We used PET to examine the pattern and time course of changes produced by repetitive transcranial magnetic stimulation (rTMS) over the dorsal premotor cortex (PMd) in healthy subjects and in patients with primary focal dystonia. Subjects received 1800 stimuli of subthreshold 1 Hz rTMS or sham stimulation to the left PMd. Afterwards, we measured regional cerebral blood flow (rCBF) as a marker of synaptic activity at rest and during performance of freely selected random finger movement. In both groups of subjects, real rTMS caused widespread bilateral decreases in neuronal activity in prefrontal, premotor, primary motor cortex, and left putamen. Conversely, rCBF in the cerebellum increased. Effects were equivalent at rest and during movement, indicating that the pattern of movement-related activation did not change. rTMS-induced changes in neuronal activity lasted for at least 1 h except in the medial aspect of the left globus pallidus. Conditioning effects on neuronal activity were larger in the patients than in the healthy subjects: there was a greater decrease of rCBF in lateral and medial premotor areas, putamen, and thalamus, including the stimulated premotor cortex, and a larger increase in cerebellar rCBF. Our findings indicate that, in healthy subjects and patients with dystonia, a single session of rTMS can produce powerful and widespread changes in regional synaptic activity as indexed by rCBF. Since the greater effects of premotor rTMS were not related to any differences in task performance, increased responsiveness of the motor system to rTMS reveals a physiological trait that characterizes patients with focal arm dystonia.
Cognitive impairment (CI) can develop during the course of ageing and is a feature of many neurological and neurodegenerative diseases. Many individuals with CI have substantial, sustained, and complex health care needs, which frequently include pain. However, individuals with CI can have difficulty communicating the features of their pain to others, which in turn presents a significant challenge for effective diagnosis and treatment of their pain. Herein, we review the literature on responsivity of individuals with CI to experimental pain stimuli. We discuss pain responding across a large number of neurological and neurodegenerative disorders in which CI is typically present. Overall, the existing data suggest that pain processing is altered in most individuals with CI compared with cognitively intact matched controls. The precise nature of these alterations varies with the type of CI (or associated clinical condition) and may also depend on the type of pain stimulation used and the type of pain responses assessed. Nevertheless, it is clear that regardless of the etiology of CI, patients do feel noxious stimuli, with more evidence for hypersensitivity than hyposensitivity to these stimuli compared with cognitively unimpaired individuals. Our current understanding of the neurobiological mechanisms underpinning these alterations is limited but may be enhanced through the use of animal models of CI, which also exhibit alterations in nociceptive responding. Further research using additional behavioural indices of pain is warranted. Increased understanding of altered experimental pain processing in CI will facilitate the development of improved diagnostic and therapeutic approaches for pain in individuals with CI.
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