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Autori principali: Mahajan, Pranav, Wall, Amanda, Camerone, Eleonora Maria, Stebbins, Julie, Kelleher, Eoin, Tong, Shuangyi, Schmid, Annina, Wiech, Katja, Irani, Anushka, Seymour, Ben
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2606.02301
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author Mahajan, Pranav
Wall, Amanda
Camerone, Eleonora Maria
Stebbins, Julie
Kelleher, Eoin
Tong, Shuangyi
Schmid, Annina
Wiech, Katja
Irani, Anushka
Seymour, Ben
author_facet Mahajan, Pranav
Wall, Amanda
Camerone, Eleonora Maria
Stebbins, Julie
Kelleher, Eoin
Tong, Shuangyi
Schmid, Annina
Wiech, Katja
Irani, Anushka
Seymour, Ben
contents Chronic pain diminishes quality of life by decreasing functional ability, yet objectively measuring this functional impact remains challenging in real-world settings. While optical motion capture provides high precision for assessing altered movement quality, it is costly and restricted to laboratory environments. We aimed to develop and validate Quantitative Movement Testing (QMT), a computer vision pipeline extracting 3D kinematic biomarkers from standard monocular smartphone video, balancing clinical accessibility with biomechanical accuracy. We validated the QMT pipeline, utilising deep learning-based 3D pose-estimation, against gold-standard optical motion capture in healthy controls (N=13). Following leave-one-subject-out calibration to correct systematic bias, we deployed QMT in two prospective clinical cohorts to assess real-world utility: a pre- and post-intervention trial for fibromyalgia patients, and a 30-day longitudinal at-home monitoring study of chronic sciatica patients and healthy controls. In laboratory validation, QMT extracted clinical kinematic metrics with high agreement to optical motion capture, yielding strong correlations (r > 0.85) and low mean absolute errors. QMT demonstrated high test-retest reliability (r > 0.86) in fibromyalgia patients and successfully tracked day-to-day movement fluctuations in chronic sciatica. While real-world home settings introduced higher measurement variance than lab settings, QMT found group-level differences between healthy controls and sciatica patients based entirely on remote recordings. Monocular 3D pose estimation offers a scalable alternative to traditional assessments. QMT provides an objective, accessible biomarker for tracking disease progression and treatment response in clinical trials, though further research is needed to optimise reliability in home environments.
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id arxiv_https___arxiv_org_abs_2606_02301
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Quantitative Movement Testing: Measuring Patient Movements from a Single Smartphone Video
Mahajan, Pranav
Wall, Amanda
Camerone, Eleonora Maria
Stebbins, Julie
Kelleher, Eoin
Tong, Shuangyi
Schmid, Annina
Wiech, Katja
Irani, Anushka
Seymour, Ben
Human-Computer Interaction
Artificial Intelligence
Computer Vision and Pattern Recognition
Chronic pain diminishes quality of life by decreasing functional ability, yet objectively measuring this functional impact remains challenging in real-world settings. While optical motion capture provides high precision for assessing altered movement quality, it is costly and restricted to laboratory environments. We aimed to develop and validate Quantitative Movement Testing (QMT), a computer vision pipeline extracting 3D kinematic biomarkers from standard monocular smartphone video, balancing clinical accessibility with biomechanical accuracy. We validated the QMT pipeline, utilising deep learning-based 3D pose-estimation, against gold-standard optical motion capture in healthy controls (N=13). Following leave-one-subject-out calibration to correct systematic bias, we deployed QMT in two prospective clinical cohorts to assess real-world utility: a pre- and post-intervention trial for fibromyalgia patients, and a 30-day longitudinal at-home monitoring study of chronic sciatica patients and healthy controls. In laboratory validation, QMT extracted clinical kinematic metrics with high agreement to optical motion capture, yielding strong correlations (r > 0.85) and low mean absolute errors. QMT demonstrated high test-retest reliability (r > 0.86) in fibromyalgia patients and successfully tracked day-to-day movement fluctuations in chronic sciatica. While real-world home settings introduced higher measurement variance than lab settings, QMT found group-level differences between healthy controls and sciatica patients based entirely on remote recordings. Monocular 3D pose estimation offers a scalable alternative to traditional assessments. QMT provides an objective, accessible biomarker for tracking disease progression and treatment response in clinical trials, though further research is needed to optimise reliability in home environments.
title Quantitative Movement Testing: Measuring Patient Movements from a Single Smartphone Video
topic Human-Computer Interaction
Artificial Intelligence
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2606.02301