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Hälsa & medicin 3.3

Brain rewires after knee injury, forcing stronger reliance on vision

ACL reconstruction patients show altered brain activity during balance tasks, with their brains working harder to process visual information to compensate for proprioceptive loss. The finding could improve rehabilitation protocols and reduce long-term disability risk—a significant cost driver for insurers, employers, and sports medicine providers managing post-injury recovery.

Originaltitel: Visual information modulates brain network characteristics during static balance following ACL reconstruction: a graph theoretical analysis

Abstrakt

<p>Long-term balance impairments are prevalent after anterior cruciate ligament (ACL) injury and are possibly linked to an overreliance on visual information and related cortical processing. We therefore aimed to explore characteristics of functional brain networks related to postural control with and without vision following ACL reconstruction (ACLR). Twenty-seven individuals after ACLR and 24 non-injured controls performed single-leg balance tasks under eyes-open/eyes-closed conditions. Graph-theoretical measures of functional network segregation (clustering coefficient, CC) and integration (path length, PL) were derived from mobile electroencephalography. Sway characteristics were calculated based on centre of pressure (CoP; area and velocity) and the mean distance between CoP and centre of mass (CoM). Knee antero-posterior kinematics were also explored. Group effects were analysed using permutation-based ANCOVA. During eyes-open only, the ACLR group exhibited greater cortical network segregation (higher CC; p = 0.025) in the alpha-1 band (8–10 Hz). While sway characteristics were similar between groups, the ACLR leg demonstrated greater knee flexion compared to their contralateral leg (p = 0.036). Individuals post-ACLR showed more efficient functional brain connectivity during eyes-open, combined with kinematic adaptations in their injured leg. These findings suggest post-ACLR neural adaptations of postural control mechanisms, particularly when visual information is available.</p>

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