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Patrick Bakenecker, Tobias Weingarten, Daniel Hahn, Brent Raiteri

• Little is known about how muscle length affects residual force enhancement (rFE) in humans. We therefore investigated rFE at short, long, and very long muscle lengths within the human quadriceps and patellar tendon (PT) using conventional dynamometry with motion capture (\(rFE_{TQ}\)) and a new, non-invasive shear-wave tensiometry technique (\(rFE_{WS}\)). Eleven healthy male participants performed submaximal (50% max.) EMG-matched fixed-end reference and stretch-hold contractions across these muscle lengths while muscle fascicle length changes of the vastus lateralis (VL) were captured using B-mode ultrasound. We found significant \(rFE_{TQ}\) at long (7\(\pm\)5%) and very long (12\(\pm\)8%), but not short (2\(\pm\)5%) muscle lengths, whereas \(rFE_{WS}\) was only significant at the very long (38\(\pm\)27%), but not short (8\(\pm\)12%) or long (6\(\pm\)10%) muscle lengths. We also found significant relationships between VL fascicle length and \(rFE_{TQ}\) (r=0.63, p=0.001) and \(rFE_{WS}\) (r=0.52, p=0.017), but relationships were not significant between VL fascicle stretch amplitude and \(rFE_{TQ}\)(r=0.33, p=0.126) or \(rFE_{WS}\) (r=0.29, p=0.201). Squared PT shear-wave-speed-angle relationships did not agree with estimated PT force-angle relationships, which indicates that estimating PT loads from shear-wave tensiometry might be inaccurate. We conclude that increasing muscle length rather than stretch amplitude contributes more to rFE during submaximal voluntary contractions of the human quadriceps.