Ultrasonic Characterization Of Localized Passive Elastic Properties Of Human Pennate Muscle With A Single-Probe Setup

Quantitative evaluation of passive elastic properties of an individual skeletal muscle in vivo is among the major challenges of biomechanics, and its clinical application is severely limited. By combining shear-wave elastography (SWE) and B-mode imaging techniques, this study develops a novel non-invasive method to measure the local elastic modulus-fascicle strain curve of human pennation muscle during passive stretching using a single probe. Physiologically meaningful parameters are estimated and compared in subjects with different ages or pathological conditions. The in vivo experimental group comprised 12 healthy subjects (four children, four adults, and four seniors) and eight patients (four suffering from pseudohypertrophy, four from atrophy). Their gastrocnemius muscles were passively stretched using an ankle joint motion instrument. Local elastic moduli of the muscle were measured using SWE imaging frames and a built-in 'F-ROI' tool. The corresponding fascicle strains were simultaneously obtained using B-mode imaging frames and a gradient Radon transform. Three parameters (eta, mu, G(0)) were estimated from a normalized elastic modulus-strain curve using the Gauss-Newton method. The measured elastic modulus-strain curves all agreed with models of the estimated parameters (0.910 < R-2 < 0.999) and presented different patterns among normal and diseased subjects. eta values were lower for pseudohypertrophies (1.93 +/- 0.12), but higher for atrophies (63.40 +/- 98.89), compared with normal ones (6.02 +/- 2.53). In addition, mu values were higher for pseudohypertrophies (22.65 +/- 16.40), but lower for atrophies (0.28 +/- 0.41), compared with normal ones (1.07 +/- 1.22). The proposed method may provide novel insight into the biomechanics of pennate muscle and has the potential to serve for clinical musculoskeletal medical diagnosis, as the single-probe scanning setup is broadly accepted.