Abstract
PurposeForce enhancement is the phenomenon of increased forces during (transient force enhancement; tFE) and after (residual force enhancement; rFE) eccentric muscle actions compared with fixed-end contractions. Although tFE and rFE have been observed at short and long muscle lengths, whether both are length-dependent remains unclear in vivo.MethodsWe determined maximal-effort vastus lateralis (VL) force-angle relationships of eleven healthy males and selected one knee joint angle at a short and long muscle lengths where VL produced approximately the same force (85% of maximum). We then examined tFE and rFE at these two lengths during and following the same amount of knee joint rotation.ResultsWe found tFE at both short (11.7%, P = 0.017) and long (15.2%, P = 0.001) muscle lengths. rFE was only observed at the long (10.6%, P < 0.001; short: 1.3%, P = 0.439) muscle length. Ultrasound imaging revealed that VL muscle fascicle stretch magnitude was greater at long compared with short muscle lengths (mean difference: (tFE) 1.7 mm, (rFE) 1.9 mm, P ≤ 0.046), despite similar isometric VL forces across lengths (P ≥ 0.923). Greater fascicle stretch magnitude was likely to be due to greater preload forces at the long compared with short muscle length (P ≤ 0.001).ConclusionAt a similar isometric VL force capacity, tFE was not muscle-length-dependent at the lengths we tested, whereas rFE was greater at longer muscle length. We speculate that the in vivo mechanical factors affecting tFE and rFE are different and that greater stretch of a passive component is likely contributing more to rFE at longer muscle lengths.
Highlights
Communicated by Olivier Seynnes.Electronic supplementary material The online version of this article contains supplementary material, which is available to authorized users.Eccentric muscle actions are important for absorbing kinetic energy and the underlying mechanisms contributing to their unique properties have been frequently examined under in vitro conditions
We found that vastus lateralis (VL) force during stretch contractions was significantly larger than the time-matched VL force during fixed-end contractions at both short and long muscle lengths and that there was no significant difference in transient force enhancement (tFE) between muscle lengths
This is supported by our data as we found that preload forces account for 26% of the variance in VL fascicle stretch magnitudes across muscle lengths, with greater preloads increasing the amount of fascicle stretch, presumably by reducing muscle–tendon unit (MTU) compliance and reducing the tendinous tissues’ ability to buffer active muscle lengthening during MTU lengthening (Konow and Roberts 2015)
Summary
Eccentric muscle actions are important for absorbing kinetic energy and the underlying mechanisms contributing to their unique properties have been frequently examined under in vitro conditions. One unique property is that during and following an eccentric muscle action, a muscle can produce enhanced force relative to its isometric force at the same muscle length and activation level (Edman et al 1978; Cook and McDonagh 1995). Enhanced forces during and following an eccentric muscle action are referred to as transient force enhancement (tFE) and residual force enhancement (rFE), respectively.
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