Abstract
Classical rate-based pathway models are invaluable for conceptualizing direct/indirect basal ganglia pathways, but cannot account for many aspects of normal and abnormal motor control. To better understand the contribution of patterned basal ganglia signaling to normal and pathological motor control, we simultaneously recorded multi-neuronal and EMG activity in normal and dystonic rats. We used the jaundiced Gunn rat model of kernicterus as our experimental model of dystonia. Stainless steel head fixtures were implanted on the skulls and EMG wires were inserted into antagonistic hip muscles in nine dystonic and nine control rats. Under awake, head-restrained conditions, neuronal activity was collected from up to three microelectrodes inserted in the principal motor regions of the globus pallidus (GP), subthalamic nucleus, and entopeduncular nucleus (EP). In normal animals, most neurons discharged in regular or irregular patterns, without appreciable bursting. In contrast, in dystonic animals, neurons discharged in slow bursty or irregular, less bursty patterns. In normal rats, a subset of neurons showed brief discharge bursts coinciding with individual agonist or antagonist EMG bursts. In contrast, in dystonics, movement related discharges were characterized by more prolonged bursts which persist over multiple dystonic co-contraction epics. The pattern of movement related decreases in discharge activity however did not differ in dystonics compared to controls. In severely dystonic rats, exclusively, simultaneously recorded units often showed abnormally synchronized movement related pauses in GP and bursts in EP. In conclusion, our findings support that slow, abnormally patterned neuronal signaling is a fundamental pathophysiological feature of intrinsic basal ganglia nuclei in dystonia. Moreover, from our findings, we suggest that excessive movement related silencing of neuronal signaling in GP profoundly disinhibits EP and in turn contributes to sustained, unfocused dystonic muscle contractions.
Highlights
Dystonia is a devastating condition characterized by ineffective, twisting movements and contorted postures
In Parkinson’s disease (PD) patients undergoing deep brain stimulator (DBS) surgery, intra-operative induction of dyskinesias was associated with alterations in phasic patterned neuronal activity in globus pallidus internus (GPi) without corresponding changes in the discharge rates (Lee et al, 2007)
In globus pallidus (GP), there was a significant shift toward more movement related decreases from increases in neuronal discharge activity in dystonic rats compared to controls
Summary
Dystonia is a devastating condition characterized by ineffective, twisting movements and contorted postures. Overall discharge rates in GPe (Bezard et al, 1999; Raz et al, 2000; Boraud et al, 2001), GPi (Bergman et al, 1994; Bezard et al, 1999; Wichmann and DeLong, 1999), and the thalamus (Pessiglione et al, 2005) are not clearly altered in primate models of PD While such models correctly predict that pallidotomy (GPi ablation) should ameliorate hypokinesia in PD patients (by disinhibiting thalamocortical activity), the models cannot likewise account for comparable surgical benefits of pallidotomy on medication-induced dyskinesias (excessive movements) in these patients (Lozano et al, 1995; Baron et al, 1996). Basal ganglia recordings in dystonia extensive neurophysiological recording studies in animals have been conducted in dtsz hamsters, which exhibit paroxysmal dystonia only in response to prolonged stress (Loscher et al, 1989; Richter and Loscher, 1993; Bhatia, 2001) Besides this limitation of the model, the neuronal recordings have been collected under general anesthesia, thereby altering the neuronal signals and not reflecting actual dystonic movements. Heterozygous non-jaundiced (Nj) rats have about 50% of the normal enzyme activity (Strebel and Odell, 1971) and remain phenotypically normal even after sulfa injection
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
