Assessing aberrant muscle activity patterns via the analysis of surface EMG data collected during a functional evaluation

Golabchi, Fatemeh Noushin; Sapienza, Stefano; Severini, Giacomo; Reaston, Phil; Tomecek, Frank J.; Demarchi, Danilo; Reaston, MaryRose; Bonato, Paolo

doi:10.1186/s12891-018-2350-x

Cited by 15 publications

(7 citation statements)

References 59 publications

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“…In spinal surgery, it is often necessary to insert implants such as pedicle screws, Kirschner wires, and artificial intervertebral discs into patients to achieve a satisfactory reset effect [49,50] . In the future, it will be possible to insert instruments with sensors into related structures of the human body, which can carry out real-time monitoring of physiological states [52] . Wearable sensors minimize the potential limitations of traditional assessment tools by generating quantitative data and greatly improving the home monitoring of patients through a timely internet-of-things data transmission mechanism, such as analyzing surface electromyogram data collected during musculoskeletal function to assess activity patterns of abnormal muscles.…”

Section: Chronic Diseases Requiring Sports Rehabilitationmentioning

confidence: 99%

Integration of Artificial Intelligence, Blockchain, and Wearable Technology for Chronic Disease Management: A New Paradigm in Smart Healthcare

Xie

Gao

et al. 2021

CURR MED SCI

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Chronic diseases are a growing concern worldwide, with nearly 25% of adults suffering from one or more chronic health conditions, thus placing a heavy burden on individuals, families, and healthcare systems. With the advent of the “Smart Healthcare” era, a series of cutting-edge technologies has brought new experiences to the management of chronic diseases. Among them, smart wearable technology not only helps people pursue a healthier lifestyle but also provides a continuous flow of healthcare data for disease diagnosis and treatment by actively recording physiological parameters and tracking the metabolic state. However, how to organize and analyze the data to achieve the ultimate goal of improving chronic disease management, in terms of quality of life, patient outcomes, and privacy protection, is an urgent issue that needs to be addressed. Artificial intelligence (AI) can provide intelligent suggestions by analyzing a patient’s physiological data from wearable devices for the diagnosis and treatment of diseases. In addition, blockchain can improve healthcare services by authorizing decentralized data sharing, protecting the privacy of users, providing data empowerment, and ensuring the reliability of data management. Integrating AI, blockchain, and wearable technology could optimize the existing chronic disease management models, with a shift from a hospital-centered model to a patient-centered one. In this paper, we conceptually demonstrate a patient-centric technical framework based on AI, blockchain, and wearable technology and further explore the application of these integrated technologies in chronic disease management. Finally, the shortcomings of this new paradigm and future research directions are also discussed.

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Section: Chronic Diseases Requiring Sports Rehabilitationmentioning

confidence: 99%

Integration of Artificial Intelligence, Blockchain, and Wearable Technology for Chronic Disease Management: A New Paradigm in Smart Healthcare

Xie

Gao

et al. 2021

CURR MED SCI

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“…Seven of the included publications used various forms of regression algorithms [37,41,52,59,62,72,80]. Instead of assigning a predefined class label, these algorithms output continuous numerical values.…”

Section: Supervised Algorithmsmentioning

confidence: 99%

Machine Learning in Chronic Pain Research: A Scoping Review

et al. 2021

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Given the high prevalence and associated cost of chronic pain, it has a significant impact on individuals and society. Improvements in the treatment and management of chronic pain may increase patients’ quality of life and reduce societal costs. In this paper, we evaluate state-of-the-art machine learning approaches in chronic pain research. A literature search was conducted using the PubMed, IEEE Xplore, and the Association of Computing Machinery (ACM) Digital Library databases. Relevant studies were identified by screening titles and abstracts for keywords related to chronic pain and machine learning, followed by analysing full texts. Two hundred and eighty-seven publications were identified in the literature search. In total, fifty-three papers on chronic pain research and machine learning were reviewed. The review showed that while many studies have emphasised machine learning-based classification for the diagnosis of chronic pain, far less attention has been paid to the treatment and management of chronic pain. More research is needed on machine learning approaches to the treatment, rehabilitation, and self-management of chronic pain. As with other chronic conditions, patient involvement and self-management are crucial. In order to achieve this, patients with chronic pain need digital tools that can help them make decisions about their own treatment and care.

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“…According as the accuracy of surface EMG has been improved, it is possible to monitor muscle condition in real time by connecting the communication module to surface EMG. 48 Pain is the most common symptom of spinal disease and an important indicator in treatment decisions and follow-up. VAS or numeric rating scale is the most common parameter used to measure pain assessment in spinal patients.…”

Section: Internet Of Things and Digital Biomarkers Associated With Spinementioning

confidence: 99%

Internet of Things, Digital Biomarker, and Artificial Intelligence in Spine: Current and Future Perspectives

et al. 2019

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Recent interest in medical artificial intelligence (AI) has increased with onset of the fourth industrial revolution. Real-time monitoring of patients is an important research area of medical AI. The medical AI is very closely related to the Internet of Things (IoT), a core element of the fourth industrial revolution. Attempts to diagnose and treat patients using IoT have been already applied to patients with chronic disease such as hypertension and arrhythmia. However, in the spine, research on IoT and digital biomarkers are still in the early stages. The digital biomarker obtained by IoT devices is objective and could represent real-time, real-world, and abundant data. Based on its characteristics, IoT and digital biomarkers can also be useful in the spine. Currently, research on real-time monitoring of physical activity or spinal posture is ongoing. Therefore, the authors introduce the basic concepts of IoT and digital biomarkers, their relationship to AI, and recent trends. Current and future perspectives of IoT and digital biomarker in spine are also discussed. In the future, it is expected that IoT, digital biomarkers, and AI will lead to a paradigm shift in the diagnosis and treatment of spinal diseases.

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Assessing aberrant muscle activity patterns via the analysis of surface EMG data collected during a functional evaluation

Cited by 15 publications

References 59 publications

Integration of Artificial Intelligence, Blockchain, and Wearable Technology for Chronic Disease Management: A New Paradigm in Smart Healthcare

Integration of Artificial Intelligence, Blockchain, and Wearable Technology for Chronic Disease Management: A New Paradigm in Smart Healthcare

Machine Learning in Chronic Pain Research: A Scoping Review

Internet of Things, Digital Biomarker, and Artificial Intelligence in Spine: Current and Future Perspectives

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