Estimation of Absolute States of Human Skeletal Muscle via Standard B-Mode Ultrasound Imaging and Deep Convolutional Neural Networks
Ryan J. Cunningham, Ian D. Loram

TL;DR
This study demonstrates that deep learning applied to 2D ultrasound images can non-invasively estimate active and passive skeletal muscle states, providing a new approach for personalized muscle diagnosis.
Contribution
The paper introduces a novel deep learning method that accurately estimates muscle activity, joint angle, and joint moment from ultrasound images, generalizing across individuals.
Findings
Deep neural networks predict muscle states with ~55% accuracy.
Ultrasound imaging combined with deep learning encodes muscle length-tension relationships.
Method offers a non-invasive tool for muscle diagnosis in various conditions.
Abstract
Objective: To test automated in vivo estimation of active and passive skeletal muscle states using ultrasonic imaging. Background: Current technology (electromyography, dynamometry, shear wave imaging) provides no general, non-invasive method for online estimation of skeletal intramuscular states. Ultrasound (US) allows non-invasive imaging of muscle, yet current computational approaches have never achieved simultaneous extraction nor generalisation of independently varying, active and passive states. We use deep learning to investigate the generalizable content of 2D US muscle images. Method: US data synchronized with electromyography of the calf muscles, with measures of joint moment/angle were recorded from 32 healthy participants (7 female, ages: 27.5, 19-65). We extracted a region of interest of medial gastrocnemius and soleus using our prior developed accurate segmentation…
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