Sensorimotor Recovery, Functional and Structural Brain Plasticity, and the Development of Chronic Pain Following Upper Limb Peripheral Nerve Transection and Microsurgical Repair

• Main Author: Taylor, Keri S.
• Other Authors: Davis, Karen
• Language: en_ca
• Published: 2010
• Subjects: peripheral nerve injury; plasticity; functional MRI; diffusion tensor imaging; cortical thickness analysis; psychophysics; chronic neuropathic pain; 0317
• Online Access: http://hdl.handle.net/1807/26519

Following peripheral nerve transection and microsurgical repair (PNIr) most patients retain significant sensorimotor impairments, a proportion of which also develop chronic neuropathic pain. Individual psychological factors may contribute to the development, intensity and duration of chronic pain. Furthermore, a large body of evidence has indentified beneficial and maladaptive cortical plasticity following disease or injury. The general aim of this thesis was to determine the extent of sensory and motor recovery, functional and structural brain changes, and the impact of chronic neuropathic pain on sensorimotor outcomes following upper limb PNIr. Towards this main aim a sensorimotor psychophysical assessment (that included psychological assessments), nerve conduction testing, and an MRI session that examined brain function and structure was performed in patients with peripipheral nerve injury induced neuropathic pain (PNI-P) and those with no neuropathic pain (PNI-NP). Nerve conduction testing demonstrated that all patients had incomplete peripheral nerve regeneration, and that PNI-P patients had worse sensory nerve regeneration. Psychophysical assessment confirmed that all PNIr patients had significant sensorimotor deficits. Additionally, deficits on tests of vibration detection, sensorimotor integration, and fine dexterity were significantly greater in PNI-P patients. Psychological measures clearly distinguished PNI-P from PNI-NP and healthy controls (HC). Vibrotactile stimulation of the deafferented territory in PNI-NP patients results in reduced BOLD activation within the primary and secondary somatosensory cortices. Interestingly, the regions of reduced BOLD corresponded with gray matter thinning which was negatively correlated with behavioural measures of sensory recovery. Structural abnormalities were also identified in the right insula. PNI-P patients had thinning within the right middle insula and a corresponding decrease in white matter pathways projecting into/out of that region. PNI-P patients also had white matter abnormalities in pathways feeding into/out of the contralesional primary somatosensory cortex and thalamus. In conclusion, PNIr is clearly associated with sensorimotor impairments and brain plasticity. Furthermore, neuropathic pain is associated with worse peripheral nerve regeneration, sensorimotor deficits, different psychological profiles, and structural alterations in brain regions involved in pain perception and somatosensation. These results provide insight into peripheral regeneration, the development of chronic pain, brain plasticity and structure-function-behavioural relationships following nerve injury and have important therapeutic implications.