284 research outputs found

    A Literature Review on the Risks and Potentials of Tracking and Monitoring eHealth Technologies in the Context of Occupational Health Management

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    Employee health is increasingly important, as is the use of eHealth technologies in the private and the organizational context. This paper examines which existing eHealth technologies that support monitoring and tracking of health are applied in occupational health management (OHM) and investigates the advantages and disadvantages of their application. To pursue this intention, we analyze the current state of research with a structured literature review and provide a comprehensive overview of relevant works. The results point out advantages and disadvantages that provide the groundwork to discuss success factors for tracking and monitoring eHealth technologies in OHM. The derived success factors aim at operational, technological, operational/technological aspects of eHealth tracking and monitoring usage. Thereby, favorable outcomes such as an increase in employee health can be achieved, and participation in OHM measures can be increased. However, it can also lead to adverse outcomes such as a reduced work-life balance

    Smartphone-based Human Fatigue Detection in an Industrial Environment Using Gait Analysis

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    Human fatigue due to repetitive and physically challenging jobs may result in poor performance and a Work-related Musculoskeletal Disorder (WMSD). Thus, the importance of being able to monitor fatigue to implement preventative interventions cannot be overstated. This study was designed to monitor fatigue through the development of a methodology that objectively classifies an individual’s level of fatigue in the workplace by utilizing the motion sensors embedded in smartphones. An experiment consisting of squatting tasks, primarily involving the lower extremity musculature, was conducted with 24 participants using a smartphone attached to their right shank. Using Borg’s Ratings of Perceived Exertion (RPE) to label gait data, we developed machine learning algorithms to classify each individual’s gait into two (no- vs. strong-fatigue), three (no-, medium-, and strong-fatigue) and four (no-, low-, medium-, and strong-fatigue) levels of fatigue, for which accuracy of 91%, 76%, and 61% were obtained, respectively. The outcomes of this study may facilitate the implementation of a proactive approach supporting the continuous monitoring of a worker’s fatigue level, which may subsequently enhance workers’ performance and reduce the risk of WMSDs

    Review of Wearable Devices and Data Collection Considerations for Connected Health

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    Wearable sensor technology has gradually extended its usability into a wide range of well-known applications. Wearable sensors can typically assess and quantify the wearer’s physiology and are commonly employed for human activity detection and quantified self-assessment. Wearable sensors are increasingly utilised to monitor patient health, rapidly assist with disease diagnosis, and help predict and often improve patient outcomes. Clinicians use various self-report questionnaires and well-known tests to report patient symptoms and assess their functional ability. These assessments are time consuming and costly and depend on subjective patient recall. Moreover, measurements may not accurately demonstrate the patient’s functional ability whilst at home. Wearable sensors can be used to detect and quantify specific movements in different applications. The volume of data collected by wearable sensors during long-term assessment of ambulatory movement can become immense in tuple size. This paper discusses current techniques used to track and record various human body movements, as well as techniques used to measure activity and sleep from long-term data collected by wearable technology devices

    Explaining the Ergonomic Assessment of Human Movement in Industrial Contexts

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    Manufacturing processes are based on human labour and the symbiosis between human operators and machines. The operators are required to follow predefined sequences of movements. The operations carried out at assembly lines are repetitive, being identified as a risk factor for the onset of musculoskeletal disorders. Ergonomics plays a big role in preventing occupational diseases. Ergonomic risk scores measure the overall risk exposure of operators however these methods still present challenges: the scores are often associated to a given workstation, being agnostic to the variability among operators. Observation methods are most often employed yet require a significant amount of effort, preventing an accurate and continuous ergonomic evaluation to the entire population of operators. Finally, the risk’s results are rendered as index scores, hindering a more comprehensive interpretation by occupational physicians. This dissertation developed a solution for automatic operator risk exposure in assembly lines. Three main contributions were presented: (1) an upper limb and torso motion tracking algorithm which relies on inertial sensors to estimate the orientation of anatomical joints; (2) an adjusted ergonomic risk score; (3) an ergonomic risk explanation approach based on the analysis of the angular risk factors. Throughout the research, two experimental assessments were conducted: laboratory validation and field evaluation. The laboratory tests enabled the creation of a movements’ dataset and used an optical motion capture system as reference. The field evaluation dataset was acquired on an automotive assembly line and serve as the basis for an ergonomic risk evaluation study. The experimental results revealed that the proposed solution has the potential to be applied in a real environment. Through direct measures, the ergonomic feedback is fastened, and consequently, the evaluation can be extended to more operators, ultimately preventing, in long-term, work-related injuries

    Work Posture Analysis at The Spinning Department of Textile Industry using Rapid Upper Limb Assessment (RULA) Method

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    The work posture of a worker affects not only his efficiency but also to his health. To a job with a high repetitive process, a bad posture will make a worker vulnerable to musculoskeletal disorders (MSDs). This study is aimed to analyze the working posture of workers engaged in the textile industry, especially in the spinning department. The work posture assessment is conducted using Rapid Upper Limb Assessment (RULA). The photo took while the worker was doing their work at the production process of yarn is used to analyze the worker’s work posture. Some postures were identified under high-risk levels which potentially causing upper limb disorders then it requires immediate change. Recommendation regarding improving the body posture while working is provided

    Appl Ergon

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    Improper manual material handling (MMH) techniques are shown to lead to low back pain, the most common work-related musculoskeletal disorder. Due to the complex nature and variability of MMH and obtrusiveness and subjectiveness of existing hazard analysis methods, providing systematic, continuous, and automated risk assessment is challenging. We present a machine learning algorithm to detect and classify MMH tasks using minimally-intrusive instrumented insoles and chest-mounted accelerometers. Six participants performed standing, walking, lifting/lowering, carrying, side-to-side load transferring (i.e., 5.7\ua0kg and 12.5\ua0kg), and pushing/pulling. Lifting and carrying loads as well as hazardous behaviors (i.e., stooping, overextending and jerky lifting) were detected with 85.3%/81.5% average accuracies with/without chest accelerometer. The proposed system allows for continuous exposure assessment during MMH and provides objective data for use with analytical risk assessment models that can be used to increase workplace safety through exposure estimation.20222023-05-01T00:00:00ZT42 OH008414/OH/NIOSH CDC HHSUnited States/35144123PMC88972251105

    Wearable Sensors and Machine Learning based Human Movement Analysis – Applications in Sports and Medicine

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    Die Analyse menschlicher Bewegung außerhalb des Labors unter realen Bedingungen ist in den letzten Jahren sowohl in sportlichen als auch in medizinischen Anwendungen zunehmend bedeutender geworden. Mobile Sensoren, welche am Körper getragen werden, haben sich in diesem Zusammenhang als wertvolle Messinstrumente etabliert. Auf Grund des Umfangs, der Komplexität, der Heterogenität und der Störanfälligkeit der Daten werden vielseitige Analysemethoden eingesetzt, um die Daten zu verarbeiten und auszuwerten. Zudem sind häufig Modellierungsansätze notwendig, da die gemessenen Größen nicht auf direktem Weg aussagekräftige biomechanische Variablen liefern. Seit wenigen Jahren haben sich hierfür Methoden des maschinellen Lernens als vielversprechende Instrumente zur Ermittlung von Zielvariablen, wie beispielsweise der Gelenkwinkel, herausgestellt. Aktuell befindet sich die Forschung an der Schnittstelle aus Biomechanik, mobiler Sensoren und maschinellem Lernen noch am Anfang. Der Bereich birgt grundsätzlich ein erhebliches Potenzial, um einerseits das Spektrum an mobilen Anwendungen im Sport, insbesondere in Sportarten mit komplexen Bewegungsanforderungen, wie beispielsweise dem Eishockey, zu erweitern. Andererseits können Methoden des maschinellen Lernens zur Abschätzung von Belastungen auf Körperstrukturen mittels mobiler Sensordaten genutzt werden. Vor allem die Anwendung mobiler Sensoren in Kombination mit Prädiktionsmodellen zur Ermittlung der Kniegelenkbelastung, wie beispielsweise der Gelenkmomente, wurde bisher nur unzureichend erforscht. Gleichwohl kommt der mobilen Erfassung von Gelenkbelastungen in der Diagnostik und Rehabilitation von Verletzungen sowie Muskel-Skelett-Erkrankungen eine zentrale Bedeutung zu. Das übergeordnete Ziel dieser Dissertation ist es, festzustellen inwieweit tragbare Sensoren und Verfahren des maschinellen Lernens zur Quantifizierung sportlicher Bewegungsmerkmale sowie zur Ermittlung der Belastung von Körperstrukturen bei der Ausführung von Alltags- und Sportbewegungen eingesetzt werden können. Die Dissertation basiert auf vier Studien, welche in internationalen Fachzeitschriften mit Peer-Review-Prozess erschienen sind. Die ersten beiden Studien konzentrieren sich zum einen auf die automatisierte Erkennung von zeitlichen Events und zum anderen auf die mobile Leistungsanalyse während des Schlittschuhlaufens im Eishockey. Die beiden weiteren Studien präsentieren jeweils einen neuartigen Ansatz zur Schätzung von Belastungen im Kniegelenk mittels künstlich neuronalen Netzen. Zwei mobile Sensoren, welche in eine Kniebandage integriert sind, dienen hierbei als Datenbasis zur Ermittlung von Kniegelenkskräften während unterschiedlicher Sportbewegungen sowie von Kniegelenksmomenten während verschiedener Lokomotionsaufgaben. Studie I zeigt eine präzise, effiziente und einfache Methode zur zeitlichen Analyse des Schlittschuhlaufens im Eishockey mittels einem am Schlittschuh befestigten Beschleunigungssensor. Die Validierung des neuartigen Ansatzes erfolgt anhand synchroner Messungen des plantaren Fußdrucks. Der mittlere Unterschied zwischen den beiden Erfassungsmethoden liegt sowohl für die Standphasendauer als auch der Gangzyklusdauer unter einer Millisekunde. Studie II zeigt das Potenzial von Beschleunigungssensoren zur Technik- und Leistungsanalyse des Schlittschuhlaufens im Eishockey. Die Ergebnisse zeigen für die Standphasendauer und Schrittintensität sowohl Unterschiede zwischen beschleunigenden Schritten und Schritten bei konstanter Geschwindigkeit als auch zwischen Teilnehmern unterschiedlichen Leistungsniveaus. Eine Korrelationsanalyse offenbart, insbesondere für die Schrittintensität, einen starken Zusammenhang mit der sportlichen Leistung des Schlittschuhlaufens im Sinne einer verkürzten Sprintzeit. Studie III präsentiert ein tragbares System zur Erfassung von Belastungen im Kniegelenk bei verschiedenen sportlichen Bewegungen auf Basis zweier mobiler Sensoren. Im Speziellen werden unterschiedliche lineare Bewegungen, Richtungswechsel und Sprünge betrachtet. Die mittels künstlich neuronalem Netz ermittelten dreidimensionalen Kniegelenkskräfte zeigen, mit Ausnahme der mediolateralen Kraftkomponente, für die meisten analysierten Bewegungen eine gute Übereinstimmung mit invers-dynamisch berechneten Referenzdaten. Die abschließende Studie IV stellt eine Erweiterung des in Studie III entwickelten tragbaren Systems zur Ermittlung von Belastungen im Kniegelenk dar. Die ambulante Beurteilung der Gelenkbelastung bei Kniearthrose steht hierbei im Fokus. Die entwickelten Prädiktionsmodelle zeigen für das Knieflexionsmoment eine gute Übereinstimmung mit invers-dynamisch berechneten Referenzdaten für den Großteil der analysierten Bewegungen. Demgegenüber ist bei der Ermittlung des Knieadduktionsmoments mittels künstlichen neuronalen Netzen Vorsicht geboten. Je nach Bewegung, kommt es zu einer schwachen bis starken Übereinstimmung zwischen der mittels Prädiktionsmodell bestimmten Belastung und dem Referenzwert. Zusammenfassend tragen die Ergebnisse von Studie I und Studie II zur sportartspezifischen Leistungsanalyse im Eishockey bei. Zukünftig können sowohl die Trainingsqualität als auch die gezielte Verbesserung sportlicher Leistung durch den Einsatz von am Körper getragener Sensoren in hohem Maße profitieren. Die methodischen Neuerungen und Erkenntnisse aus Studie III und Studie IV ebnen den Weg für die Entwicklung neuartiger Technologien im Gesundheitsbereich. Mit Blick in die Zukunft können mobile Sensoren zur intelligenten Analyse menschlicher Bewegungen sinnvoll eingesetzt werden. Die vorliegende Dissertation zeigt, dass die mobile Bewegungsanalyse zur Erleichterung der sportartspezifischen Leistungsdiagnostik unter Feldbedingungen beiträgt. Zudem zeigt die Arbeit, dass die mobile Bewegungsanalyse einen wichtigen Beitrag zur Verbesserung der Gesundheitsdiagnostik und Rehabilitation nach akuten Verletzungen oder bei chronischen muskuloskelettalen Erkrankungen leistet

    Technology in Parkinson's disease:challenges and opportunities

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    The miniaturization, sophistication, proliferation, and accessibility of technologies are enabling the capture of more and previously inaccessible phenomena in Parkinson's disease (PD). However, more information has not translated into a greater understanding of disease complexity to satisfy diagnostic and therapeutic needs. Challenges include noncompatible technology platforms, the need for wide-scale and long-term deployment of sensor technology (among vulnerable elderly patients in particular), and the gap between the "big data" acquired with sensitive measurement technologies and their limited clinical application. Major opportunities could be realized if new technologies are developed as part of open-source and/or open-hardware platforms that enable multichannel data capture sensitive to the broad range of motor and nonmotor problems that characterize PD and are adaptable into self-adjusting, individualized treatment delivery systems. The International Parkinson and Movement Disorders Society Task Force on Technology is entrusted to convene engineers, clinicians, researchers, and patients to promote the development of integrated measurement and closed-loop therapeutic systems with high patient adherence that also serve to (1) encourage the adoption of clinico-pathophysiologic phenotyping and early detection of critical disease milestones, (2) enhance the tailoring of symptomatic therapy, (3) improve subgroup targeting of patients for future testing of disease-modifying treatments, and (4) identify objective biomarkers to improve the longitudinal tracking of impairments in clinical care and research. This article summarizes the work carried out by the task force toward identifying challenges and opportunities in the development of technologies with potential for improving the clinical management and the quality of life of individuals with PD. © 2016 International Parkinson and Movement Disorder Society

    Wearable devices for ergonomics: A systematic literature review

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    Wearable devices are pervasive solutions for increasing work efficiency, improving workers’ well-being, and creating interactions between users and the environment anytime and anywhere. Although several studies on their use in various fields have been performed, there are no systematic reviews on their utilisation in ergonomics. Therefore, we conducted a systematic review to identify wearable devices proposed in the scientific literature for ergonomic purposes and analyse how they can support the improvement of ergonomic conditions. Twenty-eight papers were retrieved and analysed thanks to eleven comparison dimensions related to ergonomic factors, purposes, and criteria, populations, application and validation. The majority of the available devices are sensor systems composed of different types and numbers of sensors located in diverse body parts. These solutions also represent the technology most frequently employed for monitoring and reducing the risk of awkward postures. In addition, smartwatches, body-mounted smartphones, insole pressure systems, and vibrotactile feedback interfaces have been developed for evaluating and/or controlling physical loads or postures. The main results and the defined framework of analysis provide an overview of the state of the art of smart wearables in ergonomics, support the selection of the most suitable ones in industrial and non-industrial settings, and suggest future research directions
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