AI Article Synopsis

  • Movements are controlled by motoneurons that convert synaptic signals into activation signals for muscles, with the interactions between different input types varying across motoneuron pools and muscles.
  • The study analyzed motor unit activity in the tibialis anterior and vastus lateralis muscles during isometric contractions, examining how firing rates related to the force applied up to 80% of maximal strength.
  • Results revealed that motor unit firing rates increase in a non-linear manner that varies among motor unit types, indicating that motor pools use gain control to translate limited input variations into desired muscle force outputs.

Article Abstract

Movements are performed by motoneurons transforming synaptic inputs into an activation signal that controls muscle force. The control signal emerges from interactions between ionotropic and neuromodulatory inputs to motoneurons. Critically, these interactions vary across motoneuron pools and differ between muscles. To provide the most comprehensive framework to date of motor unit activity during isometric contractions, we identified the firing activity of extensive samples of motor units in the tibialis anterior (129 ± 44 per participant; n=8) and the vastus lateralis (130 ± 63 per participant; n=8) muscles during isometric contractions of up to 80% of maximal force. From this unique dataset, the rate coding of each motor unit was characterised as the relation between its instantaneous firing rate and the applied force, with the assumption that the linear increase in isometric force reflects a proportional increase in the net synaptic excitatory inputs received by the motoneuron. This relation was characterised with a natural logarithm function that comprised two stages. The initial stage was marked by a steep acceleration of firing rate, which was greater for low- than medium- and high-threshold motor units. The second stage comprised a linear increase in firing rate, which was greater for high- than medium- and low-threshold motor units. Changes in firing rate were largely non-linear during the ramp-up and ramp-down phases of the task, but with significant prolonged firing activity only evident for medium-threshold motor units. Contrary to what is usually assumed, our results demonstrate that the firing rate of each motor unit can follow a large variety of trends with force across the pool. From a neural control perspective, these findings indicate how motor unit pools use gain control to transform inputs with limited bandwidths into an intended muscle force.

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http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11627553PMC
http://dx.doi.org/10.7554/eLife.97085DOI Listing

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