporting of Observational Studies in Epidemiology (STROBE) Statement: Guidelines for reporting observational studies. Int. J. Surg. 2014, 12, 1495–1499. [Google Scholar] [CrossRef] [Green Version]
  138. Lind, C.M.; Sandsjö, L.; Mahdavian, N.; Högberg, D.; Hanson, L.; Olivares, J.A.D.; Yang, L.; Forsman, M. Prevention of Work: Related Musculoskeletal Disorders Using Smart Workwear–The Smart Workwear Consortium. In Proceedings of the 1st International Conference on Human Systems Engineering and Design (IHSED2018): Future Trends and Applications, Reims, France, 25–27 October 2018; pp. 477–483. [Google Scholar]
  139. Sigrist, R.; Rauter, G.; Riener, R.; Wolf, P. Augmented visual, auditory, haptic, and multimodal feedback in motor learning: A review. Psychon. Bull. Rev. 2013, 20, 21–53. [Google Scholar] [CrossRef] [Green Version]
  140. Wulf, G.; Shea, C.H.; Matschiner, S. Frequent feedback enhances complex motor skill learning. J. Mot. Behav. 1998, 30, 180–192. [Google Scholar] [CrossRef] [PubMed]
  141. Sheaves, E.G.; Snodgrass, S.J.; Rivett, D.A. Learning lumbar spine mobilization: The effects of frequency and self-control of feedback. J. Orthop. Sports Phys. Ther. 2012, 42, 114–124. [Google Scholar] [CrossRef]
  142. Burke, J.L.; Prewett, M.S.; Gray, A.A.; Yang, L.; Stilson, F.R.; Coovert, M.D.; Elliot, L.R.; Redden, E. Comparing the effects of visual-auditory and visual-tactile feedback on user performance: A meta-analysis. In Proceedings of the 8th International Conference on Multimodal Interfaces, Banff Alberta, Canada, 2–4 November 2006. [Google Scholar]
  143. Ribeiro, D.C.; Sole, G.; Abbott, J.H.; Milosavljevic, S. Cumulative postural exposure measured by a novel device: A preliminary study. Ergonomics 2011, 54, 858–865. [Google Scholar] [CrossRef] [PubMed]
  144. Bechly, K.E.; Carender, W.J.; Myles, J.D.; Sienko, K.H. Determining the preferred modality for real-time biofeedback during balance training. Gait Posture 2013, 37, 391–396. [Google Scholar] [CrossRef]
  145. Adesida, Y.; Papi, E.; McGregor, A.H. Exploring the role of wearable technology in sport kinematics and kinetics: A systematic review. Sensors 2019, 19, 1597. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  146. Ma, C.Z.-H.; Wong, D.W.-C.; Lam, W.K.; Wan, A.H.-P.; Lee, W.C.-C. Balance improvement effects of biofeedback systems with state-of-the-art wearable sensors: A systematic review. Sensors 2016, 16, 434. [Google Scholar] [CrossRef] [Green Version]
  147. Kennedy, C.A.; Amick III, B.C.; Dennerlein, J.T.; Brewer, S.; Catli, S.; Williams, R.; Serra, C.; Gerr, F.; Irvin, E.; Mahood, Q. Systematic review of the role of occupational health and safety interventions in the prevention of upper extremity musculoskeletal symptoms, signs, disorders, injuries, claims and lost time. J. Occup. Rehabil. 2010, 20, 127–162. [Google Scholar] [CrossRef] [PubMed]
  148. Lim, S.; D’Souza, C. A narrative review on contemporary and emerging uses of inertial sensing in occupational ergonomics. Int. J. Ind. Ergon. 2020, 76, 102937. [Google Scholar] [CrossRef] [PubMed]
  149. Donovan, J.J.; Radosevich, D.J. A meta-analytic review of the distribution of practice effect: Now you see it, now you don’t. J. Appl. Psychol. 1999, 84, 795. [Google Scholar] [CrossRef]
  150. Timmermans, A.A.; Seelen, H.A.; Geers, R.P.; Saini, P.K.; Winter, S.; te Vrugt, J.; Kingma, H. Sensor-based arm skill training in chronic stroke patients: Results on treatment outcome, patient motivation, and system usability. IEEE Trans. Neural Syst. Rehabil. Eng. 2010, 18, 284–292. [Google Scholar] [CrossRef]
  151. Salmoni, A.W.; Schmidt, R.A.; Walter, C.B. Knowledge of results and motor learning: A review and critical reappraisal. Psychol. Bull. 1984, 95, 355. [Google Scholar] [CrossRef] [PubMed]
  152. Alemanno, F.; Houdayer, E.; Emedoli, D.; Locatelli, M.; Mortini, P.; Mandelli, C.; Raggi, A.; Iannaccone, S. Efficacy of virtual reality to reduce chronic low back pain: Proof-of-concept of a non-pharmacological approach on pain, quality of life, neuropsychological and functional outcome. PLoS ONE 2019, 14, e0216858. [Google Scholar] [CrossRef] [Green Version]
  153. Ghamkhar, L.; Arab, A.M.; Nourbakhsh, M.R.; Kahlaee, A.H.; Zolfaghari, R. Examination of regional interdependence theory in chronic neck pain: Interpretations from correlation of strength measures in cervical and pain-free regions. Pain Med. 2020, 21, e182–e190. [Google Scholar] [CrossRef]
  154. Schinkel-Ivy, A.; Drake, J.D. Interaction Between Thoracic Movement and Lumbar Spine Muscle Activation Patterns in Young Adults Asymptomatic for Low Back Pain: A Cross-Sectional Study. J. Manip. Physiol. Ther. 2019, 42, 461–469. [Google Scholar] [CrossRef] [PubMed]
  155. Budhrani-Shani, P.; Berry, D.L.; Arcari, P.; Langevin, H.; Wayne, P.M. Mind-body exercises for nurses with chronic low back pain: An evidence-based review. Nurs. Res. Pract. 2016, 2016, 9018036. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  156. Vos, T.; Allen, C.; Arora, M.; Barber, R.M.; Bhutta, Z.A.; Brown, A.; Carter, A.; Casey, D.C.; Charlson, F.J.; Chen, A.Z. Global, regional, and national incidence, prevalence, and years lived with disability for 310 diseases and injuries, 1990–2015: A systematic analysis for the Global Burden of Disease Study 2015. Lancet 2016, 388, 1545–1602. [Google Scholar] [CrossRef] [Green Version]
  157. Andersen, J.; Kaergaard, A.; Mikkelsen, S.; Jensen, U.; Frost, P.; Bonde, J.; Fallentin, N.; Thomsen, J. Risk factors in the onset of neck/shoulder pain in a prospective study of workers in industrial and service companies. Occup. Environ. Med. 2003, 60, 649–654. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  158. Szeto, G.P.; Straker, L.M.; O’Sullivan, P.B. A comparison of symptomatic and asymptomatic office workers performing monotonous keyboard work—1: Neck and shoulder muscle recruitment patterns. Man. Ther. 2005, 10, 270–280. [Google Scholar] [CrossRef] [PubMed]
  159. Lau, K.T.; Cheung, K.Y.; Chan, K.B.; Chan, M.H.; Lo, K.Y.; Wing Chiu, T.T. Relationships between sagittal postures of thoracic and cervical spine, presence of neck pain, neck pain severity and disability. Man. Ther. 2010, 15, 457–462. [Google Scholar] [CrossRef]
  160. Mingels, S.; Dankaerts, W.; van Etten, L.; Thijs, H.; Granitzer, M. Comparative analysis of head-tilt and forward head position during laptop use between females with postural induced headache and healthy controls. J. Bodyw. Mov. Ther. 2016, 20, 533–541. [Google Scholar] [CrossRef]
  161. Szeto, G.P.; Straker, L.M.; O’Sullivan, P.B. A comparison of symptomatic and asymptomatic office workers performing monotonous keyboard work—2: Neck and shoulder kinematics. Man. Ther. 2005, 10, 281–291. [Google Scholar] [CrossRef]
  162. Straker, L.; Skoss, R.; Burnett, A.; Burgess-Limerick, R. Effect of visual display height on modelled upper and lower cervical gravitational moment, muscle capacity and relative strain. Ergonomics 2009, 52, 204–221. [Google Scholar] [CrossRef]
  163. Harms-Ringdahl, K.; Ekholm, J.; Schuldt, K.; Nemeth, G.; Arborelius, U. Load moments and myoelectric activity when the cervical spine is held in full flexion and extension. Ergonomics 1986, 29, 1539–1552. [Google Scholar] [CrossRef] [PubMed]
  164. Baker, P.; Halim, Z. An exploration of warehouse automation implementations: Cost, service and flexibility issues. Supply Chain Manag. Int. J. 2007, 12, 129–138. [Google Scholar] [CrossRef] [Green Version]
  165. Gioberto, G.; Dunne, L.E. Garment positioning and drift in garment-integrated wearable sensing. In Proceedings of the 2012 16th International Symposium on Wearable Computers, Newcastle, UK, 18–22 June 2012; pp. 64–71. [Google Scholar]
  166. Wang, Q.; Toeters, M.; Chen, W.; Timmermans, A.; Markopoulos, P. Zishi: A smart garment for posture monitoring. In Proceedings of the 2016 CHI Conference Extended Abstracts on Human Factors in Computing Systems, San Jose, CA, USA, 7–12 May 2016; pp. 3792–3795. [Google Scholar]
  167. Cancela, J.; Pastorino, M.; Tzallas, A.T.; Tsipouras, M.G.; Rigas, G.; Arredondo, M.T.; Fotiadis, D.I. Wearability assessment of a wearable system for Parkinson’s disease remote monitoring based on a body area network of sensors. Sensors 2014, 14, 17235–17255. [Google Scholar] [CrossRef] [Green Version]
  168. Boateng, G.; Motti, V.G.; Mishra, V.; Batsis, J.A.; Hester, J.; Kotz, D. Experience: Design, development and evaluation of a wearable device for mHealth applications. In Proceedings of the 25th Annual International Conference on Mobile Computing and Networking, Los Cabos, Mexico, 21–25 October 2019; pp. 1–14. [Google Scholar]
  169. Bove, L.A. Increasing Patient Engagement Through the Use of Wearable Technology. J. Nurse Pract. 2019, 15, 535–539. [Google Scholar] [CrossRef] [Green Version]
  170. Knight, J.F.; Deen-Williams, D.; Arvanitis, T.N.; Baber, C.; Sotiriou, S.; Anastopoulou, S.; Gargalakos, M. Assessing the wearability of wearable computers. In Proceedings of the 2006 10th IEEE International Symposium on Wearable Computers, Montreux, Switzerland, 11–14 October 2006; pp. 75–82. [Google Scholar]
  171. Zhao, H.; Wang, Z. Motion measurement using inertial sensors, ultrasonic sensors, and magnetometers with extended kalman filter for data fusion. IEEE Sens. J. 2012, 12, 943–953. [Google Scholar] [CrossRef]
  172. Zhou, H.; Hu, H. Reducing Drifts in the Inertial Measurements of Wrist and Elbow Positions. IEEE Trans. Instrum. Meas. 2010, 59, 575–585. [Google Scholar] [CrossRef]
  173. Fan, B.; Li, Q.; Wang, C.; Liu, T. An adaptive orientation estimation method for magnetic and inertial sensors in the presence of magnetic disturbances. Sensors 2017, 17, 1161. [Google Scholar] [CrossRef]
  174. Fan, B.; Li, Q.; Liu, T. How magnetic disturbance influences the attitude and heading in magnetic and inertial sensor-based orientation estimation. Sensors 2018, 18, 76. [Google Scholar] [CrossRef] [Green Version]
  175. Corrales, J.A.; Candelas, F.; Torres, F. Hybrid tracking of human operators using IMU/UWB data fusion by a Kalman filter. In Proceedings of the 2008 3rd ACM/IEEE International Conference on Human-Robot Interaction (HRI), Amsterdam, The Netherlands, 12–15 March 2008; pp. 193–200. [Google Scholar]
  176. Lu, M.-L.; Feng, S.; Hughes, G.; Barim, M.S.; Hayden, M.; Werren, D. Development of an algorithm for automatically assessing lifting risk factors using inertial measurement units. In Proceedings of the Human Factors and Ergonomics Society Annual Meeting, San Francisco, CA, USA, 27 September–1 October 2010; pp. 1334–1338. [Google Scholar]
  177. Chen, H.; Schall, M.C., Jr.; Fethke, N. Effects of Movement Speed and Magnetic Disturbance on the Accuracy of Inertial Measurement Units. In Proceedings of the Human Factors and Ergonomics Society Annual Meeting, Rome, Italy, 28–30 September 2017; pp. 1046–1050. [Google Scholar]
  178. Hartmann, B.; Link, N.; Trommer, G.F. Indoor 3D position estimation using low-cost inertial sensors and marker-based video-tracking. In Proceedings of the IEEE/ION Position, Location and Navigation Symposium, Indian Wells, CA, USA, 4–6 May 2010; pp. 319–326. [Google Scholar]
  179. Islam, T.; Islam, M.S.; Shajid-Ul-Mahmud, M.; Hossam-E-Haider, M. Comparison of complementary and Kalman filter based data fusion for attitude heading reference system. In AIP Conference Proceedings; AIP Publishing LLC: Ney York, NY, USA, 2017; p. 020002. [Google Scholar]
  180. Sabatini, A.M. Kalman-filter-based orientation determination using inertial/magnetic sensors: Observability analysis and performance evaluation. Sensors 2011, 11, 9182–9206. [Google Scholar] [CrossRef] [PubMed]
  181. Sinclair, J.; Taylor, P.J.; Hobbs, S.J. Digital filtering of three-dimensional lower extremity kinematics: An assessment. J. Hum. Kinet. 2013, 39, 25–36. [Google Scholar] [CrossRef] [Green Version]
  182. Winter, D.A. Biomechanics and Motor Control of Human Movement; John Wiley & Sons: Hoboken, NJ, USA, 2009. [Google Scholar]
  183. Tulipani, L.; Boocock, M.G.; Lomond, K.V.; El-Gohary, M.; Reid, D.A.; Henry, S.M. Validation of an Inertial Sensor System for Physical Therapists to Quantify Movement Coordination During Functional Tasks. J. Appl. Biomech. 2018, 34, 23–30. [Google Scholar] [CrossRef]
Sensors 21 06377 g001 550
Figure 1. PRISMA diagram of the study selection process.
Figure 1. PRISMA diagram of the study selection process.
Sensors 21 06377 g001
Sensors 21 06377 g002 550
Figure 2. Overview of evaluated evidence for the effects of feedback from wearable inertial sensor technology on upper body posture and movement behaviour during workplace-related tasks.
Figure 2. Overview of evaluated evidence for the effects of feedback from wearable inertial sensor technology on upper body posture and movement behaviour during workplace-related tasks.
Sensors 21 06377 g002
Table
Table 1. Search terms and strings used in the scoping review.
Table 1. Search terms and strings used in the scoping review.
acceleromet* or “ambulatory monitoring” or gyroscope* or magnetomet* or “inertial sensor*” or “inertial measurement unit*”
AND
posture or “upper body” or workstation* or “work station*” or workplace or “occupational health” or “skeletal muscle” or “upper extremity” or arm or “upper limb*” or cervical or thoracic or spine or neck or back or shoulder* or “musculoskeletal disease*” or monitoring or msd
AND
wearable systems or “biomechanical phenomena” or “biomechanical feedback” or “feedback device” or movement or locomotion or “real time” or “realtime” or wireless or “chronic pain” or “reproducibility of results” or reliability or validity or “therapeutic effect” or “on-body sensor” or “Feedback effect”
Table
Table 2. Summary of study characteristics for included studies.
Table 2. Summary of study characteristics for included studies.
StudySettingStudy Population and EligibilityDesignObjectiveComparison Groups
Brakenridge, Fjeldsoe [67]Office153 desk-based office workers (53 males, 34 female)
Mean age (SD): 38.9, (8.0)
Eligibility: ambulatory for 10 m		Cluster-randomised trialEvaluation of organisational-support strategies compared to feedback from WIST and support to reduce sitting in office workers.
Duration: 12 months		Randomised: group 1 (n = 87), ORG: organisational-support intervention group 2 (n = 66), ORG + tracker. No control group
Ribeiro, Sole [68]Office62 healthcare and administration workers (5 male, 57 female)
Mean age (SD): 49.6, (12.4)
Eligibility: with or without lower back pain.		Randomised control trialEffectiveness of a feedback device for modifying lumbopelvic posture postural behaviour during daily work-related activities:
Duration: six weeks (weeks 1–6); intervention: four weeks (weeks 2–5)		Randomised into 3 groups: constant feedback (n = 19); intermediate feedback (n = 25); or control (no feedback) (n = 18). Comparison between baseline (one week) and follow up (week 4). Intervention conducted for four weeks (weeks 2–5)
Thanathornwong and Suebnukarn [69]Dental clinic 16 dental students (8 female, 8 male)
Age range 21–23. Mean, SD: NR
Eligibility: healthy. Health and work questionnaire		Randomised crossover 2 × 2 trial (pre-post-test)Differences in upper trunk posture using WIST feedback during a dental procedure. Duration: NRSame group: group A (n = 8) feedback; group B (n = 8) no feedback
Thanathornwong, Suebnukarn [70]Student periodontal clinic16 dental students (2 males, 14 female)
Age range 21–23. Mean, SD: NR
Eligibility: healthy. Health and work questionnaire 		Randomised crossover 2 × 2 trial (pre-post-test)Differences in upper trunk and neck posture using WIST feedback during a dental procedure. Duration: NRSame group: group A (n = 8) feedback; group B (n = 8) no feedback
Vignais, Miezal [71]Simulated industrial environment12 male student participants
Mean age (SD): 22.5, (2.5)
Eligibility: Health not reported		Cross-sectionalDifferences in upper body posture using WIST feedback during an industrial manual task. Duration: NRTwo groups (randomised): WR group (feedback) (n = 6); WOR group (control no feedback) (n = 6)
Ailneni, Syamala [72]Laboratory based19 participants (9 males, 10 females)
Mean (SD): 24.47 (5.32)
Eligibility: Healthy		Cross-sectional Comparison of head and neck posture with and without feedback from WIST during computer users.
Duration: 2 h 		Same group: 2 × 30 min typing tasks (30 min sitting, 30 min standing) with feedback; repeated without feedback
Boocock, Naudé [73]Laboratory based36 university students
Gender: NR
Mean (SD) age:
feedback group: 25.7 (4.6);
no feedback 25.6 (5.1)
Eligibility: healthy		Cross-sectionalModifying lumbosacral posture in response to real-time external biofeedback during a repetitive lifting task compared to no feedback
Duration: 20 min		Randomised: two groups: feedback (n = 18), no feedback (n = 18)
Bootsman, Markopoulos [74]Hospital13 female nurses (day shift)
Mean age (SD): 39.77 (13.6)
Eligibility: healthy. No lower back pain and not sedentary during work		Cross-sectionalInvestigating whether feedback from WIST influences postural behaviour positively compared to no feedback. Comparison between two feedback strategies in working nurses.
Duration: 3.5 h		Same group: a continuous four-phased condition
Breen, Nisar [75]Laboratory-basedSix asymptomatic regular computer users
Mean age (SD): NR
Gender: NR
Eligibility: healthy. No history of neck or back pain		Cross-sectionalModifying neck postures in regular computer users with and without feedback from WIST.
Duration: NR		Same group: two five-hour sessions with and without feedback during a desktop computer task (within-subject sample)
Kuo, Wang [76]Laboratory-based21 university students (8 male, 18 female)
Mean age (SD): 23.8, (3.5)
Eligibility: nonspecific neck pain		Cross-sectionalModifying spinal postures and perceived pain severity using feedback compared to no feedback during computer use.
Duration: two hours		Same group: 2 × 1 h typing task (1 with feedback; 1 h without feedback)
Park, Hetzler [77]Sedentary work environment31 lower back pain (13 male, 18 female)
Mean age (SD): 33.1, (13.3)
Eligibility: pre-existing lower back pain		Cross-sectionalEffects of postural training with vibrational biofeedback on pre-existing lower back pain during daily work-related activities.
Duration: 21 days (device worn during working hours only)		Allocated into two groups: feedback (n = 16), no feedback (n = 15)
Cerqueira, Da Silva [78] Simulated workplace environment5 individuals (1 female and 4 males)
Mean age (SD): 24.0, (1.1)
Eligibility: none specified		Cross-sectional (proof of concept)Effects of posture behaviour using biofeedback and without feedback during simulated workplace tasks.
Duration: approximately 6.5 min		Same group: five continuous tasks repeated 4 times (2 times with feedback remaining 2 times without feedback)
Lind, Diaz-Olivares [79]Simulated workplace environment16 university staff and/or students (9 female, 9 male)
Mean age (SD): 25, (8.0)
Eligibility: mail sorting experience and no musculoskeletal discomfort		Cross-sectional Effects of arm posture and movement modification using feedback during simulated mail sorting tasks.
Duration: <15 min		Same group: using two experimental conditions A and B.
Sorting mail with verbal ergonomic instructions or verbal instructions in combination with feedback
Organising mail trays with verbal ergonomic instructions or verbal instructions in combination with feedback
Doss, Robathan [80]Patient-handling tasks10 nursing students (all female)
Mean age (SD): 26.1 (9.1)
Eligibility: no history of back pain		Cross-sectionalTo provide a feedback intervention that could be implemented in a student curriculum to educate student trainees.
Duration: NR		Same group: to preform three patient-handling tasks with and without feedback
NR: not reported.
Table
Table 5. Wearable inertial sensor technology (WIST) system characteristics used in each of the included studies.
Table 5. Wearable inertial sensor technology (WIST) system characteristics used in each of the included studies.
StudySensor ModelSensor Location and AttachmentSensor Quantity/Sampling FrequencyFilter Type/Frequency Cut-OffSensor ConnectionTechnology ReadinessSensor Validation or AccuracyWearability AssessmentReported WIST Limitations
Brakenridge, Fjeldsoe [67]Accel *
LUMOback Bodytech.
ActivPal3
Pal Technologies (monitor only)		Posterior-worn sensor at the waistline1
NR		NRIntegrated Bluetooth* sync to mobile phoneCAMVNRLow uptake and self-directed usage of WIST may limit effectiveness. N = 14 (32.6%) reported using WIST device: irritation or rash (n = 3), uncomfortable (n = 8), minor back pain/strain (n = 3)
Ribeiro, Sole [68]Accel
Movement Metrics Ltd.		Participant’s belt (lateral position)1
NR		NRIntegrated within deviceCAPrior validation; accuracy to 1°NRNo time stamp of on/off periods. Error of 8° between days and 5° within days. Clothing may alter postural-pattern estimates.
Thanathornwong and Suebnukarn [69]Accel
ADXL345		Placed posteriorly onto the upper body of a gown1
Only range
12.5–400 Hz		NRCable connected (sensor to computation device)CNR;
stated accuracy of 0.01°		NRCustom-developed software may not be effectively applied to all patients
Thanathornwong, Suebnukarn [70]Accel
ADXL345
Analog devices USA		Face shield sensor +
Sensor on posterior of gown of upper body		2
Range
12.5–400 Hz		NRCable connected (sensor to computation device)CNR;
Stated accuracy of 0.01°		NRNR
Vignais, Miezal [71]IMU (Accel, Gyros and Magne).
Bi-axial goni
Colibri IMU
SG65 (monitor only)		Attached by an elastic strap: bilateral forearm, upper arm, head, chest, sacrum. Wrist angle measured by goniometers.7 IMU
2 goni
100 Hz		Kalman filters
(cut-off NR)		Cable connectedCNRNRInferred computations using the RULA tool. IMU errors influenced by magnetic disturbances
Ailneni, Syamala [72]Accel
Alex, NAMU inc		Posterior neck above C7 vertebra1
NR		NRWireless
Bluetooth		CANRNRNo direct validation conducted may result in lower sensitivity in primary outcome estimates
Boocock, Naudé [73]IMU (Accel, Gyros and Magne) *
Shimmer		L1 lumbar Spinous process and sacral body. Direct to body. Attachment method: NR2
NR		NRwirelessCAMVNRSensor placement may interfere with other working positions
Bootsman, Markopoulos [74]IMU (Accel, Gyros and Magne) *
LSM9DSO		Sewn into a tight-fitting shirt (garment) placed over the L1 and L5 lumber vertebrae 2
NR		NRWireless BluetoothCNRYesOne-size garment may not suit individual anthropometric measurements
Breen, Nisar [75]Accel
NR		C7 vertebrae sensor. Direct to body. Unable to determine mechanism for sensor attachment1
40 Hz		NR;
Low pass filtered at 10 Hz		Cable connectedCNRNRSensor measurement in single plane (sagittal)
Kuo, Wang [76]Accel
Lumo lift (Lumo Bodytech)		Taped below the left mid clavicle1
NR		NRWirelessCAMVNRNR
Park, Hetzler [77]Accel
Lumo lift (Lumo Bodytech)		Clip onto an undershirt 2.54 cm below the left clavicle1
NR		NRWirelessCAMVNRWireless connectivity issues.
Reliability and validity not evaluated prior to study.
Inconsistent tracking from non-compliance during the working day
Cerqueira, Da Silva [78]IMU (Accel, Gyros and Magne) (Invensense, USA)
MPU-9250		T4 level, posterior of head and bilaterally on each upper arm.
Vibration (haptic) motors: bilateral upper arms, cervical and lumbar region		4 IMUs
100 Hz
4 Haptic motors
200 Hz (vibration)		Kalman filter (cut-off NR)
WirelessCValidated using the UR3 robot arm. Error in full angle range 1.43% to 2.5%YesNR
Lind, Diaz-Olivares [79]IMU (Accel, Gyros and Magne) (LP Research)
LPMS-B2		Velco strapped bilaterally on upper arms over a short-sleeved shirt.
Vibration (haptic) motor on right upper arm		2 IMUs
25 Hz
1 vibration motor (haptic)		Kalman filter (cut-off NR)Wireless BluetoothCNRYesValidation procedure and IMU drift.
Potential loss of data from wireless disconnection
Doss, Robathan [80]Accel
Shimmer		Custom belt and vest2
28 Hz		NRWireless BluetoothCMV.
Accelerometers used simultaneous with a 3D motion capture system		NoNR
NR: not reported; N/A: not applicable; MV: manufacturer validation * Information obtained from manufacturer. Technological readiness based on commercial availability: (C: custom; CA: commercially available). Accel: accelerometer; Gyro: gyroscope; Magne: magnetometer; Goni: goniometer.
Table
Table 6. Risk-of-bias evaluation for randomised controlled trials (n = 2) using the National Institutes of Health risk-of-bias tool for controlled intervention studies.
Table 6. Risk-of-bias evaluation for randomised controlled trials (n = 2) using the National Institutes of Health risk-of-bias tool for controlled intervention studies.
Study1. Study Description, Randomised RCT2. Adequate Method of Randomisation 3. Was Treatment Allocation Concealed?4. Providers and Participants Blinded5. Assessors Blinded to the Participants6. Baseline Characteristics That Could Affect Outcomes7. Dropout Rate at an Endpoint of 20% or Lower8. Dropout Rate at an Endpoint of 15% or Lower9. High Adherence to Intervention Protocols in Each Group10. Other Interventions Avoided or Similar in the Group11. Outcomes Assessed Using Valid and Reliable Measures12. Sample Size Sufficient to Detect Differences in Outcome13. Outcomes Reported or Subgroups Analysed14. Randomised Participants Analysed in Original GroupQuality Rating
Brakenridge, Fjeldsoe [67]++------NRNRCD+-+Fair
Ribeiro, Sole [68]+++++NRNRNRNRNR++NRNRFair
Note: Abbreviations: + met criteria; - did not meet criteria (other: CD, cannot determine; NA, not applicable; NR, not reported).
Table
Table 7. Risk-of-bias evaluation for pre-post study designs (n = 2) using the National Institutes of Health risk-of-bias tool for before–after (pre-post) studies with no control group.
Table 7. Risk-of-bias evaluation for pre-post study designs (n = 2) using the National Institutes of Health risk-of-bias tool for before–after (pre-post) studies with no control group.
Study1. Study Question or Objective Clearly Stated2. Eligibility/Selection Criteria3. Participants Representative of the General/Clinical Population Concealed4. All Eligible Participants Enrolled5. Sample Size Large Enough6. Intervention/Test Clearly Described7. Valid, Reliable Clearly Defined Outcome Measures8. Researchers Blinded to Participants’ Interventions/Exposures9. Loss to Follow Up <20%10. Statistical Tests of Outcomes Measured Pre-Post 11. Outcomes and Measures Conducted Multiple Times before and after Tests12. Intervention at Group Level, Use of Individual Data at a Group LevelQuality Rating
Thanathornwong and Suebnukarn [69]+--NR++--+Y-+Poor
Thanathornwong, Suebnukarn [70]+--NR++--+Y-+Poor
NOTE: Abbreviations: + met criteria; - did not meet criteria (other: CD, cannot determine; NA, not applicable; NR, not reported).
Table
Table 8. Risk-of-bias evaluation for cross-sectional studies (n = 7) using the National Institutes of Health risk-of-bias tool for observational cohort and cross-sectional studies.
Table 8. Risk-of-bias evaluation for cross-sectional studies (n = 7) using the National Institutes of Health risk-of-bias tool for observational cohort and cross-sectional studies.
Study1. Research Question or Objective Clearly Stated2. Was the Study Population Clearly Specified and Defined3. Participation Rate of Eligible Persons ≥50%4. Subjects Recruited from Same or Similar Populations5. Sample Size Justification6. Exposure(S) of Interest Measured Prior to the Outcome(S)7. Sufficient Timeframe 8. Different Levels of the Exposure as Related to the Outcome9. Exposure Measure Clearly Defined, Valid and Reliable10. Exposures(S) Assessed More than Once Over Time11. Outcomes and Measures Clearly Defined, Valid and Reliable12. Outcome Assessors Blinded to the Exposure13. Follow-Up after Baseline ≤2014. Adjusted for Potential Confounding VariablesQuality Rating
Ailneni, Syamala [72]+-+NRNR--NA+++-+NAFair
Boocock, Naudé [73]+-+++--NA+-+-+NAFair
Bootsman, Markopoulos [74]+-++NR--NA-+--+NAFair
Breen, Nisar [75]--+NR---NA-+--NANAPoor
Kuo, Wang [76]+-++---NA+++-+NAPoor
Park, Hetzler [77]+-++---NA----+NAPoor
Vignais, Miezal [71]+-+NR---NA----NANAPoor
Cerqueira, Da Silva [78]+-+---+NA+++-+NAFair
Lind, Diaz-Olivares [79]+-++--+NA+++-+NAFair
Doss, Robathan [80]+-++--+NA+++-+NAFair
NOTE: Abbreviations: + met criteria; - did not meet criteria (other: CD, cannot determine; NA, not applicable; NR, not reported).
Table
Table 9. Evidence for changes in posture and movement behaviour during work or performing work-related activities.
Table 9. Evidence for changes in posture and movement behaviour during work or performing work-related activities.
StudyRisk-of-Bias Quality RatingOutcomeLevel of Evidence
Ailneni, Syamala [72]FairImproved neck and upper and/or lower trunk posture:
Sagittal plane (flexion/extension)		Limited
Breen, Nisar [75]Poor
Kuo, Wang [76]Poor
Vignais, Miezal [71]Poor
Thanathornwong, Suebnukarn [70]Poor
Thanathornwong and Suebnukarn [69]Poor
Ribeiro, Sole [68]Fair
Bootsman, Markopoulos [74]Fair
Boocock, Naudé [73]Fair
Doss, Robathan [80]Fair
Cerqueira, Da Silva [78]FairImproved neck and upper and/or lower trunk posture:
Sagittal and coronal plane (flexion/extension and lateral flexion)
Park, Hetzler [77]PoorNo neck and/or lower back pain/discomfort improvementsLimited
Kuo, Wang [76]Poor
Brakenridge, Fjeldsoe [67]FairImproved movement behaviour (Increased work stepping time)Very limited
Cerqueira, Da Silva [78]FairReduced upper-arm elevation angle or accumulative time Limited
Lind, Diaz-Olivares [79]Fair
Table
Table 10. Technology and Design Checklist.
Table 10. Technology and Design Checklist.
Data Collection
Inertial Sensor		WIST Processing/AnalysisFeedback ParametersStudy Design
Sensor
Model/manufacture
Inertial sensor type
Quantity
Connection method
Anatomical location
Attachment method
Frequency sampling rate
Filter type (e.g., Butterworth) and cut-off frequency
Fusion type (e.g., Kalman)
Processing system
3D joint/modelling angle(s)/rotation(s) *
Joint coordinate system
Algorithm origin/availability
Trigger (kinematic set-point)
Biomechanical set-point source/origin
Content ‡
Timing (latency) †
Frequencies of feedback occurrences
Monitoring duration (h, min)
Source/device of feedback
Participant evaluation on feedback content/timing
Suggested technology readiness for clinical application
Limitations
Refer to STROBE statement checklists [137]
Prior assessment of WIST validity/reliably with outcomes reported
Follow-up evaluation
* Refer to International Society of Biomechanics (ISB): https://isbweb.org/ (accessed on 2 February 2021) or if not using standardised methods, the provision of equivalent information to replicate is required. ‡ Visual, audible, vibrotactile, multimodal, other; † concurrent, terminal, fading, other.
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Lee, R.; James, C.; Edwards, S.; Skinner, G.; Young, J.L.; Snodgrass, S.J. Evidence for the Effectiveness of Feedback from Wearable Inertial Sensors during Work-Related Activities: A Scoping Review. Sensors 2021, 21, 6377. https://doi.org/10.3390/s21196377

AMA Style

Lee R, James C, Edwards S, Skinner G, Young JL, Snodgrass SJ. Evidence for the Effectiveness of Feedback from Wearable Inertial Sensors during Work-Related Activities: A Scoping Review. Sensors. 2021; 21(19):6377. https://doi.org/10.3390/s21196377

Chicago/Turabian Style

Lee, Roger, Carole James, Suzi Edwards, Geoff Skinner, Jodi L. Young, and Suzanne J. Snodgrass. 2021. "Evidence for the Effectiveness of Feedback from Wearable Inertial Sensors during Work-Related Activities: A Scoping Review" Sensors 21, no. 19: 6377. https://doi.org/10.3390/s21196377

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop