Annals of Clinical and Translational Neurology (Sep 2024)

Corticospinal premotor fibers facilitate complex motor control after stroke

  • Theresa Paul,
  • Matthew Cieslak,
  • Lukas Hensel,
  • Valerie M. Wiemer,
  • Caroline Tscherpel,
  • Christian Grefkes,
  • Scott T. Grafton,
  • Gereon R. Fink,
  • Lukas J. Volz

DOI
https://doi.org/10.1002/acn3.52159
Journal volume & issue
Vol. 11, no. 9
pp. 2439 – 2449

Abstract

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Abstract Objective The corticospinal tract (CST) is considered the most important motor output pathway comprising fibers from the primary motor cortex (M1) and various premotor areas. Damage to its descending fibers after stroke commonly leads to motor impairment. While premotor areas are thought to critically support motor recovery after stroke, the functional role of their corticospinal output for different aspects of post‐stroke motor control remains poorly understood. Methods We assessed the differential role of CST fibers originating from premotor areas and M1 in the control of basal (single‐joint muscle synergies and strength) and complex motor control (involving inter‐joint coordination and visuomotor integration) using a novel diffusion imaging approach in chronic stroke patients. Results While M1 sub‐tract anisotropy was positively correlated with basal and complex motor skills, anisotropy of PMd, PMv, and SMA sub‐tracts was exclusively associated with complex motor tasks. Interestingly, patients featuring persistent motor deficits showed an additional positive association between premotor sub‐tract integrity and basal motor control. Interpretation While descending M1 output seems to be a prerequisite for any form of upper limb movements, complex motor skills critically depend on output from premotor areas after stroke. The additional involvement of premotor tracts in basal motor control in patients with persistent deficits emphasizes their compensatory capacity in post‐stroke motor control. In summary, our findings highlight the pivotal role of descending corticospinal output from premotor areas for motor control after stroke, which thus serve as prime candidates for future interventions to amplify motor recovery.