Differential changes in muscle architecture and neuromuscular fatigability induced by isometric resistance training at short and long muscle-tendon unit lengths

Abstract: Eight weeks of isometric training at a long or short muscle-tendon unit length increased and did not change fascicle length, respectively. The “width” of the torque-angle relationship plateau became broader following isometric training at the long length. Despite marked differences in muscle architecture and functional adaptations between the groups, there was only a small-magnitude improvement in neuromuscular fatigue resistance, which was surprisingly negatively related to increased fascicle length in the lo… Show more

“…Lichtwark et al 47 determined a positive relationship between passive tibialis anterior fascicle length and sarcomere length; 2.64 µm is the average optimal sarcomere length 48 ; and 15° PF is close to the average optimal angle for dorsiflexion force production. 49 Based on these characteristics, the fascicle length adaptations (measured at 15° PF) in our study equated to a serial sarcomere number decrease of ~871 (28,955) following short-MTU training and an increase of ~947 (27,220) following long-MTU training. Serial sarcomere number changes of this magnitude may not have been pronounced enough to produce observable functional consequences in vivo, thereby not changing rFD or rFE.…”

“…To date, no study has examined the modifiability of the history dependence of force through a training program longer than 4 weeks in duration or with isometric resistance training as the model to promote fascicle length adaptations. Furthermore, only one study 28 has employed the MTU length-specific isometric training model on the tibialis anterior to investigate muscle architectural adaptations. The data reported in the present study are part of that same larger training study, 28 with participants and muscle architecture data duplicated across publications.…”

“…Furthermore, only one study 28 has employed the MTU length-specific isometric training model on the tibialis anterior to investigate muscle architectural adaptations. The data reported in the present study are part of that same larger training study, 28 with participants and muscle architecture data duplicated across publications. Therefore, the purposes of our study were to: (a) investigate how rFD and rFE are modified following 8 weeks of short-vs long-MTU training; and (b) investigate how tibialis anterior fascicle length adaptations to MTU length-specific isometric dorsiflexion training influence rFD and rFE.…”

Influence of isometric training at short and long muscle‐tendon unit lengths on the history dependence of force

“…Lichtwark et al 47 determined a positive relationship between passive tibialis anterior fascicle length and sarcomere length; 2.64 µm is the average optimal sarcomere length 48 ; and 15° PF is close to the average optimal angle for dorsiflexion force production. 49 Based on these characteristics, the fascicle length adaptations (measured at 15° PF) in our study equated to a serial sarcomere number decrease of ~871 (28,955) following short-MTU training and an increase of ~947 (27,220) following long-MTU training. Serial sarcomere number changes of this magnitude may not have been pronounced enough to produce observable functional consequences in vivo, thereby not changing rFD or rFE.…”

“…To date, no study has examined the modifiability of the history dependence of force through a training program longer than 4 weeks in duration or with isometric resistance training as the model to promote fascicle length adaptations. Furthermore, only one study 28 has employed the MTU length-specific isometric training model on the tibialis anterior to investigate muscle architectural adaptations. The data reported in the present study are part of that same larger training study, 28 with participants and muscle architecture data duplicated across publications.…”

“…Furthermore, only one study 28 has employed the MTU length-specific isometric training model on the tibialis anterior to investigate muscle architectural adaptations. The data reported in the present study are part of that same larger training study, 28 with participants and muscle architecture data duplicated across publications. Therefore, the purposes of our study were to: (a) investigate how rFD and rFE are modified following 8 weeks of short-vs long-MTU training; and (b) investigate how tibialis anterior fascicle length adaptations to MTU length-specific isometric dorsiflexion training influence rFD and rFE.…”

Influence of isometric training at short and long muscle‐tendon unit lengths on the history dependence of force

“…1 ). Some studies ( 11 – 13 ) reported that training-induced muscle hypertrophy was greater when trained at long versus short muscle lengths, but others ( 14 – 16 ) did not find a statistically significant difference. This discrepancy seems at least partly due to relatively small sample sizes ( n = 8–13 per condition) ( 11 – 16 ) and/or short intervention periods (6–8 wk) ( 11 – 14 , 16 ) of these studies.…”

“…Some studies ( 11 – 13 ) reported that training-induced muscle hypertrophy was greater when trained at long versus short muscle lengths, but others ( 14 – 16 ) did not find a statistically significant difference. This discrepancy seems at least partly due to relatively small sample sizes ( n = 8–13 per condition) ( 11 – 16 ) and/or short intervention periods (6–8 wk) ( 11 – 14 , 16 ) of these studies. Importantly, the previous studies all adopted isometric ( 11 , 12 , 14 , 15 ) or partial range of motion ( 13 , 16 ) training at different joint angles about the same joint to compare long versus short muscle length conditions (e.g., knee flexed vs extended positions to train the quadriceps).…”

Greater Hamstrings Muscle Hypertrophy but Similar Damage Protection after Training at Long versus Short Muscle Lengths

Effects of 4-weeks of elastic variable resistance training on the electrochemical and mechanical components of voluntary electromechanical delay durations