Modulation of SI and ACC response to noxious and non-noxious electrical stimuli after the spared nerve injury model of neuropathic pain.

BACKGROUND: The current knowledge on the role of SI and ACC in acute pain processing and how these contribute to the development of chronic pain is limited. Our objective was to investigate differences in and modulation of intracortical responses from SI and ACC in response to different intensities of peripheral presumed noxious and non-noxious stimuli in the acute time frame of a peripheral nerve injury in rats. METHODS: We applied non-noxious and noxious electrical stimulation pulses through a cuff electrode placed around the sciatic nerve and measured the cortical responses (six electrodes in each cortical area) before and after the spared nerve injury model. RESULTS: We found that the peak response correlated with the stimulation intensity and that SI and ACC differed in both amplitude and latency of cortical response. The cortical response to both noxious and non-noxious stimulation showed a trend towards faster processing of non-noxious stimuli in ACC and increased cortical processing of non-noxious stimuli in SI after SNI. CONCLUSIONS: We found different responses in SI and ACC to different intensity electrical stimulations based on two features and changes in these features following peripheral nerve injury. We believe that these features may be able to assist to track cortical changes during the chronification of pain in future animal studies. SIGNIFICANCE: This study showed distinct cortical processing of noxious and non-noxious peripheral stimuli in SI and ACC. The processing latency in ACC and accumulated spiking activity in SI appeared to be modulated by peripheral nerve injury, which elaborated on the function of these two areas in the processing of nociception.

Modulation of dopaminergic neuronal differentiation from sympathoadrenal progenitors.

The capacity of sympathoadrenal progenitors from adrenal medulla to generate dopaminergic neurons in vitro makes them an attractive source for replacement therapies of neurodegenerative diseases such as Parkinson's disease. Dopaminergic cells constitute one percent of the adult adrenal medulla only. Thus, isolation of sympathoadrenal progenitors and enhancement of their capacity to derive dopaminergic neurons is a strategy to be considered. Here, we summarize data on the characterization and isolation of sympathoadrenal progenitors from adult adrenal medulla capable to give rise to functional dopaminergic neurons, in vitro. Pretransplantation treatment of these cells with pharmacological means is an important prerequisite to improve dopaminergic differentiation and efficient engraftment of sympathoadrenal progenitors. Treatment of these cells with retinoic and ascorbic acids significantly increased dopamine secretion from derived neurons. Furthermore, inhibition of Notch signaling activated molecular mechanisms involved in the determination of dopaminergic neuronal subtype. Taken together, somatic adrenomedullary sympathoadrenal progenitor cells are a valid cell source for replacement therapies with a high potential for dopaminergic neuronal differentiation.