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1. Microstructure, mineral and mechanical properties of teleost intermuscular bones

   https://doi.org/10.1016/j.jbiomech.2019.07.009  

   Fiedler, I.A.K.; Zeveleva, S.; Duarte, A.; Zhao, X.; Depalle, B.; Cardoso, L.; Jin, S.; Berteau, J.P. (September 2019, Journal of Biomechanics)
2. Electro-tactile modulation of muscle activation and intermuscular coordination in the human upper extremity

   https://doi.org/10.1038/s41598-025-86342-y  

   Doan, Hy; Tavasoli, Shahabedin; Seo, Gang; Park, Hyung-Soon; Park, Hangue; Roh, Jinsook (January 2025, Scientific Reports)
3. Task-dependent alteration of beta-band intermuscular coherence is associated with ipsilateral corticospinal tract excitability

   https://doi.org/10.3389/fspor.2023.1177004  

   Ko, Na-hyeon; Laine, Christopher M; Valero-Cuevas, Francisco J (July 2023, Frontiers in Sports and Active Living)

   Beta-band (15–30 Hz) synchronization between the EMG signals of active limb muscles can serve as a non-invasive assay of corticospinal tract integrity. Tasks engaging a single limb often primarily utilize one corticospinal pathway, although bilateral neural circuits can participate in goal-directed actions involving multi-muscle coordination and utilization of feedback. Suboptimal utilization of such circuits after CNS injury can result in unintended mirror movements and activation of pathological synergies. Accordingly, it is important to understand how the actions of one limb (e.g., a less-affected limb after strokes) influence the opposite corticospinal pathway for the rehabilitation target. Certain unimanual actions decrease the excitability of the “unengaged” corticospinal tract, presumably to prevent mirror movement, but there is no direct way to predict the extent to which this will occur. In this study, we tested the hypothesis that task-dependent changes in beta-band drives to muscles of one hand will inversely correlate with changes in the opposite corticospinal tract excitability. Ten participants completed spring pinching tasks known to induce differential 15–30 Hz drive to muscles. During compressions, transcranial magnetic stimulation single pulses to the ipsilateral M1 were delivered to generate motor-evoked potentials in the unengaged hand. The task-induced changes in ipsilateral corticospinal excitability were inversely correlated with associated changes in EMG-EMG coherence of the task hand. These results demonstrate a novel connection between intermuscular coherence and the excitability of the “unengaged” corticospinal tract and provide a springboard for further mechanistic studies of unimanual tasks of varying difficulty and their effects on neural pathways relevant to rehabilitation. 

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4. Developing new intermuscular coordination patterns through an electromyographic signal-guided training in the upper extremity

   https://doi.org/10.1186/s12984-023-01236-2  

   Seo, Gang; Park, Jeong-Ho; Park, Hyung-Soon; Roh, Jinsook (December 2023, Journal of NeuroEngineering and Rehabilitation)

   Abstract BackgroundMuscle synergies, computationally identified intermuscular coordination patterns, have been utilized to characterize neuromuscular control and learning in humans. However, it is unclear whether it is possible to alter the existing muscle synergies or develop new ones in an intended way through a relatively short-term motor exercise in adulthood. This study aimed to test the feasibility of expanding the repertoire of intermuscular coordination patterns through an isometric, electromyographic (EMG) signal-guided exercise in the upper extremity (UE) of neurologically intact individuals. Methods10 participants were trained for six weeks to induce independent control of activating a pair of elbow flexor muscles that tended to be naturally co-activated in force generation. An untrained isometric force generation task was performed to assess the effect of the training on the intermuscular coordination of the trained UE. We applied a non-negative matrix factorization on the EMG signals recorded from 12 major UE muscles during the assessment to identify the muscle synergies. In addition, the performance of training tasks and the characteristics of individual muscles’ activity in both time and frequency domains were quantified as the training outcomes. ResultsTypically, in two weeks of the training, participants could use newly developed muscle synergies when requested to perform new, untrained motor tasks by activating their UE muscles in the trained way. Meanwhile, their habitually expressed muscle synergies, the synergistic muscle activation groups that were used before the training, were conserved throughout the entire training period. The number of muscle synergies activated for the task performance remained the same. As the new muscle synergies were developed, the neuromotor control of the trained muscles reflected in the metrics, such as the ratio between the targeted muscles, number of matched targets, and task completion time, was improved. ConclusionThese findings suggest that our protocol can increase the repertoire of readily available muscle synergies and improve motor control by developing the activation of new muscle coordination patterns in healthy adults within a relatively short period. Furthermore, the study shows the potential of the isometric EMG-guided protocol as a neurorehabilitation tool for aiming motor deficits induced by abnormal intermuscular coordination after neurological disorders. Trial registrationThis study was registered at the Clinical Research Information Service (CRiS) of the Korea National Institute of Health (KCT0005803) on 1/22/2021. 

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5. Improving impaired intermuscular coordination after stroke through synergy-guided human-machine interaction: a pilot study

   https://doi.org/10.1109/EMBC53108.2024.10782001  

   Portilla-Jiménez, Manuel; Seo, Gang; Houston, Michael; Hong, Yoon_No Gregory; Li, Sheng; Park, Hyung-Soon; Zhang, Yingchun; Roh, Jinsook (July 2024, IEEE)