Corticospinal recruitment of spinal motor neurons in human stroke survivors

Key points Muscle weakness after stroke results from damage to corticospinal fibres that structurally and functionally connect cerebral cortex to the spinal cord. Here, we show an asymmetry in corticospinal recruitment of spinal motor neurons that is linked to maximal voluntary output of hand muscle...

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Bibliographic Details
Published in:The Journal of physiology 2021-09, Vol.599 (18), p.4357-4373
Main Authors: Urbin, Michael A., Collinger, Jennifer L., Wittenberg, George F.
Format: Article
Language:English
Subjects:
Asymmetry
Cortex (motor)
corticospinal tract
Electrical stimuli
Latency
Motor evoked potentials
Motor neurons
Motor task performance
Muscles
Neural networks
Neuromodulation
Neurons
Pyramidal tracts
spike timing‐dependent plasticity
Spinal cord
Stroke
stroke hemiparesis
α‐motor neurons
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Summary:Key points Muscle weakness after stroke results from damage to corticospinal fibres that structurally and functionally connect cerebral cortex to the spinal cord. Here, we show an asymmetry in corticospinal recruitment of spinal motor neurons that is linked to maximal voluntary output of hand muscles weakened by stroke. Spike timing‐dependent plasticity of synapses between corticospinal and spinal motor neurons transiently reversed recruitment failures in some survivors. These modulatory effects were strongly associated with recruitment asymmetry and hand impairment. Our findings highlight the functional relevance of spinal motor neuron recruitment by corticospinal inputs and the viability of corticospinal motor neuronal synapses for restoring activation of lower motor neurons after stroke. Corticospinal input to spinal motor neurons is structurally and functionally altered by hemiparetic stroke. The pattern and extent to which corticospinal recruitment of spinal motor neurons is reorganized and whether such changes are linked to the severity of motor impairments is not well understood. Here, we performed experiments using the triple stimulation technique to quantify corticospinal recruitment of spinal motor neurons serving paretic and non‐paretic intrinsic hand muscles of humans with longstanding motor impairment secondary to stroke (n = 13). We also examined whether recruitment failures could be transiently reversed by strengthening corticospinal–motoneuronal synaptic connectivity via targeted, temporally controlled non‐invasive stimulation to elicit spike timing‐dependent plasticity (STDP). Asymmetries were detected in corticospinal recruitment of spinal motor neurons, central conduction time and motor‐evoked potential (MEP) latency. However, only recruitment asymmetry correlated with maximal voluntary motor output from the paretic hand. STDP‐like effects were observed as an increase in spinal motor neuron recruitment. Control experiments to isolate the locus of plasticity demonstrated a modulation in MEPs elicited by electrical stimulation of primary motor cortex but not F‐wave size or persistence, suggesting that plasticity was mediated through enhanced efficacy of residual corticospinal–motor neuronal synapses. The modulation in recruitment was strongly associated with baseline recruitment asymmetry and impairment severity. Our findings demonstrate that asymmetry in corticospinal recruitment of spinal motor neurons is directly related to impairments
ISSN:0022-3751
1469-7793
DOI:10.1113/JP281311