In this work, functional changes in the sensorimotor cortex following unilateral hand immobilisation were investigated in 11 healthy volunteers. Sensory and motor function of both hands was also assessed. Cortical activation was monitored with functional magnetic resonance imaging at 3 T. All examinations were performed prior to and directly after 72 h of immobilisation of the dominant hand and wrist. Following unilateral immobilisation, cortical activation increased substantially during tactile stimulation of the non-immobilised hand. This was particularly evident in the ipsilateral somatosensory cortex. Additionally, a redistribution of hemispheric dominance towards zero lateralisation was seen. A bilateral cortical activation increase was also seen during performance of a finger-tapping task by the non-immobilised hand, although this increase was less prominent than during tactile stimulation. In contrast, performance of the finger-tapping task with the immobilised hand resulted in an activation decrease, predominantly in the ipsilateral sensorimotor cortex. This site was anatomically close to the regional activation increase of the non-immobilised hand. These functional changes were associated with reduced grip strength, dexterity and tactile discrimination of the immobilised hand, and simultaneously improved tactile discrimination of the non-immobilised hand. This suggests that brain adaptation following hand immobilisation includes inter-hemispheric dynamics. In summary, the improved sensory function of the non-immobilised hand following unilateral immobilisation is associated with cortical expansion, predominantly contralateral to the immobilised hand, and a redistribution of hemispheric dominance. Both cortical and clinical effects of immobilisation were identified after 72 h, suggesting rapid inter-hemispheric plasticity using existing neural substrates.
BackgroundCarpal tunnel syndrome (CTS) is the most common compression neuropathy, but there is no gold standard for establishing the diagnosis. The ability to feel vibrations in the fingertips is dependent on the function in cutaneous receptors and afferent nerves. Our aim was to investigate vibration perception thresholds (VPTs) in patients with CTS using multi-frequency vibrometry.MethodsSixty-six patients (16 men and 50 women) with CTS, diagnosed from clinical signs and by electroneurography, and 66 matched healthy controls were investigated with multi-frequency vibrometry. The VPTs were assessed at seven frequencies (8, 16, 32, 64, 125, 250, and 500 Hz) in the index finger and little finger bilaterally. The severity of the CTS was graded according to Padua and the patient’s subjective symptoms were graded according to the Boston carpal tunnel questionnaire. Touch thresholds were assessed using the Semmes-Weinstein monofilaments.ResultsPatients with CTS had significantly higher VPTs at all frequencies in the index finger and in 6 out of 7 frequencies in the little finger compared to the controls. However, the VPT was not worse in patients with more severe CTS. Patients with unilateral CTS showed significantly higher VPTs in the affected hand. There were no correlations between VPTs and electrophysiological parameters, subjective symptoms, or touch threshold.ConclusionsPatients with CTS had impaired VPTs at all frequencies compared to the controls. Since the VPTs are dependent on function in peripheral receptors and their afferent nerves, multi-frequency vibrometry could possibly lead to diagnosis of CTS.
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