Constant illumination causes spatially discrete dopamine depletion in the normal and degenerate retina.

A fully competent retinal dopamine system underpins normal visual function. Although this system is known to be compromised both prior to and during retinal degeneration, the spatial dynamics of dopamine turnover within the degenerate retina are at present unknown. Here, using immunohistochemistry for dopamine in combination with quantitative optical density measurements, we reveal a global decline in retinal dopamine levels in the light adapted RCS dystrophic rat, which is restricted to plexiform layers in the dark. Pharmacological blockade of dopamine production with the drug alpha-methyl-p-tyrosine (AMPT) allows the direct visualisation of dopamine depletion in normal and degenerate retina in response to constant illumination. In normal retinae this effect is spatially discrete, being undetectable in perikarya and specific to amacrine cell fibres in sublamina 1 of the inner plexiform layer. A similar response was observed in the retinae of dystrophic rats but with a reduction in amplitude of approximately 50%. It is suggested that the pattern of dopamine depletion observed in rat retina may reflect an AMPT-resistant pool of perikaryal dopamine and/or a reduction in extrasynaptic release of this neurotransmitter in response to illumination in vivo. We conclude that the visualisation of dopamine depletion reported here represents a release of this neurotransmitter in the response to light. Turnover of dopamine in the dystrophic retina is discussed in the context of surviving photoreceptors, including the intrinsically photosensitive melanopsin ganglion cells of the inner retina.

Integration of neural responses originating from different regions of the cortical somatosensory map.

The neural pathways responsible for detecting peripheral tactile stimuli are well known; however, the interactions between different somatosensory regions have been less well investigated. This study demonstrates how the contralateral sensory response of rat barrel cortex to whisker stimulation is affected by stimulation of contralateral forepaw and ipsilateral whisker and forepaw. The barrel cortex in the right hemisphere was located using optical imaging. A 16-channel multielectrode was used to measure field potentials evoked by contralateral electrical stimulation of the whisker pad. A standard response in the right barrel cortex to single pulse electrical stimulation of the contralateral whisker pad was modulated by applying conditioning stimulation to one of three other regions of the body (the ipsilateral whisker pad, the ipsilateral or contralateral forepaws). In conditions where the standard contralateral whisker stimulus preceded the conditioning pulse, the size of response was identical to when it was stimulated alone. However, when the ipsilateral whisker and contralateral forepaw conditioning stimuli preceded the contralateral whisker pad stimulation, up to a 35% reduction in the contralateral whisker response was observed. These results confirm and extend previous studies [Proc. Natl. Acad. Sci. U. S. A. 97 (2000) 11026-11031; J. Neurosci. 21 (2001) 5251-5261], which show bilateral integration of neural activity within the rat somatosensory system. Furthermore, the longer latency of the inhibition following stimulation of the contralateral forepaw suggests the possible involvement of extracortical circuitry.

Retinotopy within rat primary visual cortex using optical imaging.

The purpose of this study was to determine the retinotopic organization of rat primary visual cortex (area 17) using optical imaging technology. Stimulating discrete regions of visual space resulted in localised changes in the remitted light during optical imaging of visual cortex in rat. From these localised changes, our results confirm previous electrophysiological studies on the location, size and organization of rat primary visual cortex. Small differences in the cortical magnification factor (CMF) were found between visual field areas with the highest CMF confined to the upper nasal region. No significant CMF differences were found within the horizontal and vertical visual field axes. No secondary visual areas were activated either anterior or medial to area 17 with the pattern stimuli used in the current study. However, there was evidence of activity to upper nasal stimulation on the posterior lateral extrastriate area. The location of area 17 from optical imaging activity was confirmed anatomically using conventional immunohistochemical techniques. This study shows the retinotopic organization of rat primary visual cortex and serves as a precursor before examining animal models of retinal degeneration and the effectiveness of potential therapies to stem retinal disease.